WO2012107529A1 - Combination of biomarkers for forecasting a response or non-response to an anti-hcv treatment - Google Patents

Abstract

The application relates to means for forecasting whether an individual infected with one or more HCVs has a strong probability of responding to an anti-HCV treatment that will comprise the administration of interferon and of ribavirin, or whether, on the contrary, this individual has a strong probability of not responding to this anti-HCV treatment. The means of the invention implement in particular the assay of the expression levels of selected genes, said selected genes being: - at least two genes among HERC5, IL8 and STAT2; and - at least one gene among CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IFI27, IFI35, IFI44, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2 and USP18.

Description

 TITLE

 Combination of biomarkers for the prognosis of a response or non-response to anti-HCV treatment

FIELD OF THE INVENTION

 The application relates to means which make it possible to establish a prognosis of high probability of response or non-response to anti-Hepatitis C Virus (HCV) treatment. Advantageously, the means of the invention make it possible to establish this prognosis before the anti-HCV treatment has even begun.

BACKGROUND OF THE INVENTION

 Hepatitis C virus (HCV) infection leads, in the vast majority of cases, to chronic hepatitis C. Chronic hepatitis C can progress to hepatic cirrhosis, with complications of portal hypertension, and to hepatocellular carcinoma. One of the goals of treatment for HCV infection, especially chronic hepatitis C, is to ensure that the tissue damage to the liver caused by the viral infection regresses or is eliminated, or at least they do not progress. This allows in particular to reduce or eliminate the risk of complications and hepatocellular carcinoma. The treatments currently available to meet this goal are treatments, which aim to eradicate the virus. These treatments must initially induce a significant decrease in HCV viral load, so that they can reach an undetectable level at the end of treatment. Current anti-HCV therapies include the administration of a combination of pegylated interferon and ribavirin. The duration of these treatments is long: they are generally administered over a period of at least 24 weeks and up to 48 weeks or more. However, anti-HCV treatments cause major side effects for the patient.

Regarding interferon, side effects are common and numerous. The most common side effect is flu-like symptoms (fever, arthralgia, headache, chills). Other possible side effects are: asthenia, weight loss, moderate hair loss, sleep disturbances, mood disorders with irritability that can affect daily life, difficulty concentrating and dryness skin. Some rare side effects can be serious and should be anticipated such as psychiatric disorders. A depression can occur in about 10% of cases. This one must be detected and treated because it can have serious consequences (attempted suicide). Dysthyroidism can occur. Interferon treatment is also contraindicated during pregnancy.

Regarding ribavirin, the main side effect is hemolytic anemia. Anemia leads to discontinuation of treatment in approximately 5% of cases. Decompensation of coronary heart disease or underlying cardiac disease related to anemia may occur. Neutropenia is observed in approximately 20% of patients receiving pegylated interferon and ribavirin, and is the major cause of reduced dose of pegylated interferon. The cost of these treatments is also very high.

Being able to predict whether or not a particular patient will respond to treatment, even before starting treatment with HCV, is of major clinical and economic importance.

 The search for such predictive means has led to the analysis of various clinical, biological and viral factors.

Patient-specific clinical factors, such as age, weight, ethnicity and liver fibrosis score, are known to influence the efficacy of anti-HCV therapy. For example, the rate of patients responding to anti-HCV treatment is lower among patients whose liver fibrosis score is F3 or F4, compared to those whose liver fibrosis score is Fl or F2 (scores according to the treatment system). F Metavir scores). These clinical factors alone do not predict reliably, before the start of treatment, whether or not a given patient will respond to anti-HCV treatment. In themselves, these factors are therefore not good pretreatment prognostic indicators.

 In an attempt to predict whether or not a patient will respond to anti-HCV treatment before treatment is given, viral factors are currently being used.

It has been found that patients who are infected with HCV genotype 2 or 3 respond better to anti-HCV treatment than those who are infected with HCV genotype 5 or 6, who themselves better respond to anti-cancer treatment. -VHC than those infected with genotype 1 or 4 HCV. However, the distribution of the different genotypes is not homogeneous according to the geographical locations, and the only detection of the viral genotype therefore does not provide a predictive solution applicable to all patients. There are also differences between virus subtypes. In fact, knowledge of the nature of the viral genotype essentially makes it possible to adjust the dosage and / or the duration of treatment, but does not in itself establish a reliable prognosis before starting treatment.

 Various combinations of biological and / or clinical and / or viral factors have, moreover, been tested, in an attempt to predict, before possible administration of the treatment, whether or not a patient will respond to anti-HCV treatment. But the combinations that have so far been tested do not achieve satisfactory predictive performance.

For example, Hidetsugu Saito et al. 2010 were able to identify combinations of biological, clinical, and viral factors with predictable performance that are reliable when applied during treatment, but have not yet achieved a combination that is sufficiently reliable when it is applied before start of anti-HCV treatment.

 Chen et al. 2005 and Chen et al. 2010 have proposed a transcriptomic signature to predict, before HCV therapy is administered, whether a patient will respond or not respond to this treatment. This signature combines the expression levels of eighteen genes (G1P2, OAS2, G1P3, OAS3, RPLP2, CEB1, IFIT1, VIPERIN, RPS28, PI3KAP1, MX1, DUSP1, ATF5, LAP3, USP18, LGP1, ETEF1, STXBP5). .

 In addition, at least two of these genes encode proteins that are exclusively membrane-bound (G1P3 and VIPERIN); the product of their expression can not be detected in the circulating blood.

 Asselah et al. 2008 analyzed the level of expression of fifty-eight genes before application of anti-HCV treatment in forty patients with chronic hepatitis C, fourteen of whom are non-responders to anti-HCV treatment. They have identified two signatures that can predict, before an anti-HCV treatment is administered, whether a patient will be non-responder to this treatment.

 The first signature is based on the expression levels of two genes, namely IFI27 and CXCL9, which are analyzed according to the KNN method (k-nearest neighbor method).

The second signature is based on the expression levels of three genes, namely IFI27, CXCL9 and IFI-6-16, which are analyzed according to the WV method (weighted voting method). For each of these two signatures, Asselah et al. 2008 indicate that adding additional genes does not improve the accuracy of the classification.

There is always a need for means to predict, before the HCV therapy has only started, if the patient has a history of high probability of responding, or conversely, a high probability of not responding to treatment.

SUMMARY OF THE INVENTION

The request relates to means that make it possible to establish a prognosis for a high probability of response or non-response to anti-HCV treatment.

Advantageously, the means of the invention make it possible to establish this prognosis before the anti-HCV treatment has even begun.

 The inventors have identified genes whose expression levels are prognostic biomarkers of response or non-response to anti-HCV treatment. More particularly, the inventors propose to establish the expression profile of these genes, and to use this profile as a prognostic signature of the response or non-response to anti-HCV treatment.

 Demand provides means that are specially adapted for this purpose. The means of the invention implement in particular the assay or the measurement of the expression levels of selected genes, said selected genes being chosen from the following list of genes:

HERC5, IL8, STAT2, CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18.

More particularly, said selected genes comprise:

 at least two of HERC5, IL8, STAT2; and

 at least one of CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IFI27, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18.

Optionally, the means of the invention may further implement the assay or measurement of one or more other clinical factors and / or one or more other virological factors and / or one or more other biological factors.

The means of the invention comprise in particular:

 methods that include assaying or measuring expression levels of selected genes;

products or reagents that are specially adapted for assaying or measuring these levels of gene expression; manufactured articles, compositions, pharmaceutical compositions, kits, tubes, solid supports comprising such products or reagents, as well as

 computer systems (in particular, computer program product and computer device), which are specially adapted for implementing the means of the invention.

DETAILED DESCRIPTION OF THE INVENTION

 The stage of liver tissue involvement, particularly the nature and extent of hepatic tissue injury, is assessed by a liver fibrosis score, including the Metavir F score system, which comprises five stages of F0 to F4.

When the liver fibrosis score is at most F1, the practitioner may decide not to administer HCV treatment, whereas, when the score is at least F2, it is currently recommended to administer a treatment. anti-HCV, regardless of the degree of necrotico-inflammatory activity.

 Since anti-HCV treatments are very long-lasting (usually 6 to 12 months or more), they induce particularly serious side effects, and are very expensive, the present application proposes means that are intended to assist the decision administer or not administer anti-HCV therapy.

The means of the invention allow a prognosis of high probability of response or non-response to anti-HCV treatment. Advantageously, the means of the invention make it possible to establish this prognosis before this treatment has even begun.

The means of the invention comprise measuring or assaying the expression levels of selected genes. They concern subjects who are infected with one or more hepatitis viruses, including at least one HCV, and more particularly those subjects who have a hepatic fibrosis score of at least F1, more particularly at least F2. according to the F Metavir score system.

In the request, unless otherwise specified, or the context dictates otherwise, all terms have their usual meaning in the area (s) concerned. The term "anti-HCV treatment", "treatment of hepatitis C", or equivalent expression, or, by way of a shortcut, the term "treatment" means therapeutic treatment, which is intended to induce reduction of the HCV load of the patient, so that at the end of treatment, it is possible to reach an undetectable level of HCV load, or even an eradication of the HCV (s). From a clinical point of view, the goal desired therapeutic action is in particular to stop, regress or even eliminate tissue lesions of the liver, that is to say, at the very least, to prevent the hepatic fibrosis score from increasing or even this score decreases, preferably decreases to a score of at most Fl.

The anti-HCV treatment comprises at least the administration of interferon, more particularly alpha interferon, in particular interferon alpha-2a or interferon alpha-2b, or an interferon prodrug.

 This interferon is usually a genetically engineered version of the natural human cytokine. This interferon may nevertheless be an interferon derived from Chinese hamster ovary cells (CHO cells), such as omega interferon (for example, omega interferon which is available from Intarcia Therapeutics, Hayward, California, USA). .

 This interferon may in particular be linked to other compounds, groups or chemical molecules, in particular to polyethylene glycol (for example, PEG-INTRON® marketed by Schering Plow Corporation, Kenilworth, New Jersey, USA, or PEGASYS® marketed by F. Hoffmann-La Roche Ltd., Basel, Switzerland).

The pegylated form of interferon has a longer lifespan in the human body, which limits the rate of administration to a single administration per week (in this case, to a single injection per week), instead of three administrations per week for the non-pegylated form.

 The pegylated form of interferon is therefore currently the preferred form of interferon. For example, pegylated interferon may be administered:

 at a dose of about 1.5 g / kg / week for pegylated interferon alpha-2b (such as PEG-INTRON®),

at a concentration of 180 g / kg / week for pegylated interferon alpha-2a (such as PEGASYS®).

 In addition to interferon, an anti-HCV treatment generally comprises the administration of at least one other antiviral agent.

 In addition to interferon, current anti-HCV treatment usually includes administration of ribavirin.

 Ribavirin is a nucleoside analogue of guanosine.

In the context of the application, and according to a particular embodiment of the invention, the anti-HCV treatment comprises the administration of interferon and the administration of: ribavirin (for example, ribavirin REBETOL® marketed by Plow Corporation, Kenilworth, New Jersey, USA, or ribavirin COPEGUS® marketed by Roche Corporation, F. Hoffmann-La Roche Ltd., Basel, Switzerland), or

- an analogue of ribavirin, or

- a pro-drug of ribavirin or one of its analogues.

 The pro-drugs of ribavirin include taribavirin (eg, taribavirin which is available from Valeant, Aliso Viejo, California, USA).

The administration of ribavirin is usually daily.

For example, ribavirin may be administered at 800 to 1200 mg / kg / day.

An anti-HCV treatment may for example include the administration of:

 pegylated interferon alpha-2b (such as PEG-INTRON®) at a dose of about 1.5 g / kg / week, and ribavirin at a dose of 800 to 1200 mg / kg / day (if hepatopathy involves HCV genotype 2 or 3, a dose of approximately 800 mg / kg / day is generally advised), or

pegylated interferon alpha-2a (such as PEGASYS®) at a concentration of 180 g / kg / week and ribavirin at 1000 to 1200 mg / kg / day.

In addition to interferon, or interferon and ribavirin, anti-HCV treatment may further comprise the administration of at least one other generic or HCV-specific antiviral agent, such as:

at least one HCV protease inhibitor, such as an NS3 protease inhibitor, and / or

 at least one HCV polymerase inhibitor, such as an NS5B polymerase inhibitor,

more particularly at least one HCV protease inhibitor, such as an NS3 protease inhibitor.

Said NS3 protease inhibitor can be, for example, telaprevir (VX-950, Vertex, Cambridge, Massachusetts, USA) or boceprevir (SCH-503034, Schering-Plow, Kenilworth, New Jersey, USA). The combination of interferon (or an interferon analogue or prodrug), ribavirin (or a ribavirin analogue or prodrug) and a protease inhibitor HCV, such as telaprevir or boceprevir (or an analogue or pro-drug of this protease inhibitor), is a triple therapy that is especially considered for the treatment of patients who are infected with at least one HCV genotype 1 or 4. Said NS5B polymerase inhibitor may for example be a nucleoside analogue such as R1479, or its pro-drug R1626 (Roche, Basel, Switzerland), or the nucleoside analogue PSI-6130, or its pro-drug R7128 (Pharmasset , Princeton, NJ, USA, Roche, Basel, Switzerland).

In addition to the anti-viral agent or agents, the anti-HCV treatment may further comprise the administration of at least one other product, without direct anti-viral activity, such as a medication adjuvant, for example a hormone that stimulates the production of erythrocytes and / or leukocytes, such as erythropoietin (EPO).

 The duration of anti-HCV treatment is usually at least about 24 weeks, usually about 24 to 48 weeks, but sometimes longer. For example, it can be:

- about 24 weeks for genotype 2 or 3 HCV hepatopathy,

 - about 48 weeks for HCV hepatopathy genotype 1, 4 or 5, or for a non-responder patient after 24 weeks.

 The expressions "answering machine" or "non-answering machine" are understood according to their usual meaning in the medical field. The term "responder" or "non-responder" refers to an "anti-HCV responder" or "non-responder to anti-HCV treatment," respectively.

It is considered that a subject is:

 a treatment-responsive subject (R-rated patient), when the HCV viral load has become undetectable in the patient's blood upon anti-HCV treatment combining administration of interferon and administration of ribavirin (or a prodrug or an analogue of these active ingredients), and that this viral load remains undetectable 6 months after stopping this treatment;

 a subject not responding to treatment (patient ranked R), when the viral load of HCV remains detectable in the blood of the patient at the end of this anti-HCV treatment;

- a responder-recess subject (patient classified as RR), when the HCV viral load became undetectable in the patient's blood after this anti-HCV treatment, but became detectable again 6 months after stopping of this anti-HCV treatment.

 This anti-HCV treatment is usually administered:

- about 24 weeks for HCV genotype 2 or 3 hepatitis,

 - about 48 weeks for HCV hepatopathy genotype 1, 4, 5 or 6.

The treatment may be one of the above-mentioned treatments, such as, in particular, a treatment comprising or consisting of the administration of ribavirin (or of a prodrug or analogue of this active ingredient) and of interferon alpha- 2a or interferon alpha-2b, more particularly pegylated interferon (more particularly, pegylated interferon alpha-2a or pegylated interferon alpha-2b), or a pro-drug or an analogue of this active ingredient. Interferon is usually given at a rate of once a week, while ribavirin is usually given at a rate of twice a day.

 Examples of treatment include the following examples:

 - treatment by administration:

 o pegylated interferon alpha-2b (PEG-INTRON®, Schering Plow Corporation, Kenilworth, NJ, USA) at a dose of 1.5 g / kg / week, and o ribavirin (REBETOL®, Schering Plow Corporation, Kenilworth ,

NJ; U.S.A.), based on patient weight and HCV genotype (s), at a dose of:

^■ 800 to 1200 mg / kg / day for those patients who were infected with at least one genotype 1 and / or 4 and / or 5 and / or 6 HCV, or at a dose of

^■ 800 mg / kg / day for patients who were infected with at least one genotype 2 and / or 3 HCV,

or

 - treatment by administration:

 o pegylated interferon alpha-2a (PEGASYS®, Roche Corporation, F.

 Hoffmann-La Roche Ltd. ; Basel, Switzerland) at a dose of 180 g / kg / week, and

 o Ribavirin (COPEGUS®, Roche Corporation, F. Hoffmann-La Roche Ltd., Basel, Switzerland) at a dose of 1000 to 1200 mg / kg / day.

Either of these two treatment examples may be given for 24 weeks for those who were infected with at least one genotype 2 and / or 3 for HCV, and for 48 weeks for those who were infected. by at least one genotype 1 and / or 4 and / or 5 and / or 6 of HCV.

The HCV viral load may be considered undetectable in the subject's blood when the HCV RNA assay in the subject's serum resulted in a value of less than 12 International Units (IU) per mL of serum, as measured by a quantification test of HCV RNA, for example as measured by a quantification test performed using the VERSANT® HCV-RNA 3.0 (bDNA) assay kit from the Siemens Healthcare Diagnostics (limit of quantification = 615 - 7,690,000 IU / mL), following the recommendations of the manufacturer of this kit.

 The inventors have identified genes whose expression levels are biomarkers which, when taken in combination, are relevant for determining the "responder" (R) or "non-responder" (R) status of a subject.

 The inventors have further observed that, according to these combinations of expression levels, the population of the responder-relapse (RR) subjects segregates very strongly with that of the responders (R): the RR subjects are mainly classified as R's (cf. examples below).

The genes thus identified are the following twenty-eight genes: HERC5, IL8, STAT2, CCL21, CLDN1, CXCL6, FOX01, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18.

 Most of these genes encode proteins whose location is not transmembrane, or at least not exclusively. Most of these genes therefore encode proteins that are likely to be detected in a biological fluid of the subject, such as blood, serum or plasma. This is in fact the case of the twenty-eight genes listed above, with the exception of the following seven genes, which encode strict membrane proteins: CLDN1, G1P3, IFI27, IFITM1, ITGA2, OCLN, PLSCR1.

The inventors have further identified that the most relevant combinations include:

 at least two of HERC5, IL8, STAT2; and

 at least one of CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IFI27, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18.

Each of these genes is individually known to those skilled in the art, and is understood in accordance with its significance in the art. A reminder of their respective identities is presented as an indication in Table 1 below. Table 1: Genetic Identity

Name (in French) Name (in English) Number

Alias symbol

 of the encoded protein of the accession protein encoding protein NM protein 5 containing a domain

 HECT domain and RCCl-like

 HERC5 HECT and domains of type CBE1, CEBP1 NM_016323 domain-containing protein 5

 RCC1

 CXCL8, GCP-1, GCP1, Read,

 IL8 interleukin 8 interleukin 8 LUCT, LYNAP, MDNCF, MONAP, NM_000584

 NAF, NAP-1, NAP1

 signal transducer and activator Signal Transducer and Activator of

 STAT2 PI 13, ISGF-3, STAT113, MGC59816 NM_005419 Transcription 2 Transcription 2

 CCL21 chemokine ligand 21 (C-C motif) chemokine (C-C motif) ligand 21 ECL, SLC, SCYA21 NM_002989

CLDN1 Claudine 1 Claudin-1 CLD &, SEMP1, ILVASC NM_021101

CXCL6 chemokine ligand 6 (motif CXC) chemokine (CXC motif) ligand 6 CKA-3, GCP-2, GCP2, SCYB6 NM_002993 protein 01 canned

FOXOl Forkhead box protein 01 FKH1, FKHR, F0X01A NM_002015 fork

Table 1 (continued): gene identity

Name (in French) Name (in English) Number

Alias symbol

 of the encoded protein of the accession coded protein NM protein inducible by interferon interferon alpha inducible protein

 G1P2 ISG15, IFI15 M_005101.3 alpha (clone IFI-15K) (clone IFI-15K)

 6-16 inducible protein 6, FAM14C, IFI616, IFI-6-16,

 G1P3 interferon alpha-inducible protein 6 M_022873 alpha interferon IFI6

 inducible protein 27 by

 IFI27 interferon alpha-inducible protein 27 P27, ISG12, FAM14D, ISG12A M_005532 alpha interferon

 35kDa protein induced by

 IFI35 interferon-induced 35kDa protein IFP35, FLJ21753 M_005533 interferon

 IFI44 protein 44 induced by interferon interferon-induced protein 44 P44, MTAP44 M_006417 protein with repeats

 interferon-induced protein with G10P1, IFI56, ISG56, IFI-56,

 IFIT1 tetratricopeptide 1 induced by M_001548 tetratricopeptide repeats 1 IFNAI1, RNM561

 interferon

 protein with repetitions

 interferon-induced protein with IRG2, IF160, ISG60, RIG-G, CIG-49,

 IFIT4 tetratricopeptide 3 induced by M_001549 tetratricopeptide repeats 3 GARG-49, IFIT3

interferon

Table 1 (continued): gene identity

Name (in French) Name (in English) Number

Alias symbol

 of the encoded protein of the transmembrane interferon-induced transmembrane protein

 IFITM1 9-27, CD225, IFI17, LEU13 M_003641 induced by interferon protein 1

 CD49B, BR, GPla, CD49B, VLA-2,

 ITGA2 integrin alpha 2 integrin alpha-2 M_002203

 VLAA2

 binding protein to LGALS3

 lectin, galactosidase-binding,

 LGALS3BP (lectin, binding to galactosidase, 90K, MAC-2-BP M_005567.3 soluble, 3 binding protein

 soluble, 3)

 MDK midkine midkine EGF2 M_001012334 1 resistance protein

 Myxovirus (Influenza virus)

 Myxovirus

 MX1 resistance protein 1 IFI78 M_002462

 (protein 78 induced by

 (interferon induced protein 78)

 interferon)

 OAS1 synthetase 1 2'-5'-oligoadenylate 2'-5'-oligoadenylate synthetase 1 OIAS, IFI-4, OIASI M_016816

OAS2 synthetase 2 2'-5'-oligoadenylate 2'-5'-oligoadenylate synthetase 2 MGC78578 M_016817

OAS3 synthetase 3 2'-5'-oligoadenylate 2'-5'-oligoadenylate synthetase 3 plOO, MGC133260 M_006187

Table 1 (continuation and end): gene identity

Name (in French) Name (in English) Number

Alias symbol

 of the encoded protein of the encoded accession protein NM

OCLN occludin occludin - M_002538

PLSCR1 scramblase phospholipid 1 phospholipid scramblase 1 M MTR A 1 B M_021105 protein 2 containing a domain

 S-adenosyl methionine radical

 RSAD2 of S-Cig5 methionine radical, vigl, cig33, 2510004LOlRik M_080657 domain-containing protein 2

 adenosyl

 signal transducer and activator Signal Transducer and Activator of

 STAT1 ISGF-3, STAT91, DKFZp686B04100 M_007315 Transcription 1 alpha / beta Transcription 1 -alpha / beta

 STMN2 stathmine 2 Stathmin-2 SCG10, SCGN10, SGC10 M_007029

USP18 carboxy-terminal hydrolase Ubl Ubl carboxyl-terminal hydrolase 18 ISG43, UBP43 M_017414 ribosomal phosphoprotein acid human acidic ribosomal

 RPLPO 36B4 M_001002

 PO human phosphoprotein PO

TBP protein binding to a TATA box TATA box binding protein - M_003194

None of these genes is a hepatitis virus gene. These are mammalian genes, more specifically human genes. In addition to the expression levels of genes selected from the list of twenty-eight genes of the invention (HERC5, IL8, STAT2, CCL21, CLDN1, CXCL6, FOX01, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4 , IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18), the means of the invention may further comprise the measurement of other factors, in particular one or more clinical factors and / or one or more virological factors and / or one or more biological factors other than the level of expression of genes selected from said list of twenty-eight genes.

More particularly, in addition to the expression levels of genes selected from said list of twenty-eight genes of the invention, the means of the invention may optionally include:

 assaying the level of expression of mammalian genes (more particularly human genes) other than those in said list of twenty-eight genes, for example for assaying the level of transcription of genes which are listed below as " other biological factors, such as the gene encoding alkaline phosphatase (PAL); cf. example 2d) below, and / or

 the dosage of intracorporeal metabolites (eg, cholesterol), and / or

 the dosage of figured elements of blood (eg platelets), and / or

 the dosage of the amount of iron circulating.

These are, however, optional assays.

According to the application, the number of mammalian genes (more particularly of human genes), the level of expression of which is assayed, and which are not genes selected from the said list of twenty-eight genes of the invention (for example: example gene encoding gamma glutamyl transpeptidase and / or gene encoding alkaline phosphatase), is preferably at most 18, more particularly 14 or less, more particularly 11 or less, more particularly 6 or less, more particularly 4 or 3 or 2 or 1 or 0, more particularly 3 or 2 or 1 or 0, especially 2 or 1 or 0. As a result, by counting these "other" mammalian genes (more particularly those "other" human genes), whose level of expression can be possibly measured, as well as the maximum number of the twenty-eight genes that may be selected genes according to the invention, the total number of genes whose level of expression is assayed in a method according to the application, is preferably from 3 to 46 genes, more particularly from 3 to 42, more particularly from 3 to 39, more particularly from 3 to 34, more particularly from 3 to 32, more particularly from 3 to 31, more particularly from 3 to 30, more particularly from 3 to 29, in particular from 3 to 28, more particularly from 3 to 27, more particularly from 3 to 26, more particularly from 3 to 25, more particularly from 3 to 24, more particularly from 3 to 23, more particularly from 3 to 22, more particularly from 3 to 21, more particularly from 3 to 20, more s especially from 3 to 19, more particularly from 3 to 18, more particularly from 3 to 17, more particularly from 3 to 16, more particularly from 3 to 15, more particularly from 3 to 14, more particularly from 3 to 13, more particularly from 3 to 12, more particularly from 3 to 11, more particularly from 3 to 10, more particularly from 3 to 9, more particularly from 3 to 8, more particularly from 3 to 7 (for example from 4, 5, 6 or 7), more particularly from 3 to 6 (for example 4, 5 or 6).

Furthermore, as is presented in more detail below, and as illustrated by examples, the number of genes selected from the list of twenty-eight genes of the invention (HERC5, IL8, STAT2, CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18) can advantageously be 3, 4, 5 or 6, more particularly 3, 4 or 5, in particular 4 or 5.

According to one embodiment, the total number of genes whose level of expression is assayed is:

 3, 4, 5 or 6 genes selected from said list of twenty-eight genes of the invention, and

 - 0, 1, 2, 3 or 4 "other" mammalian genes, more particularly 0, 1, 2 or 3 "other" mammalian genes, more particularly 0, 1 or 2 "other" mammalian genes.

According to one embodiment, the total number of mammalian genes whose expression level is assayed in a method according to the application, is therefore from 3 to 10, more particularly from 3 to 9, more particularly from 3 to 8, more particularly from 3 to 7, more particularly from 3 to 6, more particularly from 3 to 5, more particularly from 3 to 4.

The means of the invention may optionally comprise the assay of the expression product (RNA or protein) of one or more non-human genes, more particularly one or more viral genes, more particularly one or more virus genes. hepatitis, more particularly one or more HCV genes.

The means of the invention may optionally comprise the determination of the genotype (s) of the HCV (s) whose subject is infected.

The means of the invention may optionally comprise the determination of one or more clinical factors of said subject such as the viral load before treatment (CVavantTTT in the examples below).

 The means of the invention may optionally comprise the determination of one or more biological factors of said subject other than the level of expression of a gene of this subject, such as, for example, the determination of the cholesterol of said subject.

A feature of the means of the invention is that they include dosing (or measuring) the level at which selected genes are expressed in the body of said subject. The expression "level of expression of a gene" or equivalent expression here refers to both the level at which this gene is transcribed into RNA, more particularly mRNA, than the level at which a protein encoded by this gene is expressed.

 The term "dose" or "measure" or equivalent term is understood according to its common sense in the field, and refers to quantifying.

 The level of transcription (RNA) of each of said genes may be assayed, or the level of translation (protein) of each of said genes may be assayed, or the level of transcription may be assayed for some of the said selected genes and the level of translation for the others. of these selected genes. According to one embodiment of the invention, either the level of transcription or the level of translation of each of said selected genes is measured.

Assaying (or measuring) the level of transcription of a gene comprises quantifying transcribed RNAs of that gene, more particularly determining the concentration of RNA transcribed by that gene (for example, the amount of these RNAs). relative to the total amount of RNA initially present in the sample, such as, for example, a Ct value normalized by the 2 ^{~ ACt method} , see below). Assaying (or measuring) the level of translation of a gene comprises quantifying proteins encoded by that gene, more particularly determining the concentration of proteins encoded by that gene (e.g., the amount of that protein by volume of biological fluid).

Certain proteins encoded by a mammalian gene, including a human gene, may sometimes undergo post-translational modifications such as, for example, cleavage into polypeptides and / or peptides. If so, dosing (or measuring) the level of translation of a gene may then include quantifying or determining the concentration not of the protein (s) themselves, but of one or more forms. post-translational agents of this or these proteins, such as, for example, polypeptides and / or peptides which are specific fragments of this or these proteins. To measure or measure the level of expression of a gene, we can therefore quantify:

 transcribed RNAs of this gene, or

 proteins expressed by this gene, or post-translational forms of such proteins, such as, for example, polypeptides or peptides which are specific fragments of these proteins.

The application relates to the objects defined in the claims as filed, to the objects described below and to the objects illustrated in part "examples".

