WO1990000179A2 - Novel proteins, dna coding for said proteins, and their use - Google Patents

Abstract

Novel amino-acid sequences containing at least one of the following amino acid chains: MREYKLVVL (I), ALTVQFVQGIFVEKYDPTIEDSYRKQVEVDCQQCMLEIL (II), QFTAMRDLYMKNGQGFALVYSITAQSTFNDLQDLREQILRVKDTEDVPM (III), EDERVVGKEQGQNLARQWCNCAFL (IV), SKINVNEIEYDLVRQINRKTPVEKKKPKKKSCLLL (V), ALTVQFVQGIFVEKYDPTIEDSYRKQVEVDAQQCMLEIL (VII), QFTAMRDLYMKNGQGFALVYSITAQSTFNDLQDLREQILRVKDTDDVPMI (VIII), EDERVVGKEQGQNLARQWNNCAFL (IX), SKINVNEIFYDLVRQINRKTPVPGKARKKSSCQLL (X), MREYKVVVL (XI), ALTVQFVTGTFIEKYDPTIEDFYRKEIEVDSSPSVLEIL (XII), QFASMRDLYIKNGQGFILVYSLVNQQSFQDIKPMRDQIIRVKRYEKVPVI (XIII), ESEREVSSSEGRALAEEWGCPFM (XIV), SKTMVDELFAEIVRQMNYAAQPDKDDPCCSACNIQ (XV). Said amino-acid sequences can be used for in vitro diagnosis of pathologies linked with oncogenic factors.

Description

NOVEL PROTEINS, DNA ENCODING THEM AND THEIR USE

The subject of the invention is new amino acid sequences, the nucleic acids coding for these amino acid sequences and their applications, in particular for diagnosis, in. in vitro, pathologies linked to the action of oncogenic factors.

Protooncogenes such as H-ras, K-ras and N-ras are known (De Feo et al., (1981) Proc. Natl. Acad. Sci., USA, 78, 3328-3332; Ellis et al., ( 1981), Nature, 292, 506-511; Shimizu et al. (1983) Proc. Natl. Acad. Sci., USA, 80, 383-387) and new genes have been identified in a wide variety of organisms on the basis of their homology with the mammalian ras gene. In mammals, the proteins encoded by these genes close to the ras genes (rai, R-ras, rho and rab) have 50 to 30% homology with the ras proteins (Chardin et al., (1986) EMBO J., 5, 2203-2208; Madaule et al., (1985) Cell, 41, 31-40; Touchot et al., (1987) Proc. Natl. Acad. Sci., USA, 84, 8210-8214).

Ras proteins and proteins close to ras proteins have molecular weights of about 21,000 to 24,000 d. Ras proteins are active when associated with GTP (Guanosine 5'-triphosphate) and are inactive when associated with GDP (Guanosine 5'-diphosphate) and the hydrolysis of GTP takes place by the action of their low activity. intrinsic GTPase (Papageorge et al., (1982) J. Virol., 44, 509-519; Mcgrath et al., (1984) Nature, 310, 644-649).

The transforming ras proteins detected in human tumors very frequently exhibit a substitution of the amino acids located in the GTP binding domain, in position 12, 13 or 61 (Barbacid (1987) Annual Review of Biochemistry, 56, 779-827).

This domain plays an essential role in the regulation of the biological properties of ras proteins.

The GTP binding site consists of four non-contiguous regions which belong to all ras proteins.

Among these regions, six amino acids: DTGAQE at position 57 to 62 of the K-ras protein, seem to be a characteristic of the ras protein and of all the neighboring ras proteins (Chardin et al., (1986) EMBO J., 5 , 2203-2208; Touchot et al., (1987) Proc. Natl. Acad. Sci., USA, 84, 8210-8214). These six residues are strictly conserved in ras, rai and rab proteins.

In the H-ras proteins, it has been found (Der et al., (1986) Cell, 44, 167-176) that practically each mutation of the residue at position 61 of the ras protein is correlated with the acquisition of the transforming potential.

