DE19511243A1 - New growth / differentiation factor of the TGF-beta family - Google Patents

Abstract

The invention concerns a protein of the TGF- beta family, the DNA which codes for it and a pharmaceutical composition containing such a protein.

Description

The present invention relates to a new growth / Differentiation factor of the TGF-β family and coding for it DNA sequences.

The TGF-β family of growth factors include the BMP, TGF and activin / inhibin related proteins (Roberts and Sporn, Handbook of Experimental Pharmacology 95, 419-472 (1990)). They are more medical for a wide range Treatment methods and applications relevant. These factors are suitable in procedures that improve wound healing and Affect tissue restoration. Furthermore, several induce Members of the TGF-β family see tissue growth, such as Example of bone growth.

Wozney (Progress in Growth Factor Research 1 (1989), 267-280) and Vale et al. (Manual of Experimental Pharmacology 95 (1990), 211-248) describe various growth factors, such as those with BMP and activin / inhibin Group are related. The members of this group point significant structural similarities. The forerunner of Protein consists of an amino terminal signal sequence, one Propeptide and a carboxy terminal sequence from 110 to 140 Amino acids that are split off from the precursor and the mature one Represents protein. Furthermore, their members are represented by a Amino acid sequence homology defined. The mature protein contains the most conserved sequences, especially seven Cysteine residues preserved among family members are. The TGF-β-like proteins are multifunctional, hormonally active growth factors. They also assign relatives biological activities, such as chemotactic attraction of Cells, promoting cell differentiation and tissue induction skills. EP 0 222 491 A1 discloses sequences of Inhibin alpha and beta chains.  

Overall, the proteins of the TGF-β family show differences in their structure, causing significant variations in their exact biological function. Furthermore, they are in one wide range of different tissue types and development levels found. Hence, they can differ in terms their exact function, e.g. B. the required cellular physiological environment, their lifespan, their destinations, their requirements for auxiliary factors and their durability against degradation. Although numerous proteins make up a Show tissue inductive potential, must be described their natural functions in the organism and more importantly their medical relevance is still being researched in detail. The Presence of as yet unknown members of the TGF-β Family responsible for differentiation / induction of various important types of tissue are very likely accepted. A great difficulty in isolation of these new TGF-β-like proteins, however, is that their functions are not yet accurate enough for development a distinctive bioassay can. On the other hand, the expected nucleotide sequence is homolo Too few known members of the family to Screening using classic nucleic acid hybridization techniques to enable. Nevertheless, the further isolation and character Terization of new TGF-β-like proteins urgently needed necessary for further induction and differentiation proteins to provide all the medical needs you want meet nisse. These factors could be medical application in healing damage and treating degenerati Find diseases of different tissues.

In the patent application PCT / EP93 / 00350 there is a nucleotide and Amino acid sequence given for the TGF-β protein MP-121, where much of the sequence corresponding to the mature peptide is specified. The full sequence of the MP-121 propeptide is not revealed.

The object underlying the present invention is to provide DNA sequences that are new Members of the TGF-β protein family with mitogenic and / or Coding differentiation-inductive potential. Especially the object of the present invention is that complete DNA and amino acid sequence of the TGF protein MP-121 to provide.

This task is solved by a DNA molecule that is responsible for a Protein of the TGF-β family encoded and

• a) the portion coding for the mature protein and given if necessary, further functional parts of the in SEQ ID NO. 1 nucleotide sequence shown,
• b) one of the sequence from (a) in the context of the degeneration of the nucleotide sequence corresponding to genetic codes,
• c) an an allelic derivative of one of the sequences from (a) and (b) corresponding nucleotide sequence, or
• d) one with one of the sequences from (a), (b) or (c) hybridizing sequence

on the condition that a DNA molecule according to (d) at least least that coding for a mature protein of the TGF-β family Share contains.

Further embodiments of the present invention relate to the subject of claims 2 to 10. Other features and Advantages of the invention emerge from the description of the preferred embodiments. The sequence listing and Drawings will now be briefly described.

SEQ ID NO. 1 shows the complete nucleotide sequence for that for DNA encoding TGF-β protein MP-121. The ATG start codon starts with nucleotide 128. The start of full maturity Protein starts with nucleotide 836.  

SEQ ID NO. 2 shows the complete amino acid sequence of the TGF-β Protein MP-121, which is derived from the in SEQ ID NO. 1 nucleo shown tid sequence was derived. The beginning of the preferred ripening Protein is at amino acid 237.

Fig. 1 shows a comparison of the amino acid sequence of MP-121 with some members of the TGF-β family (inhibin α and β chains) starting from the first of the seven conserved cysteine residues. * means that the amino acid is the same in all compared proteins; + means that the amino acid in at least one of the proteins matches in comparison to MP-121.

Figure 2 shows the nucleotide sequences of the oligonucleotide primers used in the present invention and a comparison of these sequences with known members of the TGF-β family. M means A or C, S means C or G, R means A or G and K means G or T. 2 a shows the sequence of the primer OD, 2 b shows the sequence of the primer OID.