In particular, the application relates to means for predicting whether an HCV-infected person has a high probability of responding to anti-HCV treatment which will include the administration of interferon and ribavirin, or if, on the contrary, this subject has a high probability of not responding to this anti-HCV treatment. The means of the invention comprise in particular:

 methods that include assaying or measuring the expression levels of selected genes (transcription or translation levels);

 products or reagents that are specially adapted for assaying or measuring these levels of gene expression;

manufactured articles, compositions, pharmaceutical compositions, kits, tubes, solid supports comprising such products or reagents, as well as computer systems (in particular, computer program product and computer device), which are specially adapted for implementing the means of the invention. The means of the invention, more particularly the method of the invention, are implemented prior to treatment of the HCV infection, and advantageously can be implemented before the anti-HCV treatment has been performed. started, especially before any anti-HCV treatment started. According to one aspect of the invention, the application is thus related to a method, more particularly an in vitro method, for predicting whether a subject infected with HCV (s) has a high probability of responding to an anti-HCV treatment which will include administration of interferon and ribavirin, or if, on the contrary, this subject has a high probability of not responding to this anti-HCV treatment.

The method comprises assaying the levels at which selected genes are transcribed or translated, said selected genes being genes selected from the following list of genes: HERC5, IL8, STAT2, CCL21, CLDN1, CXCL6, FOX01, G1P2, G1P3, IFI27, IFI35, IFI44, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18.

More particularly, the prognostic method of the application comprises assaying the levels at which selected genes are transcribed or translated, said selected genes being:

 at least two of HERC5, IL8, STAT2; and

 at least one of CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1,

OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18.

These assays may be made in a sample previously obtained from said subject.

In the prognostic method of the invention, the total number of genes thus chosen may in particular be 3, 4, 5 or 6, more particularly 3, 4 or 5, in particular 4 or 5. This being, as is presented and illustrated in more detail below, the prognostic method of the invention may further comprise assaying or measuring one or more other factors, including one or more virological factors and / or one or more factors. clinical and / or one or more biological factors other than gene expression levels selected from HERC5, IL8, STAT2, CCL21, CLDN1, CXCL6, FOX01, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18.

 A prognostic method of the invention may therefore be defined by the fact that it comprises the step of carrying out measurements, which comprise or consist of the following measures:

 in a sample previously obtained from said subject, assaying the levels at which selected genes are transcribed or translated, said selected genes being:

 at least two genes among HERC5, IL8, STAT2; and

 at least one of CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IFI27, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18,

 optionally, measuring or determining, for said subject, the value of one or more clinical factors and / or one or more virological factors and / or one or more biological factors other than the expression levels of genes selected from HERC5, IL8, STAT2, CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STATL STMN2, USP18.

The application also relates to a method of anti-HCV therapy, which comprises prognosing the response of a subject to anti-HCV treatment using the prognostic method of the invention. If said subject is non-responder prognostic, the practitioner may choose not to administer a treatment that includes (more particularly that essentially consists of) administration of interferon and administration of ribavirin (or their pro-drugs), more particularly not to administer such treatment as a first-line treatment. In such a situation, the practitioner may, for example, choose to administer an anti-HCV treatment that does not include (or is not essentially comprised of) administration of interferon and administration of ribavirin (or their pro-drugs). especially to administer such treatment as a first-line treatment. The practitioner may alternatively choose not to administer anti-HCV treatment, at least first-line. If said subject is prognostic responder, the practitioner may choose to administer an anti-HCV treatment, in particular a treatment which comprises (more particularly which essentially consists of) administration of interferon and administration of ribavirin (or their pro-drugs), more particularly to administer as a first-line treatment which comprises ( more particularly which consists essentially of) administration of interferon and administration of ribavirin (or their prodrugs).

The assay (or measurement) of the level of expression of said selected genes can be done in a sample previously obtained from said subject, such as:

 a biological sample taken or collected from said subject, or

 a sample comprising nucleic acids (in particular RNAs) and / or proteins and / or polypeptides and / or peptides of said biological sample, in particular a sample comprising nucleic acids and / or proteins and / or polypeptides and / or peptides which have been , or are likely to have been extracted and / or purified from said biological sample, or

 a sample comprising cDNAs that have been, or are likely to have been, obtained by reverse transcription of said RNAs.

 A biological sample collected or taken from said subject may for example be a sample taken or collected, or capable of being taken or collected, from:

 an organ or internal tissue of said subject, in particular of his liver or of his liver parenchyma, or

 a biological fluid of said subject, including an intracorporeal fluid such as blood, serum, plasma, or urine.

A biological sample collected or taken from said subject may for example be a sample comprising a portion of tissue of said subject, in particular a portion of hepatic tissue, more particularly a portion of hepatic parenchyma.

A biological sample collected or taken from said subject may for example be a sample comprising cells which have been, or may be, collected or collected from a tissue of said subject, in particular liver tissue, more particularly hepatic cells. .

A biological sample collected or taken from said subject may for example be a biological fluid sample, such as a sample of blood, serum, plasma or urine, more particularly a sample of intracorporeal fluid such as a blood sample. or serum or plasma. This is particularly the case when said selected genes from said list of twenty-eight genes of the invention encode proteins that have an extracellular location, or at least those of said selected genes that encode proteins having such location.

 According to one embodiment of the invention, said biological sample is therefore a sample of biological fluid of said subject, such as a sample of intracorporeal fluid, such as blood, serum, plasma, or urine sample, and the expression levels of said selected genes that are assayed may be levels of protein translation.

The collection or collection of said biological sample may be done by insertion of a sampling instrument, in particular by insertion of a needle or a catheter, into the body of said subject. This instrument can for example be inserted:

 in an organ or internal tissue of said subject, in particular in his liver or in hepatic parenchyma, for example,

 for taking a sample of liver or liver parenchyma, this sample may for example be made by hepatic biopsy puncture (PBH), more particularly by transjugular or transparietal PBH, or

 to collect or collect cells from the hepatic compartment (removal of cells, and not of tissue), more particularly from the hepatic parenchyma, in particular for taking liver cells, this sampling or collection being able for example to be done by cyto hepatic dysfunction;

and or

 in a vein, an artery or a vessel of said subject for taking a biological fluid from said subject, such as blood.

 The means of the invention are not limited to an implementation on a tissue biopsy, including liver tissue. They can be implemented on a sample obtained, or likely to be obtained by a sample size or volume significantly smaller than a tissue sample, namely a sample which is limited to a few cells. The means of the invention may in particular be implemented on a sample obtained, or obtainable by hepatic cytopuncture.

The quantity or volume of material removed by hepatic cytopuncture is much smaller than that taken by PBH. In addition to the immediate gain for the patient in terms of decreased invasiveness of the sampling technique and decreased associated morbidity, hepatic cytopuncture has the advantage that it can be repeated at different times on the same patient (by example, to determine the course of fibrosis between two instants), whereas PBH can not be reasonably repeated on the same patient. The hepatic cytopuncture therefore has, unlike PBH, the advantage of allowing to follow the clinical evolution of the patient.

 Thus, according to the invention, said biological sample may advantageously be:

 - a collection or collection of cells from the liver compartment (collection or collection of cells, not tissue), more particularly from the liver parenchyma, ie a biological sample obtained, or susceptible to be obtained by hepatic cytopuncture;

and or

 a sample or collection of biological fluid from said subject, such as blood or urine, especially blood.

 The assay (or measurement) can be done in a biological sample that has been collected or taken from said subject, and that has been further processed, for example:

 by extraction and / or purification of the nucleic acids, in particular RNAs, more particularly mRNAs, and / or by reverse transcription of these RNAs, in particular these mRNAs, or

 by extraction and / or purification of the proteins and / or polypeptides and / or peptides, or by extraction and / or purification of a protein fraction, such as serum or plasma extracted from the blood.

For example, when the biological sample collected or collected is a biological fluid such as blood or urine, this sample may, before carrying out the assay or the measurement, be transformed:

 by extraction of nucleic acids, in particular RNA, more particularly mRNA, and / or by reverse transcription of these RNAs, in particular these mRNAs (most generally, by extraction of the RNAs and reverse transcription of these RNAs), or

 by separation and / or extraction of the serum fraction, or by extraction or purification of the proteins and / or polypeptides and / or serum peptides.

Thus, according to one embodiment of the invention, said sample obtained from said subject comprises (for example in a solution), or is, a sample of biological fluid of said subject, such as a sample of blood, serum, plasma or urine, and / or is a sample that includes (for example in a solution): RNAs, especially mRNAs, which may have been extracted or purified from a biological fluid, such as blood or urine, especially blood; and / or cDNAs that may have been obtained by reverse transcription of such RNAs; and / or proteins and / or polypeptides and / or peptides likely to have been extracted or purified from a biological fluid, such as blood or urine, especially blood, and / or likely to have been coded by such RNAs,

 preferably,

 proteins and / or polypeptides and / or peptides likely to have been extracted or purified from a biological fluid, such as blood or urine, in particular blood, and / or likely to have been coded by such RNA.

 When said sample obtained from said subject comprises a biological sample obtained, or obtainable by taking a biological fluid, such as blood or urine, or when said sample obtained from said subject is derived, or likely to be derived from such a biological sample by extraction and / or purification of molecules contained in this biological sample, the assay is preferably an assay of proteins and / or polypeptides and / or peptides, rather than an assay of nucleic acids.

 When the biological sample collected or taken is a sample comprising a portion of tissue, in particular a portion of hepatic tissue, more particularly a portion of liver parenchyma, such as, for example, a biological sample taken or likely to be taken by liver biopsy puncture. (PBH), or when the biological sample collected or taken is a sample comprising cells obtained, or obtainable from such a tissue, such as for example a sample collected, or capable of being collected, by hepatic cytopuncture, this biological sample can be transformed:

 by extraction of nucleic acids, in particular RNA, more particularly mRNA, and / or by reverse transcription of these RNAs, in particular these mRNAs (most generally, by extraction of these RNAs and reverse transcription of these RNAs), or

 by separation and / or extraction of the proteins and / or polypeptides and / or peptides.

A step of lysis of the cells, in particular lysis of the hepatic cells, contained in said biological sample may be carried out beforehand so as to render nucleic acids, or, where appropriate, proteins and / or polypeptides and / or peptides directly accessible to the patient. 'analysis. Thus, according to one embodiment of the invention, said sample obtained from said subject is a sample of tissue of said subject, in particular of hepatic tissue, more particularly of hepatic parenchyma, or is a sample of cells of such a tissue, and / or is a sample which comprises (for example in a solution):

 hepatic cells, more particularly hepatic parenchyma cells, for example cells obtained, or capable of being obtained by dissociation of the cells of a liver tissue biopsy or by hepatic cytopuncture; and / or RNAs, in particular mRNAs, which may have been extracted or purified from such cells; and or

 cDNAs that may have been obtained by reverse transcription of such RNAs; and or

 proteins and / or polypeptides and / or peptides likely to have been extracted or purified from such cells, and / or likely to have been coded by such RNAs. According to the invention, said subject is a human or a non-human animal, in particular a human or a non-human mammal, more particularly a human.

Because of the particular selection of genes proposed by the invention, the responder or non-responder status of said subject can be deduced, or determined from, the values of the measurements obtained for said subject, in particular by statistical induction and / or statistical classification, for example against reference cohorts (pre-) established according to their responder or non-responder status.

 In addition to dosing (or measuring) the level at which selected genes are expressed in the body of said subject, a method of the invention may further include a step of deducing or determining the responder or non-responder status. said subject's responder from the measurement values obtained for said subject. This deduction or determination step is a step by which the measurement values obtained for said subject are analyzed to induce the responder or non-responder status of said subject.

The deduction or determination of the responder or non-responder status of the subject may be made by comparing the values of the measurements obtained for said subject with their values, or the distribution of their values, in pre-established reference cohorts according to their status of responder or non-responder to anti-HCV treatment, to classify said subject in those cohorts of reference with respect to which he has the highest probability of belonging (that is to say, to attribute to his subject his status as an answering or non-answering machine). The individuals composing these cohorts are individuals for whom it has been established, by application of anti-HCV treatment, that they are responders or non-responders to this treatment.

The assays carried out on said subject and on the individuals of the reference cohorts or subpopulations are assays of levels of expression (transcription or translation) of genes.

To measure the level of transcription of a gene, its transcription level is measured in RNA. Such an assay may for example comprise measuring the concentration of transcribed RNAs of each of said selected genes, either by measuring the concentration of these RNAs, or by measuring the concentration of the cDNAs obtained by reverse transcription of these RNAs. The nucleic acid assay is well known to those skilled in the art. For example, the assay of RNA or corresponding cDNAs can be done by amplification of nucleic acid, in particular by PCR. Reagents are described below for this purpose (cf. example 1 below). Examples of appropriate primers and probes are also given (cf. for example Table 10 below). Nucleic acid amplification conditions may be selected by those skilled in the art. Examples of amplification conditions are given in the "Examples" section which follows (cf. example 1 below).

 To measure the level of translation of a gene, its level of translation into protein is measured. Such an assay may for example comprise measuring the concentration of proteins translated from each of said selected genes (for example, assaying proteins in the general circulation, especially in serum). The protein assay is well known to those skilled in the art. For example, the proteins (and / or polypeptides and / or peptides) can be assayed by ELISA or by any other immunometric method known to those skilled in the art, or by a method using mass spectrometry known to those skilled in the art.

Assay values are concentration or proportion values, or values that represent a concentration or a proportion. The objective is that within the same combination, the dosage values of the expression levels of each of said selected genes reflect as accurately as possible, at least one with respect to the other, the degree to which each of these genes is expressed (degree of transcription or degree of translation), in particular by being proportional to these respective degrees.

For example, in the case of assaying the level of expression of a gene by assaying the transcribed RNAs, that is to say, in the case of assaying the level of transcription of this gene, the assay is generally done by amplification. RNA by reverse transcription and PCR (RT-PCR), and by measuring Ct (Cycle threshold) values.

A Ct value gives a measure of the initial amount of amplified RNAs (the lower the Ct value, the higher the amount of these nucleic acids). The Ct values measured for a target RNA (Ct _C ibie) are generally related to the quantity of total RNA initially present in the sample, for example by deducing from this Ct _C ibi _e the value of a reference Ct ( Ctrerreference), such as the Ct value that has been measured under the same operating conditions for the RNA of an endogenous control gene whose level of expression is stable (for example a gene involved in a cellular metabolic cascade, such as RPLPO or TBP, see example 1 below).

According to one embodiment of the invention, the difference (Ct _C ibie - Cferreference), or ACt, can also be exploited by the method known as the 2 ^{~ ACt method} (Livak and Schmittgen 2001, Schmittgen and Livak 2008), in the form:

 2 -ACt _ 2 - (Target Ct - Ct reference)

 Thus, according to one embodiment of the invention, the assay of the levels at which each of said selected genes are transcribed is carried out by:

 amplification of a fragment of the RNAs transcribed by each of said selected genes, for example by reverse transcription and PCR of these RNA fragments, to obtain the Ct values of each of these RNAs,

optionally, normalization of each of these Ct values with respect to the Ct value obtained for the RNA of an endogenous control gene, such as RPLPO or TBP, for example by the 2 ^{"ACt method} ,

 optionally, Box-Cox transformation of said normalized values of Ct.

In the case of assaying the level of expression of a gene by assaying the proteins expressed by this gene, that is to say, in the case of the assay of the level of translation of this gene, the assay is generally done by a immunometric method with the aid of specific antibodies, and by expression of the measurements thus made in quantities by weight or in international units, using a standard range. Examples of specific antibodies are shown in Table 27 below. Examples of ways to Protein dosage are given in Table 16 below. For example, a value for assaying the level of translation of a gene may be expressed as the quantity of this protein per volume of biological fluid, for example, per volume of serum (for example, in mg / ml or in μg / ml or in ng / mL or in μg / mL).

 If desired or required, the distribution of the dosage values obtained on the individuals of a cohort can be smoothed, so as to bring it closer to a Gaussian law.

For this purpose, the assay values obtained on the individuals of this cohort, for example the values obtained by the 2 ^{"ACt method} , can be transformed by a Box-Cox type transformation (Box and Cox, 1964, see tables 6 and 25 below, see Example 2 below).

The request therefore relates in particular to an in vitro method for predicting whether an HCV-infected subject has a high probability of being a responder to an anti-HCV treatment which will include the administration of interferon and ribavirin, or if on the contrary, this subject has a high probability of not being an answer to this anti¬ treatment.

HCV

said method comprising the following steps:

 i) carry out the following measures:

 in a sample previously obtained from said subject, assaying the levels at which selected genes are transcribed or translated, said selected genes being:

 at least two genes among HERC5, IL8, STAT2, and

 at least one of CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1,

OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18,

optionally, measuring or determining, for said subject, the value of one or more clinical factors and / or of one or more virological factors and / or of one or more biological factors other than the expression levels of selected genes among HERC5, IL8, STAT2, CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK,

MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18, ii) comparing the values of the measurements obtained for said subject in step i), their values, or the distribution of their values, in pre-established reference cohorts according to their status as responders or non-responders to anti-HCV treatment, to classify said subject in that of these reference cohorts with respect to which he has the highest probability of belonging.

The comparison of step ii) can in particular be done by combining the assay (or measurement) values obtained for said subject in a multivariate classification model.

 Such a multivariate classification model compares (in a combined manner) the values of the measurements obtained for said subject with their values, or the distribution of their values, in pre-established reference cohorts according to their responder or non-responder status. anti-HCV treatment, to classify said subject in that reference cohort with respect to which he has the highest probability of belonging, for example by assigning him an output value indicating the status of responder or not -response of the said subject.

 Such a multivariate classification model can be constructed, in particular previously constructed, by making an inter-cohort comparison of the measurement values obtained for said reference cohorts or distributions of these measurement values.

More particularly, such a multivariate classification model can be constructed, in particular previously constructed, by assaying or measuring the expression levels of said selected genes in pre-established reference cohorts according to their responder or non-responder status to the anti-cancer treatment. HCV, and analyzing these assay values, or their distribution, by a multivariate statistical method to construct a multivariate classification model that induces or determines a responder or non-responder status to anti-HCV treatment from the level values of expression of said selected genes.

If, in addition to the assay values of the transcription or translation levels of said selected genes, the values assayed for said subject include the value (s) of one or more other factors, such as one or more virological factors and / or or several clinical factors and / or one or more of the other biological factors (cf. below and in the examples), the classification model is of course constructed, in particular previously constructed, by assaying or measuring the same values in pre-established reference cohorts according to their status of responder or non-responder to anti-cancer treatment. VHC, and analyzing these values, or their distribution, by a multivariate statistical method to construct a multivariate classification model that induces or determines a responder or non-responder status to anti-HCV treatment from these values.

 For example, a model can be constructed by a mathematical function, a non-parametric technique, a heuristic classification procedure or a probabilistic prediction approach. A typical example of classification based on the quantification of the level of expression of biomarkers is the discrimination of "healthy" versus "sick" subjects. The formalization of this problem consists of m independent samples, described by n random variables. Each individual i (i = 1, ..., m) is characterized by a vector x, describing the n characteristic values:

x, _j , i = \, ... mj = \, ... n

 These characteristic values may for example represent gene expression values and / or protein data intensities and / or metabolic data intensities and / or clinical data.

Each sample x is associated with a discrete value, representing the clinical status of the individual i. For example, y, = 0 if the patient has a non-responder status to anti-HCV treatment, y = 1 if the patient has respondent status to anti-HCV treatment. A model provides a decision rule (for example, a mathematical function, algorithm, or procedure) that uses the information available from x to predict .y in each sample observed. The aim is to use this model to predict the clinical status of the patient p, ie, _p , from the available biological and / or clinical values, ie x _p .

 Different multivariate classification models are known to those skilled in the art (cf. Hastie, Tibishirani and Friedman, 2009; Falissard, 2005; Theodoridis and Koutroumbos 2009).

They are usually constructed by processing and interpreting data according to, for example:

 - a multivariate statistical analysis method, for example:

 o a linear or nonlinear mathematical function, in particular a linear mathematical function, such as a function generated by the mROC method (multivariate ROC method), or

 o a Receiver Operating Characteristics (ROC) method;

 o a regression method, linear or non-linear, such as logistic regression;

o a PLS-DA method (Partial Least Squares - Discriminant Analysis); o Linear Discriminant Analysis (LDA) method;

 a method by learning or artificial intelligence, for example, a learning or artificial intelligence algorithm, a nonparametric classification method, or heuristic, or probabilistic prediction, such as:

 o a decision tree; or

 o a boosting method, based on binary classifiers (ex:

 Adaboosi) or a method related to boosting (bagging); or o a k-nearest neighbors (KN) method, or more generally the weighted k-nearest neighbors (WKNN) method, or

 o a method (for example, an algorithm) Support Vector Machines {Support Vector Machine or S VM); or

 o a random forest (Random Forest or RF); or

 o a Bayesian network; or

 o a neural network (Neural Network); or

 o a Galois lattice (or Formai Concept Analysis).

For example, the decision rules of multivariate classification models can be based on a mathematical formula of the type .y = f (x _1} x ₂ , ... x _n ) where f is a linear or nonlinear mathematical function (logistic regression, mROC , for example), or on a machine learning or artificial intelligence algorithm whose characteristics consist of a series of setting parameters identified as most effective for subject discrimination (eg KNN, WKNN, SVM, RF).

 The multivariate ROC method (mROC) is a generalization of the Receiver Operating Characteristic (ROC) method (see Reiser and Faraggi 1997, Su and Liu 1993, Shapiro, 1999). It calculates the area under the Area Under the Curve (AUC) curve for a linear combination of biomarkers and / or biomarker transformations (in the case of normalization), under the assumption of a normal distribution multivariate. The mROC method has in particular been described in Kramar et al. 1999 and Kramar et al. 2001. Reference is also made to the examples below, particularly in point 2 of example 1 below (model mROC).

The mROC software version 1.0, available commercially from the designers (A. Kramar, A. Fortune, D. Farragi and B. Reiser) can for example be used to build a model mROC. Andrew Kramar and Antoine Fortune can be contacted at, or via, the Biostatistics Unit of the Regional Center for the Fight Against Cancer (CRLC) Val d'Aurelle - Paul Lamarque (208, rue des Apothicaires, Euromedecine Park, 34298 Montpellier Cedex 5, France).

David Faraggi and Benjamin Reiser can be contacted at, or through, the Department of Statistics at Haifa University (Mount Carmel, Haifa 31905, Israel).

 The family of artificial intelligence or machine learning methods is a family of algorithms which, instead of making explicit generalizations, compare the examples of a new problem with the examples considered in learning and which were stored in memory. These algorithms directly construct the hypotheses from the learning examples themselves. A simple example of this type of algorithm is the k-nearest neighbors (KNN) algorithm, and one of its possible extensions known as the k nearest neighbor weighted algorithm (weighted k nearest neighbors or WKNN) (Hechenbichler and Schliep, 2004).

 In the context of classifying a new observation x, the simple founding idea is to have the nearest neighbors vote on this observation. The class (or clinical status) of x is determined according to the majority class among the k nearest neighbors of the observation x.

 KKNN specific function libraries are available for example in the R software (http://www.r-project.org/). The R software was originally developed by John Chambers and Bell Laboratories (see Chambers 2008). The current version of this software suite is version 2.11.1. The source code is freely available under the terms of the GNU Free Software Foundation's General Public License, at http: // www. R-project.org/. This software can be used to build a WKNN model. Reference is also made to the examples below, particularly in point 2 of Example 1 below (WKNN model).

A Random Forest (Random Forest or RF) consists of a set of simple prediction trees, each of which is able to produce an answer when presented with a subset of predictors (Breiman 2001, Liaw and Wiener 2002). The calculations are done with the software R. This software can be used to build RF models. Reference is also made to the examples below, particularly in point 2 of Example 1 below (RF model). A neural network consists of an oriented weighted graph whose nodes symbolize the neurons. The network is built from examples of each class (for example, F2 versus Fl), and is then used to determine which class a new element belongs to; cf. Intrator and Intrator 1993, Riedmiller and Braun 1993, Riedmiller 1994, Anastasiadis et. al. 2005; cf. http://cran.r-project.org/web/packages/neuralnet/index.html. The R software freely available at http://www.r-project.org/, (version 1.3 of Neuralnet, written by Stefan Fritsch and Frauke Guenther, following the work of Marc Suling) can for example be used to build a network of neurons.

Reference is also made to the examples below, especially in point 2 of example 1 below (model NN).

 The comparison of said step ii) can therefore be carried out in particular by following a method, and / or by using an algorithm or software:

 - mROC,

 KNN, WKNN, more particularly WKNN,

 - RF, or

 - NN,

more particularly, mROC.

 Each of these algorithms, software or methods makes it possible to construct a multivariate classification model, from the measurement values of each of said reference cohorts, and to combine the measurement values obtained on said subject in this model to induce its status of answering machine or non-answering machine.

 According to one embodiment of the invention, the multivariate classification model implemented in the method of the invention is expressed by a mathematical function, linear or non-linear, more particularly a linear function (for example, a mROC model). . The responder or non-responder status of said subject is then induced by combining said measurement values obtained for said subject in this mathematical function, in particular a linear or non-linear function, to obtain an output value, more particularly a numerical value of output indicative of responder or non-responder status of said subject.

According to one embodiment of the invention, the multivariate classification model implemented in the method of the invention is a model by learning or artificial intelligence, a non-parametric classification model, or heuristic, or probabilistic prediction (by example, a model WKNN, RF or NN). The responder or non-responder status of said subject is then induced by combining said measurement values. obtained for said subject in a non-parametric, or heuristic, or probabilistic prediction model (for example, a WKNN, RF or NN model), to obtain an output value, more particularly an output tag, indicative of the status of answering machine or non-answering machine of said subject.

Alternatively or additionally, said comparison of step ii) may comprise comparing the measurement values obtained for said subject to at least one reference value which discriminates between an answering or non-answering status, for classify said subject in the group of responding individuals or in the group of non-responders.

For example, the values of the measurements can be compared to their reference values in:

 a subpopulation of individuals who are of the same species as said subject, who are infected with HCV, to whom the anti-HCV treatment has been administered, and who have been shown to respond to this treatment, and / or

 a subpopulation of individuals of subjects who are of the same species as said subject, who are infected with HCV, to whom the anti-HCV treatment has been administered, and who have shown themselves to be non-responders to this treatment,

or a reference value which represents the combination of these reference values. A reference value may for example be:

 the value of the expression level assay of each of said genes selected in each of the individuals for each of the reference subpopulations or cohorts, or

 - a position criterion, for example the mean or median, or a quartile, or the minimum or maximum of these values in each of these subpopulations or reference cohorts, or

 - a combination of these values or means, or median, or quartile, or minimum, or maximum.

 The reference value (s) used must make it possible to distinguish the responder from the non-responder status.

For example, it can be a decision or prediction threshold, based on the distribution of the measurement values in each of said subpopulations or cohorts, and depending on the levels of sensitivity (Se) and specificity ( Spe) set by the user (Se = VP / (VP + FN) and Sp = VN / (VN + FP), with VP = the number of true positives, FN = the number of false negatives, VN = the number of true negatives, FP = the number of false positive). This decision threshold or prediction can in particular be an optimal threshold that assigns a fair weight to the sensitivity (Se) and the specificity (Spe), such as the threshold maximizing the Youden index (J) defined by J = Se + Spe -1.

 Alternatively or additionally, there may be comparison to several reference values. This is particularly the case when the values of the measurements obtained for said subject are compared with their values in each of said subpopulations or reference cohorts, for example using a classification method by machine learning or by artificial intelligence. .

 Thus, the comparison of step ii) can for example be done as follows:

 - choose the levels of sensitivity (Se) and specificity (Spe) that one wishes to give to the method,

 establish a mathematical function, linear or nonlinear, including a linear mathematical function (for example, by the method mROC), from the dosage values of said genes in each of said subpopulations or cohorts, and calculate the decision threshold or prediction associated with this function because of the choices of sensitivity levels (Se) and specificity (Spe) made (for example, by calculating the threshold maximizing the Youden index),

 combining the dosage values obtained for said subject in this mathematical function, to obtain an output value, which, compared to said decision threshold or prediction, makes it possible to assign an answering machine status or non-responder status to said subject, that is, to classify the subject as one of those subpopulations or reference cohorts with respect to which he has the highest probability of belonging. The invention is based in particular on the demonstration that, when taken in combination, the levels of expression of:

 at least two of HERC5, IL8, STAT2; and

 at least one of CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IFI27, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18,

are biomarkers that provide a predictive "signature" of responder or non-responder status. The person skilled in the art having a combination of genes described by the invention is able to construct a multivariate classification model, in particular a multivariate statistical analysis model (for example a linear or nonlinear mathematical function) or a model of multivariate statistical analysis. learning or artificial intelligence (for example, a learning algorithm or artificial intelligence), with the help of his general knowledge in the field of statistical techniques and means, particularly in the field of processing and processing. statistical interpretation of data, especially biological data. A multivariate classification model can for example be constructed, in particular previously constructed, as follows:

 (a) for a population of individuals who are of the same species as the subject and who are infected with HCV (s), determine for each of those individuals whether they respond to or do not respond to anti-HCV treatment that includes the administration of interferon and ribavirin, and classify these individuals into distinct subpopulations according to whether they have been responders or non-responders to this treatment, thus constituting reference cohorts based on response or non-response of these individuals to anti-HCV treatment; (b) in at least one sample that has been previously obtained from each of the said individuals, the nature of which is identical to that of the sample of the said subject, carry out the same measurements as those made for the subject in the said step i);

 c) make an inter-cohort comparison of the values of the measurements obtained in step b), or of the distribution of these values, in order to construct a multivariate classification model, which induces a responder status to the anti-cancer treatment.