However, the Applicant has found new amino acid sequences, among which position 61 is a threonine, and which however have non-transforming properties.

One aspect of the invention is to propose new amino acid sequences, having the ability to fix GTP and GDP and having GTPase activity.

One of the other aspects of the invention is to propose new nucleic acids coding for amino acid sequences exhibiting interesting biological properties.

One of the other aspects of the invention is to propose screening means, in _. in vitro, certain pathologies linked either to protein contents located outside the range of values that they generally have in a healthy individual, or to mutations in these proteins.

The subject of the invention is new amino acid sequences characterized in that they contain at least one of the following amino acid sequences: MREYKLWL (I)

ALTVQFVQGIFVEKYDPTIEDSYRKQVEVDCQQCMLEIL (II)

QFTAMRDLYMKNGQGFALVYSITAQSTFNDLQDLREQILRVKDTEDVPM (III)

EDERVVGKEQGQ LARQ CNCAFL (IV)

SKINVNEIFYDLVRQINRKTPVEKKKPKKKSCLLL (V)

ALTVQFVQGIFVEKYDPTIEDSYRKQVEVDAQQCMLEIL {VII)

QFTAMRDLYMKNGQGFALVYSITAQSTFNDLQDLREQILRVKDTDDVPMI (VIII),

EDERVVGKEQGQNLARQWNNCAFL (I)

SKINVNEIFYDLVRQINRKTPVPGKARKKSSCQLL (X)

MREYKVWL (XI) ALTVQFVTGTFIEKYDPTIEDFYRKEIEVDSSPSVLEIL (XII)

QFASMRDLYIKNGQGFILVYSLVNQQSFQDIKPMRDQIIRVKRYEKVPVI (XIII)

ESEREVSSSEGRALAEEWGCPFM (XIV)

⁵ .

SKTMVDELFAEIVRQMNYAAQPDKDDPCCSACNIQ (XV)

In what precedes and what follows, the amino acids are represented by a single letter, in accordance with the nomenclature conventionally used in this field.

The amino acid sequences are written in such a way that the leftmost end corresponds to the N-terminal end of the first amino acid delimiting the above sequences and i _ the rightmost end corresponds to the end C-terminal of the last amino acid delimiting the above-mentioned sequences.

According to an advantageous embodiment of the invention, the amino acid sequences of the invention contain at least one of the sequences (I), (II), (III), (IV) or (V) defined above.

According to an advantageous embodiment of the invention, the amino acid sequences of

--- The invention contains at least one of the sequences (VII), (VIII), (IX) or (X) defined above.

According to an advantageous embodiment of the invention, the amino acid sequences of

The invention contains at least one of the sequences (XI), (XII), (XIII), (XIV) or (XV) defined above.

35 According to an advantageous embodiment of the invention, the amino acid sequences of the invention comprise a threonine in position 61.

According to another advantageous embodiment of the invention, the amino acid sequences of the invention are such that the fourth amino acid from the last C-terminal amino acid is a cysteine.

According to another embodiment according to the invention, the amino acid sequences contain the 5 sequences (I), (II), (III), (IV) and (V) defined above.

When the amino acid sequences according to the invention comprise the 5 sequences indicated above, these are advantageously located, from left to right, in the order (I) - (II) - (III) - (IV ) - (V), these sequences also being advantageously non-contiguous.

According to another embodiment according to the invention, the amino acid sequences contain the 5 sequences (VII), (VIII), (IX) and (X) defined above.

When the amino acid sequences according to the invention comprise the 5 sequences indicated above, these are advantageously located, from left to right, in the order (VII) - (VIII) - (IX) - (X ), these sequences being also advantageously non-contiguous.

According to another embodiment according to the invention, the amino acid sequences contain the 5 sequences (XI), (XII), (XIII), (XIV) and (XV) defined above.

When the amino acid sequences according to the invention comprise the 5 sequences indicated above, these are advantageously located, from left to right, in the order (XI) - (XII) - (XIII) - (XIV) - (X), these sequences being also advantageously non-contiguous.