In the context of the present invention, the term "mature Protein "but also functional parts of the Total protein, which is essentially the same biological Have activity and preferably those areas that at least the range of seven in the TGF-β family con served cysteine. In particular, it is here possible that the N-terminus of the mature protein is slightly modified is adorned, that of the in SEQ ID NO. 2 sequence shown deviates. There can be both additional amino acids here do not affect the functionality of the protein as well as amino acids are missing, as far as in this case the functionality is not restricted. Is preferred however, that the protein contains all amino acids from amino acid 237 on in SEQ ID NO. 2 contains the amino acid sequence shown. From others Family members of the TGF-β family are already aware that appending additional amino acids to the N-terminus of the  mature protein does not impair activity, with u. a. 6 additional histidines were attached to the N-terminus.

The present invention thus includes that for the mature protein portion coding according to the above definition and, if appropriate further functional parts of the in SEQ ID NO. 1 shown Nucleotide sequence as well as sequences that frame this sequence correspond to the degeneration of the genetic code and all lische derivatives of such sequences. Furthermore, the The present invention also hybridizes with such sequences sequences provided that such a DNA Molecule at least that for a mature protein of the TGF-β family (as defined above) coding part completely contains and the biological activity is preserved.

The term "functional part" in the sense of the present Invention means a portion of protein that is capable of e.g. B. as a signal peptide, propeptide or mature protein portion act, d. H. at least one of the biological functions of meet natural proportions of MP-121.

The area coding for the mature portion of the protein preferably ranges from nucleotide 836 to the stop codon, which is found in nucleotide 1184 in SEQ ID NO. 1 shown Sequence begins. If necessary, the DNA molecule can still further functional parts of the in SEQ ID NO. 1 shown Include sequence, namely that for the signal and / or propep nucleotide sequences encoding the tid portion. Particularly preferred the DNA molecule comprises the sequence for the signal and propep tid percentage and the percentage of mature protein, d. H. the nucleo tide 128 to 1184 of the in SEQ ID NO. 1 sequence shown. On the other hand, the DNA molecule can be next to that for the mature one Protein coding portion also functional signal or / and propeptide portions of other proteins, e.g. B. from Proteins with Cystine Knot Motif (Cell, Vol. 73 (1993), p. 421-424) and in particular of other proteins of the TGF-β family, e.g. B. the above-mentioned activin / inhibin or BMP proteins,  in particular also include MP52 (see PCT / EP94 / 02630). The corresponding nucleotide sequences are from the above To take references, to the disclosure of which reference is hereby made is taken. It is important that the correct reading frame for the mature protein is preserved. Whichever Host cell expression is taking place, could be the presence be another signal sequence and / or another Propeptide portion positively affect expression. Of the Exchange of propeptide parts by corresponding parts other proteins is e.g. B. at Mol. Endocrinol. 5 (1991), 149-155 and Proc. Natl. Acad. Sci. USA 90: 2905-2909 (1993) wrote.

Although the allelic, degenerate and hybridizing Sequences encompassed by the present invention structural differences due to minor changes in have the nucleotide or / and amino acid sequence the proteins encoded by such sequences are still in the essentially the same useful properties that their Use in basically the same medical applications enable.

According to the present invention, the term "hybri "usual hybridization conditions, preferably Conditions with a salt concentration of 6 × SSC at 62 to 66 ° C, followed by a one hour wash with 0.6 × SSC, 0.1% SDS at 62 to 66 ° C.

Preferred embodiments of the present invention are DNA sequences, as defined above, from vertebrates, preferably mammals such as pigs, cows and rodents such as such as rats or mice, and especially primates such as such as humans, are available or corresponding sequences are reproduced.

A particularly preferred embodiment of the present invention is that in SEQ ID NO. 1 and shown as MP-121. The transcripts of MP-121 were obtained from liver tissue and code for a protein which shows considerable amino acid homology to the mature part of the Inhi bin / activin-like proteins (see Fig. 1). The protein sequences of human α-inhibin, inhibin βA and inhibin βB are described by Mason et al. (Biochem. Biophys. Res. Comm. 135, 957-964 (1986)). Some typical sequence homologies specific to known inhibin sequences were also found in the propeptide part of MP-121, while other parts of the propeptide of MP-121 show significant differences from inhibin propeptides.

Another object of the present invention is a Vector which contains at least one copy of a DNA Contains molecule. In such a vector, this is invented DNA sequence according to the invention preferably surgically with a Expression control sequence linked. Such vectors are suitable to produce TGF-β-like proteins in stable or transiently transformed cells. Various animal, Plant, fungal and bacterial systems can be used for transformation and the subsequent cultivation can be used. Preferential wise contain the vectors of the invention for the replica tion in the host cell and are autonomous replicable. Furthermore, the use of vectors preferred, which contain selectable marker genes, whereby the Transformation of a host cell is detectable.

Another object of the invention is a host cell that with an inventive DNA or an inventive Vector is transformed. Examples of suitable host cells include various eukaryotic and prokaryotic cells such as E.coli, insect cells, plant cells, mammalian cells and mushrooms, such as yeast.