HCV or a non-responder status to this treatment, from the combination of said measurement values obtained in step b).

If said subject or subjects whose responder or non-responder status is to be determined have this fibrosis due to a particular chronic liver disease known, for example, due to infection with a particular genotype of HCV, advantageously uses individuals of comparable clinical situation. Individuals are also selected to constitute a statistically acceptable cohort, with no particular bias, including no particular clinical bias. The objective is to construct a multivariate classification model that is as relevant as possible from a statistical point of view.

 Preferably, cohorts or subpopulations of individuals include as many individuals as possible. If the number of individuals is too small, the comparison or constructed model may not be sufficiently reliable and generalizable for the intended medical applications.

 In particular, cohorts or subpopulations that each comprise at least 30 individuals, for example at least 40 individuals, preferably at least 50 individuals, more particularly at least 70 individuals, and more particularly at least 100 individuals, will be used.

 Preferably, a comparable number of individuals are present in each cohort or subpopulation. For example, the number of individuals in a cohort or subpopulation does not exceed the threshold of 3 times the number of individuals in another cohort, especially the threshold of 2.5 times the number of individuals in a cohort or subpopulation. another cohort.

When the statistical analysis carried out uses a mathematical function, such as for example in the case of a mROC method, the number of individuals required per cohort may be of the order of 20 to 40 individuals per reference cohort. In the case of an automatic learning analysis method, such as a KNN, WKNN, RF or NN method, it is preferable to have at least 30 individuals per cohort, preferably at least 70 individuals, more preferably more particular at least 100 individuals. In the following examples, the total number of individuals in all cohorts is more than 120.

 The individuals making up the reference cohorts are individuals who have received anti-HCV treatment and whose responder or non-responder status has been determined after the application of this treatment, in particular by measuring the HCV load of these individuals. individuals at the end of the treatment, and if this load then became undetectable, 6 months after treatment.

In order to determine the respondent or non-responder status of an individual, and consequently to assign that individual to a reference cohort, the person skilled in the art may implement any means that he deems appropriate. The VERSANT® HCV-RNA 3.0 (bDNA) assay assay from Siemens Healthcare Diagnostics (quantification limit = 615 - 7 690 000 IU / mL) is an example of a means to measure viral load, and to determine if this load became undetectable at the end of treatment and the rest 6 months after treatment (individuals responders), or if this load is still detectable at the end of the treatment (non-responders).

 Although it is of course necessary to limit the number of samples taken on the same individual, especially in case of liver biopsy puncture, several samples can be collected on the same individual. In this case, the assay results of the different samples of the same individual are considered in their resulting average; they are not considered to be equivalent to assay values obtained on separate individuals.

 The comparison of the values of the measurements in each of said cohorts can be done by any means known to those skilled in the art. It is usually done by statistical processing and interpretation of these values. This multivariate statistical comparison makes it possible to construct a multivariate classification model that induces an responder or non-responder status value from the combination of these values.

Once said multivariate classification model is constructed, it can be used for the analysis of the measurement values obtained for said subject, and especially be used for the analysis of the measurement values of other subjects. Thus, said multivariate classification model can be established independently of the measurements made for said one or more subjects, and can be previously constructed.

 If need be, rather than constituting cohorts and collecting the data of the individuals who constitute them, the person skilled in the art can, to build examples of multivariate classification models according to the invention, use, as individuals of cohorts, the topics described in the examples below, and may, as cohort data, use the data presented for these topics in the examples below, particularly in Tables 12-15. below.

Preferably, said multivariate classification model is a particularly discriminating system. Advantageously, said multivariate classification model has an area under the ROC curve (or AUC) and / or a particular LOOCV error value (s). The acronym "AUC" refers to Area Under the Curve, that is, the area under the Receiver Operating Characteristic (ROC) curve. The acronym "LOOCV" means Leave-One-Out-Cross-Validation, cf. Hastie, Tibishirani and Friedman, 2009.

The characteristic of AUC comes especially to apply to the multivariate classification models, which are defined by a mathematical function, as for example the models using a classification mROC method. Artificial intelligence or multivariate machine learning models are not properly defined by a mathematical function. Nevertheless, since they involve a threshold threshold, they can be apprehended using a ROC curve, and therefore an AUC calculation. This is for example the case of models using an RF method {Random Forest). Indeed, in the case of the RF method, a ROC curve can be calculated from the predictions of OOB samples (Out-Of-Bag, or "out-of-the-bag" according to the French translation).

Those models of artificial intelligence or multivariate machine learning, which could not be characterized by an AUC value, can on the other hand, like all other models of artificial intelligence or machine learning multivariate, be characterized by the value of the "classification error" parameter associated with them, such as, for example, the value of the LOOCV error.

Said particular value of AUC may especially be at least 0.84, or at least 0.85 preferably, with a 95% confidence interval to at most ± 11%, more particularly less than ± 10%. , 5%, even more particularly less than ± 9.5%, especially less than ± 8.5%); cf. for example, combinations No. 1 to No. 30 in Tables 7 and 26 below.

 Said particular value of AUC may be at least 0.86, or at least 0.87, or at least 0.88, or at least 0.89, or at least 0, 90 (preferably with a 95% confidence interval to not more than ± 11%, more preferably less than ± 10.5%, more preferably less than ± 9.5%, especially less than ± 8%, 5%). This may especially be the case when one of the combinations No. 1 to No. 30 shown in Table 2 below is combined with one or more other biological factors and / or one or more virological factors and / or one or more clinical factors. for example at least one virological factor and / or at least one other biological factor; cf. for example, combination No. 29 further combined with two other factors (in this case viral load before treatment and concentration of gamma glutamyl transpeptidase) in Table 26 below.

Advantageously, said particular error value LOOCV is at most 17%, or at most 16%), or at most 15%, or at most 14% (see, for example, combinations no. 1 to 30 in Table 3 below). Said particular LOOCV error value may be at most 13%, or at most 12%, or at most 11%), or at most 10%, or at most 9%, or not more than 8%, or not more than 7%, or not more than 6%>, or not more than 5%, or not more than 4%, or not more than 3%, or not more than 2%, or not more than 1%). This may especially be the case when one of the combinations No. 1 to No. 30 shown in Table 2 below is combined with one or more other biological factors and / or one or more virological factors and / or one or more clinical factors. for example at least one virological factor and / or at least one other biological factor. The diagnostic performance of a biomarker is generally characterized according to at least one of the following two indices:

 sensitivity (Se), which represents its ability to detect the so-called population

"pathological" consisting of individuals called "cases" (in this case, patients who have a status of non-responders);

 - specificity (Sp or Spe), which represents its ability to detect the so-called population

"healthy", consisting of so-called "control" patients (in this case, patients who have an answering status).

When a biomarker generates continuous values (for example, concentration values), different predictive threshold positions (Prediction Threshold or PT) can be set to assign a sample to the positive class (positive test: y = \) .

Comparing the concentration of the biomarker with the PT value makes it possible to classify the subject in the cohort at which he has the highest probability of belonging.

 For example, if we consider a cohort of individuals who have responder status and a cohort of individuals with non-responder status, and if we consider a subject or patient p, whose status should be be determined, for which the value of the combination of measures is V (V being equal to Z in the case of the mROC models), the decision rule is as follows:

 - when the average value of the combination of measures in the "responder" cohort is lower than that of the "non-responder" cohort:

 if V> PT: the test is positive, a non-responder status is assigned to said patient p,

if V <PT: the test is negative, an answering machine status is assigned to said patient p, or

 - when the average value of the combination of measures in the "responder" cohort is greater than that of the "non-responder" cohort:

 if V> PT: the test is negative, an answering machine status is assigned to said patient p, - if V <PT: the test is positive, a non-responder status is assigned to said patient p.

Since the combination of biomarkers of the invention is indeed discriminating, the supposed Gaussian distributions of the combination of biomarkers in each population of interest differ significantly. It is then necessary to define the optimal threshold value which will confer on this combination of biomarkers the best diagnostic performance.

 Indeed, for a given threshold PT, the following values can be calculated:

 the number of true positives: VP;

 - the number of false negatives: FN;

 the number of false positives: FP;

 the number of true negatives: VN.

The calculations of the sensitivity parameters (Se) and specificity (Sp) are deduced from the following formulas:

Se = VP / (VP + FN);

Sp = VN / (VN + FP).

 Sensitivity can therefore be considered as the probability that the test is positive knowing that the status of the subject is a non-responder status; and the specificity can be considered as the probability that the test is negative knowing that the status of the subject is an answering machine status.

A ROC curve can be used to visualize the predictive power of the biomarker (or for the multivariate approach, the predictive power of the combination of biomarkers integrated into the model) for different PT values (Swets 1988). Each point of the curve represents the Sensitivity versus (1 -Specificity) for a specific value PT.

For example, if the concentrations of the biomarker of interest vary from 0 to 35, different PT values can be successively set to 0.5; 1; 1.5; ...; 35. Thus, for each PT value, the tested samples are classified, the sensitivity and specificity are calculated and the resulting points are plotted on a graph.

 The closer the ROC curve is to the first diagonal (right connecting the lower left corner to the upper right corner), the poorer the discriminant performance of the model. A test with high discriminating power will occupy the upper left of the graph. A poorly discriminating test will be next to the first diagonal of the graph. The area under the ROC curve (AUC) is a good indicator of diagnostic performance. This varies from 0.5 (non-discriminating biomarker) to 1 (perfectly discriminating biomarker). The value 0.76 induces a discriminant biomarker.

An ROC curve can be approximated by two main techniques: parametric and non-parametric (Shapiro 1999). In the first case, the data is assumed to follow a specific statistical distribution (eg, Gaussian), which is then adjusted to the observed data to produce a smoothed ROC curve. Non-parametric approaches consider the estimation of Se and (1-Sp) from the observed data. The resulting empirical ROC curve is not a smoothed mathematical function, but a piecewise constant curve.

 The choice of the threshold or the optimal threshold, denoted δ (delta), depends on the priorities of the user in terms of sensitivity and specificity. In the case of equitable weights attributed to the sensitivity and specificity, the latter can be defined as the threshold that maximizes the Youden index (J = Se + Sp - 1).

Advantageously, the means of the invention make it possible to achieve:

 - a sensitivity [Se = VP / (VP + FN)] of at least 77% (or more), and / or

 a specificity [Sp = VN / (VN + FP)] of at least 80% (or more).

According to the invention, the sensitivity can be at least 77%, or at least 78%, or at least 79%, or at least 80%, or at least 81%, or at least 82%, or at least 83%, or at least 84% (see, for example, combinations Nos. 1 to 30 in Tables 3 and 23 below).

More particularly, the sensitivity can be at least 80%, at least 81%, or at least 82%, or at least 83%, or at least 84% (see, for example, , combinations No. 1 to 18 in Table 3, see also combination No. 29 combined with other factors (in the occurrence of another biological factor and a virological factor) in Table 23 below).

Alternatively or additionally, the specificity may be at least 79%, at least 80%>, or at least 81%>, or at least 82%, or at least 83%>, or at least 84% o, or at least 85%>, or at least 86%>, or at least 87%, or at least 88%>, or at least 89% >, or at least 90% (see, for example, combinations Nos. 1 to 30 in Tables 3 and 23 below).

 Specifically, the specificity may be at least 84%>, or at least 85%>, or at least 86%>, or at least 87%, or at least 88%, or at least 89%, or at least 90% (see, for example, combinations No. 1 to 24 in Table 3).

All combinations of these sensitivity thresholds and specificity thresholds are explicitly included in the content of the application (see, for example, combinations Nos. 1 to 30 in Tables 3 and 23 below).

 More particularly, all combinations comprising at least the combination of a sensitivity threshold and a specificity threshold are explicitly included in the content of the application. Alternatively or additionally to these characteristics of sensitivity and / or specificity, the Negative Prediction Values (VPN) reached, or likely to be achieved, by the means of the invention are particularly high.

The VPN is equal to VN / (VN + FN), with VN = True Negatives and FN = False Negatives, and therefore represents the probability that the test subject is responder to the anti-HCV treatment, knowing that the test of the invention is negative.

 In accordance with the invention, the VPN may be at least 80%, or at least 81%, or at least 82%, or at least 83%, or at least 84%, or at least 85%, or at least 86%, or at least 87% (see, for example, combinations Nos. 1 to 30 in Tables 3 and 23 below).

More particularly, the VPN may be at least 84%, or at least 85%, or at least 86%, or at least 87% (e.g. 2 to 6, 14 to 28 in Table 3; cf. also combination No. 29 combined with other factors (in this case another biological factor and a virological factor) in Table 23 below). All combinations of VPN thresholds and / or sensitivity thresholds and / or specificity thresholds are explicitly included in the content of the request.

More particularly, all combinations comprising at least the combination of a sensitivity threshold and a VPN threshold are explicitly included in the content of the application.

Alternatively or additionally to these characteristics of sensitivity and / or specificity and / or VPN, the Positive Prediction Values (VPP) achieved, or likely to be achieved, by the means of the invention are particularly high. The VPP is equal to VP / (VP + FP) with VP = True Positive and FP = False Positive, and therefore represents the probability that the test subject is non-responder, knowing that the test of the invention is positive.

 In accordance with the invention, the VPP may be at least 72%, or at least 73%), or at least 74%, or at least 75%, or at least less than 76%, or at least 77%, or at least 78%, at least 79%, or at least 80%, or at least 81%, or at least 82% %, or at least 83%, or at least 84%, or at least 85%, or at least 86%), or at least 87%, or at least 88% or at least 89% (see, for example, combinations Nos. 1 to 30 in Tables 3 and 23 below).

 In particular, the PPV may be at least 78%, at least 79%, or at least 80%, or at least 81%, or at least 82%, or at least less than 83%, or at least 84%), or at least 85%, or at least 86%, or at least 87%, or at least 88%, or at least 89% {see, for example, combinations No. 1 to 24 in Table 3 below).

All combinations of VPP and / or VPN thresholds and / or sensitivity thresholds and / or specificity thresholds are explicitly included in the content of the request.

More particularly, all combinations comprising at least the combination of a sensitivity threshold and a VPP threshold are explicitly included in the content of the request. More particularly, all the combinations comprising at least one of said VPN thresholds and / or at least one of said sensitivity thresholds, more particularly at least one of said VPN thresholds and one of said sensitivity thresholds, more particularly at least one of said VPN thresholds. and one of said sensitivity thresholds and one of said specificity thresholds are included in the application. The predictive combinations of the invention include combinations of gene expression levels, selected as above indicated.

 As indicated in more detail below, and as illustrated in the examples below (cf. Example 2d) below), it may nevertheless be chosen to involve in these combinations one or more factors other than the levels of expression of these genes, to combine this or these other factors and the expression levels of the selected genes. as a decision rule.

 This or these other factors are preferably chosen so as to construct a classification model whose predictive power is further improved compared to the model that does not include this or these other factors.

 In addition to the level of expression of said selected genes, it is also possible to measure or measure one or more other factors, such as one or more clinical factors and / or one or more virological factors and / or one or more biological factors other than the level of expression of said selected genes (cf. for example, Tables 23 to 26 below, which gives an example for Combination No. 29).

 The value (s) of this (these) other factor (s) can then be taken into account to build the multivariate classification model, and can thus lead to further improved classification performance, particularly sensitivity and / or specificity characteristics and / or increased VPN and / or VPP.

 For example, if we compare the values presented for combination No. 29 in Tables 3 and 7 on the one hand, and in Tables 23 and 26 on the other hand (cf. below), it is found that the sensitivity, specificity, VPN, VPP and AUC values increase (without decreasing the specificity) when, at the combination of the transcription levels of said selected genes, other factors are combined. , including another biological factor (in this case, PAL) and a virological factor (in this case, CVavantTTT).

Advantageously, when one or more other factors are combined with a combination of genes selected from said list of twenty-eight genes of the invention, at least one of the characteristics of AUC (if any, of LOOCV error) sensitivity, specificity, VPN and VPP are improved.

As previously indicated, and as illustrated below, the means of the invention involve the assay of the level of expression of:

at least two of HERC5, IL8, STAT2; and at least one of CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2 , STAT1, STMN2, USP18.

 Advantageously, the total number of genes thus chosen is 3, 4, 5 or 6, more particularly 3, 4 or 5, for example 4 or 5.

 The choice of genes is made according to the requirements or desired performance to be achieved, for example depending on the sensitivity and / or specificity and / or VPN and / or VPP that one wishes or wishes to achieve. Of course, the smaller the number of selected genes, the easier the implementation of the means of the invention is.

All possible gene choices are explicitly included in the application.

 Similar to what has been indicated above for sensitivity thresholds, specificity thresholds, VPN thresholds, VPP thresholds, and the total number of genes chosen, all the gene combinations chosen in each of the lists of genes and / or total numbers of selected genes and / or sensitivity thresholds and / or specificity thresholds and / or VPN thresholds and / or VPP thresholds are explicitly included in the content of the application.

Thirty examples of gene combinations according to the invention are shown in Table 2 below.

Tables 3 to 7 below illustrate the performance of the combination of transcription levels of four or five genes (in this case, the Ct value that was measured for the RNA transcripts of this gene and which was normalized by the 2 ^{~ ACt method} ).

Tables 23 to 26 below illustrate the performance of the combination of the transcription levels of five genes chosen according to the invention (combination No. 29), when these levels are further combined with other factors (in another biological factor such as the concentration of alkaline phosphatase, and a virological factor such as the HCV load before treatment).

For example, said genes selected from said list of twenty-eight genes of the invention are:

 HERC5, IFI44, IL8, MDK (combination No. 1), or

 - HERC5, IFI44, IL8, MDK, OAS 1 (combination No. 2), or

G1P2, IL8, OCLN, STAT2, USP18 (combination No. 3), or CXCL6, IFIT4, IL8, STAT1, STAT2 (combination No. 4), or

 CXCL6, IL8, MX1, PLSCR1, STAT2 (combination No. 5), or

 CXCL6, IL8, MX1, STAT1, STAT2 (combination No. 6), or

 - HERC5, IFI44, IL8, MDK, STMN2 (combination No. 7), or

HERC5, IL8, PLSCR1, STMN2 (combination No. 8), or

 - HERC5, IFI35, IFIT1, IL8, MX1 (combination 9), or

 - HERC5, IFI44, IL8, OAS1, RSAD2 (combination No. 10), or

 HERC5, IFI44, IL8, ITGA2, MDK (combination No. 11), or

 - HERC5, IFIT1, IL8, MX1 (combination # 12), or

HERC5, IL8, MDK, OAS3, RSAD2 (combination No. 13), or

 - CCL21, G1P2, IL8, MDK, STAT2 (combination No. 14), or

 - G1P2, IFITM1, IL8, OCLN, STAT2 (combination No. 15), or

 - G1P2IL8, OAS1, OCLN, STAT2 (combination No. 16), or

 CLDN1, IL8, OAS2, OAS3, STAT2 (combination No. 17), or

- CXCL6, IFITM1, IL8, MX1, STAT2 (combination No. 18), or

 - CXCL6, IFIT1, IL8, STAT2 (combination No. 19), or

 FOXO1, G1P2, IL8, MDK, STAT2 (combination No. 20), or

 CXCL6, G1P2, IL8, MDK, STAT2 (combination No. 21), or

 CXCL6, IL8, OAS2, STAT1, STAT2 (combination No. 22), or

FOXO1, IFI27, IFITM1, IL8, STAT2 (combination No. 23), or

 - HERC5, IFI35, IFI44, IL8, OAS2 (combination No. 24), or

 IL8, CCL21, G1P3, HERC5, RSAD2 (combination No. 25), or

 IL8, G1P3, HERC5, OAS3, RSAD2 (combination No. 26), or

 IL8, ITGA2, G1P3, HERC5, RSAD2 (combination No. 27), or

IL8, STMN2, G1P3, HERC5, RSAD2 (combination No. 28), or

 IL8, CLDN1, G1P3, HERC5, RSAD2 (combination No. 29), or

 IL8, G1P3, HERC5, LGALS3BP, RSAD2 (combination No. 30).

According to one embodiment of the invention, said at least two genes selected from HERC5, IL8, STAT2 comprise IL8, more particularly IL8 and HERC5 or IL8 and STAT2. These are in particular combinations No. 1 to No. 30 above listed.

According to an alternative or complementary embodiment of the invention, the number of genes selected from CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2 and USP18, is 1, 2, 3 or 4, more particularly 1, 2 or 3. , for example 2 or 3. According to an alternative or complementary embodiment of the invention, the number of genes selected from CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1. , ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2 and USP18, is at least two, and these at least two genes comprise at least two of:

CXCL6, IFI44, MDK, MX1 and RSAD2.

 According to an alternative or complementary embodiment of the invention, said at least one gene selected from CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2 and USP18, is:

CXCL6, IFI44, MDK, MX1 or RSAD2.

 This is particularly the case with combinations Nos. 1, 2, 4, 5, 6, 7, 9, 10, 11, 13, 14, 18, 19, 20, 21, 22, 24, 25, 26, 27, 28, 29 and 30 above listed.

According to an alternative or complementary embodiment of the invention, the number of genes selected from CCL21, CLDN1, CXCL6, FOX01, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1. , OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2 and USP18, is at least two, and these at least two genes include IF144 and MDK. This is particularly the case of combinations Nos. 1, 2, 7 and 11 listed above.

According to an alternative or complementary embodiment of the invention, said genes chosen in step i) do not comprise CLDN1, G1P3, IF127, IFITM1, ITGA2, OCLN and PLSCR1. This is especially the case for combinations Nos. 1, 2, 4, 6, 7, 9, 10, 12, 13, 14, 19, 20, 21, 22 and 24 above listed. The genes CLDN1, G1P3, IF127, IFITM1, ITGA2, OCLN and PLSCR are those genes of said list of twenty-eight genes of the invention, which encode a protein whose location is strictly membrane.

According to an alternative or complementary embodiment of the invention, said genes chosen according to the invention do not comprise any gene that encodes a protein whose location is strictly membrane. Such genes do not permit the assay of their levels of expression in a biological fluid sample of said subject (such as a sample of intracorporeal fluid, such as blood, serum, plasma, or a urine sample). According to an alternative or complementary embodiment of the invention:

 the number of genes selected from CCL21, CLDN1, CXCL6, FOX01, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2; , STAT1, STMN2 and USP18, is at least two, and these at least two genes comprise at least two genes among CXCL6, IFI44, MDK, MX1 and RSAD2, more particularly among IFI44, MDK, MX1 or

RSAD2, and

 said genes selected in step i) do not comprise CLDN1, G1P3, IF127, IFITM1, ITGA2, OCLN and PLSCR1, and / or said genes chosen in accordance with the invention do not comprise any gene which encodes a protein whose location is strictly membrane.

This is particularly the case for combinations Nos. 1, 2, 5, 11, 18, 25, 26, 27, 28, 29 and 30 above listed.

Table 2: Examples of combinations of expression levels of four or five genes

 Selected genes

 combination

 1

 HERC5 IFI44 IL8 MDK

 2

 HERC5 IFI44 IL8 MDK OAS1

3

 G1P2 IL8 OCLN STAT2 USP18

4

 CXCL6 IFIT4 IL8 STAT1 STAT2

5

 CXCL6 IL8 MX1 PLSCR1 STAT2

6

 CXCL6 IL8 MX1 STAT1 STAT2

7

 HERC5 IFI44 IL8 MDK STMN2

8

 HERC5 IL8 PLSCR1 STMN2

 9

 HERC5 IFI35 IFIT1 IL8 MX1

10

 HERC5 IFI44 IL8 OAS1 RSAD2

11

 HERC5 IFI44 IL8 ITGA2 MDK

12

 HERC5 IFIT1 IL8 MX1

 13

 HERC5 IL8 MDK OAS3 RSAD2

14

CCL21 G1P2 IL8 MDK STAT2

Table 2 (continuation and end): examples of combinations of the expression levels of four or five genes

 Selected genes

 combination

 15

 G1P2 IFITM1 IL8 OCLN STAT2

16

 G1P2 IL8 OAS1 OCLN STAT2

17

 CLDN1 IL8 OAS2 OAS3 STAT2

18

 CXCL6 IFITM1 IL8 MX1 STAT2

19

 CXCL6 IFIT1 IL8 STAT2

 20

 FOXOl G1P2 IL8 MDK STAT2

21

 CXCL6 G1P2 IL8 MDK STAT2

22

 CXCL6 IL8 OAS2 STAT1 STAT2

23

 FOXOI IFI27 IFITM1 IL8 STAT2

24

 HERC5 IFI35 IFI44 IL8 OAS2

25

 IL8 CCL21 G1P3 HERC5 RSAD2

26

 IL8 G1P3 HERC5 OAS3 RSAD2

27

 IL8 ITGA2 G1P3 HERC5 RSAD2

28

 IL8 STMN2 G1P3 HERC5 RSAD2

29

 IL8 CLDN1 G1P3 HERC5 RSAD2

30

IL8 G1P3 HERC5 LGALS3BP RSAD2

Table 3: Sensitivity (Se), Specificity (Spe), Negative Predictive Value (VPN), Positive Predictive Value (PPV), and LOOCV values that can be associated with combinations of transcription levels of four or five selected genes according to the invention (RNA transcripts, more particularly RNA of a tissue sample or liver cells)

LOOCV error = cross-validation error or "Leave-One-Out Cross Validation" (Hastie, Tibishirani and Friedman, 2009); ND = determined

Table 3 (continued): Sensitivity values (Se), Specificity (Spe), Negative Predictive Value (NPV), Positive Predictive Value (PPV) error LOOCV that can be associated with combinations of transcriptional levels (RNA) of four or five cho genes according to the invention (RNA transcripts, more particularly RNA of a tissue sample or liver cells)

LOOCV error = cross-validation error or "Leave-One-Out Cross Validation" (Hastie, Tibishirani and Friedman, 2009); ND = determined

Table 3 (continuation and end): Sensitivity values (Se), specificity (Spe), Negative Predictive Value (NPV), Positive Predictive Value (PPV) error LOOCV that can be associated with combinations of transcription levels (RNA) of four or five genes selected according to the invention (RNA transcripts, more particularly RNA from a tissue sample or liver cells)

LOOCV error = cross-validation error or "Leave-One-Out Cross Validation" (Hastie, Tibishirani and Friedman, 2009); ND = determined

ND = not determined

Table 4: Examples of setting parameters for classification models established according to WKNN method No. of combination

 Distance (D) Number of neighbors (k) Kernel (K)

{Cf. Tables 2 and 3 above)

 1 1 5 reverse

 2 2 4 triangular

7 1 6 triangular

8 1 7 cosine

 9 1 14 tri-weighted

10 1 6 cosine

 11 2 3 inverse

 12 1 10 triangular

13 2 3 inverse

Table 5: examples of mROC models (Z function) combining the transcription levels of four or five selected genes (transc RNA, more particularly RNA from a tissue sample or liver cells), and example of a PT threshold for these functions. occurrence, threshold maximizing the Youden index δ)

 Function No. Z Combining Threshold Levels Combination Threshold Combination (RNA) Genes Selected Function PT

{Cf. Tables 2 and 3 (δ) above)

 Z = 0.218 x CCL21 * + 0.441 x G1P3 * + 0.98 x HERC5 * + 0.121 x IL8 - 0.482 x RSAD2 * Z25ARN -2, 182

26 Z = 0.437 x G1P3 * + 0.99 x HERC5 * + 0.131 x IL8 + 0.151 x OAS3 * - 0.522 x RSAD2 * Z26ARN -1.239

27 Z = 0.508 x G1P3 * + 1.036 x HERC5 * + 0.124 x IL8 + 0.084 x ITGA2 - 0.467 x RSAD2 * Z27ARN -1.444

Z = 0.511 x G1P3 * + 1.038 x HERC5 * + 0.127 x IL8 - 0.468 x RSAD2 * + 0.017 x STMN2 Z28ARN -1.472

29 Z = 0.134 x CLDN1 * + 0.488 x G1P3 * + 0.966 x HERC5 * + 0.129 x IL8 - 0.487 x RSAD2 * Z29ARN -1.281

Z = 0.4 x G1P3 * + 1.028 x HERC5 * + 0.13 x IL8 + 0.11 x LGALS3BP * - 0.481 x RSAD2 * Z30ARN -1.594

Table 6: List of genes, for which it is advisable to normalize the measured assay values (in particular, the assay values RNA transcription levels, more particularly when these RNAs come from a tissue sample or liver cells), for example by a Box-Cox normalization, and example of Box-Cox parameter values (λ) usable in the Z functions indicated in Table 5 above.