Particularly advantageous amino acid sequences according to the invention contain the chain of amino acids XVI, shown in FIG. 1.

Particularly advantageous amino acid sequences according to the invention consist of the chain of amino acids XVI, shown in FIG. 1.

Particularly advantageous amino acid sequences according to the invention contain the chain of amino acids XVII, shown in FIG. 2.

Particularly advantageous amino acid sequences according to the invention consist of the chain of amino acids XVII, shown in FIG. 2.

Particularly advantageous amino acid sequences according to the invention contain the chain of amino acids XVIII, shown in FIG. 3.

Particularly advantageous amino acid sequences according to the invention consist of the chain of amino acids XVIII, shown in FIG. 3.

The amino acid sequences XVI, XVII and XVIII will also be designated respectively by RAP1A, RAP1B and RAP2 in the remainder of the text.

These amino acid sequences have a threonine at position 61 and a cysteine 4 amino acids from the last C-terminal amino acid. In this respect, for the amino acid sequences represented respectively in FIGS. 1, 2 and 3, the position of a determined amino acid is identified with respect to the first amino acid of the sequence whereas for the nucleotide sequences (also appearing in FIGS. 1, 2 and 3) the position of a determined nucleotide is identified with respect to the first nucleotide.

These amino acid sequences have interesting biochemical and biological properties: they have the capacity to fix GTP and GDP and exhibit GTPase activity.

They are moreover non-transforming, that is to say in particular do not modify the morphological and kinetic properties of the cell and do not alter the property of inhibition of contact of the cells.

This being so, their absence, their overexpression (that is to say their expression in quantities greater than those generally contained in a healthy individual), as well as some of their mutations may correspond to a pathological state.

These amino acid sequences are also likely to bind to the intracellular membrane.

The preceding amino acid sequences can be modified as long as they retain the biochemical and biological properties of the amino acid sequences (XVI), (XVII) and (XVIII) defined above.

For example, and without limitation, amino acid sequences falling within the scope of the invention can be distinguished from the amino acid sequences defined above:

- by adding and / or removing one or more amino acids and / or

- modification of one or more amino acids, provided that the biochemical and biological properties as indicated above are retained.

Also included within the scope of the invention are the amino acid sequences (XVI), (XVII) and (XVIII) having mutations in position 12 (that is to say replacement of glutamine in 12 by any what other amino acid).

Also included within the scope of the invention are the amino acid sequences (XVI), (XVII) and (XVIII) having mutations at position 61 (that is to say replacement of threonine at 61 with any which other amino acid and in particular by glutamine and valine).

The invention also relates to the amino acid sequences containing at least one of the amino acid sequences encoded by the following nucleotide sequences:

ATG CGT GAG TAC AAG CTA GTG GTC CT (1)

GCT CTG ACA GTT CAG TTT GTT CAG GGA ATT TTT GTT GAA

AAA TAT GAC CCA ACG ATA GAA GAT TCC TAC AGA AAG CAA GTT GAA GTC GAT TGC CAA CAG TGT ATG CTC GAA ATC CTG (2) CAA TTT ACA GCA ATG AGG GAT TTG TAT ATG AAG AAC GGC

CAA GGT TTT GCA CTA GTA TAT TCT ATT ACA GCT CAG TCC

ACG TTT AAC GAC TTA CAG GAC CTG AGG GAA CAG ATT TTA

CGG GTT AAG GAC ACG GAA GAT GTT CCA ATG ATT (3)

GAA GAT GAG CGA GTA GTT GGC AAA GAG CAG GGC CAG AAT TTA GCA AGA CAG TGG TGT AAC TGT GCC TTT TTA (4)

TCA AAG ATC AAT GTT AAT GAG ATA TTT TAT GAC CTG GTC

AGA CAG ATA AAT AGG AAA ACA CCA GTG GAA AAG AAG AAG

CCT AAA AAG AAA TCA TGT CTG CTG CTC (5)