Another object of the invention is a protein of TGF β family encoded by a DNA sequence according to claim 1 becomes. The protein according to the invention preferably has the in  SEQ ID NO. 2 amino acid sequence shown or optionally functional portions thereof (as defined above) and shows biological properties, such as tissue inductive ability that may be for therapeutic use are relevant. The above characteristics of the protein can depending on the formation of homodimers or heterodimers other proteins with Cystine Knot Motif and especially TGF- β proteins vary. Such structures can also prove and form suitable for clinical applications also an object of the present application. Before pulled heterodimers include heterodimers from a monomer of protein and monomers according to the invention of the α-, βA- or βB- Inhibin chains. Resulting from heterodimer formation resulting properties can be more towards the eigen be shifted by activin or inhibins. If e.g. B. a heterodimer with inhibin u proteins or with others Inhibin β proteins is formed, it is believed that the MP121 / inhibin (α chain) - or MP121 / activin (βA or βB- Chain) heterodimer the production of follicle-stimulating Could inhibit or activate hormone (FSH). MP121 / Activin Heterodimers could also e.g. B. Influence on the mesoderm Take development. It can still be expected that heterodimeric forms with a member of the BMP group of TGF β proteins cause BMP-like activities to increase be such. B. the ability to form bones, cartilage induction or formation of connective tissue promote.

Another object of the invention is therefore heterodimeric Proteins of a protein of the TGF-β family according to the invention, which is encoded by a DNA sequence according to claim 1, with a monomer of a protein with Cystine Knot Motif, preferred of another member of the TGF-β family. Similar heterodi Other proteins are described in WO 93/09229, EP 0 626 451 A2 and J. Biol. Chem. 265 (1990), 13198-13205.  

The invention further relates to chimeric proteins, the functional derivatives or portions of the protein according to SEQ ID NO. 2, in particular functional parts of the mature protein have and also portions of another protein. The other protein can in turn be a protein Cystine Knot Motif, which is also preferred for TGF-β Family belongs, such as B. in particular MP52 (PCT / EP94 / 02630). However, it can also contain parts of a completely different protein be present, e.g. B. receptor-binding domains of proteins, which gives the original MP121 protein a different specificity to lend.

The biological properties of the proteins according to the invention, preferably MP-121, e.g. B. in assays according to Wrana et al. (Cell 71, 1003-1014 (1992)) Ling et al. (Proc. Natl. Acad. Of Science, 82: 7217-7221 (1985)), Takuwa et al. (Am. J. Physiol., 257, E797-E803 (1989)), Fann and Patterson (Proc. Natl. Acad. of Science, 91, 43-47 (1994)), Broxmeyer et al. (Proc. Natl. Acad. of Science, 85, 9052-9056 (1988)), Green et al. (Cell, 71, 731-739 (1992)) or Partridge et al. (Endocrinology, 108, 213-219 (1981)).

Another object of the present invention is a Process for the production of a protein of the TGF-β family, which is characterized in that one with a DNA according to the invention or a vector according to the invention transformed host cell and cultivated the TGF-β protein the cell or / and from the culture supernatant. Such one The method involves culturing the transformed host cell in a suitable culture medium and cleaning the produced TGF-β-like protein. This way the process of producing a sufficient amount of the desired protein for use in medical treatment or in applications using cell culture technology where growth factors are needed. The hosts cell can be a bacterium such as Bacillus or E. coli Fungus, such as yeast, a plant cell, such as tobacco,  Potato or Arabidopsis or an animal cell, ins especially a vertebrate cell line, such as Mo-, Cos- or CHO- Cell lines or an insect cell line. In the preparation of in bacteria it can happen that the invention Protein in the form of inclusion bodies is produced. These inclusion bodies are then turned on known methods and then renatured the protein in an active form (see e.g. Jaenicke, R. u. Rudolph, R., Protein Structure, ed. Creighton, T.E., IRL Press, Chapter 9). For the production of heterodimeric proteins with other members of the TGF-β family, both are protein monomers expressed either in the same cell or separately, also a common renaturation in the case of forms of inclusion bodies appears suitable. With coexpression in In particular, the same cell are also viral systems, such as. B. the baculovirus system or the vaccina virus system.

The production of heterodimeric proteins is basically the same Known expert and z. B. in WO 93/09229 and EP 0 626 451 A2.

The production of chimeric proteins with other protein share requires a corresponding change to DNA Level that is familiar to and carried out by the expert (EMBO J. 10 (1991), 2105-2110; Cell 69 (1992), 329-341; J. Neurosci. 39: 195-210 (1994).

Yet another object of the present invention is that Providing pharmaceutical compositions containing a pharmaceutically effective amount of a TGF-β- according to the invention like protein as an active ingredient. If necessary includes such a composition is a pharmaceutical acceptable Carrier, auxiliary, diluent or filler. Such pharmaceutical composition can help in wound healing and Tissue restoration alone or in combination with others Active ingredients, e.g. B. other proteins of the TGF-β family or Growth factors such as EGF (epidermal growth factor) or PDGF (platelet derived growth factor) can be used. Further  can such a pharmaceutical composition in the Disease prevention can be used.

Other items are pharmaceutical compositions that heterodimeric proteins or / and chimeric proteins according to the invention Contain proteins.

The pharmaceutical combination according to the invention is preferred used for the treatment and prevention of bone, Cartilage, connective tissue, skin, mucous membrane, endothelial, Epithelial, neuronal, brain, renal or tooth damage, for use with dental implants, for use in wounds recovery or tissue recovery processes, as a morphogen used for induction of liver tissue growth, induction the proliferation of progenitor cells or bone marrow cells, to maintain a state of differentiation and Treatment of fertility disorders or for contraception tung.