Genes, for which

 Example of value of

 it is advisable to

 Box-Cox parameter (λ)

 normalize value

 usable for Z functions

 level of

 from Table 5 above

 transcription (ARN)

 CCL21 0.02

 G1P3 0, 19

 HERC5 0, 19

 RSAD2 -0.05

 OAS3 0, 13

 CLDN1 0.68

LGALS3BP -0.06

Table 7: AUC Table 5 Z-functions Combination No. Function Name AUC AUC Limit AUC Limit

{Cf. table 2 above) (cf. Table 5 above) lower upper

 25 Z25ARN

 0.854 0.759 0.916

26 Z26ARN

 0.853 0.758 0.915

27 Z27ARN

 0.854 0.757 0.916

28 Z28ARN

 0.855 0.759 0.917

29 Z29ARN

 0.857 0.761 0.919

30 Z30ARN

0.856 0.761 0.917

In addition to the levels of expression of said genes selected from the list of seventeen genes of the invention, the means of the invention may further comprise the combination of one or more other factors, such as:

 - one or more clinical factors, such as:

 o sex (female F or male M),

 o Age at the date of collection (Age), for example, age at time of PBH, age at hepatic puncture, age at time of collection of blood, serum, plasma or urine,

 o patient's age at the time of infection,

 o age of the patient at the beginning of the treatment,

 o body mass index (BMI),

 o insulin sensitivity index (HOMA),

 o diabetes,

 o alcohol consumption,

 o degree of steatosis,

 o mode of contamination,

 o Metavir activity,

 o hepatic fibrosis score measured according to the Metavir system (Metavir F score) or the Ishak system;

and or

 - one or more virological factors, such as:

 o viral genotype, more particularly genotype of the HCV (s), o duration of the infection,

 o viral load before treatment, more particularly HCV load before treatment (CVavantTTT),

 o viral load, more particularly HCV load, measured in the patient at the start of treatment (viral load on day 0), o viral load, more particularly HCV load, measured in the patient at the date of sampling (viral load at PBH, viral load at the time of hepatic cytopuncture, viral load at the time of collection of blood, serum, plasma or urine);

and or one or more biological factors other than the expression levels of said selected genes, which can be chosen in particular from concentrations, levels or levels of intracorporeal proteins, concentrations, levels or levels of intracorporeal metabolites, concentrations, levels or levels thereof; figured elements of the blood, measures representative of the amount of circulating iron, such as:

 o haptoglobin concentration (Hapto),

 o concentration of apolipoprotein Al (ApoAl),

 o total bilirubin content (TLB),

 o concentration of gamma glutamyl transpeptidase (GGT),

 o concentration of aspartate aminotransferase (AST),

 o concentration of alanine aminotransferase (ALT),

 o platelet content (PLQ),

 o prothrombin rate (TP),

 o HDL cholesterol content (Chol-HDL),

 o total cholesterol content,

 Ferritin concentration (ferritin),

 o glycemic content (glycemia),

 o concentration in peptide C,

 o insulin content (insulinemia),

 o concentration of triglycerides (TG),

 o albumin content,

 iron saturation factor of transferrin (CS),

 o alkaline phosphatase concentration (PAL).

Tables 23 to 26 below (combination No. 29) illustrate the performance of the combination of transcription levels of five genes (in this case, the Ct value that was measured for the RNA transcripts of this gene and which was has been standardized with the 2 ^"ACt ) method, combined with one or more other biological factors and / or one or more virological and / or one or more clinical factors (in this case another biological factor such as concentration alkaline phosphatase, and a virological factor such as HCV loading before treatment).

This or these other factors can be measured on a sample of a different nature from that used to measure the expression levels of said selected genes. For example, the biological sample for measuring the expression levels of said genes selected from said list of twenty-eight genes of the invention may be a sample of PBH or hepatic cytopuncture, and the biological sample for measuring the values said other factors may be a biological fluid sample, such as blood, plasma or serum or urine. Likewise, the nature of the level of expression measured may be different; for example, for measuring the level of expression of said selected genes, the levels of their transcription can be measured in RNA, whereas for those of said other factors which are biological factors, the level of expression measured will generally be a concentration. protein.

The measurement or measurement of some of these factors could sometimes be considered as the determination of the level of translation (measurement of the protein concentration) of a gene other than a gene chosen according to the invention (for example PAL; example 2d) below).

The number of genes whose level of expression is assayed, and which are not genes selected from said list of twenty-eight genes of the invention (for example PAL), is preferably at most 18, more particularly of 14 or less, more particularly 11 or less, more particularly 6 or less, more particularly 4 or 3 or 2 or 1 or 0, more particularly 3 or 2 or 1 or 0, especially 2 or 1 or 0.

Advantageously, this or these other factors are or comprise one or more biological factors, in particular the concentration of alkaline phosphatase (PAL).

Example 2d) above gives an illustration of such combinations.

Alternatively or additionally, this or these factors may more particularly be or comprise one or more of the following virological factors:

 o viral load before treatment (CVavantTTT); and or

 o genotype of HCV (s).

 Example 2d) and 3b) above give an illustration of such combinations.

Alternatively or additionally, this or these factors may more particularly be or comprise one or more clinical factors, in particular the clinical factor score. hepatic fibrosis, which can be measured using the Metavir system (Metavir F score) or the Ishak system.

According to a particular embodiment of the invention, in addition to the assay of gene expression levels selected from said list of twenty-eight genes of the invention, the means of the invention may further comprise the assay or the measure of other factors:

 - one or more clinical factors that is or includes the liver fibrosis score (which can be measured using the Metavir system (Metavir F score) or the Ishak system); and or

 - one or more virological factors that is or includes the genotype of the HCV (s) and / or the HCV load before treatment; and or

 one or more biological factors other than the expression levels of genes selected from CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1 , OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18, which is or include the alkaline phosphatase (ALP) concentration.

Alternatively or additionally, in addition to the assay of gene expression levels selected from said list of twenty-eight genes of the invention, the means of the invention may further comprise:

 determining the hepatic fibrosis score of said subject, more particularly determining whether the liver fibrosis score of said subject is a score which, according to the Metavir score system, is at most Fl or at least F2 more particularly at least F2; and or

 determining whether the HCV or HCV of which said subject is infected comprises HCV of genotype 1, 4, 5 or 6, more particularly of genotype 1 or 4, more particularly of genotype 1.

These determinations can be made during step i), or be done independently of step i). Table 23: Sensitivity (Se), Specificity (Spe), Negative Predictive Value (VPN), Positive Predictive Value (PPV), and LOOCV values that can be associated with a combination of transcription levels of five genes selected according to at the time of invention (RNA transcripts, more particularly when these RNAs are derived from a tissue sample or liver cells), combined with other biological factors and / or clinical factors and / or virological factors

(*): The values of Se, Spe, VPN, VPP and Error LOOCV given are those of the function of Table 24 below.

 (§): more particularly, RNA derived from a tissue sample or liver cells

10 NA = not determined

Table 24: example of model mROC (function Z) for a combination of five genes selected according to the invention (assay their RNA transcription levels), combined in addition to other factors (biological factors other than the levels of expressio genes selected according to the invention and / or clinical factors and / or virological factors), and example of threshold PT for this function the occurrence, threshold maximizing the Youden index δ),

(§): more particularly, RNA derived from a tissue sample or liver cells

Table 25: Example of Box-Cox parameter values (λ) usable in the Z function indicated in Table 23 above.

(*): lambda parameter of the Box-Cox transformations [BMQ * = (ΒΜ0) ^λ -1) / λ] Table 26: for the function of Table 24, AUC value

 AUC Name AUC limit AUC limit

 upper lower function

 Z29ARNsupp

 0.904 0.828 0.948

{Cf. table 24)

According to a complementary aspect of the invention, the application relates to products or reagents for detecting and / or determining and / or assaying said measurements, more particularly for detecting and / or assaying the levels of expression of said selected genes, and manufactured articles, compositions, pharmaceutical compositions, kits, tubes, solid supports comprising such reagents, as well as computer systems (in particular, computer program product and computer device), which are especially adapted to the implementation of a method of the invention. The application relates in particular to a reagent which specifically detects a transcript (RNA) of one of said genes selected from said list of twenty-eight genes of the invention, or a translation product of one of said selected genes. among said list of twenty-eight genes of the invention (protein, or post-translational form of this protein, such as a specific fragment of this protein).

The application relates in particular to reagents that specifically detect each of the transcription products (RNA) of said genes selected from said list of twenty-eight genes of the invention, or each of the translation products of said genes selected from said list of twenty-eight genes of the invention (protein, or post-translational form of this protein, such as a specific fragment of this protein).

Advantageously, a set of such reagents is formed, which detects each of said transcription products of said selected genes and / or which detects each of said translation products of said genes selected from said list of twenty-eight genes of the invention, that is, that is, a set of reagents that specifically detect at least one expression product for each of these genes.

Preferably, said reagents not only specifically detect a transcription or translation product, but also make it possible to quantify it.

The application relates in particular to a manufactured article comprising said reagents as a combination product (or in combined form, or in combined preparation), in particular for their simultaneous, separate or spread use over time. This manufactured article may for example be in the form of a set of reagents, or a kit. Of course, the characteristics of the selected gene combinations described above, as well as those illustrated below, apply to the reagents of the invention mutatis mutandis.

 Said reagents may, for example, hybridize specifically to the RNA of said selected genes and / or to the cDNA corresponding to these RNAs (under at least stringent conditions of hybridization), or to bind specifically to the proteins encoded by said selected genes (or specific fragments of these proteins), for example according to an antigen-antibody type reaction.

 At least stringent hybridization conditions are known to those skilled in the art. It can for example be the following conditions:

 for filter hybridization: in 5xSSC, 2% sodium dodecyl sulfate (SDS), 100 micrograms / mL single-stranded DNA at 55-65 ° C for 8 hours, and wash in 0.2xSSC and 0.2% SDS at 60-65 ° C for thirty minutes;

 for PCR hybridization: the PCR conditions shown in Example 1 below.

 Said reagents of the invention may especially be:

 nucleic acids (DNA, RNA, mRNA, cDNA), including oligonucleotide aptamers, optionally labeled to enable their detection, in particular with fluorescent markers well known to those skilled in the art, or

 protein ligands, such as proteins, polypeptides or peptides, for example aptamers, and / or antibodies or antibody fragments.

The nucleic acids of the invention may for example be primers and / or probes (cf. SEQ ID NO: 1 to 56 in Table 10 below), especially pairs of primers (cf. the primer pairs shown in Table 10 below). For each of said genes selected from said list of twenty-eight genes of the invention, one skilled in the art can construct a pair of primers and / or a probe that specifically hybridizes to that gene. An article of manufacture of the invention may therefore comprise the number of primers and / or probes necessary for the detection of the RNA or cDNA of each of said selected genes.

The nucleic acid sequence of the invention may, for example, be from 9 to 40 nucleotides, more particularly from 10 to 30 nucleotides, more particularly from 14 to 29 nucleotides, more particularly from 19 to 24 nucleotides. The sequences of the primers of the same pair may for example be the sequences of a fragment of the sequence of one of said selected genes and a fragment of its complementary sequence (cf. Table 1 indicating the sequence accession numbers of these genes). One and / or the other of these two primer sequences may not be strictly identical to the sequence of a fragment of the gene or its complementary sequence; one and / or the other of these two primer sequences can:

 deriving therefrom by one or more substitutions and / or additions and / or deletions of nucleotides, more particularly by one or more nucleotide substitutions, and / or having a sequence identity of at least 80%, or at least 85%, or at least 90%, or at least 95% with the sequence of this fragment or its complementary sequence (identity calculated over the longest of the two aligned sequences - optimal alignment),

 since the resultant primer pair has retained the ability to hybridize specifically to one of said selected genes.

A primer pair of the invention advantageously has a Tm delta of about 1 ° C or less. According to one embodiment of the invention, a pair of primers of the invention targets an amplicon of about 70 to 120 bp (i.e., the sense primer and the antisense primer hybridize to such positions on the target nucleic acid, that amplicon produced by elongation of these hybridized primers has a length of about 70 to 120 bp).

Examples of such primers and primer pairs are shown in Table 10 below (SEQ ID NO: 1 to 56, forming 28 pairs of primers).

The sequence of a probe of the invention may for example be:

 the sequence of a fragment of the sequence of one of said selected genes (cf. Table 1 indicating the sequence accession numbers of these genes), said fragment hybridizing specifically to the sequence of this gene;

 - a sequence :

which derives from the sequence of such a fragment by one or more substitutions and / or additions and / or nucleotide deletions, more particularly by one or more nucleotide substitutions, and / or a sequence which has a sequence identity of at least 80%, or at least 85%, or at least 90%, or at least 95% with the sequence of this fragment or its complementary sequence (identity calculated on the longest of the two aligned sequences - alignment optimal-), but o which has retained the ability to hybridise specifically to one of said selected genes;

 and or

 a sequence complementary to such sequences.

A probe of the invention may in particular be a probe for real-time amplification, intended to be used with a pair of primers of the invention. Alternatively, detection in real-time PCR may use intercalent molecules (eg SYB green) which have the property of intercalating in double-stranded structures. The ligands of the invention which specifically bind to the proteins encoded by the genes selected from said list of twenty-eight genes of the invention (or to specific fragments of these proteins) may be for example proteins, polypeptides or peptides, for example aptamers, or antibodies or antibody fragments.

For each of said selected genes, one skilled in the art can produce such a ligand.

Antibodies may for example be produced by immunizing a non-human mammal (such as a rabbit) with a protein encoded by said selected gene, or with an antigenic fragment of such a protein, possibly associated with or coupled to an adjuvant immunization (such as Freund's adjuvant or such as KLH -keyhole limpet hemocyanin-), for example by intraperitoneal or subcutaneous injection, and by collecting the antibodies thus obtained in the serum of said mammal.

Monoclonal antibodies can be produced according to a lymphocyte hybridization technique (hybridomas) such as the Kohler and Milstein 1975 (see also US 4,376,110), the human B-cell hybridoma technique (Kosbor et al. 1983, Cole et al., 1983), or the technique of immortalizing lymphocytes using the Epstein-Barr-EBV-virus (Cole et al., 1985). Such antibodies may for example be IgG, IgM, IgE, IgA, IgD or any subclass of these immunoglobulins.

 Genetically engineered antibodies can be produced, such as recombinant, chimeric, humanized antibodies by grafting one or more CDR -Complementary Determining Region-.

 The antibodies used in the invention may be antibody fragments or artificial derivatives of such fragments, insofar as these fragments or derivatives have said specific binding property. Such fragments may for example be Fab, F (ab ') 2, Fv, Fab / c, scFv (single chain Fragment variable) fragments.

Examples of antibodies are given in the following Table 27. Table 27: Examples of specific antibodies

 MAb = monoclonal antibody

AcP = polyclonal antibody

Table 27 (continued): examples of specific antibodies

MAb = monoclonal antibody

AcP = polyclonal antibody

Table 27 (continuation and end): examples of specific antibodies

MAb = monoclonal antibody

AcP = polyclonal antibody

Other examples of means for assaying the transcription levels of selected genes are also presented in Table 16 below (immunoassay kits).

Said reagents may further comprise a marker for their detection (for example, an ophore fluorine).

 Said reagents may be in the form of composition (s), pharmaceutical composition (s), for example in a tube (s) or in a well (s) of a plate of nucleic acid amplification.

 Said reagents may be in a mixture, or in separate forms or physically separated from each other.

 Said reagents may be attached to a solid support, for example a support made of polymer, plastic, in particular polystyrene, glass or silicon.

 Said reagents may be attached directly or indirectly to said solid support, for example via a binding or capture agent which is attached to the solid support. The binding or capture agent may comprise a portion attached to said solid support and a portion that comprises a ligand that specifically binds to one of said selected genes.

Such a ligand may for example be an antibody, a monoclonal antibody, in particular a human antibody such as IgG, IgM or IgA, or a fragment of such an antibody having retained the binding specificity.

Said solid support may for example be a plastic plate, in particular polystyrene, comprising several analysis wells, such as a titration plate or protein microtitre, for example, an ELISA plate.

 Said solid support can also be magnetic microbeads or not, for microtitration, for example according to the technique described by Luminex.

Said solid support may for example be a nucleic acid, protein or peptide chip, for example a chip made of plastic, glass or silicon.

Said reagents may not be fixed to a solid support and may for example be contained in a solution, such as a buffer, for example for their storage until use. More particularly, the reagents may be nucleic acids not bound to a solid support, whose nucleotide sequence is adapted to the specific amplification (case of primers or primer pairs) and / or specific hybridization (case probes) of the transcription product (RNA) of one of said genes selected from said list of twenty-eight genes of the invention. In addition to reagents which detect the transcripts or translation products of mammalian genes, more particularly human genes, and in particular genes selected from said list of twenty-eight genes of the invention, a manufactured article conforming to the application can optionally include other reagents, for example reagents to assay or determine one or more virological factors and / or one or more clinical factors.

 For example, a demand-manufactured article may include reagents that specifically detect one or more hepatitis viruses, and / or its or their genotype.

According to one embodiment, the application relates to an article of manufacture comprising reagents in combined preparation for their simultaneous, separate or spread use over time, said reagents being constituted:

 reagents which specifically detect (preferably, which specifically detect and quantify) each of the transcription or translation products of 3 to 46 mammalian genes, more particularly from 3 to 46 human genes, (e.g. by specifically hybridizing to RNA of these genes and / or to the cDNA obtained by reverse transcription of these RNAs, or by specifically binding to the proteins encoded by these genes), said 3 to 46 mammalian genes , or, where appropriate, said 3 to 46 human genes, comprising said genes selected from said list of twenty-eight genes of the invention,

and

 optionally, reagents which specifically detect (preferably which specifically detect and quantify) a hepatitis virus and / or the genotype of a hepatitis virus.

In this manufactured article, the number of mammalian genes, more particularly human genes whose transcription or translation products can be detected, is from 3 to 36, more particularly from 3 to 33, more particularly from 3 to 28, more particularly from 3 to 26, more particularly from 3 to 25, more particularly from 3 to 24, more particularly from 3 to 23, more particularly from 3 to 22, more particularly from 3 to 20, more particularly from 3 to 19, more particularly from 3 to at 10, more particularly from 3 to 9, more particularly from 3 to 8, more particularly from 3 to 7 (for example from 4, 5, 6 or 7), more particularly from 3 to 6 (for example from 4, 5 or 6), more particularly from 3 to 5 (for example, 3, 4 or 5). The mammalian genes, more particularly the human genes, whose transcription or translation products can be detected by the reagents contained in the manufactured article of the application comprise said genes selected from said list of twenty-eight genes of the invention. and optionally other genes, which are not genes selected from said list of twenty-eight genes of the invention, but whose expression product, more particularly, of translation may be of interest, such as the genes listed here as "other biological factors" (for example, the gene encoding alkaline phosphatase or PAL).

 In the manufactured article of the application, the number of reagents that specifically detect the expression product of mammalian genes (more particularly human genes) that are not genes selected from said list of twenty-eight genes of the invention (for example, a reagent specifically detecting PAL) is preferably at most 5, more preferably 4 or less, more preferably 3 or less, more preferably 2 or less, more preferably 2 or less; 1 or 0. Said manufactured article can therefore for example be:

 - one or more tubes,

 a kit, in particular a kit comprising one or more tubes,

 a solid support, for example, made of plastic, polystyrene, glass, silicon or polymer, or comprising a magnetic material such as iron oxide, such as:

 a plastic plate comprising several analysis wells such as:

^■ a nucleic acid amplification plate having wells for receiving a biological sample and a reaction mixture of nucleic acid amplification, ■ a titer plate or microtiter protein, especially an ELISA plate,

 magnetic microbeads (for example, microbeads made from iron oxide, and coated with a polymer to which the proteins or polypeptides can adhere or be attached by chemical coupling); a nucleic acid, protein, polypeptide or peptide chip.

Optionally, the manufactured article of the invention further comprises instructions (e.g., an instruction sheet) for assaying the level of expression of said selected genes on a biological sample collected or obtained from said subject, more particularly for implementing implement a method of the invention. Said manufactured article may further include one or more of the following:

 - an instrument for taking the sample, in particular:

 a needle and / or a syringe, more particularly a needle and / or a syringe for taking an intracorporeal fluid, such as blood, and / or

 a needle adapted for hepatic cytopuncture, for example a needle of diameter 18 to 22G, and / or

 o a needle and / or catheter and / or biopsy gun adapted to the PBH; a computer or software program product, in particular a computer program product or statistical analysis software, for example a computer program product of the invention as described below;

 RNA extraction reagents;

 a reverse transcriptase;

 a polymerase, for example a Taq polymerase;

 nucleotides (dNTPs).

The application is particularly related to said manufactured article, or said reagents, for their use in a method for predicting whether a subject infected with HCV or HCV has a high probability of responding to an anti-HCV treatment which will include the administration of interferon ribavirin (or their pro-drugs), or if, on the contrary, this subject has a high probability of not responding to this anti-HCV treatment, more particularly to said manufactured article, or to said reagents, for their use in a prognostic method of the invention.

This use can include:

the collection of a biological sample from said subject, in particular by insertion of a needle or catheter into the body of said subject, and

 the use of said reagents in said method on this biological sample, or on a sample comprising nucleic acids and / or proteins and / or polypeptides and / or peptides extracted or purified from said biological sample, or on a sample comprising cDNAs to have been obtained by reverse transcription of said nucleic acids.

 This use can for example include:

taking a biological sample from said subject, optionally transformed by: extraction or purification of the RNAs of said sample taken and, optionally, by reverse transcription of the extracted RNAs, or by

 o extraction or purification of its proteins from said sample taken, and the implementation of said reagents of the invention on this biological sample optionally transformed.

 Said biological sample collection may be done by insertion of a sampling instrument, in particular by insertion of a needle or a catheter, into the body of said subject.

 The insertion of the sampling instrument is in particular made to collect intracorporeal fluid from said subject (such as for example blood) and / or a portion of liver tissue of said subject (for example by PBH) and / or hepatic cells of said subject (for example by hepatic cytopuncture).

This instrument can for example be inserted:

 in a vein, artery or blood vessel of said subject for taking blood from said subject; and or

 in the liver of said subject, to take a sample of hepatic parenchyma, that is to say to make a liver biopsy (PBH) puncture, for example by transjugular or transparietal route; and or

 - through the skin to the liver of said subject, so as to make a cytopuncture liver. The application relates in particular to said manufactured article, or to said reagents, for their use in a method for the treatment of hepatopathy which involves a tissue involvement of the liver, more particularly a hepatic fibrosis, more particularly a method of anti-HCV therapy, more particularly in a method of anti-HCV therapy which comprises administration of interferon and administration of ribavirin (or their pro-drugs), more particularly in a method of anti-HCV therapy which comprises, as a first-line treatment, administration of interferon and administration of ribavirin (or their pro-drugs).

Such use may include, in particular, the use of said reagents in a method of the invention to predict whether an HCV-infected subject has a high probability of responding to anti-HCV treatment which will include the administration of interferon and or if, on the contrary, this subject has a high probability of not responding to this anti-HCV treatment.

If said subject is prognostic non-responder, the practitioner may choose not to administer a treatment that includes (more particularly who is essentially consisting of) administration of interferon and administration of ribavirin (or their prodrugs), more particularly not to administer such treatment as a first-line treatment. In such a situation, the practitioner may, for example, choose to administer an anti-HCV treatment that does not include (or is not essentially comprised of) administration of interferon and administration of ribavirin (or their pro-drugs). especially to administer such treatment as a first-line treatment. The practitioner may alternatively choose not to administer anti-HCV treatment, at least first-line. If said subject is a responder prognostic, the practitioner may elect to administer an anti-HCV treatment, including a treatment that includes (more particularly that essentially consists of) administration of interferon and administration of ribavirin (or their prodrugs), plus particularly to administer as a first-line treatment which comprises (more particularly which consists essentially of) administration of interferon and administration of ribavirin (or their pro-drugs).

This use can for example include:

 the use of said reagents of the invention on a biological sample which has been taken from said subject, and which has optionally been transformed, for example:

 o by extraction and / or purification of the RNAs of said sample taken and, optionally, by reverse transcription of the extracted RNAs, or o by extraction and / or purification of the proteins and / or polypeptides and / or peptides of said sampled sample,

 to predict whether a HCV-infected person has a high likelihood of responding to anti-HCV treatment which will include the administration of interferon and ribavirin, or if, on the contrary, this subject has a high probability of not respond to this anti-HCV treatment,

 optionally, determining the HCV genotype of which said patient is infected and / or determining his liver fibrosis score (more particularly, determining whether this score is a score of at least F2 according to the Metavir system).

If said subject is non-responder prognostic, the practitioner may choose not to administer a treatment that includes (more particularly that essentially consists of) administration of interferon and administration of ribavirin (or their prodrugs), particularly not not give such treatment as a first-line treatment. In such a situation, the practitioner may, for example, choose to administer anti-HCV treatment that does not include (or is not essentially consisting of) administration of interferon and administration of ribavirin (or their pro-drugs), more particularly to administer such treatment as a first-line treatment. The practitioner may alternatively choose not to administer anti-HCV treatment, at least first-line. If said subject is a responder prognostic, the practitioner may elect to administer an anti-HCV treatment, including a treatment that includes (more particularly that essentially consists of) administration of interferon and administration of ribavirin (or their prodrugs), plus particularly to administer as a first-line treatment which comprises (more particularly which consists essentially of) administration of interferon and administration of ribavirin (or their pro-drugs).

 Said treatment may for example be an anti-HCV treatment as described above and below illustrated.

 The application also relates to a medicinal product or combination intended for the treatment of hepatopathy involving tissue involvement of the liver, more particularly liver fibrosis (such as standard interferon or pegylated interferon, as monotherapy, or in combination therapy combining one or more other drugs). active ingredients, especially ribavirin), especially an anti-HCV treatment, for its use in the treatment method of the invention. The application also relates to a computer program product intended to be stored in a memory of a processing unit, or to a removable memory medium intended to cooperate with a reader of said processing unit. The computer program product of the invention comprises instructions for the implementation of a method of the invention, in particular for the implementation of a statistical analysis adapted to the implementation of a method of the invention. invention (in particular adapted to the multivariate statistical analysis of the measurements, and more particularly to the expression levels of said selected genes) and / or for the construction of a multivariate classification model adapted to the implementation of a method of the invention.

 The application also relates to a computer installation, a computing device, or a computer, comprising a processing unit in the memory of which are stored or recorded:

 a computer program product of the invention, and, optionally,

assays, or assay values, levels of expression (transcription and / or translation) of said selected genes. The term "comprising", with which "including" or "containing" is synonymous, is an open term, and does not exclude the presence of one or more element (s), ingredient (s) or step (s) of additional method (s) that would not be explicitly stated, while the term "consistent" or "constituted" is a closed term, which excludes the presence of any additional element, step, or ingredient that does not would not be explicitly exposed. The term "substantially consisting of" or "essentially consisting of" is a partially open term, which does not exclude the presence of one or more element (s), ingredient (s) or additional step (s) in the to the extent that such element (s), ingredient (s) or additional step (s) do not materially affect the basic properties of the invention.

 Therefore, the term "comprising" (or "comprises (include)") includes the terms "consisting", "consisting", as well as the terms "consisting essentially" and "essentially consisting".

In order to facilitate the reading of the application, the description has been separated into various paragraphs, sections and embodiments. It should not be considered that these separations disconnect the substance of a paragraph, section or embodiment, from that of another paragraph, section, or embodiment. On the contrary, the description encompasses all possible combinations of the different paragraphs, sections, sentences and embodiments that it contains.

 The content of the bibliographic references cited in the application is specifically incorporated by reference into the content of the application.

 The following examples are given for illustrative purposes only. They do not limit the invention in any way.

EXAMPLES

EXAMPLE 1: CONSTRUCTION OF CLASSIFICATION MODELS 1. Populations and patients, assay of the level of gene expression, determination of the response to treatment:

The study was approved by the local Ethics Committee in accordance with the Declaration of Helsinki, and all patients gave their informed written consent. Patient presentation

The patients are adult patients infected with the hepatitis C virus (HCV), followed at the Beaujon Hospital (Clichy, France).

 The clinical diagnosis of hepatitis C virus infection in selected patients was established based on the detection of antibodies to HCV proteins and detection of circulating HCV RNA.

Serology HCV screening was performed by the Abbott test 3 ^rd generation (AxSYM ™ HCV Version 3.0 (Abbott) Technique MEIA; index> 1 = positive; index <1 = negative) and the RNA quantification test VERSANT® HCV-RNA 3.0 (bDNA) ASSAY from Siemens Healthcare Diagnostics (Quantification Limit = 615 - 7,690,000 IU / mL). In order to establish a homogeneous cohort perfectly representative of the pathology exemplified, patients likely to present chronic liver diseases of non-hepatitis C origins (such as a chronic liver disease due to an infection with hepatitis B virus) were excluded from the study. Other exclusion criteria that have been applied include excessive alcohol consumption, hemochromatosis, autoimmune hepatitis, Wilson's disease, a-1 antitrypsin deficiency, primary sclerosing cholangitis, primary biliary cirrhosis, previous anti-HCV treatment.