ATG CGT GAG TAT AAG CTA GTC GTT CTT (6)

GCT TTG ACT GTA CAA TTT GTT CAA GGA ATT TTT GTA GAA

AAA TAC GAT CCT ACG ATA GAA GAT TCT TAT AGA AAG CAA

GTT GAA GTA GAT GCA CAA CAG TGT ATG CTT GAA ATC TTG (7)

CAA TTT ACA GCA ATG AGG GAT TTA TAC ATG AAA AAT GGA CAA GGA TTT GCA TTA GTT TAT TCC ATC ACA GCA CAG TCC ACA TTT AAC GAT TTA CAA GAC CTG AGA GAA CAG ATT CTT CGA GTT AAA GAC ACT GAT GAT • GTT CCA AT ATT (8)

GAA GAT GAA AGA GTT GTA GGG AAG GAA CAA GGT CAA AAT CTA GCA AGA CAA TGG AAC AAC TGT GCA TTC TTA (9)

TCA AAA ATA AAT GTT AAT GAG ATC TTT TAT GAC CTA GTG

CGG CAA ATT AAC AGA AAA ACT CCA GTG CCT GGG AAG GCT

CGC AAA AAG TCA TCA TGT CAG CTG CTT (10)

ATG CGC GAG TAC AAA GTG GTG GTG CTG (11) GCC CTG ACC GTG CAG TTC GTG ACC GGC ACC TTC ATC GAG

AAA TAC GAC CCC ACC ATC GAG GAC TTC TAC CGC AAG GAG

ATC GAG GTG GAT TCG TCG CCG TCG GTG CTG GAG ATC CTG (12)

CAG TTC GCG TCC ATG CGG GAC CTG TAC ATC AAG AAC GGC

CAG GGC TTC ATC CTC GTC TAC AGC CTC GTC AAC CAG CAG

AGC TTC CAG GAC ATC AAG CCC ATG CGG GAC CAG ATC ATC

CGC GTG AAG CGG TAT GAG AAA GTG CCA GTC ATC (13)

GAA AGT GAG AGA GAA GTA TCG TCC AGC GAA GGC AGA GCC CTT GCT GAA GAG TGG GGC TGC CCC TTT ATG (14)

AGT AAA ACA ATG GTG GAC GAA CTC TTT GCA GAA ATT GTG

AGG CAG ATG AAC TAT GCT GCT CAG CCT GAC AAA GAT GAC

CCA TGC TGT TCT GCA TGT AAC ATA CAA (15)

Also within the scope of the invention are nucleic acids containing at least one of the sequences of nucleotides coding for the amino acid sequences defined above.

According to an advantageous embodiment of the invention, the nucleic acids belong to the human genome.

According to an advantageous embodiment, the nucleic acids of the invention code for the sequences of amino acids I to XVIII defined above. According to yet another advantageous embodiment, the nucleic acid sequences of the invention code for the amino acid sequences containing the sequences XVI, XVII and XVIII defined above. According to another advantageous embodiment of the invention, the nucleic acid sequences of the invention code for the sequences of amino acids XVI, XVII and XVIII defined above.

Advantageous nucleic acids of the invention are those containing at least one of the following nucleotide sequences:

ATG CGT GAG TAC AAG CTA GTG GTC CTT (1)

GCT CTG ACA GTT CAG TTT GTT CAG GGA ATT TTT GTT GAA AAA TAT GAC CCA ACG ATA GAA GAT TCC TAC AGA AAG CAA

GTT GAA GTC GAT TGC CAA CAG TGT ATG CTC GAA ATC CTG (2)

CAA TTT ACA GCA ATG AGG GAT TTG TAT ATG AAG AAC GGC

CAA GGT TTT GCA CTA GTA TAT TCT ATT ACA GCT CAG TCC

ACG TTT AAC GAC TTA CAG GAC CTG AGG GAA CAG ATT TTA

CGG GTT AAG GAC ACG GAA GAT GTT CCA ATG ATT (3)