Another possible clinical application of the invention TGF-β-like protein is use as a suppressor of the Immune response to avoid organ trans rejection plantations or an application related to angiogenesis. Furthermore, the protein according to the invention can be used for fertility increase or contraception. The Pharmaceutical composition according to the invention can also used prophylactically or in cosmetic surgery will. Furthermore, the application of the composition is not limited to humans, but can also be animals, in particular Include domestic and farm animals.

Incidentally, heterodimeric and chimeric proteins The possible uses and specificity also by the proteins Proportion of the other protein or monomer as desired can be varied.  

In general, diseases can be caused by the proteins according to the invention treated with the expression of MP121 depend on the one hand by increasing the amount or the Activity on existing MP121, on the other hand too by suppressing MP121 activity. So is another The invention relates to the production of antisense nu small acids and ribozymes, which are the translation of MP121 inhibit. This inhibition can either be by masking the mRNA with an antisense nucleic acid or by cleavage with a ribozyme.

The production of antisense nucleic acids is known (Weintraub, H.M., Scientific American 262: 40 (1990)). The Antisense nucleic acids hybridize with the corresponding one mRNA and form a double-stranded molecule, which then can no longer be translated. The usage of Antisense nucleic acids is e.g. B. from Marcus-Sekura, C.J., Anal. Biochem. 172 (1988), pp. 289-295.

Ribozymes are RNA molecules that have the ability specifically other single-stranded RNA molecules similar to DNA To cleave restriction endonucleases. The production of Ribozymes are described in Cech, J. Amer. Med. Assn. 260 (1988), p. 3030 described.

According to the invention, it is also possible to use suitable vectors with the DNA sequence according to the invention in vitro or in vivo in To transfect patient cells or in vitro the vectors Transfect cells and then deliver them to a patient implant. MP121 antisense polynucleotides can also be used in Cells are introduced that have an undesired expression of Show MP121.

The MP121 activity can also be suppressed by binding molecules that, unlike MP121, do not Trigger signal forwarding to the MP121 receptors.  

It is therefore also within the scope of the invention the receptors for MP121 on cells of interest. To find receptors can first different cell lines on their binding behavior radioactively labeled MP121 (¹²⁵J-MP121) with cross-linking. Of cells, the MP121 can bind a cDNA library in an Ex pressure vector (available from InVitrogen). Cells transfected with receptor cDNA can then selected for the binding of radioactively labeled MP121 will. These are methods known to the person skilled in the art, such as, for. B. for the isolation of active- (Mathews, L.S. & Vale, W.W., Cell 65 (1991), 973-982) and TGF-β receptors type II (Lin, H. Y. et al., Cell 68 (1992), 775-785) were used. It is in Analogy to the known activin receptors to suspect that the MP121 receptor is also one of them Family belonging receptor complex acts, so that on find parts of the heteromeric complex more Methods known to those skilled in the art, such as, for. B. PCR with degenerate Oligonucleotides can be used. This method is e.g. B. also with the Activin and TGF-β receptors type I. (Tsuchida et al., Proc. Natl. Acad. Sci. USA 90 (1993), 11242-11246; Attisano et al., 1993, Cell 75: 671-680; Franzen et al. (1993) Cell 75: 681-692).

Finally, another subject of the present Invention an antibody that is specific to the Invention can bind appropriate proteins, or such an antibody fragment (e.g. Fab or Fab ′). Process for producing a such specific antibody or antibody fragment belong to the general specialist knowledge of the average specialist. Such an antibody is preferably a monoclonal Antibody. Such antibodies or antibody fragments could are also suitable for diagnostic methods.

The invention is further intended to be illustrated by the following examples are illustrated.  