One hundred forty patients were selected. Table 8 below presents the clinical, biological and virological data of the patients thus selected. These data were collected before the patient received antiviral treatment, in this case during liver biopsy (PB H). In Table 8 below:

 UI = International Unit

 NR patients = non-responders to treatment;

 R = patients responding to the treatment;

 RR patients = responder-relapse patients;

cf. below for the definition of these three subpopulations or cohorts. Table 8: Clinical, Biological, and Virological Data (All Selected Patients)

Clinical, Biological Data and Patients Patients NR Patients R Patients RR

 virological

n 140 51 68 21

Sex: Male (%) / Female (%) 89 (64) / 51 (36) 31 (61) / 20 (39) 43 (63) / 25 (37) 15 (71) / 6 (29)

Age [mean ± deviation 45.8 ± 8.5 (27-72) 47.3 ± 8.6 (33-72) 44.7 ± 9.0 (27-65) 44.4 ± 4.9 -66) standard (range)]

 Source of infection [n (%)]

 blood transfusion 30 (21) 11 (22) 16 (23) 3 (14) intravenous administration 42 (30) 17 (33) 21 (31) 4 (19)

 of a drug

 unknown 68 (49) 23 (45) 31 (46) 14 (67)

Alanine aminotransferase 106 ± 73 (18-459) 112 ± 81 (30-354) 102 ± 74 (20-459) 100 ± 36 (18,176)

(ALT) UI / L [mean ±

standard deviation (range)]

Table 8 (continued and end): clinical, laboratory and virological data

Clinical, Biological Data and Patients Patients NR Patients R Patients RR

 virological

 Genotypes HCV [n (%)]

 1 76 (54.3) 40 (78.4) 28 (41.2) 8 (38, 1)

2 13 (9.3) 10 (14.7) 3 (14.3)

3 19 (13.6) 3 (5.9) 12 (17.6) 4 (19.0)

4 31 (22, 1) 8 (15.7) 17 (25.0) 6 (28.6)

5 1 (0.7) 0 10.5) 0

Fibrosis score (F score

 Metavir) [n (%)]

 0 1 (0.7) 0 1 (1.5) 0

1 45 (32, 1) 15 (29.5) 26 (38.2) 4 (19.0)

2 53 (37.9) 18 (35.3) 29 (42.7) 6 (28.6)

3 18 (12.9) 9 (17.6) 3 (4.4) 6 (28.6)

4 22 (15.7) 9 (17.6) 9 (13.2) 4 (19.0) unknown 1 (0.7) 0 0 1 (4.8)

Samples collection:

Hepatic puncture biopsy (PBH) was performed on each patient before he received antiviral treatment. PBHs were performed according to good clinical practice. The biopsies were immediately stored at -80 ° C for total RNA extraction, and treated with paraffin for histological studies. A serum sample was taken from each of the patients included in the study within +/- 6 months from the date of the biopsy, but still before the patient received the antiviral treatment.

Treatment of liver biopsy samples (for RNA assay):

Gene expression levels (in this case RNA transcription level) were assayed on each of 140 biopsies (1 biopsy per patient).

Liver biopsies were crushed in nitrogen using a pestle and a ceramic mortar (100% manual grinding).

 The powder was recovered using a scalpel (Swann Morton 22, Reference 0208). a) RNA extraction

The powder thus obtained was solubilized in 1 ml of RNAble® Ref. GEXEXT00, Eurobio Laboratories, France, to which 100 μl of chloroform has been added.

The resulting mixture was placed in ice or at 4 ° C for 5 minutes and then centrifuged at 13,000 xg for 15 minutes.

 The upper aqueous phase containing the RNAs was recovered in a new tube and 1 volume of isopropanol was added thereto.

 The tube was shaken by turning and was placed at 4 ° C overnight and then centrifuged at 13,000 xg for 15 minutes. The supernatant was removed, and the pellet containing the RNAs was taken up in 70% ethanol (freshly prepared) and centrifuged again.

The RNA precipitate pellet obtained was dried in the open air for approximately 1 hour, then dissolved in 15 μl of water and then stored at -80 ° C. b) RNA assay The evaluation of the concentration of extracted RNAs was performed by measuring the optical density by a spectrometer (Nanodrop), and was checked after a freeze / thaw cycle.

 The extracted RNAs were then diluted to obtain a 50 ng / L solution.

The quality controls of the RNA were carried out by real-time PCR (cf. below), by targeting a ubiquitous control (so-called endogenous) gene to verify that the RNA has not been degraded (in this case targeting RPLPO).

Reverse transcription stage (RT):

Reverse transcription was performed on 200 ng of RNA in a reaction mixture made in a volume of 20 μl comprising the following reagents:

Table 9:

Reverse transcription reactions were performed at the following temperatures:

 at 20 ° C for 10 minutes and then

at 42 ° C for 30 minutes, and at 99 ° C for 5 minutes.

At this stage, the reaction mixtures were either frozen, or aliquoted, or directly used for real-time PCR amplification. Quantitative real-time PCR step (PCRq):

 Amplification was performed using a light Cycler® 480 (Roche Diagnostics, Mannheim, Germany). The results are generated by the software light Cycler® Software 4.05 / 4.1.

The Light Cycler® technology allows continuous monitoring of the appearance of amplification products through the emission of a quantity of fluorescence proportional to the amount of amplified product, itself dependent on the amount of targets initially present in the sample to be analyzed. The quantification (in relative values) of the gene expression is carried out by the method known under the name 2 ^"Δα (2 ^{" Δα} = 2 ^{" (} ctcibie - ct reference ⁾ _{c Liyak and Schmittgen 2000} , Schmitten and Livak 2008 ), using the "Cycle Threshold" or Ct values determined by the real-time quantitative PCR apparatus, the lower the Ct value, the higher the initial amount of transcribed RNA.

 The reaction mixtures and the protocol used are described in the package insert of the LIGHT CYCLER® 480 SYBR GREEN I MASTER MIX kit (Roche Diagnostics, Mannheim, Germany, US 4,683,202, US 4,683,195, US 4,965,188, US 6,569,627).

After the reverse transcription step, the reaction mixtures (cDNAs) were diluted to l / ^40th (for quality check) or l / 100 ^th (for target genes) prior to use in qPCR.

 For each gene, the PCRqs were carried out in a reaction volume of 10 μΕ on a 384-well plate:

5 μΕ reverse transcription reaction diluted to l / ^40th (or l / 100 ^th);

 4.8 μΕ reaction mixture of the light Cycler® 480 kit SYBR Green I Master mix

 0, 1 μΕ of a 50μΜ solution for each of the 2 primers, ie a final volume of 0.5 μΜ for each primer.

The reaction mixtures are generally prepared for 384-well plates. The following primers were used: Table 10: Examples of primers

 Symbol Primer meaning SEQ ID NO: SEQ ID NO antisense primer NO:

HERC5 CCT GGG CCA CAC TGA GAG TAA A 1 GAG CCA CCA CAA GCG ACA AA 2

 IL8 CAC CGG AAG GAA CCA TCT CAC TGT 3 TCC TTG GCA AAA CTG CAC CTT CA 4

 STAT2 GAG TCA GGG TT GAT TTG GGA CTT 5 CTG TCA CAC CTA GTG GCC CCT TA 6

 CCL21 CTC CAT CCC AGC TAT CCT GTT CTT 7 TCT GCA AGC CAT TCT GCC TGA GA 8

 CLDN1 TAT TTC TTC TTG CAG GTC TGG CTA 9 CAA ATT CGT ACC TGG CAT TGA CT 10

 CXCL6 GTT TAC GCG TTA CGC TGA GAG TAA A 11 CGT TCT TCA GGG AGG CTA CCA 12

 FOXOl GTC AAG AGC GTG CCC TAC TTC AT 13 TGA ACT TGC TGT GTA GGG ACA GAT TAT 14

 G1P2 GAG GCA GCG AAC TCA TCT TTG CCA 15 CCG CCA GCA TCT TCA CCG TCA 16

G1P3 GAT GAG CTG GTC TGC GAT CCT GAA 17 CCA CCA GCC CCG AGG CTC T 18

Table 10 (continued): examples of primers

 Symbol Primer meaning SEQ ID NO: SEQ ID NO antisense primer NO:

IFI27 TGG GTA CTC TGC AGT CAC TGG GA 19 CCG CAA TGG CAG ACC CAA T 20

 IFI35 AGG CCA GAC TCA AGA TGA GGC TGT 21 GGG CAC TGA AAA TGG GAC CTT GT 22

 IFI44 AAA ATC TTG GAC TTG CTC AAA ATT GTA 23 CTT TCA TCC AGT GAA TCT TCG CA 24

 IFIT1 GAG CAA CCA TGA GTA CAA ATG GTG A 25 CGT CAT CAA TGG ATA ACT CCC ATG T 26

 IFIT4 ATC AGC CTG GTC ACC AGC TTT 27 ATT CTT GGT GAC CTC ACT CAT GAC T 28

 IFITM1 TCA ACA CCC TCT TCT TGA ACT GGT 29 CAA CCA TCT TCC TGT CCC TAG ACT T 30

 ITGA2 AGG TGC CTG CAG AAG AAT ATG GT 31 GAC AAC ATC AGA GGG CTC CTG TAT 32

 LGALS3BP TGA CCC CTC CGA GGC TCT TC 33 ATG TCA CCA TCG TTC ACG CCT T 34

 MDK GGG CAG CGA GAT GCA GCA C 35 CCA CTC AGC GCA CTC GCT CC 36

MX1 ACA CAC CGT GAC GGA TAT GGT C 37 GGC GGT TCT GTG GAG GTT AAA 38

Table 10 (continuation and end): examples of primers

 Symbol Primer meaning SEQ ID NO: SEQ ID NO antisense primer NO:

OAS1 CTG AAG GAA AGG TGC TTC CGA G 39 GCC TGA GGA GCC ACC CTT TAC 40

 OAS2 TGA AGC ACT GGT ACA AGT AGT GTG A 41 TGA GCA GCT AGA AGG CAT ACT T 42

 OAS3 TCG ACA TCA TCT TGC GCT GC 43 CCA AAT GAG CCC CCT TTA CTG A 44

 OCLN CCC AAT GTC GAG GAG TGG GTT A 45 AGT ATG CCA TGG GAC TGT CAA CTC T 46

 PLSCR1 GAA TGC TTC TCA CCC GGA AAC A 47 AGC CAC TAT ATC CTG GAG GTC CTT G 48

 RSAD2 AGC AAA GAG AGG ATT GCT TT GC 49 AGG TAT TCT CCC CGG TCT TGA A 50

 STAT1 AGC ATG AAA TCA AGA GCC TGG A 51 ACC ATT GGT CTC GTG TTC TCT GTT 52

 STMN2 GCG GAG GAA AAG CTG ATC CTG A 53 TCC GCA GCA TGC CTC TCC TT 54

 USP18 CCG TGG GAA ACA GGT CTT GAA 55 ATG GAG AAT CGC ATG AGG TGG 56

RPLPO GGC GAC CTG GAA GTC CAA CT 57 CCA TCAG CAC CAC AGC CTT C 58

The PCRqs were carried out according to the following temperature conditions:

 a denaturation initiation step at 95 ° C. for 10 minutes;

 - 50 cycles of:

 denaturation at 95 ° C. for 15 seconds;

 hybridization / elongation at 65 ° C. for 30 seconds.

 Each target sample is amplified in duplicate. In order to overcome variations in the initial amounts of total RNA from one sample to another, the duplicate amplification of the RNAs of a gene used as an endogenous control, in the same sample, is carried out in parallel on the same sample. a gene involved in cellular metabolic cascades, for example RPLP0 (also known as 36B4, GENBANK accession NM 001002) or TBP (GENBANK accession NM_003194). In this case, it is the RPLP0 gene that has been used here as endogenous control. The quality of the RNA extraction made from the 140 biopsies was evaluated on the basis of the Ct value of the RPLP0 reference gene. The classification was carried out as follows:

 - Ct RPLP0 less than 22: very good RNA quality;

 - Ct RPLP0 from 22 to 24: good RNA quality;

 - Ct RPLP0 greater than 24 and less than 26: average RNA quality;

 - Ct RPLP0 greater than or equal to 26: bad RNA quality.

 In order to increase the reliability of bio-statistical analyzes, only data from very good and good quality RNA extraction (Ct RPLP0 <24) were retained, 128 biopsies [91.4% of 140 samples] 107 with strict responder or non-responder status; cf. Table 11 below.

The amount of transcripts of a target gene was deduced from the Ct ("Cycle threshold") which corresponds to the number of PCR cycles necessary to obtain a significant fluorescence signal. The target samples were standardized based on their RPLP0 (or, if applicable, TBP) content according to the 2 ^{~ ACt method} .

This standardized dosage value is generally noted here as "BMQ" (for biomarker).

 The BMQ values obtained for each of the 128 patients are presented in Tables 12 to 15 below.

 Treatment of serum samples (for the determination of serum proteins):

Protein assays can be performed using the kits shown in Table 16 below, following the manufacturer's recommendations. B09072 and B09072A - FP / BA 91 ANSWER # 1

CONFIDENTIAL & ATTORNEY PRIVILEGED Project # 1

Table 11: Clinical, Biological and Virological Data

B09072 and B09072A - FP / B A 92 REPLY No. l CONFIDENTIAL & ATTORNEY PRIVILEGED Project No. 1

Table 11 (continuation and end): clinical, biokmic and virological data

Table 12: BMQ Patient Values for the HERC5, IL8, STAT2, CXCL6, GIP2, IFI35 and IFI44 Genes (Ct Standardized in Accordance with the 2 ^{~ ACt Method} )

Status

 Patient (NR, R HERC5 IL8 STAT2 CXCL6 G1P2 IFI35 IFI44 or RR)

 45 R 0.588 1.641 1.072 0.092 0.959 0.415 0.056

50 R 0.144 0.444 0.730 0.027 1.586 0.174 0.018

55 R 0.235 1.395 0.307 0.053 1.275 0.082 0.034

59 R 0.269 0.329 0.454 0.000 0.877 0.240 0.039

62 R 0.280 0.058 0.771 0.080 0.943 0.318 0.074

63 R 1,129 0.199 0,904 0,000 12,295 0,523 0,291

65 R 0.258 0.168 0.448 0.013 1.613 0.209 0.055

66 R 0.374 0.420 0.580 0.119 0.308 0.103 0.018

71 R 0.255 0.228 0.304 0.000 0.564 0.087 0.015

72 R 0.097 0.064 0.290 0.052 0.176 0.074 0.010

73 R 1.409 0.191 0.691 0.027 1.064 0.181 0.180

76 R 0.293 1.257 1.091 0.051 0.653 0.163 0.067

86 R 0.259 0.451 0.564 0.102 14.123 0.244 0.086

88 R 0.660 0.297 0.745 0.072 2.042 0.172 0.092

90 R 0.342 0.089 0.516 0.045 1.912 0.207 0.046

91 R 0.149 0.040 0.270 0.096 0.664 0.130 0.042

92 R 0.025 0.087 0.127 0.027 0.049 0.046 0.006

125 R 0.248 0.000 0.126 0.000 1.257 0.099 0.047

222 R 0.631 0.330 0.318 0.023 5.187 0.253 0.181

227 R 0.145 0.260 0.210 0.000 0.119 0.062 0.036

306 R 0.380 0.372 0.976 0.186 3.568 0.559 0.130

344 R 0.429 0.923 1.683 0.330 0.646 0.114 0.181

346 R 0,503 0,182 2,267 0,029 0,601 0,293 0,146

366 R 0.194 0.179 0.279 0.020 0.159 0.081 0.029

501 R 0.151 0.601 0.443 0.070 1.424 0.200 0.067

502 R 0.158 2.676 0.189 0.557 0.465 0.074 0.016

503 R 0.154 0.109 0.230 0.011 0.755 0.131 0.026

504 R 0.150 2.289 0.274 0.142 0.563 0.162 0.034

506 R 0.042 10.483 0.347 0.343 0.678 0.115 0.043

508 R 0.114 0.446 0.545 0.000 0.143 0.084 0.040

513 R 0.105 0.538 0.332 0.000 0.280 0.086 0.038

523 R 0.028 2.29 0.212 0.176 0.134 0.070 0.009 Table 12 (continued): Patient BMQ values for the HERC5, IL8, STAT2, CXCL6, GIP2, IFI35 and IFI44 genes (Ct normalized according to the ^2Ctt method)

Status

 Patient (NR, R HERC5 IL8 STAT2 CXCL6 G1P2 IFI35 IFI44 or RR)

 528 R 0.253 4.547 0.883 1.189 1.261 0.263 0.056

529 R 0.188 0.354 0.350 0.053 1.210 0.127 0.037

530 R 0.218 0.000 1.240 0.000 0.144 0.130 0.042

532 R 0.173 0.387 0.561 0.032 0.245 0.073 0.019

535 R 0.804 0.328 0.609 0.026 15.348 0.446 0.138

536 R 0.212 0.119 0.448 0.180 0.313 0.125 0.035

537 R 0.052 0.058 0.182 0.027 0.080 0.047 0.010

538 R 0.422 0.041 0.413 0.000 5.152 0.375 0.068

546 R 0.408 0.000 0.735 0.062 0.236 0.164 0.076

556 R 0.409 0.063 0.221 0.000 6.869 0.254 0.170

560 R 0.203 0.530 0.270 0.082 3.249 0.157 0.058

565 R 0.538 1.079 0.079 0.000 4.857 0.301 0.124

567 R 0.238 1.297 0.051 0.356 2.497 0.262 0.059

568 R 0.034 0.127 0.005 0.000 0.055 0.038 0.003

569 R 0.077 0.559 0.018 0.000 0.092 0.202 0.031

570 R 0.113 0.371 0.868 0.000 0.118 0.207 0.060

571 R 0.325 0.804 0.747 0.036 0.609 0.245 0.111

572 R 0.169 0.064 0.243 0.005 2.129 0.125 0.050

575 R 1.653 0.892 1.952 0.226 15.348 1.061 0.350

577 R 0.215 0.262 0.841 0.084 0.224 0.159 0.057

581 R 0.084 2.549 0.309 0.129 1.210 0.126 0.041

583 R 0.231 0.230 0.551 0.367 1.297 0.432 0.058

585 R 0.396 0.818 0.660 0.111 3.1411 0.331 0.094

598 R 0.050 0.660 0.201 0.033 0.200 0.073 0.023

601 R 0.431 0.459 1.133 0.077 1.053 0.249 0.199

604 R 0.200 0.084 0.473 0.082 1.061 0.221 0.079

605 R 0.847 0.178 0.622 0.000 5.315 0.228 0.149

613 R 0.083 0.111 0.419 0.000 0.108 0.161 0.028

614 R 0.132 0.218 0.541 0.078 0.135 0.098 0.040

629 R 0.070 0.152 0.644 0.000 0.074 0.113 0.026

639 R 0.121 0.399 0.895 0.000 0.109 0.119 0.042

6 NR 0.247 2.648 0.624 0.000 0.685 0.113 0.046 Table 12 (continued): Patient BMQ values for the HERC5, IL8, STAT2, CXCL6, GIP2, IFI35 and IFI44 genes (Ct normalized according to the ^2Ctt method)

Status

 Patient (NR, R HERC5 IL8 STAT2 CXCL6 G1P2 IFI35 IFI44 or RR)

 46 NR 0.563 0.911 1.693 0.115 8.969 0.329 0.177

58 NR 0.607 0.616 0.787 0.152 13.881 0.490 0.149

75 NR 1.035 0.908 2.158 0.082 8.664 0.601 0.319

80 NR 0.570 0.745 0.493 0.096 0.963 0.146 0.057

83 NR 2,549 0,231 2,063 0.154 6,169 0.798 0.218

145 NR 1,283 0.755 0.838 0.196 7.490 0.423 0.183

167 NR 0.653 0.923 0.502 0.112 5.046 0.405 0.075

308 NR 0.886 0.853 0.440 0.115 6.658 0.437 0.154

509 NR 0.719 1.157 0.637 0.218 6.162 0.264 0.102

516 NR 0.358 0.844 0.559 0.049 3.160 0.232 0.098

521 NR 1,670 3,732 3,745 0,170 4,362 1,292 0,785

524 NR 0.236 0.949 0.578 0.025 0.286 0.120 0.028

526 NR 0.418 2.370 0.940 0.169 5.260 0.441 0.127

527 NR 0.868 0.657 1.057 0.060 9.318 0.495 0.192

534 NR 0.667 1.828 0.853 0.194 2.129 0.340 0.114

549 NR 0.639 0.979 1.759 0.080 2.297 0.434 0.290

574 NR 1,210 5,756 2,540 0,139 4,959 0,877 0.735

582 NR 0.476 2.949 0.455 0.409 4.675 0.230 0.081

596 NR 0.374 0.883 0.639 0.080 0.914 0.230 0.066

602 NR 0.047 0.936 0.180 0.059 0.091 0.086 0.012

618 NR 0.547 1.035 1.206 0.294 4.757 0.486 0.273

619 NR 0.276 0.301 1.218 0.064 1.542 0.284 0.237

636 NR 2,395 0,270 3,063 0.081 18,765 1,010 0.898

645 NR 0.026 0.000 0.124 0.000 0.069 0.058 0.008

646 NR 1.113 0.518 1.866 0.087 35.383 1.177 0.221

647 NR 0.859 0.192 1.283 0.110 20.393 0.883 0.216

649 NR 1.083 2.742 1.161 0.167 3.918 0.288 0.110

650 NR 1,000 5,816 2,354 0,446 12,381 0,990 0,294

651 NR 0.705 0.940 1.094 0.150 4.773 0.394 0.093

657 NR 0.356 4.840 0.787 2.412 2.949 0.322 0.135

658 NR 0.236 0.557 0.392 0.000 0.322 0.081 0.048

659 NR 0.547 4.423 0.536 0.237 0.690 0.150 0.067 Table 12 (continued and end): Patient BMQ values for the HERC5, IL8, STAT2, CXCL6, GIP2, IFI35 and IFI44 genes (Ct normalized according to the

₂ -AC _t)

Status

 Patient (NR, R HERC5 IL8 STAT2 CXCL6 G1P2 IFI35 IFI44 or RR)

 660 NR 0.874 1.113 0.856 0.308 6.612 0.284 0.138

662 NR 1.050 0.046 0.426 0.051 5.483 0.179 0.066

664 NR 0.420 0.953 1.157 0.139 2.704 0.316 0.066

665 NR 0.176 0.949 0.495 0.061 0.576 0.118 0.024

666 NR 0.578 2,799 1,275 0,000 5,796 0,358 0,100

67 NR 0.133 0.104 0.369 0.036 0.314 0.125 0.021

563 NR 0.208 0.330 0.085 0.063 0.235 0.221 0.030

573 NR 0.940 0.323 0.990 0.064 6.892 0.543 0.207

599 NR 0.826 0.262 0.221 0.005 1.248 0.115 0.050

641 NR 0.408 0.657 0.462 0.150 2.444 0.204 0.048

642 NR 0.516 13.408 1.993 1.682 6.635 0.880 0.285

49 RR 0.521 0.284 1.853 0.000 1.905 0.262 0.177

56 RR 0.468 0.363 0.607 0.000 3.249 0.225 0.115

60 RR 0.690 0.145 0.841 0.000 7.945 0.362 0.126

87 RR 1,072 1,608 1,310 0.117 11.432 0.570 0.183

505 RR 0.476 0.410 0.325 0.000 4.084 0.263 0.138

514 RR 0.200 1.053 1.193 0.066 0.525 0.224 0.055

531 RR 0.039 0.053 0.101 0.004 0.103 0.036 0.010

533 RR 0.135 3.084 0.405 0.189 1.145 0.132 0.038

543 RR 0.486 0.597 1.157 0.059 1.548 0.375 0.204

554 RR 0.033 1.072 0.324 0.125 0.148 0.096 0.011

557 RR 0.355 0.700 0.304 0.061 3.317 0.248 0.073

558 RR 0.045 0.983 0.030 0.097 0.289 0.067 0.023

559 RR 0.076 0.536 0.113 0.069 0.871 0.101 0.015

562 RR 0.459 1.380 0.216 0.140 3.668 0.305 0.122

576 RR 0.493 1.064 0.956 0.127 5.187 0.332 0.198

579 RR 0.370 0.483 0.490 0.072 0.147 0.065 0.059

588 RR 0.025 0.255 0.384 0.041 0.053 0.059 0.016

589 RR 0.697 0.315 0.750 0.033 7.387 0.324 0.159

591 RR 0.412 0.113 0.262 0.048 2.378 0.179 0.071

592 RR 0,959 7,781 1,149 1,094 6,000 0,355 0,196

643 RR 0.083 15.835 0.597 1.197 0.390 0.228 0.026 Table 13: Patient BMQ Values for the IFIT1, IFIT4, ITGA2, MDK, MX1, OAS1 and OAS3 Genes (Ct normalized according to the 2 ^{"ACt method} )

Status

 Patient (NR, R IFIT1 IFIT4 ITGA2 MDK MX1 OAS1 OAS3 or RR)

 45 R 0.020 0.753 0.408 0.037 0.254 1.014 1.879

50 R 0.011 0, 111 0, 166 0, 132 0.681 0.826 1.479

55 R 0.034 0.305 0.275 0.054 1.035 0.883 0.911

59 R 0.017 0.426 0.000 0.090 0.771 1.380 0.856

62 R 0.020 0.607 0, 160 0.043 0.986 1.444 1.821

63 R 0,261 4,347 0,063 0, 106 4,042 3,506 5,676

65 R 0.023 0.256 0.000 0, 105 0.582 0.908 0.979

66 R 0.011 0, 179 0.066 0.054 0.361 0.378 0.465

71 R 0.013 0, 193 0.000 0.021 0.455 0.437 0.760

72 R 0.008 0.092 0, 115 0.001 0.245 0, 162 0.391

73 R 0.048 0.885 0.000 0.055 0.841 1.364 0.568

76 R 0.024 0.391 0.376 0.045 0.717 1, 161 1.283

86 R 0.045 0.491 0.070 0.060 1.474 1.053 2.007

88 R 0.046 0.620 0.000 0.024 1, 165 0.976 1.227

90 R 0.033 0.372 0.030 0, 115 1.500 0.853 1.057

91 R 0.017 0.211 0.082 0.051 0.796 0.651 0.518

92 R 0.003 0.064 0.045 0.001 0.052 0, 187 0.084

125 R 0.026 0.345 0, 198 0.058 0.465 0.963 0, 102

222 R 0.089 2,250 0.074 0.063 1.840 1.537 1, 137

227 R 0.011 0.259 0.071 0.002 0.218 0.301 0, 120

306 R 0.032 1.886 0.553 0, 125 3.732 3.972 2.204

344 R 0.047 0.858 0.022 0.045 1.766 1.378 1.388

346 R 0.037 0.695 0.422 0.032 1.352 2.519 0.965

366 R 0.014 0, 137 0.273 0.012 0.297 0.325 0.547

501 R 0.027 0.358 0.094 0.046 1.017 0.826 0.083

502 R 0.007 0, 139 0.693 0.056 0.476 0.299 0.019

503 R 0.018 0.257 0.000 0.014 0.690 0.936 0.059

504 R 0.012 0.376 0.000 0.028 0.301 0.747 0.067

506 R 0.017 0.289 0.702 0.057 0.415 0.525 0, 173

508 R 0.006 0.349 0.080 0.032 0, 163 0.588 0, 143

513 R 0.012 0.298 0.425 0.034 0.409 0.553 0, 113

523 R 0.003 0.079 0.214 0.045 0.052 0, 140 0.062 Table 13 (continued): Patient BMQ values for IFIT1, IFIT4, ITGA2, MDK, MX1, OAS1 and OAS3 genes (Ct normalized according to the 2 ^{~ ACt method} )

Status

 Patient (NR, R IFIT1 IFIT4 ITGA2 MDK MX1 OAS1 OAS3 or RR)

 528 R 0.018 0.432 0.285 0, 188 2.092 1.647 0.787

529 R 0.014 0.207 0, 136 0.084 0.920 0.669 0.331

530 R 0.008 0.281 0.216 0.023 0.498 0.847 0.200

532 R 0.010 0, 152 0, 121 0.207 0.288 0, 179 0.329

535 R 0.075 1, 161 0.000 0.057 2.969 1.892 2.770

536 R 0.012 0.221 0.087 0.010 0.443 0.351 0.406

537 R 0.004 0.072 0, 140 0.014 0, 196 0, 154 0, 131

538 R 0.039 0.536 0.072 0, 108 2.466 1.705 1.210

546 R 0.012 0.372 0.644 0.039 0.355 1.061 0.667

556 R 0.073 1, 189 0.093 0.011 2, 121 2,676 2,266

560 R 0.049 0.370 0, 172 0.028 1.257 0.930 1, 149

565 R 0, 135 1.625 0.071 0.049 3.042 1.879 2.042

567 R 0.051 0.412 0.399 0.038 1.834 0.963 1.306

568 R 0.004 0.054 0.000 0.005 0, 146 0, 146 0, 184

569 R 0.021 0.216 0.000 0.008 0.566 0.633 0.683

570 R 0.012 0.441 0.000 0.046 0.785 0.889 0.707

571 R 0.018 0.509 0.000 0.050 12.000 0.883 1.275

572 R 0.028 0.206 0.080 0.009 1.253 0.674 0.626

575 R 0, 123 3,837 0.543 0.525 7.945 6.431 9.849

577 R 0.020 0.525 0.000 0.024 12.951 1, 117 1, 181

581 R 0.030 0.329 0.367 0.034 1.959 0.683 1, 165

583 R 0.015 0.737 0, 118 0.056 1.495 1.542 1.575

585 R 0.038 0.886 0.217 0.063 2.445 2.445 1.474

598 R 0.010 0, 103 0.056 0.009 0.214 0.203 0.365

601 R 0.053 1.376 0.507 0, 125 3.48 0.631 2.979

604 R 0.021 0.481 0, 173 0, 157 1.376 1.244 1.711

605 R 0.078 0.953 0, 109 0, 173 2,313 1,586 2,313

613 R 0.011 2,313 0.753 0.017 0, 177 0.620 0.446

614 R 0.004 0.211 0.525 0.036 0.233 0.371 0.444

629 R 0.006 0.225 0.000 0.012 0.356 0.420 0.449

639 R 0.007 0.292 0.541 0.031 0.305 0.486 0.367

6 NR 0.010 0, 171 17.569 0.688 0.457 0.228 0.702 Table 13 (continued): Patient BMQ values for IFIT1, IFIT4, ITGA2, MDK, MX1, OAS1 and OAS3 genes (Ct normalized according to the 2 ^{~ ACt method} )