GAA GAT GAG CGA GTA GTT GGC AAA GAG CAG GGC CAG AAT TTA GCA AGA CAG TGG TGT AAC TGT GCC TTT TTA (4)

TCA AAG ATC AAT GTT AAT GAG ATA TTT TAT GAC CTG GTC

AGA CAG ATA AAT AGG AAA ACA CCA GTG GAA AAG AAG AAG

CCT AAA AAG AAA TCA TGT CTG CTG CTC (5)

ATG CGT GAG TAT AAG CTA GTC GTT CTT (6)

GCT TTG ACT GTA CAA TTT GTT CAA GGA ATT TTT GTA GAA

AAA TAC GAT CCT ACG ATA GAA GAT TCT TAT AGA AAG CAA

GTT GAA GTA GAT GCA CAA CAG TGT ATG CTT GAA ATC TTG (7) CAA TTT ACA GCA ATG AGG GAT TTA TAC ATG AAA AAT GGA

CAA GGA TTT GCA TTA GTT TAT TCC ATC ACA GCA CAG TCC

ACA TTT AAC GAT TTA CAA GAC CTG AGA GAA CAG ATT CTT CGA GTT AAA GAC ACT GAT GAT GTT CCA ATG ATT

(8)

GAA GAT GAA AGA GTT GTA GGG AAG GAA CAA GGT CAA AAT CTA GCA AGA CAA TGG AAC AAC TGT GCA TTC TTA (9)

TCA AAA ATA AAT GTT AAT GAG ATC TTT TAT GAC CTA GTG

CGG CAA ATT AAC AGA AAA ACT CCA GTG CCT GGG AAG GCT

CGC AAA AAG TCA TCA TGT CAG CTG CTT (10)

ATG CGC GAG TAC AAA GTG GTG GTG CTG (11)

GCC CTG ACC GTG CAG TTC GTG ACC GGC ACC TTC ATC GAG

AAA TAC GAC CCC ACC ATC GAG GAC TTC TAC CGC AAG GAG

ATC GAG GTG GAT TCG TCG CCG TCG GTG CTG GAG ATC CTG (12)

CAG TTC GCG TCC ATG CGG GAC CTG TAC ATC AAG AAC GGC

CAG GGC TTC ATC CTC GTC TAC AGC CTC GTC AAC CAG CAG

AGC TTC CAG GAC ATC AAG CCC ATG CGG GAC CAG ATC ATC

CGC GTG AAG CGG TAT GAG AAA GTG CCA GTC ATC (13)

GAA AGT GAG AGA GAA GTA TCG TCC AGC GAA GGC AGA GCC CTT GCT GAA GAG TGG GGC TGC CCC TTT ATG (14)

AGT AAA ACA ATG GTG GAC GAA CTC TTT GCA GAA ATT GTG AGG CAG ATG AAC TAT GCT GCT CAG CCT GAC AAA GAT GAC CCA TGC TGT TCT GCA TGT AAC ATA CAA (15)

According to another advantageous embodiment, the nucleic acids of the invention contain the five sequences of nucleotides (1), (2), (3), (4) and (5), defined above.

According to another advantageous embodiment, the nucleic acids of the invention contain the five sequences of nucleotides (6), (7), (8), (9) and (10), defined above.

According to another advantageous embodiment, the nucleic acids of the invention contain the five sequences of nucleotides (11), (12), (13), (14) and (15), defined above.

According to another advantageous embodiment, the nucleic acids of the invention contain the sequence of nucleotides (16), delimited by the end nucleotides corresponding to the nucleotides located at positions 43 and 594 in FIG. 1.

According to another advantageous embodiment, the nucleic acids of the invention consist of the sequence of nucleotides (16), delimited by the end nucleotides corresponding to the nucleotides located at positions 43 and 594 in FIG. 1.

According to another advantageous embodiment, the nucleic acids of the invention contain the sequence of nucleotides (19) delimited by the end nucleotides corresponding to the nucleotides located in positions 1 and 605 of FIG. 1.