example 1 Isolation of MP-121

• 1.1 Total RNA was derived from human liver tissue (40 years old Mann) using the Chirgwin et al. (Biochemistry, 18, 5294-5299 (1979)) isolated. Poly (A +) RNA was extracted from the total RNA by oligo (dT) chromatography according to the regulations of Manufacturer (Stratagene Poly (A) Quick columns) separated.
• 1.2 For the reverse transcription reaction, 1 to 2.5 µg of poly (A +) RNA were heated to 65 ° C. for 5 minutes and quickly cooled on ice. The reaction mixture contained 27 U RNA-Guard (Pharmacia), 2.5 μg oligo (dT) _12-18 (Pharmacia), 5 × buffer (250 mmol / l Tris / HCl pH 8.5, 50 mmol / l MgCl₂, 50 mmol / l DTT, 5 mmol / l of each dNTP, 600 mmol / l KCl) and 20 U AMV reverse transcriptase (Boehringer Mannheim) per µg poly (A +) - RNA. The reaction mixture (25 µl) was incubated at 42 ° C for 2 hours. The cDNA pool was kept at -20 ° C.
• 1.3 The deoxynucleotide primers OD and OID shown in FIG. 2 were produced on an automatic DNA synthesizer (biosearch). The purification was carried out by denaturing polyacrylamide gel electophoresis and isolation of the main band from the gel by isotachophoresis. The oligonucleotides were designed by comparing the nucleic acid sequences of known members of the TGF-β family and selecting regions with high conservation. A comparison of this region is shown in FIG. 2. To facilitate cloning, both oligonucleotides contained Eco RI sites and OD additionally contained an Nco I restriction site at its 5'-terminus.
• 1.4 In the PCR reaction, 20 ng of poly (A +) RNA was obtained cDNA (see 1.2) used as starting material. The Reaction was carried out in a volume of 50 µl and contained 1 × PCR buffer (16.6 mmol / l (NH₄) ₂SO₄, 67 mmol / l Tris / HCl pH 8.8, 2 mmol / l MgCl₂, 6.7 µmol / l EDTA, 10 mol / l β-  Mercaptoethanol, 170 µg / ml bovine serum albumin (Gibco), 200 µmol / l of each dNTP (Pharmacia), 30 pmol of each Oligonu Kleotide (OD and OID) and 1.5 U Taq polymerase (AmpliTaq, Perkin Elmer Cetus). The reaction mixture was covered with paraffin layers and 40 PCR cycles were carried out. The PCR reaction products were purified by phenol / chloroform Extraction cleaned and concentrated by ethanol precipitation trated.
• 1.5 Half of the PCR reaction products were with the Restriction enzymes SphI (Pharmacia) and AlwNI (Biolabs) split according to the manufacturer's instructions. The second half was in a series of reactions with Ava I (BRL), AlwN I (Biolabs) and Tfi I (Biolabs) cut. The Restrictions were in 100 ul with 8 U enzyme over 2 to 12 Hours at 37 ° C (except for Tfi I at 65 ° C).
• 1.6 The restriction cleavage products were by Fractionated agarose gel electrophoresis. After staining with Ethidium bromide was not cleaved amplification products cut out of the gel and by phenol extraction isolated. The DNA obtained was then run through twice Phenol / chloroform extraction cleaned.
• 1.7 After ethanol precipitation, a quarter or a Fifth of the DNA isolated reamplified, being the same Conditions as used for primary amplification except that the number of cycles has been reduced to 13. The Reamplification products were purified using the same Enzymes as cut above and the uncut products were, as explained above for the amplification products Agarose gels isolated. The reamplification step was repeated.
• 1.8 After the last isolation from the gel, the Amplification products by 4 U Eco RI (Pharmacia) among the split the conditions recommended by the manufacturer. A quarter  of the restriction mixture was cleaved with Eco RI Vector pBluescript SK + (Stratagene) ligated. After ligation 24 clones of each enzyme combination were sequenced analyzed further. The approach with AlwN I and Sph I ge was cut, contained no new sequences, only BMP6 and Inhibin βA sequences. 19 identical new sequences, MP-121 were cut with Ava I, AlwN I and Tfi I found approaches. These plasmids were pSK-MP121 (OD / OID) called. One sequence differed mainly from this found sequence on two nucleotides. The ligation and Transformation in E. coli was carried out as in Sambrook et al., Molecu lar cloning: A laboratory manual (1989) described by guided.

The clone became the 3'-end of the cDNA according to the details of Frohmann (published by Perkin-Elmer Corp., Amplifica tions, 5, 11-15 (1990)).

The same liver mRNA used to isolate the first MP-121 Fragment was used, was reversed as described above transcribed using Oligo dT (16mer) linked with the adapter primer (AGAATTCGCATGCCATGGTCGACGAAGC -T₁₆). The Amplification was done with the adapter primer (AGAATTCGCATGCCATGGTCGACG) and an internal primer (GGCTACGCCATGAACTTCTGCATA), according to the MP-121 sequence poses, carried out. The amplification products were with another internal primer (ACATAGCAGGCATGCCTGGTATTG), made according to the MP-121 sequence and the adapter primer reamplified. The reamplification products were after Restriction with Sph I in the similarly cut vector pT7 / T3 U19 (Pharmacia) cloned and sequenced. The clones were through their sequence overlap with the already known part the MP121 sequence. A clone called p121Lt 3 ′ MP13, was used to make an Nco I (blunted with T4 Polymerase) / Sph I fragment to isolate. This fragment was into one of the pSK-MP121 (OD / OID) vectors mentioned above cloned whose OD primer sequence to the T7 primer of the pSK Multiple cloning site was oriented. To do this, the vector was created with  SphI and SmaI restricted. The construct became pMP121DFus6 called. It contains the MP-121 sequence from position 922 to 1360 as shown in SEQ ID NO.1.

• 1.9 A Dde I fragment of pMP-121DFus6, which from position 931 to 1304 in SEQ ID NO. 1 is enough to screen one human liver cDNA library (Clontech, # HL3006b, bot 36223) used, as detailed in Ausubel et al. (Current Protocols in Molecular Biology, published by Greene Publishing Associates and Wiley-Interscience (1989)) is. 24 mixed plaques were picked from 8.1 × 10⁵ phages and isolated. This resulted in 10 clones which were subjected to PCR using Ver application of the primers LO2 (ACATAGCAGGCATGCCTGGTATTG) and LOI1 (CTGCAGCTGTGTTGGCCTTGAGA) from the Dde I fragment, a positive Signal, selected and isolated. The cDNA was over an EcoRI restriction was isolated from the phages and into the pBluescript SK vector loo also cleaved with Eco RI kidney.