Status

 Patient (NR, R IFIT1 IFIT4 ITGA2 MDK MX1 OAS1 OAS3 ORRR)

 46 R 0.080 1.283 0.091 0.308 2.173 3.543 3.811

58 R 0,100 1,231 0,175 0,631 2,838 2,313 2,657

75 NR 0.198 3.306 0.459 1.248 7.062 3.959 6.612

80 NR 0.022 0.331 0.152 0.030 0.829 0.559 0.969

83 NR 0.235 2.732 0.237 0.476 6.498 3.1411 7.037

145 NR 0.079 1,292 0,270 0,255 3,340 2,395 0,563

167 NR 0.100 1.214 0.231 0.521 0.463 2.204 2.549

308 NR 0.044 1.253 0.000 0.446 1.711 2.305 1.693

509 NR 0.061 0.908 0.444 0.172 3.021 1.324 0.651

516 NR 0.063 1.072 0.105 0.043 1.079 1.664 0.261

521 NR 0.349 7.648 1.193 1.676 8.140 6.233 2.114

524 NR 0.009 0.270 0.142 0.028 0.294 0.444 0.167

526 NR 0.063 0.997 0.282 0.189 2.630 2.305 1.035

527 NR 0.066 0.956 0.582 0.276 5.598 2.732 1.586

534 NR 0.083 1.046 0.300 0.140 2.173 1.608 2.395

549 NR 0.064 1.414 0.323 0.156 3.506 4.084 3.306

574 NR 0,163 3,193 0,435 0,191 10,629 6,277 6,916

582 NR 0.038 0.624 0.547 0.034 2.898 1.057 2.222

596 NR 0.035 0.551 0.262 0.069 1.682 1.017 1.390

602 NR 0.005 0.110 0.169 0.012 0.151 0.154 0.240

618 NR 0.072 1,796 0,000 0,152 2,949 4,213 3,238

619 NR 0.033 1.602 0.557 0.075 3.193 1.474 2.949

636 NR 0.256 6.364 0.277 0.712 15.242 9.580 13.690

645 NR 0.002 0.134 0.179 0.032 0.052 0.141 0.268

646 NR 0.091 4,611 0,000 0,314 1,564 5,389 10,666

647 NR 0.111 3.084 0.000 0.053 3.317 3.771 7.362

649 NR 0.048 0.993 0.104 0.053 0.448 1.474 1.366

650 NR 0.154 2.505 0.179 0.233 3.864 5.028 6.364

651 NR 0.031 0.859 0.218 0.253 1.925 2.488 2.114

657 NR 0.075 0.990 0.620 0.782 0.979 1.376 2.158

658 NR 0.021 0.379 0.271 0.018 0.410 0.518 0.308

659 NR 0.025 0.467 0.251 0.024 1.039 0.898 1.068 Table 13 (continued and end): Patient BMQ values for IFIT1, IFIT4, ITGA2, MDK, MX1, OAS1 and OAS3 genes (Ct normalized according to the method of 2

AC

Status

 Patient (NR, R IFIT1 IFIT4 ITGA2 MDK MX1 OAS1 OAS3 or RR)

 660 R 0.077 0.760 0.206 0.037 1.061 1.979 1.688

662 R 0.019 0.284 0.072 0.047 1.803 0.790 1, 110

664 NR 0.071 0.681 0.013 0.046 1.495 1, 165 1.723

665 NR 0.024 0, 182 0.000 0.026 0.258 0.366 0.514

666 NR 0.058 0.676 0.000 0.221 2.780 6.233 2.878

67 NR 0.007 0, 144 0, 188 0.017 0.264 0.374 0.545

563 NR 0.012 0.534 0.232 0.011 0.269 0.568 0.908

573 NR 0, 123 1,747 0, 105 0,047 3,850 3,375 4,362

599 NR 0.020 0.271 0.000 0.010 0.793 0.463 0.657

641 NR 0.027 0.459 0, 138 0.028 0.717 0.914 1, 110

642 NR 0.089 3,824 1,352 0,688 1,939 6,342 6, 169

49 RR 0.045 0.678 0.202 0.076 0.859 2.4771 1.952

56 RR 0.057 0.889 0.067 0.349 1.853 1.591 2014

60 RR 0.031 0.642 0.000 0, 192 1.853 1.790 2.227

87 RR 0, 153 1,564 0,384 0,077 7,362 2,387 3,904

505 RR 0.049 1.404 0.000 0.037 1.338 1.641 0.622

514 RR 0.016 0.451 0, 123 0.021 1.333 1.320 0.279

531 RR 0.004 0.094 0.209 0.034 0.214 0, 150 0, 115

533 RR 0.024 0.289 0, 155 0.041 1.050 0.662 1,000

543 RR 0.031 0.940 0, 179 0.075 1.747 1.532 1.409

554 RR 0.005 0, 176 0.091 0.014 0.328 0.366 0.325

557 RR 0.053 0.605 0.216 0.001 1.952 0.946 0.787

558 RR 0.009 0, 102 0, 186 0.006 0.305 0.270 0.315

559 RR 0.015 0, 191 0.091 0.007 1.091 0.349 0.572

562 RR 0.050 0.911 0.367 0.075 2.049 1.424 2.266

576 RR 0.073 1.521 0.435 0.069 0.245 3, 117 2.630

579 RR 0.008 0.247 0.000 0.006 0.202 0.465 0.331

588 RR 0.006 0, 105 0.246 0.008 0, 158 0.249 0.219

589 RR 0.054 1.434 0.205 0.054 3.605 1.959 3, 117

591 RR 0.035 0.432 0, 171 0.035 1.569 0.818 0.747

592 RR 0.089 1,270 1,925 0, 138 3,758 0,549 2,639

643 RR 0.011 0.261 0.755 0.054 0.299 0.859 1, 137 Table 14: BMQ patient values for OCLN, PLSCR1, RSAD2, STAT1, STMN2 andUSP18 genes (Ct normalized according to the ^2Ctt method)

Status

 Patient (NR, R OCLN PLSCR1 RSAD2 STAT1 STMN2 USP18 or RR)

 45 R 0.072 0.584 0.597 0.541 0.000 0.821

50 R 0.016 0.228 0.194 0.137 0.127 0.732

55 R 0.015 0.242 0.221 0.114 0.253 0.584

59 R 0.023 0.361 0.283 0.080 0.046 0.835

62 R 0.031 0.662 0.568 0.370 0.103 1.569

63 R 0.028 0.877 5.637 0.705 0.174 3.031

65 R 0.022 0.313 0.480 0.135 0.164 0.485

66 R 0.035 0.346 0.100 0.148 0.061 0.434

71 R 0.013 0.224 0.322 0.071 0.000 0.599

72 R 0.016 0.075 0.054 0.041 0.000 0.218

73 R 0.048 0.483 2.493 0.064 0.007 0.467

76 R 0.031 0.476 0.340 0.363 0.143 0.629

86 R 0.027 0.432 0.681 0.289 0.119 0.883

88 R 0.045 0.278 0.557 0.309 0.125 0.753

90 R 0.019 0.320 0.376 0.232 0.081 0.352

91 R 0.018 0.304 0.248 0.170 0.000 0.376

92 R 0.008 0.097 0.052 0.054 0.038 0.075

125 R 0.012 0.173 0.448 0.129 0.108 0.354

222 R 0.019 0.158 1.235 0.483 0.000 0.856

227 R 0.020 0.119 0.099 0.077 0.000 0.295

306 R 0.030 0.973 1.925 0.536 0.115 2.144

344 R 0.042 0.493 2.785 0.335 0.000 1.150

346 R 0.043 0.606 1.691 0.212 0.000 0.520

366 R 0.021 0.196 0.420 0.099 0.000 0.625

501 R 0.028 0.297 0.490 0.297 0.336 0.495

502 R 0.015 0.195 0.099 0.139 1.261 0.254

503 R 0.017 0.188 0.241 0.085 0.054 0.251

504 R 0.018 0.170 0.237 0.128 0.307 0.574

506 R 0.018 0.207 0.186 0.285 2.858 0.398

508 R 0.000 0.129 0.176 0.357 0.205 0.228

513 R 0.008 0.137 0.220 0.137 0.057 0.485

523 R 0.010 0.070 0.053 0.137 1.083 0.158 Table 14 (continued): Patient BMQ values for OCLN, PLSCR1, RSAD2, STAT1, STMN2 andUSP18 genes (Ct normalized according to the 2

ACt ^

Status

 Patient (NR, R OCLN PLSCR1 RSAD2 STAT1 STMN2 USP18

 ouRR)

 528 R 0.020 0.118 0.354 0.209 2.878 0.536

529 R 0.016 0.218 0.356 0.138 0.070 0.448

530 R 0.050 0.354 0.185 0.124 0.266 0.382

532 R 0.022 0.117 0.112 0.068 0.000 0.288

535 R 0.021 0.119 2.455 0.195 0.000 1.682

536 R 0.018 0.154 0.182 0.134 0.292 0.497

537 R 0.017 0.104 0.065 0.051 0.066 0.117

538 R 0.028 0.267 1.181 0.254 0.063 1.189

546 R 0.057 0.379 0.260 0.177 0.000 0.631

556 R 0.011 0.250 1.729 0.260 0.076 0.956

560 R 0.018 0.401 0.480 0.254 0.140 0.395

565 R 0.013 0.486 2.144 0.350 0.226 1.223

567 R 0.021 0.387 0.740 0.275 0.312 0.609

568 R 0.005 0.064 0.056 0.028 0.146 0.080

569 R 0.027 0.202 0.147 0.134 0.000 1.161

570 R 0.036 0.395 0.202 0.283 0.707 0.963

571 R 0.034 0.547 0.497 0.620 0.147 0.597

572 R 0.014 0.240 0.252 0.089 0.060 0.576

575 R 0.074 1.619 5.011 0.847 0.223 3.904

577 R 0.021 0.405 0.304 0.181 0.000 1.310

581 R 0.016 0.296 0.295 0.177 1.778 0.574

583 R 0.022 0.493 0.402 0.247 0.363 0.898

585 R 0.016 0.601 1.292 0.432 0.067 1.449

598 R 0.009 0.131 0.090 0.084 0.108 0.207

601 R 0.019 0.167 0.790 0.511 0.000 1.815

604 R 0.020 0.475 0.609 0.156 0.163 1.050

605 R 0.022 0.485 1.218 0.287 0.074 1.035

613 R 0.035 0.264 0.152 0.120 0.000 0.379

614 R 0.026 0.305 0.067 0.202 0.193 0.262

629 R 0.035 0.150 0.122 0.092 0.000 0.760

639 R 0.025 0.257 0.202 0.126 0.000 0.667

6 R 0.020 0.755 0.266 0.151 87.730 0.224 Table 14 (continued): Patient BMQ values for OCLN, PLSCR1, RSAD2, STAT1, STMN2 andUSP18 genes (Ct normalized according to the 2

AC

Status

 Patient (NR, R OCLN PLSCR1 RSAD2 STAT1 STMN2 USP18

 or RR)

 46 R 0.063 0.690 2.395 0.367 0.620 1.613

58 R 0.041 0.503 1.439 0.283 0.041 1.753

75 NR 0.079 1, 197 2.959 0.943 0.298 3.344

80 NR 0.027 0.283 0.309 0, 147 0, 179 0.441

83 NR 0.088 1.315 4.362 0.700 0.330 2.918

145 NR 0.047 0.653 1.469 0.578 0.315 1.253

167 NR 0.027 0.559 0, 129 0.467 0.580 1.821

308 NR 0.049 0.069 1,057 0.209 0.000 2,362

509 NR 0.025 0.428 1.564 0.580 0, 110 0.973

516 NR 0.031 0.282 0.892 0.416 0, 189 0.917

521 NR 0.077 0.973 6,681 2,258 0.880 7,808

524 NR 0.027 0.230 0, 168 0, 183 0.362 0.281

526 NR 0.028 0.311 0.973 0.301 0, 131 2.007

527 NR 0.036 0.532 2, 121 0.425 0.369 1.919

534 NR 0.024 0.236 1.338 0.234 0, 106 1.240

549 NR 0.041 0.446 1.202 0.707 0.000 2.667

574 NR 0.063 1,847 6,042 1,619 0,509 2,723

582 NR 0.033 0.620 1.050 0.272 2.523 0.551

596 NR 0.020 0.382 0.324 0.352 0, 164 0.541

602 NR 0.014 0, 174 0.080 0, 124 0.022 0, 180

618 NR 0.022 0.039 2.305 0.648 0.700 2.092

619 NR 0.010 0.441 1.010 0.460 0.000 1, 193

636 NR 0.082 1.847 12.773 2, 196 0.363 6, 105

645 NR 0.000 0, 105 0, 163 0.022 0.000 0, 126

646 NR 0.063 2, 151 3.945 0.435 0.000 7, 111

647 NR 0.045 1.925 3.543 0.662 0, 170 3,000

649 NR 0.041 0.631 0.559 0.354 0, 105 0.993

650 NR 0.080 1.266 3.732 0.824 0.547 4.098

651 NR 0.055 0.545 0.868 0.206 0.000 1.717

657 NR 0.046 0.541 0.732 0.418 1.676 1.244

658 NR 0.019 0.309 0, 140 0.259 0, 173 0.538

659 NR 0.023 0.422 0.676 0.248 0, 123 0.438 Table 14 (continued and end): BMQ patient values for OCLN, PLSCR1, RSAD2, STAT1, STMN2 andUSP18 genes (Ct normalized according to the method of 2

AC

Status

 Patient (NR, R OCLN PLSCR1 RSAD2 STAT1 STMN2 USP18

 ouRR)

 660 R 0.037 0.60 1.385 0.291 0.123 0.785

662 R 0.023 0.398 1.189 0.115 0.091 0.507

664 NR 0.046 0.449 0.674 0.315 0.710 1.117

665 NR 0.015 0.153 0.141 0.122 0.156 0.349

666 NR 0.040 0.601 1.210 0.310 0.262 1.301

67 NR 0.017 0.272 0.091 0.078 0.221 0.349

563 NR 0.019 0.199 0.098 0.139 0.000 0.215

573 NR 0.034 0.785 3.488 0.898 0.139 2.173

599 NR 0.008 0.198 0.219 0.088 0.023 0.409

641 NR 0.026 0.448 0.519 0.180 0.031 0.829

642 NR 0.116 1.580 0.862 1.094 1.919 2.532

49 RR 0.048 0.707 0.593 0.296 0.336 1.014

56 RR 0.018 0.273 1.283 0.345 0.212 1.046

60 RR 0.037 0.540 1.283 0.205 0.000 1.516

87 RR 0.039 0.624 3.29 0.697 0.105 1.741

505 RR 0.012 0.241 1.153 0.299 0.386 1.218

514 RR 0.060 0.422 0.460 0.300 0.073 0.727

531 RR 0.001 0.050 0.149 0.027 0.011 0.119

533 RR 0.020 0.183 0.530 0.226 1.569 0.676

543 RR 0.064 0.151 0.582 0.674 0.247 1.039

554 RR 0.024 0.115 0.091 0.160 0.179 0.384

557 RR 0.016 0.226 0.930 0.240 0.340 0.807

558 RR 0.009 0.096 0.084 0.067 0.351 0.194

559 RR 0.008 0.189 0.306 0.100 0.128 0.182

562 RR 0.037 0.518 1.177 0.365 0.904 1.061

576 RR 0.019 0.763 2.121 0.527 0.702 1.177

579 RR 0.018 0.137 0.163 0.127 0.188 0.235

588 RR 0.019 0.094 0.038 0.059 0.138 0.253

589 RR 0.023 0.601 1.735 0.412 0.284 1.064

591 RR 0.021 0.372 0.584 0.248 0.140 0.584

592 RR 0.041 0.973 1.747 0.868 4.141 1.297

643 RR 0.039 0.380 0.052 0.190 1.790 0.597 Table 15: Patient BMQ Values for the CCL21, CLDN1, FOX01, G1P2, G1P3, IF127, LGALS3BP and OAS2 Genes (Ct Standardized in Accordance with the 2 ^{"ACt Method} )

Status

 Patient (NR, R CCL21 CLDN1 FOXO1 G1P2 G1P3 IF127 IFITM1 LGALS3BP OAS2 or RR)

 45 R 0.033 3.732 0.402 0.959 0.020 0.120 0.162 0.063 0.152

50 R 0.013 1.409 0.083 1.586 0.097 0.844 0.189 0.087 0.202

55 R 0.006 0.856 0.026 1.275 0.060 0.949 0.115 0.046 0.224

59 R 0.006 1.840 0.071 0.877 0.089 0.705 0.195 0.045 0.109

62 R 0.017 3.042 0.101 0.943 0.141 1.653 0.232 0.113 0.271

63 R 0.025 2.235 0.064 12.295 0.401 2.479 0.714 0.115 0.595

65 R 0.012 1.664 0.092 1.613 0.061 1.235 0.150 0.048 0.776

66 R 0.013 1.400 0.154 0.308 0.012 0.115 0.079 0.028 0.076

71 R 0.002 0.607 0.082 0.564 0.038 0.331 0.065 0.014 0.086

72 R 0.005 0.406 0.050 0.176 0.006 0.124 0.050 0.015 0.094

73 R 0.004 2.230 0.174 1.064 0.038 0.171 0.109 0.060 0.230

76 R 0.012 2.403 0.166 0.653 0.041 0.498 0.148 0.064 0.153

86 R 0.023 1.361 0.124 14.123 0.329 2.063 0.378 0.103 0.328

88 R 0.010 1.828 0.102 2.042 0.124 2.549 0.163 0.034 0.201

90 R 0.012 1.357 0.067 1.912 0.150 0.702 0.182 0.048 0.280

91 R 0.008 1.261 0.056 0.664 0.038 0.495 0.096 0.023 0.152

92 R 0.005 0.224 0.026 0.049 0.003 0.043 0.024 0.008 0.019

125 R 0.005 0.801 0.028 1.257 0.077 2.166 0.128 0.012 0.088

222 R 0.016 0.774 0.052 5.187 0.091 1.641 0.313 0.021 0.582

227 R 0.003 0.801 0.060 0.119 0.005 0.042 0.052 0.014 0.030

Table 15 (continued): Patient BMQ values for CCL21, CLDN1, FOXO1, G1P2, G1P3, IFI27, LGALS3BP and OAS2 genes (Ct normalized according to the 2 ^{"ACt method} )

Status

 Patient (NR, R CCL21 CLDN1 FOXO1 G1P2 G1P3 IF127 IFITM1 LGALS3BP OAS2 or RR)

 306 R 0.018 2.612 0, 128 3.568 0, 137 2.021 0.835 0.273 0.516

344 R 0.067 2.500 0.489 0.646 0.099 0.892 0, 196 0.037 0.211

346 R 0.004 2.088 0.342 0.601 0.340 1.521 0.718 0, 133 0.324

366 R 0.009 2.031 0, 161 0, 159 0.014 0.042 0.088 0.015 0.049

501 R 0.016 2.007 0.034 1.424 0, 112 0.801 0, 113 0.032 0.290

502 R 0.009 0.953 0.065 0.465 0.020 0.056 0.055 0.022 0, 104

503 R 0.004 1.790 0.390 0.755 0.067 0, 160 0, 133 0.024 0, 128

504 R 0.012 0.796 0.078 0.563 0.037 0.232 0.237 0.044 0.091

506 R 0.019 0.815 0.053 0.678 0.028 0.847 0.084 0.016 0.085

508 R 0.013 0.892 0.070 0, 143 0.004 0.046 0.072 0.028 0.073

513 R 0.006 0.223 0, 118 0.280 0.045 0.265 0, 139 0.035 0.081

523 R 0.018 0.901 0.049 0, 134 0.005 0.221 0.039 0.028 0.034

528 R 0.022 1.945 0, 140 1.261 0.099 1, 129 0.304 0.082 0.807

529 R 0.012 1.444 0.048 1.210 0, 130 1, 153 0, 137 0.031 0, 149

530 R 0.009 2,266 0.295 0, 144 0.015 0.073 0, 168 0.052 0.053

532 R 0.010 2.049 0.340 0.245 0.074 0, 161 0.066 0.029 0.020

535 R 0.025 0.002 0.060 15.348 0.324 3.732 0.431 0.053 0.394

536 R 0.010 1.784 0, 105 0.313 0.025 0.588 0.014 0.015 0.066

537 R 0.007 0.946 0.066 0.080 0.006 0, 102 0.050 0.012 0.029

538 R 0.014 1,966 0.064 5,152 0,237 2,282 0.403 0.068 0.452

546 R 0.012 1.670 0.253 0.236 0.030 0.309 0, 134 0.056 0, 108

556 R 0.008 0.859 0.017 6.869 0.071 2.437 0.252 0.022 6.084

Table 15 (continued): BMQ patient values for CCL21, CLDN1, FOXO1, G1P2, G1P3, IFI27, LGALS3BP and OAS2 genes (Ct normalized according to the 2 ^" method)

 Status

 Patient (NR, R CCL21 CLDN1 FOXO1 G1P2 G1P3 IF127 IFITM1 LGALS3BP OAS2 or RR)

 560 R 0.008 1.647 0.071 3.249 0.093 1.753 0.166 0.038 0.220

565 R 0.006 0.829 0.134 4.857 0.065 2.056 0.220 0.022 0.503

567 R 0.006 1,235 0,050 2,497 0,101 1,050 0,108 0.068 0.134

568 R 0.002 0.740 0.018 0.055 0.005 0.087 0.035 0.007 0.023

569 R 0.003 2,313 0.086 0.092 0.016 0.167 0.177 0.047 0.072

570 R 0.006 2.028 0.493 0.118 0.023 0.186 0.221 0.028 0.085

571 R 0.026 2.378 0.205 0.609 0.033 0.063 0.161 0.057 0.155

572 R 0.005 1.161 0.038 2.129 0.115 2.021 0.148 0.020 0.125

575 R 0.036 3.70 0.202 15.348 0.821 9.254 1.414 0.360 1.157

577 R 0.007 2.035 0.052 0.224 0.022 0.047 0.166 0.093 0.046

581 R 0.006 1.357 0.082 1.210 0.072 0.332 0.085 0.036 0.138

583 R 0.015 1.117 0.045 1.297 0.106 1.641 0.386 0.146 0.113

585 R 0.017 1.575 0.064 3.1411 0.155 0.886 0.403 0.121 0.228

598 R 0.008 0.732 0.017 0.200 0.024 0.486 0.053 0.009 0.040

601 R 0.005 1.275 0.056 1.053 0.253 1.759 0.362 0.069 0.157

604 R 0.011 1.310 0.063 1.061 0.123 3.470 0.248 0.124 0.003

605 R 0.009 1.153 0.064 5.315 0.258 2.338 0.311 0.048 0.023

613 R 0.007 3,000 0.087 0.108 0.011 0.053 0.113 0.035 0.049

614 R 0.011 1.705 0.249 0.135 0.005 0.084 0.056 0.057 0.041

629 R 0.003 2,437 0.142 0.074 0.009 0.588 0.065 0.059 0.036

639 R 0.005 1.553 0.033 0.109 0.005 0.043 0.086 0.021 0.021

6 R 0.004 0.237 0.355 0.685 0.041 0.388 0.083 0.044 0.092

Table 15 (continued): Patient BMQ values for CCL21, CLDN1, FOXO1, G1P2, G1P3, IFI27, LGALS3BP and OAS2 genes (Ct normalized according to the 2 ^{"ACt method} )

Status

 Patient (NR, R CCL21 CLDN1 FOXO1 G1P2 G1P3 IF127 IFITM1 LGALS3BP OAS2 or RR)

 46 R 0.021 4, 112 0.295 8.969 0.209 3.329 0.511 0, 164 0.850

58 R 0.016 1.966 0.072 13.881 0.476 5.464 0.467 0, 149 0.512

75 NR 0.033 4, 170 0.215 8.664 0.607 1.993 0.877 0.265 1.035

80 NR 0.018 2.329 0, 144 0.963 0.031 0.288 0, 131 0.032 0.088

83 NR 0.073 5.766 0.220 6, 169 0.730 7.701 0.892 0, 164 1.266

145 NR 0.023 2.959 0, 186 7.490 0.360 2.770 0.345 0, 193 0.601

167 NR 0.018 1.500 0.098 5.046 0.434 1.765 0.283 0.099 0.750

308 NR 0.022 2.305 0, 144 6.658 0.545 6.821 0.613 0.251 0.485

509 NR 0.025 1.464 0.060 6, 126 0, 198 1.459 0.312 0.045 0.521

516 NR 0.017 1.591 0.309 3, 160 0, 199 1.007 0.222 0.065 0.266

521 NR 0.052 4,317 1,253 4,362 1,315 4,377 1,315 0.576 0.774

524 NR 0.009 2.523 0.094 0.286 0.017 0, 108 0.072 0.042 0.068

526 NR 0.028 1.741 0.084 5.260 0.293 3, 106 0.413 0, 130 0.459

527 NR 0.045 1.636 0.238 9.318 0.432 3.811 0.468 0.457 0.904

534 NR 0.017 2.742 0.058 2, 129 0.259 0.990 0.402 0.048 0.491

549 NR 0.023 2.878 0.314 2.297 0.245 1.490 0.415 0, 142 0.370

574 NR 0.031 3.986 0.512 4.959 0.305 3.945 1.042 0.241 1.343

582 NR 0.012 2.549 0.077 4.675 0, 120 0.470 0, 143 0.037 0.277

596 NR 0.017 1.945 0.077 0.914 0.079 0.622 0, 189 0.059 0.221

602 NR 0.010 1.479 0.055 0.091 0.005 0.087 0.047 0.019 0.040

Table 15 (continued): Patient BMQ values for CCL21, CLDN1, FOXO1, G1P2, G1P3, IFI27, LGALS3BP and OAS2 genes (Ct normalized according to the 2 ^{"ACt method} )

Status

 Patient (NR, R CCL21 CLDN1 FOXO1 G1P2 G1P3 IF127 IFITM1 LGALS3BP OAS2 or RR)

 618 R 0.025 3,399 0, 137 4,757 0,475 4,070 0.603 0.221 0.601

619 R 0.011 1.253 0.080 1.542 0.387 1.444 0.432 0, 151 0.266

636 NR 0.048 6, 169 0.089 18.765 0.969 6.498 1.659 0.459 1.729

645 NR 0.004 0.009 0.642 0.069 0.009 0.081 0.071 0.017 0.011

646 NR 0.018 2.305 0.284 35.383 0.463 11.551 1.210 0.529 1.526

647 NR 0.028 3.021 0.287 20.393 0.297 5.979 0.936 0.097 1.564

649 NR 0.034 3.543 0.286 3.918 0, 109 1, 157 0.334 0.051 0.332

650 NR 0.022 3.272 0.254 12.381 0.465 2, 181 0.889 0.241 0.821

651 NR 0.009 3,238 0,392 4,773 0,416 6,298 0.398 0, 146 0.306

657 NR 0.013 2.362 0, 114 2.949 0.202 2.258 0.236 0.075 0.315

658 NR 0.009 1.361 0, 116 0.322 0.016 0.279 0, 125 0.019 0, 101

659 NR 0.006 1.847 0, 127 0.690 0.026 0.094 0.085 0.016 0, 175

660 NR 0.021 2.979 0, 150 6.612 0.399 2.523 0.334 0.074 0.286

662 NR 0.022 1.206 0.059 5.483 0.087 1.619 0, 180 0.049 0.053

664 NR 0.029 3, 106 0, 116 2,704 0, 184 0,917 0,371 0.063 0.002

665 NR 0.014 0.298 0.040 0.576 0.067 0.505 0.059 0.042 0.057

666 NR 0.028 3.387 0, 159 5.766 0.351 3, 127 0.326 0.095 0.774

67 NR 0.006 1.404 0.088 0.314 0.011 0, 146 0.051 0.034 0.069

563 NR 0.005 1.608 0.050 0.235 0.010 0.070 0, 128 0.038 0.058

573 NR 0.028 2,809 0.446 6,892 0.403 2,576 0.488 0, 134 0.660

599 NR 0.005 0.505 0.050 1.248 0.065 1.516 0, 109 0.013 0.079

641 NR 0.012 1.636 0, 174 2.444 0, 148 1.828 0, 187 0.035 0.259

Table 15 (continued and end) BMQ patient values for CCL21, CLDN1, FOX01, G1P2, G1P3, IFI27, LGALS3BP and OAS2 genes (Ct normalized according to the 2 ^{"ACt method} )

Status

 Patient (NR, R CCL21 CLDN1 FOXO1 G1P2 G1P3 IF127 IFITM1 LGALS3BP OAS2 or RR)

 642 R 0.046 2.949 0.200 6.635 0.382 2.990 0.917 0.429 0.877

49 RR 0.018 3.986 0.084 1.905 0.261 0.549 0.480 0.128 0.467

56 RR 0.011 1.087 0.092 3.249 0.270 1.741 0.264 0.062 0.252

60 RR 0.015 2.462 0.128 7.945 0.230 4.322 0.435 0.059.0.201

87 RR 0.021 3.605 0.123 11.432 0.361 3.193 0.521 0.104 1.057

505 RR 0.006 0.844 0.010 4.084 0.188 3.042 0.226 0.082 0.357

514 RR 0.011 2,488 0.352 0.525 0.031 0.200 0.184 0.082 0.194

531 RR 0.002 0.099 0.091 0.103 0.013 0.091 0.049 0.006 0.025

533 RR 0.008 1.548 0.059 1.145 0.073 0.702 0.072 0.046 0.092

543 RR 0.040 1.173 0.131 1.548 0.098 2.085 0.570 0.112 0.139

554 RR 0.005 1.772 0.100 0.148 0.009 0.094 0.035 0.029 0.062

557 RR 0.007 1.597 0.065 3.317 0.090 1.419 0.199 0.057 0.213

558 RR 0.002 0.730 0.070 0.289 0.019 0.331 0.032 0.015 0.048

559 RR 0.005 0.730 0.082 0.871 0.047 0.467 0.054 0.028 0.025

562 RR 0.007 2.828 0.102 3.668 0.242 1.676 0.266 0.121 0.271

576 RR 0.010 1.625 0.113 5.187 0.272 1.625 0.590 0.136 0.164

579 RR 0.004 1.206 0.053 0.147 0.006 0.034 0.060 0.019 0.021

588 RR 0.002 2.063 0.044 0.053 0.004 0.018 0.033 0.127 0.028

589 RR 0.012 2.674 0.048 7.387 0.280 2.305 0.387 0.094 0.435

591 RR 0.013 1.693 0.137 2.378 0.125 1.347 0.161 0.140 0.246

592 RR 0.020 2,297 0.191 6,000 0.204 1,010 0.468 0.158 0.553

643 RR 0.014 2.063 0.189 0.390 0.015 0.088 0.115 0.058 0.081

Table 16: Kits for Protein Assays

IL8 LGALS3BP MDK CCL21 Markers

QUANTIKINE HUMAN

HUMAN MID INE HUMAN CCL21 / 6Ckine

EIA Kit CXCL8 / IL-8 90K / Mac-2 BP ELISA

 ELISA IMMUNOASSAY

IMMUNOASSAY

R & D Systems Supplier Abnova Abnova R & D Systems

Reference D8000C KA0140 KA0028 V.02 D6C00

ELISA Type Sandwich Sandwich Sandwich Sandwich

Serum, plasma,

 serum, serum supernatant, plasma, tissue,

 Sample types culture medium serum, plasma

 cell culture cell culture medium

 cellular

test sample 50μΙ. 20μΙ. 25μΙ, ΙΟΟμΕ

Table 16 (continued): Kits for Protein Assays

solid phase mAc anti-IL8 mAc anti-LGALS3BP pAc anti MDK mAc anti-CCL21 mAc-HRP anti-conjugate pAc-HRP anti-IL8 pAc-biotin anti-MDK pAc-HRP anti-CCL21

LGALS3BP sensitivity 3.5 pg / mL 0.92 ng / mL 0.33 ng / mL 9.9 pg / mL detection range 31.2-2000 pg / mL 12.5 to 200 ng / mL 2 - 10 ng / mL mL 91-371 pg / mL

Table 16 (continuation and end): kits for protein assays

 pAc = polyclonal antibody

mAc = monoclonal antibody

Administration of anti-viral treatment and analysis of the patient's response:

After PBH and serum collection, each patient received an antiviral treatment which is currently considered the standard treatment for hepatitis C, namely a treatment based on the combination of two antiviral agents, namely alpha interferon and ribavirin .