According to another advantageous embodiment, the nucleic acids of the invention consist of the sequence of nucleotides (19) delimited by the end nucleotides corresponding to the nucleotides located in positions 1 and 605 of FIG. 1. According to yet another embodiment, the nucleic acids of the invention contain the sequence of nucleotides (17), delimited by the end nucleotides corresponding to the nucleotides located at positions 54 and 605 in FIG. 2.

According to yet another embodiment, the nucleic acids of the invention consist of the sequence of nucleotides (17), delimited by the end nucleotides corresponding to the nucleotides located at positions 54 and 605 in FIG. 2.

According to yet another embodiment, the nucleic acids of the invention contain the sequence of nucleotides (20) delimited by the end nucleotides corresponding to the nucleotides located at positions 1 and 838 in FIG. 2.

According to yet another embodiment, the nucleic acids of the invention consist of the sequence of nucleotides (20) delimited by the end nucleotides corresponding to the nucleotides located in positions 1 and 838 of FIG. 2.

According to yet another embodiment, the nucleic acids of the invention contain the sequence of nucleotides (18), delimited by the end nucleotides corresponding to the nucleotides located at positions 4 and 552 in FIG. 3.

According to yet another embodiment, the nucleic acids of the invention consist of the sequence of nucleotides (18), delimited by the end nucleotides corresponding to the nucleotides located at positions 4 and 552 in Figure 3.

According to yet another embodiment, the nucleic acids of the invention contain the sequence of nucleotides (21) delimited by the end nucleotides corresponding to the nucleotides located at positions 1 and 558 in FIG. 3.

According to yet another embodiment, the nucleic acids of the invention consist of the sequence of nucleotides (21) delimited by the end nucleotides corresponding to the nucleotides located in positions 1 and 558 of FIG. 3.

The nucleic acids (16), (17), (18), (19), (20) and (21) of the invention all have the particularity of hybridizing with the Dras-3 gene of Drosophila as shown in FIG. 5, under the weakly stringent conditions defined below: hybridization at 60 ° C. in 5X SSC, 5X Denhardt, 0.1% SDS and 100 μg / ml of DNA from salmon sperm, last washing in 2X SSC and 0.1% SDS, at 60 ° C for about 15 min.

The nucleic acids (16), (17), (18), (19), (20) and (21) can be modified as soon as the amino acid sequences which they encode retain their biochemical and biological properties.

Such non-limiting modifications lead, for example, to variant nucleic acids which are distinguished from the above nucleic acids:

- by addition and / or - deletion of one or more nucleotides and / or modification of one or more nucleotides, provided that the sequence thus formed is capable of hybridizing with the same RNA or DNA sequence as the corresponding sequence unmodified, and that the amino acid sequences, encoded by these nucleic acids, retain the biochemical and biological properties indicated above.

The nucleic acids (16) and (19) can also be characterized by the restriction map which is the subject of FIG. 7.

The nucleic acids (17) and (20) can also be characterized by the restriction map which is the subject of FIG. 8.

The nucleic acids (18) and (21) can also be characterized by the restriction map which is the subject of FIG. 9.

These restriction maps should not be interpreted as having a limiting character in order to identify the nucleic acids comprising respectively the sequence indicated above.

Equivalent nucleic acids could also be defined by a restriction map having a community with the previously defined restriction maps of at least 50% of the restriction sites, located in the same order.

The invention also relates to the probes used to characterize the nucleic acids described above.

These probes are defined by their ability to hybridize with the above nucleic acids or their complementary sequences under the following hybridization conditions:

- for probes capable of hybridizing with nucleic acids (2), (3), (4), (5), (7),

(8), (9), (10), (12), (13), (14) and (15) or their complementary sequences the hybridization conditions are as follows: actual hybridization: 60 ° C, 5X SSC , 5X Denhardt, 0.1% SDS, 100 μg / ml of DNA 'of salmon sperm; washing: 60 ° C, 2X SSC, 0.1% SDS, 30 min;

- for probes capable of hybridizing with nucleic acids or complementary sequences (1), (6) and (11) the hybridization conditions are as follows: actual hybridization: 45 ° C, 5X SSC, 5X Denhardt , 0.1% SDS, 100 μg / ml DNA ^" of salmon sperm;

1 ° washing: room temperature, 2X SSC, 0.1% SDS, 30mn,

2nd wash: 45 ° C, 2X SSC, 0.1% SDS, 30mn.