Sequencing one of the resulting plasmids, SK121L9.1, showed that the start codon at position 128 of SEQ ID NO. 1 starts because there are three stop codons in-frame before this Start codon at positions 62, 77 and 92. The start of the Tire MP121 is at position 836 of SEQ ID NO. 1, you put the sequence analogy to other TGF-β proteins is based on what amino acid 237 in SEQ NO. 2 corresponds. The stop codon starts at position 1184 of SEQ ID NO. 1.

The plasmid SK121L9.1 was deposited under the accession number 9177 deposited with the DSM on April 26, 1994.

Example 2 Expression of MP121

Expression of MP121 is both in eukaryotic and also possible in prokaryotic systems.  

Only the mature part was used for expression in prokaryotes used by MP121. After purification, this can be done in E.coli Monomer then expressed mature MP121 protein into a dimer be folded back. To clean up the MP121 too can simplify to the N-terminus of the mature protein an additional 6 histidines are attached by binding to Nickel chelate columns facilitate protein purification tern.

The mature part of MP121 (amino acid 237 to 352 in SEQ ID NO. 2) with 13 additional amino acids including 6 histidines at the N-terminus (MHHHHHHKLEFAM) in the prokaryotic vector pBP4. This vector is a pBR322 derivative with tetracycline resistance Lich the T7 promoter from the pBluescript II SK plasmid (Stra days) contains. Furthermore, the vector after contains T7 promoter a ribosomal binding site and a start codon followed by 6 codons for histidine. Behind several singular Restriction interfaces such as Eco RI, Xho I, Sma I and Apa I for the insertion of inserts and stop codons in all three A terminator (T⌀) follows the reading frame. To get the cDNA for the mature part of MP121 was PCR with the two Oligonucleotides GAATTCGCCATGGGCATCGACTGCCAAGGAGG and CCGCTCGAGAAGCTTCAACTGCACCCACAGGC on plasmid SK121L9.1 (DSM deposit number: 9177). Both oligo nucleotides contain restrictions added at the ends interfaces (Eco RI and Nco I or Xho I and Hind III).

The resulting 377 bp fragment was blunt-ended in the with Eco RV restricted vector pBluescript II SK (Stra days) cloned in between. A clone with the orientation of the 5 ′, end of MP121 to T7 promoter was with Eco RI restricted and the resulting insert (0.38 kb) in the also cloned with Eco RI restricted pBP4 vector. The correct orientation of the insert in the resulting plasmid pBP4MP121His was determined by restriction analysis and sequencing determined. The plasmid pBP4MP121His was created on 30.1.1995 deposited with the DSM (deposit number: 9704).  

MP121 protein can be expressed by simultaneously providing T7 RNA polymerase. The T7 RNA polymerase can be provided by various methods, such as. B. a second plasmid with a gene for T7 RNA polymerase or by infection with phages that code for the T7 RNA polymerase or by special bacteria that have integrated the gene for T7 RNA polymerase. Using the bacterial strain BL21 (DE3) pLysS (Nova gen, # 69451-1) and inducing T7 RNA polymerase expression according to the manufacturer's instructions with IPTG, the mature MPI2I protein with His tag (MP121His) is formed in inclusion bodies. The protein in SDS-polyacrylamide gels (15%) has an apparent molecular weight of almost 16 kD (theoretical molecular weight: 14.2 kD), as is shown representatively in the Western blot of FIG. 3. The bacteria transformed with pBP4 as controls each show no staining of specific bands. Because of His day, this protein can be chelated by nickel columns such as. B. described in Hochuli et al. (BIO / Technology Vol. 6, 1321-1325 (1988)).

Additional cleaning is possible via a reversed HPLC phase. A reversed phase column (Nucleosil 300-7C4 from Macherey-Nagel, Art. 715023) with a flow rate of 2 ml / min and an acetonitrile gradient in 0.1% TFA of 0 to 90% used in 100 min. Under these conditions elutes MP121His from approx. 40% acetonitrile.

The proof that it is MP121 protein was carried out by Western blot analysis with MP121-specific antibodies. Polyclonal antibodies to MP121 were raised in both chickens and rabbits. To obtain the antigen for the immunization, part of the mature portion of MP121 (amino acids 260 to 352 in SEQ ID NO. 2) was fused with the first 98 amino acids of the polymerase of the MS2 bacteriophage and expressed in E. coli. After isolation of the inclusion bodies, the fusion protein (MS2-MP121) was separated on polyacrylamide gels and after copper staining by electroelution (Tessmer, U. & Dernick, R., IBL (1990) 8-13) for immunization. Antibodies from both chickens and rabbits make it possible to specifically detect expression of MP121. For the schematic Western blot in FIG. 3, chicken antibodies were used, which via PEG precipitation (Thalley BS and Car roll, SB, BIO / Technology Vol. 8, 934-938 (1990)) and via membrane-bound antigen ( Fusion protein (MS2-MP121)) (18.17 in Sambrook et al. Molecular Cloning, second edition, Cold Spring Harbor Laboratory Press 1989). Anti-Chicken IgG with coupled alkaline phosphatase (Sigma A9171) was used as the second antibody. Detection was carried out using the Tropix Western-Light Protein Detection Kit (Serva # WL10RC) according to the manufacturer's instructions.