As part of the trial described here, all patients received the following treatment:

 is :

 o pegylated interferon alpha-2b (PEG-INTRON®; Schering Plow

Corporation; Kenilworth, NJ; U.S.A.) at a dose of 1.5 g / kg / week, and o ribavirin (REBETOL®, Schering Plow Corporation, Kenilworth, NJ, U.S.A.) at a dose of:

^■ 800 to 1200 mg / kg / day for those patients who were infected with at least one genotype 1 and / or 4 and / or 5 HCV, or at a dose of

^■ 800 mg / kg / day for patients who were infected with at least one genotype 2 and / or 3 HCV,

 is :

 o pegylated interferon alpha-2a (PEGASYS®, Roche Corporation, F.

 Hoffmann-La Roche Ltd. ; Basel, Switzerland) at a dose of 180 g / kg / week, and

 o ribavirin (COPEGUS®, Roche Corporation, F. Hoffmann-La Roche Ltd., Basel, Switzerland) at a dose of 1000 to 1200 mg / kg / day.

The treatment was administered for 24 weeks for those patients who were infected with at least one genotype 2 and / or 3 HCV, and for 48 weeks for those of patients who were infected with at least one genotype 1 and / or 4 and or 5 HCV.

The viral load was measured at week 24, at the end of treatment and 6 months after the end of treatment, by quantification of the HCV RNA present in the serum of each patient, using the RNA quantification test. HCV VERSANT® HCV RNA 3.0 (bDNA) ASSAY from Siemens Healthcare Diagnostics (Quantification Limit = 615 - 7,690,000 IU / mL). Each patient was ranked according to their response to treatment as measured by the serum HCV viral load test.

A patient was considered to be:

 - a patient responding to treatment (patient rated R), when the viral load of HCV became undetectable in the patient's blood after treatment and remained undetectable 6 months after stopping treatment;

 a non-responder patient (patient classified NR), when the HCV viral load remained detectable in the patient's blood at the end of the treatment;

- a responder-recess patient (RR-rated patient), when the HCV viral load became undetectable in the patient's blood after treatment, but became detectable again 6 months after stopping treatment.

The HCV viral load was considered undetectable in the patient's blood when the HCV RNA assay in the patient's serum resulted in a value of less than 12 International Units (IU) per mL of serum as measured by the patient. VERSANT® HCV RNA 3.0 (bDNA) ASSAY HCV RNA assay from Siemens Healthcare Diagnostics as indicated above.

 Three subpopulations, or cohorts, were formed (subpopulation of patients R, subpopulation of patients NR and subpopulation of patients RR). 2. Comparison of NR and R subpopulation values to establish a multivariate classification model

The dosage values obtained in §1. above for the "responder" (R) and "non-responder" (NR) subpopulations were compared with one another to construct a multivariate classification model that, from the combination of these values, ranks the test patient among patients who have a high probability of responding to anti-HCV treatment (R level) or from the class of patients who have a high probability of not responding to anti-HCV treatment (NR class).

The dosage values obtained in §1. above for the "responder-relapse" subpopulation (RR) were also compared to the assay values obtained for the R and NR subpopulations. It has been observed that the RR subpopulation is very strongly segregated with that of the Rs: RR patients are mainly classified as R. For example, a classification model can be obtained using a multivariate statistical analysis method, or a multivariate mathematical analysis method.

MROC Models:

A suitable multivariate mathematical analysis method is the mROC method (Multivariate Receiver Operating Characteristic method).

 Using the dosage values obtained in §1. above for the R and NR subpopulations, mROC models were constructed as described in Kramar et al. 1999 and Kramar et al. 2001. For this purpose, the software mROC version 1.0, available commercially from the designers (Andrew Kramar, Antoine Fortune, David Farragi, Benjamin Reiser) was used.

 Andrew Kramar and Antoine Fortune can be contacted at or via the Biostatistics Unit of the Regional Center for the Fight Against Cancer (CRLC) Val d'Aurelle - Paul Lamarque (208, rue des Apothicaires, Euromedecine Park, 34298 Montpellier Cedex 5, France).

 David Faraggi and Benjamin Reiser can be contacted at, or through, the Department of Statistics at Haifa University (Mount Carmel, Haifa 31905, Israel).

From the dosing data entered, the mROC method generates a decision rule in the form of a linear function [Z = f (BMQi _; BMQ _2, BMQ ₃ , ...)] of type Z =

where BMQi, BMQ ₂ , BMQ ₃ ... are the dosage values of the expression levels of each of the genes chosen, and

the user identifies the reference value or threshold (δ) that gives the best performance to this combination.

This function and threshold is a multivariate classification model. The function f calculated by the mROC method was then applied to the assay values of the level of expression of BMQi, BMQ ₂ , BMQ ₃ ... genes measured for a test subject p. The calculated Z value for a test subject then was compared with the threshold δ. For example, when the average value of the combination of expression levels of said genes selected in the cohort of individuals "R" is lower than that of the cohort of individuals "NR":

 if Z> δ, the test is positive: it is declared that the subject p is a patient NR (prognostic subject non-responder to the treatment); and

 if Z <δ, the test is negative: it is declared that the subject p is a patient R (prognostic subject answering the treatment).

 Conversely, when the average value of the combination of the expression levels of said genes selected in the cohort of individuals "R" is greater than that of the cohort of individuals "NR":

 if Z> δ, the test is negative: it is declared that the subject p is a patient R (prognostic subject answering the treatment); and

 if Z <δ, the test is positive: it is declared that the subject p is a patient NR (prognostic subject non-responder to the treatment).

WKNN models:

An appropriate multivariate statistical method of analysis is WKNN (Weighed k Nearest Neighbors).

Using the dosage values obtained in §1. above for the R and NR subpopulations, WKNN models were constructed as described in Hechenbichler and Schliep

2004.

Schematically, a method WKNN assigns each new case (y, x) to the class / of maximum weight in a neighborhood to k neighbors according to the formula:

where r represents the index of clinical classes of interest (in this case, subpopulation R or subpopulation NR), and is equal to 0 or 1.

To build the WKNN models, the R software (WKNN library), freely available at http://www.r-project.org/, was used. The following setting parameters were used:

{see, for example, combination No. 1) - Kernel (K): inverse;

 - Distance (D): minkowski of parameter 1;

- Number of neighbors (k): 5;

or {see, for example, combination No. 2)

 - Kernel (K): triangular;

 - Distance (D): minkowski of parameter 2;

- Number of neighbors (k): 4;

or {see, for example, combination No. 7)

 - Kernel (K): triangular;

 - Distance (D): minkowski of parameter 1;

- Number of neighbors (k): 6;

or {see, for example, combination No. 8)

 - Kernel (K): cosine;

 - Distance (D): minkowski of parameter 1; - Number of neighbors (k): 7;

or {see, for example, combination No. 9)

 - Kernel (K): triweighted;

 - Distance (D): minkowski of parameter 1;

- Number of neighbors (k): 14;

or {see, for example, combination No. 10)

 - Kernel (K): cosine;

 - Distance (D): minkowski of parameter 1;

- Number of neighbors (k): 6;

or {see, for example, combinations No. 1 and No. 13) - Kernel (K): inverse;

 - Distance (D): minkowski of parameter 2;

- Number of neighbors (k): 3;

or {see, for example, combination No. 12)

 - Kernel (K): triangular;

 - Distance (D): minkowski of parameter 1;

- Number of neighbors (k): 10. The WKNN models thus constructed were then used to determine the subjects' R or NR status, by entering the dosage values of these subjects in the WKNN models thus constructed.

 The assay values of the expression levels of the selected genes of a test subject p were compared with those of these neighbors (k). The model WKNN calculates the weight to be assigned to the class "subpopulation R" and that to be assigned to the class "subpopulation NR" for this subject p. The subject p is then classified by the WKNN model in the majority class, for example, in the class "NR subpopulation" if the weights of the "subpopulation R" and "NR subpopulation" classes calculated by the WKNN method. were 0.3 and 0.7, respectively.

 The Leave-One-Out-Cross-Validation (LOOCV) error is as defined in Hastie, Tibishirani and Friedman, 2009.

Random forest models (Random Forest or RF):

Using the dosage values obtained in §1. above for the R and NR subpopulations, random forest models (Random Forest or RF) were constructed as described in Breiman 2001, Liaw and Wiener 2002.

 For this purpose, the R software, freely available at http://www.r-project.org/, was used. The following setting parameters were used:

 NumberOfTrees = 500;

 NumberOfDescriptors = sqrt (D).

The numerical data listed in the output file of R allow to evaluate the signatures with the calculation of the following parameters: calculation of the values of True Positive (VP), False Positive (FP), True Negative (VN) and False Negative (FN ), cf. below.

The data extracted from the output file of the RF models thus constructed have the following form:

 "OOB estimate of error rate: overall error rate

Confusion matrix:

 NR R Class. error

NR VP FN NR classification error rate

R FP VN R classification error rate

ROC score (out-of-bag data): ROC score for predicted samples " OOB is the acronym for Out-Of-Bag, and represents an assessment of the error.

These output data directly indicate the values of the parameters VP (number of NR patients who were classified NR), FP (number of patients R who were classified NR), VN (number of patients R who were classified R) and FN ( number of NR patients who were classified R).

 The following formulas are used to calculate the sensitivity (Se), specificity (Spe), Positive Predictive Value (PPV), and Negative Predictive Value (VPN) values:

Se = VP / (VP + FN);

Sp = VN / (VN + FP);

VPP = VP / (VP + FP);

VPN = VN / (VN + FN).

 The output data also directly indicates the error rate and the ROC score of the constructed model.

The RF models thus constructed were then used to determine the liver fibrosis score of test subjects. The assay values of the expression levels of the genes of these test subjects were entered into an RF model, which generates the output data as above presented, and classifies the tested subject in the class "subpopulation R" or " NR subpopulation ".

 The LOOCV error is as defined in Hastie, Tibishirani and Friedman, 2009. Models with neural networks:

Another method of appropriate multivariate statistical analysis is a neural network method. Schematically, a neural network comprises an oriented weighted graph whose nodes symbolize the neurons. The network is constructed from the subpopulation assay values (in this case, R versus NR), and is then used to determine which class (in this case, R or NR) belongs to a new element (in the occurrence, a test patient p).

Using the dosage values obtained in §1. above for the R and NR subpopulations, neural network models were constructed as described in Intrator and Intrator 1993, Riedmiller and Braun 1993, Riedmiller 1994, Anastasiadis et. al. 2005; cf. http://cran.r-project.org/web/packages/neuralnet/index.html.

 For this purpose, the R software freely available at http://www.r-project.org/ has been used (version 1.3 of Neuralnet, written by Stefan Fritsch and Frauke Guenther, following the work of Marc Suling).

 The following calculation options were used:

 NumberOfiiiddenNodes = 1 and 2

WeightDecayfactor = 0.001

CrossValidate = True

CrossValidationFolds = 5

 MaxNumberlterations = 2000

MaxNumberWeights = 2000 ".

For each combination, the confusion matrix is extracted in a form of the following type:

 Cross-validation results (5-fold):

 Nodes Decay ROC Score Best

 1 1

 2 2 ***

Contingency Table (best CVmodel):

 Predicted

Actual R NR

 R VN FP NR FN VP

In this example, we observe that the best model is model 2, indicated by "***" in the "ScoreBest" column.

These output data directly indicate the values of the parameters VP (number of NR patients who were classified NR), FP (number of patients R who were classified NR), VN (number of patients R who were classified R) and FN ( number of NR patients who were classified R). The following parameters are evaluated: sensitivity (Se), specificity (Spe), Positive Predictive Value (PPV) and Negative Predictive Value (VPN) {cf. formulas of Se, Spe, VPP and VPN above).

 The ROC score is extracted directly from the output file on the line identified by "***" which corresponds to the best model. The error rate is calculated by the following formula: Class_err = (FP + FN) / (FP + VP + FN + VN).

The neural network models thus constructed were then used to determine whether a test subject has a high probability of responding to, or not responding to, anti-HCV treatment. The assay values of the gene expression levels of these test subjects were entered into a neural network model, which generates output data as above presented, and classifies the test subject in the class "subpopulation R". "Or" NR subpopulation ". 3. Examples of classification models obtained:

The inventors have thus identified genes whose levels of expression constitute biomarkers which, when taken in combination, are relevant for determining the "responder" (R) or "non-responder" (NR) status of a subject .

These genes are the following twenty-eight genes: HERC5, IL8, STAT2, CCL21, CLDN1, CXCL6, FOX01, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18.

 Most of these genes encode proteins whose location is not transmembrane, or at least not exclusively. Most of these genes therefore encode proteins that are likely to be detected in a biological fluid of the subject, such as blood, serum or plasma. This is in fact the case of the twenty-eight genes listed above, with the exception of the following seven genes, which encode strict membrane proteins: CLDN1, G1P3, IF127, IFITM1, ITGA2, OCLN, PLSCR1.

The inventors have further identified that the most relevant combinations include:

at least two of HERC5, IL8, STAT2; and at least one of CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IFI27, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18. Illustratively, examples of suitable biomarker combinations include combinations of four or five biomarkers (combinations of the expression levels of four or five genes) shown in Table 2 above, in part descriptive.

Examples of classification schemes that can be implemented with these combinations of biomarkers are shown in Tables 3 to 5 above (combination of transcription levels of four or five genes selected according to the invention), cf. also the examples below. The predictive combinations of the invention are combinations of gene expression levels, chosen as above indicated.

 However, it may be chosen to involve in these combinations one or more factors other than the expression levels of these genes, to combine this or these other factors and the levels of expression of the genes chosen in a decision rule.

This or these other factors are preferably chosen so as to construct a classification model whose predictive power is further improved compared to the model that does not include this or these other factors (cf. example below).

This or these other factors may for example be clinical, biological or virological factors, for example:

 - one or more clinical factors, such as sex (female F or male M), age at time of collection (for example, age at time of PBH, age at date of hepatic puncture, age at date of collection of blood, serum, plasma or urine), age at time of infection, age at start of treatment, body mass index (BMI), insulin sensitivity index (HOMA) , diabetes, alcohol consumption, degree of steatosis, mode of contamination, Metavir activity, liver fibrosis score measured according to the Metavir system (Metavir F score) or according to the Ishak system,

and or one or more biological factors other than the expression levels of said selected genes, such as haptoglobin concentration (Hapto), apolipoprotein Al concentration (ApoAl), total bilirubin content (BLT), gamma glutamyl transpeptidase (GGT) concentration , Aspartate aminotransferase (AST) concentration, alanine aminotransferase (ALT) concentration, platelet content (PLQ), prothrombin (TP) level, HDL cholesterol (Chol-HDL) content, total cholesterol content, ferritin concentration ( Ferritin), glycemic content (glycemia), C-peptide concentration, insulin content (insulinemia), triglyceride concentration (TG), albumin content, transferrin iron saturation (CS), alkaline phosphatase concentration (PAL) );

and or

 - one or more virological factors, such as viral genotype, duration of infection, viral load before treatment (CVavantTTT), viral load measured in the patient at the start of treatment (viral load on day 0), viral load measured at the patient at the time of collection (PBH viral load, viral load at the date of hepatic cytopuncture, viral load at the time of collection of blood, serum, plasma or urine).

EXAMPLE 2: Liver Puncture Biopsy RNA (HPB) / Applications of Models Constructed to Test Patients

2a) example of application of the combination of expression levels (RNA) of genes HERC5, IFI44, IL8 and MDK (combination No. 1 in Table 2 above): By the method WKNN (cf. Example 1 above), the LOOCV error associated with the combination of the transcription levels (RNA) of the HERC5, IFI44, IL8 and MDK genes (combination No. 1 in Table 2 above) is 15 (cf. Table 3 above).

The best performances of this combination according to the WKNN method (calculated on the population of the 107 responders and non-responders presented in table 11 above) are the following:

sensitivity (Se) = 84%; specificity (Sp) = 86% (cf. Table 3 above).

 The setting parameters used for the WKNN method were as follows:

 Kernel (K): inverse,

Distance (D): minkowski of parameter 1, Number of neighbors (k): 5.

An example of prediction on 20 subjects (human patients) is given in Table 17 below, which presents the assay values of the expression levels of the selected genes (BMQ values obtained by the 2 ^{~ ACt method} ; 1 above).

 One or more clinical, biological and virological factors can be combined with these biomarkers (expression levels of four genes), and lead to a decision rule whose predictive power is still greater than that of the rule presented above. The following table 18 presents examples of such clinical, biological and virological factors, as well as their values for the test subjects in Table 17. ND = not determined

CV = viral load

Table 17: Example of Application of a Classification Model Based on the Combination of HERC5, IFI44, IL8 and MDK Gene Expression Levels (Combination No. 1 of Table 2 Above) Model WKNN Status

 R or NR, n ° of (kernel = inverse, distance = minkowski of parameter 1, k = 5)

 as subject

 n determined test Predicto

 HERC5 IFI44 IL8 MDK

 WKNN after treatment

521 1.670 0.785 3.732 1.676 R NR

509 0.719 0, 102 1, 157 0, 172 R NR

308 0.886 0, 154 0.853 0.446 NR NR

167 0.653 0.075 0.923 0.521 NR NR

145 1.283 0, 183 0.755 0.255 NR NR

80 0.570 0.057 0.745 0.030 NR NR

75 1,035 0,319 0,908 1,248 NR NR

58 0.600 0, 149 0.616 0.631 NR NR

46 0.563 0, 177 0.911 0.308 NR NR

6 0.247 0.046 2.648 0.688 NR NR

91 0, 149 0.042 0.040 0.051 R R

90 0.342 0.046 0.089 0, 115 R R

86 0.259 0.086 0.451 0.060 R R

76 0.293 0.067 1.257 0.045 R R

72 0.097 0.010 0.064 0.001 R R

71 0.255 0.015 0.228 0.021 R R

65 0.258 0.055 0, 168 0, 105 R R

62 0.280 0.074 0.058 0.043 R R

59 0.269 0.039 0.329 0.090 R R

50 0, 144 0.018 0.444 0, 132 RR

Table 18: Examples of clinical, virological, and biological data for the test subjects in Table 17

 Age at

Steatosis age

No. of topic IMC Alcohol Mode of Activity Fibrosis Fibrosis early

 Sex at the HOMA Diabetes (score 0

test (kg / m ² ) (g / day) contamination Metavir Ishak Metavir from

 PBH at 3)

 treatment

521 M 58.4 23.8 D No 30 0 Transfusion 1 4 3 58.9

509 F 48.2 20.8 1.4 No ND 0 Transfusion 1 4 3 48.4

308 M 34.9 27.7 ND No 0 0 Endemic area (Egypt) 1 1 1 35.4

167 F 48.6 37.8 2.3 No ND 0 Transfusion 2 1 48.8

145 M 40.8 28.4 2.3 No 10 0 Substance abuse 1 2 1 42.2

80 F 36.6 31.6 ND No 0 2 Transfusion 1 1 2 37.2

75 F 53.0 27.9 NS No 0 0 ND 2 2 53.3

58 M 48, 1 25.2 2, 1 No 0 0 Substance abuse 1 3 2 48.2

46 M 54.4 26.9 2.4 No 5 1 Unknown 2 1 55, 1

6 M 59.0 19.6 1.2 No 30 0 Substance abuse 1 3 2 59.3

91 F 47.8 21.4 N / A No 0 0 N / A 1 2 1 48.0

90 F 58.7 25.2 ND No 0 2 Transfusion 1 3 2 59.0

86 M 50, 1 28.4 N / A Yes 40 1 Unknown 1 1 1 50.3

76 F 53.5 22.8 NA No 0 0 Unknown 3 2 53.6

72 M 37.2 29.0 2.2 No 0 2 Endemic area (Egypt) 1 3 2 37.3

71 M 43.3 20.2 0.6 No 0 0 Unknown 1 2 1 43.3

65 M 35.6 29.6 3.9 No 0 0 Endemic area (Egypt) 1 2 1 35.7

62 M 61.6 27.4 8.7 ND 50 1 Nosocomial 1 3 2 61.7

59 F 50.9 23.7 1.5 No 0 0 Transfusion 1 2 1 51.3

50 M 48, 1 28.4 3.4 No 0 1 Endemic area (Egypt) 2 2 2 48.7

Table 18 (continued): Examples of clinical, virological, and biological data for Table 17 test subjects

 Genotype Duration of infection HP PBH (copies / mL 10E3) CVavantTTT (copies / mL .10E3) test

 521 1 34.8 14654 14432

 509 1 49, 1 8779 8779

 308 4 ND 423 423

 167 4 ND 12616 12616

 145 1 25.8 26631 18304

 80 1 38, 1 7606 12932

 75 1 ND 3276 2347

 58 1 30.9 5079 5079

 46 1 ND 7903 9103

 6 1 33.7 10450 10450

 91 1 ND 3902 3902

 90 1 ND 515 515

 86 2 ND 57 57

 76 1 ND 19227 19927

 72 4 ND 1155 1155

 71 4 ND 6935 6935

 65 4 ND 1135 450

 62 2 ND 14 185

 59 5 26.8 524 1120

50 4 ND 445 445

Table 18 (continued): Examples of Clinical, Virological, and Biological Data for the Test Subjects of Table 17

 No. of the subject alpha2macroglobulin Haptoglobin Apo Al BLT GGT AST ALT PLQ Chol-HDL

 TP (%)

test (g L) (g L) (g / L) (μιηοΙ / L) (U / L) (U / L) (U / L) (x 10E3 / mm ³ ) (mmol / L)

521 N / A N / A 11,127 83,166 189,100 1,62

509 4.24 0.39 1.89 13 43 154 243 121 86 1.88

308 ND ND ND 16 246 30 36 214 100 ND

167 2.9 0.54 1.64 15 378 163 144 183 78 1.28

145 2, 1 0.48 1.56 11 133 36 92 225 ND 1.25

80 N / A N / A 18 132 44 67 311 92 N / A

75 ND ND ND 12 135 64 50 233 100 2, 15

58 3, 16 0.63 1.79 4 162 62 93 222 91 1.43

46 4.77 0.21 1.48 14 174 91 125 216 100 0.89

6 2.97 0.3 1.82 13 78 50 69 200 99 1.63

91 N / A N / A 9 39 64 79 353 99 N / A

90 ND ND ND 11 21 61 119 359 100 ND

86 ND ND ND 13 287 53 105 160 100 ND

76 N / A N / A 14 81 90 157 209 96 N / A

72 1.5 0.96 1.44 15 23 31 71 249 98 0.76

71 1.89 0.47 1.92 7 22 37 58 177 94 1.63

65 4.07 1, 15 1, 17 8 46 61 152 210 92 0.72

62 4.37 0.94 1.37 12 46 34 47 257 87 1

59 2.3 0.97 2.04 20 18 49 80 239 100 2, 13

50 5.21 1.09 1.6 14 160 93 167 161 89 0.81

Table 18 (continued and end): Examples of clinical, virological, and biological data for test subjects in Table 17 No. of the subject Ferritin Glycemia Peptide C Insulin TG Albumen Chol Total PAL

 CS (%)

 test (μίΐ / L) (mmol / L) (ng / mL) (μϋΙ / mL) (mmol / L) (S / L) (mmol / L) (U / L)

521 514 6.2 ND ND 1.76 47 32 4.62 62

509 179 4.3 2.8 7.5 0.56 48 32 4.02 56

308 455 5, 1 ND ND 1, 13 48 46 4,81 73

167,702 5.22 2.3 9.82 0.62 43 70 4.58 114

145,260 5.7 2.87 8.99 1.2 40 43 5, 1 48

80 52 4.2 ND NA 0.97 47 30 5, 16 100

75 271 5,4 ND ND 0.69 44 40 4,72 149

58,693 5.4 2.35 8.79 0.93 46 33 4.93 51

46 D 4.9 3.03 11, 18 1.5 43 36 4.22 71

6,150 5.4 1.88 4.87 0.66 45 35 4.5 40

91 206 4.7 N / A 1 43 36 4.5 72

90 137 4.2 ND ND 0.88 48 42 5.4 52

86 837 6.6 ND NA 0.69 48 46 5.82 77

76,156 4.2 ND 1 ND, 12 47 36 4.96 58

72,397 5 2,34 9,74 3,57 47 27 4,72 70

71 101 4.5 0.81 3, 13 0.36 47 15 4.96 65

65,147 5.2 3,31 17.07 1.09 46 43 3.82 49

62,822 6.3 5.21 30.99 0.9 45 45 5 52

59 30 5 2, 18 6.65 0.71 46 27 5.46 77

50 182 5.2 3, 15 14.74 1.59 47 36 3.57 84

2b) example of application of the combination of the expression levels (RNA) of the HERC5, IFI44, IL8, MDK and OAS1 genes (combination No. 2 in Table 2 above): By the WKNN method (cf. Example 1 above), the LOOCV error associated with the combination of the transcription levels (RNA) of the genes HERC5, IFI44, IL8, MDK and OAS1 (combination No. 2 in Table 2 above) is 14 { cf. Table 3 above). The best performances of this combination according to the WKNN method (calculated on the population of the 107 responders and non-responders presented in table 11 above) are the following:

sensitivity (Se) = 82%; specificity (Sp) = 89% (cf. Table 3 above).

 The setting parameters used for the WKNN method were as follows:

 Kernel (K): triangular,

 Distance (D): minkowski of parameter 2,

Number of neighbors (k): 4.

An example of prediction on 20 subjects (same human patients as in example 2a) above) is given in Table 19 below, which presents the assay values of the expression levels of the selected genes (BMQ values obtained by the 2 ^{~ ACt method} , see example 1 above).

One or more clinical, biological and virological factors can be combined with these biomarkers (levels of expression of five genes), and lead to a decision rule whose predictive power is still greater than that of the rule presented above. Table 18 above presents examples of such clinical, biological and virological factors, as well as their values for the test subjects of Table 19. ND = not determined Table 19: Example of Application of a Classification Model Based on the Combination of HERC5, IFI44, IL8, MDK and OAS1 Gene Expression Levels (combination # 2 of Table 2 above) Model WKNN Status

 R or NR, n ° of (kernel = triangular, distance = minkowski of parameter 2, k = 4)

 as subject

 determined test

 HERC5 IFI44 IL8 MDK OASl Prediction after

 WKNN treatment

521 1.670 0.785 3.732 1.676 6.233 R NR

509 0.719 0, 102 1, 157 0, 172 1.324 R NR

308 0.886 0, 154 0.853 0.446 2.305 NR NR

167 0.653 0.075 0.923 0.521 2.204 NR NR

145 1.283 0, 183 0.755 0.255 2.395 NR NR

80 0.570 0.057 0.745 0.030 0.559 NR NR

75 1,035 0,319 0,908 1,248 3,959 NR NR

58 0.600 0, 149 0.616 0.631 2.313 NR NR

46 0.563 0, 177 0.911 0.308 3.543 NR NR

6 0.247 0.046 2.648 0.688 0.228 NR NR

91 0, 149 0.042 0.040 0.051 0.651 R R

90 0.342 0.046 0.089 0, 115 0.853 R R

86 0.259 0.086 0.451 0.060 1.053 R R

76 0.293 0.067 1.257 0.045 1, 161 R R

72 0.097 0.010 0.064 0.001 0, 162 R R

71 0.255 0.015 0.228 0.021 0.437 R R

65 0.258 0.055 0, 168 0, 105 0.908 R R

62 0.280 0.074 0.058 0.043 1.444 R R

59 0.269 0.039 0.329 0.090 1.380 R R

50 0, 144 0.018 0.444 0, 132 0.826 RR

2c) example of application of the combination of the expression levels (RNA) of the genes IL8, CLDN1, G1P3, HERC5 and RSAD2 (combination No. 29 in Table 2 above): The AUC relating to the combination of Expression levels of the IL8, CLDN1, G1P3, HERC5 and RSAD2 genes (combination No. 29 in Table 2 above) calculated on the population of the 107 responders and non-responders presented in Table 1 1 above is 0.857 {cf. Table 7 above). By the mROC method, the threshold maximizing the Youden index (δ) for this combination is -1.281 {cf. Table 5 above).

 For the choice of this threshold, the performances of the combination are as follows:

Sensitivity (Se) = 77%; specificity (Spe) = 79% (cf. Table 3 above). An example of a decision rule is the following rule:

 Z = 0.14 x CLDN1 * + 0.488 x G1P3 * + 0.966 x HERC5 * + 0, 129 x IL8 - 0.487 x RSAD2 * (function Z29ARN, see Table 5 above), where:

CLDN1, G1P3, HERC5, IL8 and RSAD2 are BMQ biomarker assay values, i.e., the assay values of the expression levels of the indicated genes (Ct normalized according to the 2 ^{"ACt method} ),

 the exponent t (here carried by CLDN1, G1P3, HERC5 and RSAD2) indicates that the value to be applied in the decision rule is the Box-Cox transform (Box and Cox, 1964) of the dosage value of the expression level of the gene considered, in order to

 t λ

 normalize according to the following formula: BMQ = (BMQ - \) IX.

In the decision rule example above, the parameters λ are 0.68 for CLDN1, 0, 19 for G1P3, 0, 19 for HERC5 and -0.05 for RSAD2 (see table above). ).

If Z> -1.281: the diagnostic test is positive (prediction mROC = 1), the subject is declared 'R' (subject prognostic non-responder to the treatment),

If Z <-1,281: the test is negative (prediction mROC = 0), the subject is declared 'R' (prognostic subject responding to the treatment). An example of prediction on 20 subjects is given in Table 20 below, which presents the assay values of the expression levels of the selected genes (BMQ values obtained by the 2 ^{~ ACt method} , see Example 1 above). ).

 One or more clinical, biological and virological factors can be combined with these biomarkers indicated above (levels of expression of five genes), and lead to a decision rule whose predictive power is still greater than that of the rule above. presented. Table 21 above shows examples of such clinical, biological and virological factors, as well as their values for the test patients in Table 20. D = Not determined

CV = viral load

Table 20: Example of application of a classification model based on the combination of IL8, CLDN1, G1P3, HERC5 and RSAD2 gene expression levels (combination # 29 of Table 2 above) model mROC

 Status

 (function Z29ARN; δ = = -1.281)

 No. of test subject R or NR,

 as determined after treatment

CLDN1 GIP3 HERC5 IL8 RSAD2 Z Prediction mROC

 46 4, 112 0.209 0.563 0.911 2,395 -1, 168 R NR

50 1.409 0.097 0.44 0.444 0, 194 -1.546 R R

 55 0.856 0.060 0.235 1.395 0.221 -1.362 R R

 58 1.966 0.476 0.60 0.616 1.439 -0.779 NR NR

59 1.840 0.089 0.269 0.329 0.283 -1.291 R R

 62 3.042 0, 141 0.280 0.058 0.568 -1.380 R R

 65 1,664 0.061 0.258 0, 168 0.480 -1.745 R R

 71 0.607 0.038 0.255 0.228 0.322 -1.809 R R

 72 0.406 0.006 0.097 0.064 0.054 -1.970 R R

 75 4, 170 0.607 1.035 0.908 2.959 -0.273 NR NR

76 2.403 0.041 0.293 1.257 0.340 -1.365 R R

 80 2,329 0,031 0,570 0,745 0.309 -0.920 NR NR

83 5,776 0,730 2,549 0,231 4,362 0,630 NR NR

86 1.361 0.329 0.259 0.451 0.681 -1.348 R R

 91 1.261 0.038 0, 149 0.040 0.248 -1.988 R R

 145 2.959 0.360 1.283 0.755 1.469 -0.080 NR NR

 167 1,500 0.434 0.653 0.923 0, 129 0.461 NR NR

 308 2.305 0.545 0.886 0.853 1.057 -0, 162 NR NR

 521 4,317 1,315 1,670 3,732 6,681 0,592 NR NR

526 1,741 0,293 0,418 2,370 0,973 -0,902 NR NR

Table 21: Examples of Clinical, Virological, and Biological Data for Table 20 Test Subjects

 Age at n ° Age Steatosis

 BMI Alcohol Mode of Activity Fibrosis Fibrosis early subject sex at the HOMA Diabetes (score 0 to

(kg / m ² ) (g / day) Metavir Ishak Metavir contamination of the PBH test 3) Treatment

46 M 54.4 26.9 2.4 No 5 1 Unknown 2 2 1 55, 1

50 M 48, 1 28.4 3.4 No 0 1 Endemic area (Egypt) 2 2 2 48.7

55 F 48.2 22.2 3.5 No 60 2 Unknown 1 3 2 49.8

58 M 48, 1 25.2 2, 1 No 0 0 Substance abuse 1 3 2 48.2

59 F 50.9 23.7 1.5 No 0 0 Transfusion 1 2 1 51.3

62 M 61.6 27.4 8.7 ND 50 1 Nosocomial 1 3 2 61.7

65 M 35.6 29.6 3.9 No 0 0 Endemic area (Egypt) 1 2 1 35.7

71 M 43.3 20.2 0.6 No 0 0 Unknown 1 2 1 43.3

72 M 37.2 29.0 2.2 No 0 2 Endemic area (Egypt) 1 3 2 37.3

75 F 53.0 27.9 D No 0 0 ND 2 2 2 53.3

76 F 53.5 22.8 D No 0 0 Unknown 2 3 2 53.6

80 F 36.6 31.6 ND No 0 2 Transfusion 1 1 2 37.2

83 F 51.4 25.7 ND No ND 2 NC 1 2 1 52.0

86 M 50, 1 28.4 N / A Yes 40 1 Unknown 1 1 1 50.3

91 F 47.8 21.4 N / A No 0 0 N / A 1 2 1 48.0

145 M 40.8 28.4 2.3 No 10 0 Substance abuse 1 2 1 42.2

167 F 48.6 37.8 2.3 No ND 0 Transfusion 2 2 1 48.8

308 M 34.9 27.7 ND No 0 0 Endemic area (Egypt) 1 1 1 35.4

521 M 58.4 23.8 N / A No 30 0 Transfusion 1 4 3 58.9

526 F 73.0 24.8 ND No 0 1 Transfusion 2 6 4 73.2

Table 21 (cont'd): Examples of clinical, virological, and biological data for the test subjects in Table 20

 n ° of

 Subject Genotype Infection duration CV PBH (copies / mL 10E3) CV before TT (copies / mL .10E3) test

 46 1 ND 7903 9103

 50 4 ND 445 445

 55 1 ND 150 299

 58 1 30.9 5079 5079

 59 5 26.8 524 1120

 62 2 ND 14 185

 65 4 ND 1135 450

 71 4 ND 6935 6935

 72 4 ND 1155 1155

 75 1 ND 3276 2347

 76 1 ND 19227 19927

 80 1 38, 1 7606 12932

 83 1 ND 1579 3928

 86 2 ND 57 57

 91 1 ND 3902 3902

 145 1 25.8 26631 18304

 167 4 ND 12616 12616

 308 4 ND 423 423

 521 1 34.8 14654 14432

526 1 38.4 778 778

Table 21 (cont'd): Examples of clinical, virological, and biological data for the test subjects in Table 20

 n ° of

 alpha2macroglobulin Haptoglobin Apo Al BLT AST GGT ALT PLQ Chol-HDL subject TP (%)

 (x 10E3 / mm3) (mmol / L) test (g L) (g L) (g / L) (μιηοΙ / L) (U / L) (U / L) (U / L)

 46 4.77 0.21 1.48 14 174 91 125 216 100 0.89

50 5.21 1.09 1.6 14 160 93 167 161 89 0.81

55 4.4 0.38 1.4 13 118 210 314 156 95 1.05

58 3, 16 0.63 1.79 4 162 62 93 222 91 1.43

59 2.3 0.97 2.04 20 18 49 80 239 100 2, 13

62 4.37 0.94 1.37 12 46 34 47 257 87 1

65 4.07 1, 15 1, 17 8 46 61 152 210 92 0.72

71 1.89 0.47 1.92 7 22 37 58 177 94 1.63

72 1.5 0.96 1.44 15 23 31 71 249 98 0.76

75 ND ND ND 12 135 64 50 233 100 2, 15

76 N / A N / A 14 81 90 157 209 96 N / A

80 N / A N / A 18 132 44 67 311 92 N / A

83 ND ND ND 13 82 78 95 232 101 ND

86 ND ND ND 13 287 53 105 160 100 ND

91 N / A N / A 9 39 64 79 353 99 N / A

145 2, 1 0.48 1.56 11 133 36 92 225 ND 1.25

167 2.9 0.54 1.64 15 378 163 144 183 78 1.28

308 ND ND ND 16 246 30 36 214 100 ND

521 N / A N / A 11,127 83,166 189,100 1,62

526 ND ND ND 17 172 128 210 187 77 ND

Table 21 (continuation and end): examples of clinical, virological, and biological data for the following tests in Table 20

 Ferritin Glycemia Peptide C Insulin TG Albumen Chol Total PAL subject CS (%)

 (mmol / L) (ng / mL) (μM / mL) (mmol / L) (g L) (mmol / L) (U / L) test

 46 D 4.9 3.03 11, 18 1.5 43 36 4.22 71

50 182 5.2 3, 15 14.74 1.59 47 36 3.57 84

55,943 5.6 4.04 14.04 0.68 46 43 4.88 55

58,693 5.4 2.35 8.79 0.93 46 33 4.93 51

59 30 5 2, 18 6.65 0.71 46 27 5.46 77

62,822 6.3 5.21 30.99 0.9 45 45 5 52

65,147 5.2 3,31 17.07 1.09 46 43 3.82 49

71 101 4.5 0.81 3, 13 0.36 47 15 4.96 65

72,397 5 2,34 9,74 3,57 47 27 4,72 70

75 271 5,4 ND ND 0.69 44 40 4,72 149

76,156 4.2 ND 1 ND, 12 47 36 4.96 58

80 52 4.2 ND NA 0.97 47 30 5, 16 100

83 71 5.6 ND NA 0.76 44 37 3.68 97

86 837 6.6 ND NA 0.69 48 46 5.82 77

91 206 4.7 N / A 1 43 36 4.5 72

145,260 5.7 2.87 8.99 1.2 40 43 5, 1 48

167,702 5.22 2.3 9.82 0.62 43 70 4.58 114

308 455 5, 1 ND ND 1, 13 48 46 4,81 73

521 514 6.2 ND ND 1.76 47 32 4.62 62

526,320 4.4 ND N / A 0.7 41 35 4.33 108

2d) combination of expression levels (RNA) of the IL8, CLDN1, G1P3, HERC5 and RSAD2 genes (combination No. 29 in Table 2 above), further combined with clinical factors and / or other biological factors and / or virological factors:

One or more clinical factors and / or one or more biological factors and / or one or more virological factors can be combined with the expression levels of genes selected according to the invention (in this case, RNA transcription levels measured in a sample of PBH), and thus lead to a decision rule whose predictive power is still greater than that of the only combination of said levels of expression.

For example, the combination:

 expression levels (RNA) of the IL8, CLDN1, G1P3, HERC5 and RSAD2 genes (combination No. 29 in Table 2 above, see Example 2c above),

 the value of the (other) biological factor

 o alkaline phosphatase or PAL concentration (in IU / mL), and the following virological factor value:

o viral load before the start of treatment or CVavantTTT (copies / mL.10 ³ )

led to a decision rule whose area under the ROC curve (AUC), calculated on those of the 107 responders and non-responders in Table 11 above, for which biological and virological data were available (a total of 97 responders and non-responders, see Table 22 below) is 0.904 {cf. Table 26 above), whereas it is 0.857 (cf. Table 7 above), when the combination of the expression levels of the IL8, CLDN1, G1P3, HERC5 and RSAD2 genes is used alone, without being combined with the clinical and virological factors indicated above (PAL and CVavantTTT).

By the method mROC {cf. Example 1), the threshold maximizing the Youden index for this combination is 4,687 {cf. table 24 above).

 For the choice of this threshold, the performances of the combination are as follows:

Sensitivity (Se) = 81%; specificity (Spe) = 80% (cf. Table 23 above).

An example of a decision rule is the following rule: Z = 0.3 x CLDN1 * + 0.634 x GIP3 * + 1, 154 x HERC5 <+ 0.114 x IL8 - 0.685 x RSAD2 <+

0,036 x CV beforeTTT * + 2, 139 x PAL *

 (see Z29ARNsupp, see Table 24 above), where:

IL8, CLDN1, G1P3, HERC5 and RSAD2 are the BMQ assay values of the biomarkers, that is to say the assay values of the expression levels of the indicated genes (Ct normalized according to the method of 2 ^"ACt ) ,

 - CVavantTTT and PAL are the values of the virological factor and the biological factor indicated above, and

 - the exponent t (here carried by CLDN1, G1P3, HERC5, RSAD2, CVavantTTT and PAL) indicates that the value to be applied in the decisional rule is the transform Box-

Cox (Box and Cox, 1964) of the assay value of the level of expression of the gene considered, in order to normalize it according to the following formula: BMQ '= (BMÇ) /.

In the decision rule example above, the parameters λ are 0.63 for CLDN1, 0.21 for G1P3, 0.15 for HERC5, -0.02 for RSAD2, 0.2 for CVavantTTT and -0.26 for PAL {cf. Table 25 above).

If Z> 4,687: the diagnostic test is positive (prediction mROC = 1), the subject is declared 'NR'. If Z <4,687: the test is negative (prediction mROC = 0), the subject is declared 'R'.

Table 22: Clinical, Biological and Virological Data

Table 22 (continued and end): clinical, laboratory and virological data

Clinical, Biological and Virological Data Patients Patients NR Patients R

Genotypes HCV [n (%)]

 1 60 (61.86) 36 (85.71) 24 (43.64)

2 8 (8.25) 0 (0) 8 (14.55)

3 11 (11,34) 2 (4,76) 9 (16,36)

4 17 (17.53) 4 (9.52) 13 (23.64)

5 1 (1.03) 0 (0) 1 (1.82)

Fibrosis Score (Metavir F Score) [n (%)]

 1 33 (34.02) 12 (28.57) 21 (38, 18)

38 (39, 18) 15 (35.71) 23 (41.82)

3 11 (11.34) 8 (19.05) 3 (5.45)

4 (15,46) 7 (16,67) 8 (14,55)

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Claims

1. An in vitro method to predict, prior to treatment, whether an HCV-infected subject has a high likelihood of being a responder to anti-HCV treatment which will include interferon administration and administration of ribavirin or a prodrug of ribavirin, or if, on the contrary, this subject has a high probability of not being a responder to this anti-HCV treatment,

said method comprising the following steps:

 i) carry out the following measures:

 in a sample previously obtained from said subject, assaying the levels at which selected genes are transcribed or translated, said selected genes, whose transcription or translation levels are measured, being the following combination of genes:

 at least two genes among HERC5, IL8 and STAT2,

 and

 at least one of CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IFI27, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2 and USP18,

 optionally, measuring or determining, for said subject, the value of one or more clinical factors and / or of one or more virological factors and / or of one or more biological factors other than the expression levels of selected genes among HERC5, IL8, STAT2, CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2 , STAT1, STMN2 and USP18, ii) comparing the values of the measurements obtained for said subject in step i), their values, or the distribution of their values, in pre-established reference cohorts according to their responder status or not responder to the anti-HCV treatment, to classify said subject in that of these reference cohorts with respect to which he has the highest probability of belonging,

said method being further characterized in that the total number of mammalian genes whose level of expression is assayed is from 3 to 10.

2. The method of claim 1, characterized in that it is implemented before said anti-HCV treatment has begun.

The method of any one of claims 1 to 2, wherein the total number of said clinical, virological and other biological factors, the value of which is measured or determined in step i), is 0 to 4.

The method of any one of claims 1 to 3, wherein the comparison of step ii) is made by combining the measurement values obtained for said subject in step i), in a multivariate classification model. , who compares these values with their values, or the distribution of their values, in pre-established reference cohorts according to their responder or non-responder status, to classify said subject in that of these reference cohorts vis-à- which he has the highest probability of belonging to.

5. The method of any one of claims 1 to 4, wherein the comparison of step ii) is made by combining the measurement values obtained for said subject in step i), in a multivariate classification model. previously constructed as follows:

 (a) for a population of individuals who are of the same species as the subject and who are infected with HCV (s), determine for each of those individuals whether they respond to or do not respond to anti-HCV treatment that includes the administration of interferon and ribavirin, and classify these individuals into distinct subpopulations according to whether they are responders or nonresponsive to this treatment, thus constituting reference cohorts based on the response or not -response of these individuals to anti-HCV treatment; (b) in at least one sample that has been previously obtained from each of the said individuals, the nature of which is identical to that of the sample of the said subject, carry out the same measurements as those made for the subject in the said step i);

c) make an inter-cohort comparison of the values of the measurements obtained in step b), or the distribution of these values, to construct a multivariate classification model, which induces an anti-HCV responder status or a status non-responder to this treatment, from the combination of said measurement values obtained in step b).

The method according to any one of claims 1 to 5, wherein the comparison of step ii) is performed by combining said measurement values obtained in step i) into a mathematical function, in particular a linear function or non-linear, more particularly a linear function, to obtain an output value indicative of the responder or non-responder status of said subject.

The method according to any one of claims 1 to 5, wherein the comparison of step ii) is performed by combining said values obtained in step i) in a multivariate machine learning model, for example a multivariate nonparametric classification model, multivariate heuristic model, or multivariate probabilistic prediction model, to obtain an output value indicative of respondent or non-responder status of said subject.

8. The method according to any of claims 1 to 7, wherein the classification of said subject in that of these reference cohorts with respect to which he has the highest probability of belonging is done with:

 - a sensitivity (Se) of not less than 77%, or not less than 78%, not less than 79%, or not less than 80%>, or not less than 81%>, or at least 82%, or at least 83%>, or at least 84%; and / or with

 - specificity (Sp) of at least 79%, at least 80%, or at least 81%, or at least 82% o, or at least 83%, or at least 84%; %, or at least 85%, or at least 86%, or at least 87%, or at least 88%, or at least 89%, or at least 90%; and / or with

- a Negative Predictive Value (NPV) of at least 80%, or at least 81%, or at least 82%, or at least 83%, or at least 84%, or at least 85%, or at least 86% o, or at least 87%; and / or with

- a Positive Predictive Value (PPV) of at least 72%, or at least 73%, or at least 74%, or at least 75%, or at least 76%, or at least 77%, or at least 78%, at least 79%, or at least 80%, or at least 81%, or at least 82%, or at least less than 83%, or at least 84%, or at least 85%, or at least 86%, or at least 87%, or at least 88%, or at least 89% %.

The method according to any one of claims 1 to 8, wherein said multivariate classification model presents:

 - an area under the ROC (AUC) curve of at least 0.84, or at least 0.85, or at least 0.86, or at least 0.87, or at least 0.88, or at least 0.89, more preferably at least 0.90, and / or

 - a LOOCV error of not more than 17%, not more than 16%, not more than 15%, not more than 14%, not more than 13%, not more than 12%.

The method according to any one of claims 1 to 9, wherein in step i) said genes selected from:

 at least two of HERC5, IL8, STAT2, and

 at least one of CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IFI27, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18,

are :

 HERC5, IFI44, IL8, MDK (combination No. 1), or

 - HERC5, IFI44, IL8, MDK, OAS1 (combination # 2), or

 G1P2, IL8, OCLN, STAT2, USP18 (combination No. 3), or

 CXCL6, IFIT4, IL8, STAT1, STAT2 (combination No. 4), or

CXCL6, IL8, MX1, PLSCR1, STAT2 (combination No. 5), or

 CXCL6, IL8, MX1, STAT1, STAT2 (combination No. 6), or

 - HERC5, IFI44, IL8, MDK, STMN2 (combination No. 7), or

 HERC5, IL8, PLSCR1, STMN2 (combination No. 8), or

 - HERC5, IFI35, IFIT1, IL8, MX1 (combination 9), or

- HERC5, IFI44, IL8, OAS1, RSAD2 (combination No. 10), or

 HERC5, IFI44, IL8, ITGA2, MDK (combination No. 11), or

 - HERC5, IFIT1, IL8, MX1 (combination # 12), or

 HERC5, IL8, MDK, OAS3, RSAD2 (combination No. 13), or

 - CCL21, G1P2, IL8, MDK, STAT2 (combination No. 14), or

- G1P2, IFITM1, IL8, OCLN, STAT2 (combination No. 15), or

 - G1P2, IL8, OAS1, OCLN, STAT2 (combination No. 16), or

 - CLDN1, IL8, OAS2, OAS3, STAT2 (combination No. 17), or

 - CXCL6, IFITM1, IL8, MX1, STAT2 (combination No. 18), or

- CXCL6, IFIT1, IL8, STAT2 (combination No. 19), or FOXO1, G1P2, IL8, MDK, STAT2 (combination No. 20), or

 CXCL6, G1P2, IL8, MDK, STAT2 (combination No. 21), or

 CXCL6, IL8, OAS2, STAT1, STAT2 (combination No. 22), or

 FOXO1, IFI27, IFITM1, IL8, STAT2 (combination No. 23), or

- HERC5, IFI35, IFI44, IL8, OAS2 (combination No. 24), or

 IL8, CCL21, G1P3, HERC5, RSAD2 (combination No. 25), or

 IL8, G1P3, HERC5, OAS3, RSAD2 (combination No. 26), or

 IL8, ITGA2, G1P3, HERC5, RSAD2 (combination No. 27), or

 IL8, STMN2, G1P3, HERC5, RSAD2 (combination No. 28), or

IL8, CLDN1, G1P3, HERC5, RSAD2 (combination No. 29), or

 IL8, G1P3, HERC5, LGALS3BP, RSAD2 (combination No. 30).

The method of any one of claims 1 to 10, wherein said at least two genes selected from HERC5, IL8, STAT2 comprise IL8.

The method of any one of claims 1 to 11, wherein said at least one gene selected from CCL21, CLDN1, CXCL6, FOX01, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2 and USP18, is CXCL6, IFI44, MDK, MX1 or RSAD2.

The method of any one of claims 1 to 12, wherein said genes selected in step i) do not comprise CLDN1, G1P3, IF127, IFITM1, ITGA2, OCLN and PLSCR1.

The method according to any one of claims 1 to 13, wherein in step i), the total number of said genes selected from:

 at least two of HERC5, IL8, STAT2, and

 at least one of CCL21, CLDN1, CXCL6, FOXO1, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP, MDK, MX1, OAS1,

OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18,

is 3, 4 or 5.

The method of any one of claims 1 to 14, wherein - said one or more clinical factors are chosen from the following factors: sex, age at the date of sampling, age of the patient at the date of the contamination, age of the patient at the date of the beginning of the treatment, body mass index, index of insulin sensitivity, diabetes, alcohol consumption, degree of steatosis, mode of infection, Metavir activity, liver fibrosis score as measured by the Metavir system (Metavir F score) or the Ishak system; and or

 said virological factor or factors are chosen from the following factors: viral genotype, duration of the infection, viral load before treatment, viral load measured in the patient at the date of the beginning of the treatment, measured viral load in the patient on the date the levy; and or

- said one or more biological factors other than the expression levels of genes selected from HERC5, IL8, STAT2, CCL21, CLDN1, CXCL6, FOX01, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP; , MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18 are selected from the following factors: haptoglobin concentration, apolipoprotein Al concentration, total bilirubin content, gamma glutamyl transpeptidase concentration, concentration aspartate aminotransferase, alanine aminotransferase concentration, platelet content, prothrombin content, cholesterol content F (O ⁾ L, total cholesterol content, ferritin concentration, glycemic content, peptide C concentration, insulin content, triglyceride concentration, content albumin, iron saturation of transferrin, alkaline phosphatase concentration.

The method of any one of claims 1 to 15, wherein:

 the said clinical factor (s) include the liver fibrosis score measured according to the Metavir system (Metavir F score) or according to the Ishak system; and or

 said virological factor or factors comprise the viral genotype and / or the viral load before treatment; and or

 - said one or more biological factors other than the expression levels of genes selected from HERC5, IL8, STAT2, CCL21, CLDN1, CXCL6, FOX01, G1P2, G1P3, IF127, IF135, IF144, IFIT1, IFIT4, IFITM1, ITGA2, LGALS3BP; , MDK, MX1, OAS1, OAS2, OAS3, OCLN, PLSCR1, RSAD2, STAT1, STMN2, USP18 include the concentration of alkaline phosphatase.

The method of any one of claims 1 to 16, which comprises: determining whether the liver fibrosis score of said subject is a score which, according to the Metavir score system, is at least Fl, more particularly at least F2; and or

 determining whether the HCV (s) infected with said subject include HCV of genotype 1, 4, 5 or 6, more particularly of genotype 1 or 4.

18. The method according to any one of claims 1 to 17, wherein said sample previously obtained from said subject is:

 a sample of intracorporeal biological fluid previously taken from said subject, such as a sample of blood, serum, plasma, or a urine sample from said subject, or

 a sample containing proteins and / or polypeptides and / or peptides extracted or purified from said biological sample.

19. An article of manufacture comprising reagents in a combined preparation for their simultaneous, separate or spread use over time, said reagents being composed of:

reagents which specifically detect each of the transcription or translation products of 3 to 46 human genes, said 3 to 46 human genes comprising said genes selected according to any one of claims 1 to 18, and optionally other human genes,

and

 optionally, reagents which specifically detect one or more hepatitis viruses and / or the genotype (s) of hepatitis virus.

An article of manufacture comprising reagents in a combined preparation for simultaneous, separate or time-spread use in the method of any one of claims 1 to 18, said reagents comprising reagents which specifically detect each of the transcripts or translating genes selected according to any one of claims 1 to 18.

21. An article of manufacture comprising reagents in a combined preparation for simultaneous, separate or time-course use in an anti-HCV therapy method, said reagents comprising reagents which specifically detect each gene transcription or translation products selected according to any one of claims 1 to 18.

22. The manufactured article of any one of claims 19 to 21, wherein said reagents are nucleic acids that specifically hybridize to the RNA of said genes selected according to any one of claims 1 to 18. and / or cDNA obtained by reverse transcription of these RNAs, or are proteins, polypeptides, or peptides that specifically bind to the proteins encoded by said selected genes.

23. The manufactured article of any one of claims 19 to 22, wherein said reagents are amplification primers and / or nucleic acid probes, or are antibody or antibody fragments or protein aptamers, polypeptides or peptides.

24. The article of manufacture of any one of claims 19 to 23, wherein said reagents are contained in one or more tubes, or in the wells of a nucleic acid amplification plate for receiving a sample containing nucleic acids and a nucleic acid amplification reaction mixture, or in the wells of a protein titration plate, more particularly a protein microtiter plate, for example an ELISA plate, or on microbeads or on a microarray chip. the detection and quantification of nucleic acids, proteins, polypeptides or peptides.

25. Computer program product, intended to be stored in a memory of a processing unit, or on a removable memory medium intended to cooperate with a reader of said processing unit, characterized in that it comprises instructions for the implementation of a method according to any one of claims 1 to 18.

26. A computing device, comprising a processing unit in the memory of which is stored a computer program product according to claim 22, and assay values of the transcription and / or translation levels of said selected genes as defined in FIG. any one of claims 1 to 18.