In order to obtain biologically active material, this can be done in E.coli expressed and purified monomeric MP121 into one dimeric MP121 can be folded back. This can be done according to methods such as B. described by Jaenicke, R. & Rudolph, R. (Protein structure, ed. Creighton, T.E., IRL Press, Chapter 9) suc gene.

For expression in eukaryotic cells, the Vaccinia virus expression system used as it explains Lich and reworkable in the Current Proto for the specialist cols in Molecular Biology (Ausubel et al., Greene Publishing Associates and Wiley-Interscience, Wiley & Sons), below abbreviated CP, under Chapter 16 Unit 16.15-16.18 be is written. The system relies on foreign DNA under Use of certain vectors by homologous recombination can be integrated into the vaccinia virus genome. To for this purpose the vector used contains the TK (thymidine kinase) gene from the vaccinia genome. To make a selection The vector further contains enabling recombinant viruses the E.coli xanthine guanine phosphoribosyl transferase gene (gpt) (Falkner, F.G. & Moss, B., J. of Virol. 62 (1988), 1849-1854). The cDNA with the entire coding area for MP121 cloned.  

Around the 5 'and 3' non-translated areas from the original Original plasmid SK121L9.1 (DSM, deposit number: 9177) and shorten singular restrictions at the ends To insert interfaces were PCR reactions and intermediate cloning necessary. All PCR reactions were carried out with the Plasmid SK121L9.1 (DSM accession number: 9177) leads. To shorten the 5 'untranslated end was the primer CCCGGATCCGCTAGCACCATGACCTCCTCATTGCTTCTG with one inserted Bam HI and NheI restriction site in a PCR with an internal primer (CCCTGTTGTCCTCTAGAAGTG) used. The fragment obtained was in Bluescript SK (Stratagene) intercloned, sequenced and matched in line with that in SEQ ID NO. 1 shown sequence checked. For a shortened 3 'untranslated end, the Sph I / Eco RI fragment (0.22 kb) from the plasmid pBP4MP121His used.

The two end fragments of MP121 were internal re restriction cuts (Xba I and Sph I) with the missing mitt DNA sequence from the plasmid SK121L9.1 (DSM Hinterle number: 9177) according to standard methods (Sambrook et al. Molecular Cloning, second edition, Cold Spring Harbor Labora tory Press 1989). The truncated cDNA thus obtained with the complete reading frame for MP121 (nucleotide 128 bis Nucleotide 1184 in SEQ ID No. 1) could take advantage of the Restriction cuts Bam HI and Eco RI in the same ge cloned vector pBPI can be cloned. The resulting Plasmid pBPIMP121 was released on January 12, 1995 at the DSM (Hinterle number: 9665).

The plasmid pBPIMP121 was used for the production of recom Binary vaccinia viruses are used. For this purpose, 80% of the fluent 143B cells (HuTk, ATCC CRL 8303) in 35 mm culture bowl with vaccinia wild-type virus in 1 ml PBS for 30 minutes infected at room temperature with occasional shaking (1 virus on 10 cells). After aspirating the supernatant and Add 2 ml culture medium (MEM, Gibco BRL # 041-01095 with  1: 500 diluted penicillin and streptomycin Gibco BRL # 043-05140) was incubated for 2 hours at 37 ° C. The Medium was then removed and the transformation of these cells with 100 ng pBPIMP121, 2 µg carrier DNA (calf thymus, treated with ultrasound, Boehringer Mannheim # 104175) and 10 µl lipofectin (Gibco BRD # 18292-011) in 1 ml MEM for reached approx. 15 h at 37 ° C. After adding 1 ml MEM with 20% FCS (Sigma # F-7524) was kept at 37 ° C for an additional 24 hours incubated and the lysed cells then frozen.

The gpt selection for the xanthine guanine phosphoribosyl Transferase and isolation and amplification of individual recom binary viruses occurred essentially as in Unit 16.17 of the CP described, with the difference that RK13 cells (ATCC CCL 37) were used.

The integration of the MP121 cDNA into the virus genome was accomplished by Dot blot analysis (CP Unit 16.18) confirmed. A recombinant Virus from transfection with pBPMP121 as well as the wild type Virus were used for expression analysis in cell lines 143B (HuTk-, ATCC CRA 8303, human) and NIH-3T3 (DSM ACC 59, Swiss mouse embryo). The cells were made according to the information the distributor cultivated. The confluent cells were with three times the number of viruses for 30 minutes at 37 ° C infi adorned and then the appropriate culture medium with 10% FCS and penicillin / streptomycin (1: 500, Gibco BRD # 043-05140) added. After 6 hours at 37 ° C, the medium was removed the cells twice with z. B. HBSS (Gibco BRD # 14180-046) washed and production medium (MEM for HuTk or DMEM with 4.5 g / l glucose and NEAA (Gibco BRL # 11140-035) for NIH-3T3 each mixed with aprotinin (Fluka # 10820, 50 U / ml) and Penicillin / streptomycin) added without FCS. After 20 to 22 The cell supernatant was collected for hours of production. The Expression was analyzed by Western blots Standard methods (CP Unit 10.8). For that, the proteins from 1 to 3 ml of cell culture supernatant by adding the equiva volume of acetone and incubation of at least one  Hour precipitated on ice and centrifuged. According to Re suspension of the pellet in order buffer (7 M urea, 1% SDS, 7mM sodium dihydrogenphosphate, 0.01% bromophenol blue and optionally 1% β-mercaptoethanol) was carried out separation in 15% polyacrylamide gels. As marker proteins became a pre-stained protein molecular weight s standard (Gibco BRL # 6041-020). The transfer to PVDF Membrane (Immobilon # IPVH00010) and blocking the membrane were made using standard methods.

A representative schematic drawing of the Western blot results in FIG. 3 shows that specific bands occur in the recombinant viruses MP121. Expression of MP121 in NIH-3T3 cells results in a secreted protein with a molecular weight of approximately 18 kDa appearing in the gel under non-reducing conditions (expected theoretical molecular weight: 25 kD). Under reducing conditions, the protein runs in the gel at approximately 15 kDa (expected theoretical molecular weight: 12.5 kD). These results show that, as expected, MP121 is expressed as a dimeric mature protein. The relatively little slower running behavior of the dimeric MP121 protein compared to the monomeric MP121 protein is probably due to a globular structure. The processing of the precursor protein to the mature protein could also be demonstrated in HuTK cells. In cells infected with wild-type viruses (without integrated foreign DNA) (HuTK- or NIH-3T3), no bands appeared in the Western blot.

The vaccinia expression system is suitable for cotransfection with recombinant vaccinia viruses that are used for different Code members of the TGF-β family, especially for the formation of heterodimers. About affinity columns with specific antibodies against the individual TGF-β families it is then possible for members to make heterodimers of homodimers to separate. Of particular interest are the α- as well as the βA and βB chains of the inhibins.  

SEQ ID NO. 1

SEQ ID NO. 2nd

Claims (20)

1. DNA molecule which codes for a protein of the TGF-β family and

• a) the portion coding for the mature protein and optionally further functional portions of the in SEQ ID NO. 1 nucleotide sequence shown,
• b) a nucleotide sequence corresponding to the sequence from (a) in the context of the degeneration of the genetic code,
• c) a nucleotide sequence corresponding to an allelic derivative of one of the sequences from (a) and (b), or
• d) a nucleotide sequence hybridizing with one of the sequences from (a), (b) or (c) comprises, provided that a DNA molecule according to (d) completely at least the portion coding for a mature protein of the TGF-β family contains.

2. DNA molecule according to claim 1, characterized, that in addition to one of the parts (a) to (d) of claim 1 has a nucleic acid sequence which is suitable for at least one Part of another protein is encoded and arranged so that a fusion protein results after expression. 3rd vector, characterized, that he has at least one copy of a DNA molecule Claim 1 or 2 contains. 4. host cell, characterized, that with a DNA according to claim 1 or 2 or one Vector is transformed according to claim 3. 5. host cell according to claim 4, characterized,  that they are a bacterium, a fungus, a vegetable or is an animal cell. 6. Protein of the TGF-β family derived from a DNA sequence Claim 1 or 2 is encoded. 7. Protein according to claim 6, characterized, that it is the one in SEQ ID NO. 2 amino acid sequence shown or optionally has functional portions thereof. 8. chimeric protein, characterized, that it is a protein according to claim 6 or 7 and at least contains part of another protein. 9. heterodimeric protein, characterized, that it consists of a monomer of a protein according to claim 6, 7 or 8 and a monomer of another protein from the Superfamily with "Cystine Knot Motif" exists. 10. A method for producing a protein according to one of the Claims 6 to 8, characterized, that one cultivates a host cell according to claim 4 or 5 and the protein from the cell and / or the culture supernatant wins. 11. Process for the production of a heterodimeric protein according to claim 9, characterized, that one coexpression of both monomers in one Host cell. 12. Process for the production of a heterodimeric protein according to claim 9,  characterized, that there is a common renaturation of inclusion bodies of both monomers. 13. Pharmaceutical composition, characterized, that they contain at least one protein according to one of claims 6 to 9 as an active ingredient, optionally together with pharmazeu table usual carrier, auxiliary, dilution or filling contains substances. 14. Pharmaceutical composition according to claim 13 for Treatment or prevention of bone, cartilage, Connective tissue, skin, mucous membrane, endothelial, epithelial, Neuronal, brain, renal or tooth damage, for Use on dental implants, for use in wounds recovery or tissue recovery processes, as Morphogen for use in induction of liver tissue wax tum, induction of proliferation of progenitor cells or Bone marrow cells, to maintain a difference condition and for the treatment of fertility disorders or for contraception. 15. anti-sense RNA, characterized, that they are complementary to part of a DNA molecule according to claim 1. 16. ribozyme, characterized, that it is an RNA molecule that is transcribed after a DNA molecule according to claim 1, specifically cleaves. 17. Use of an antisense RNA according to claim 15 or a ribozyme according to claim 16 for blocking the Expression of a protein according to any one of claims 6 and 7.   18. Use of a DNA sequence according to claim 1 or 2 or of a vector according to claim 3 for in vitro or in vivo Transfection of patient cells. 19. Antibodies or antibody fragments, characterized, that they are attached to a protein according to any one of claims 6 to 9 tie. 20. receptor, characterized, that a protein according to one of claims 6 and 7 speci binds fish to him.