As an oligonucleotide probe for identifying the nucleic acid sequences of the invention, it is possible, for example, to use the probe constituted by the following oligonucleotide sequence: GAA ATC CTG GAT ACT GCA GGG ACA GAG CAA TTT or the corresponding complementary sequence.

To identify nucleic acids (16) and

(19) of the invention, it is possible, for example, to use as probe the sequence of oligonucleotides delimited by the nucleotides corresponding to the nucleotides located at positions 493 and 605 of FIG. 1, or the corresponding complementary sequence.

To identify nucleic acids (17) and

(20) of the invention, one can, for example, use as probe the sequence of Oligonucleotides delimited by the nucleotides corresponding to the nucleotides located at positions 504 and 838 of FIG. 2, or the corresponding complementary sequence.

To identify the nucleic acids (18) and (21) of the invention, it is possible, for example, to use as a probe the sequence of oligonucleotides delimited by the nucleotides corresponding to the nucleotides located at positions 451 and 558 of FIG. 3, or the corresponding complementary sequence.

The invention also relates to a recombinant nucleic acid characterized in that it contains a nucleic acid as described above, inserted into a heterologous nucleic acid with respect to the above fragment.

The above heterologous nucleic acid may consist of a nucleic acid or a nucleic acid fragment belonging to a bacterium or even to a eukaryotic cell, said bacterium or said eukaryotic cell being chosen as the expression system of a DNA fragments described above.

Another heterologous nucleic acid suitable for carrying out the invention may also consist of a plasmid or a phage.

The invention further relates to a recombinant vector, in particular for the cloning and / or expression of a nucleic acid according to the invention, said vector being in particular of the plasmid or phage type, characterized in that it contains an acid recombinant nucleic acid as defined above, containing the above nucleic acid at one of the sites not essential for its replication. This recombinant vector can thus be formed by the preceding heterologous DNA insofar as this constitutes an autonomous replication system.

In a particular embodiment of the invention, the above recombinant vector is an expression vector containing, in one of its sites which are not essential for its replication, elements necessary to promote expression, in a cellular host , a nucleic acid coding for an amino acid sequence of the invention, a promoter compatible with said cellular host, in particular an inducible promoter, and optionally a signal sequence and / or an anchoring sequence.

The choice of promoter, signal sequence and anchoring sequence is determined according to the nature of the expression system chosen. A particular recombinant vector suitable for the expression of the amino acid sequences according to the invention in E. Coli, which comprises, at a site which is not essential for its replication:

- the elements allowing its insertion into E.Coli, the elements allowing the expression of the nucleic acid inserted into the vector by E.Coli, and possibly the elements allowing the export of the product resulting from the expression of the above nucleic acid .

Another recombinant vector is characterized in that it contains the elements making it possible to insert a nucleic acid, described above, in a yeast and the expression of this nucleic acid in this yeast. Other eukaryotic cells may be chosen to insert the recombinant vector containing the nucleic acid of the invention, this choice being oriented by the capacity of said eukaryotic cell to organize the expression of said nucleic acid.

The invention also relates to cellular hosts transformed by a recombinant vector such as those described above, which vector is capable of replicating in said microorganism.

A first preferred cellular host is constituted by E.coli transformed by a recombinant vector as described previously.

Another preferred cellular host is a yeast transformed with a recombinant vector. The yeast generally used is Saccharo yces Cere% 'isiae.

Other cellular hosts can also be used.

The invention naturally relates to the expression product of each of the microorganisms transformed by one of the recombinant vectors described in the preceding pages.

The invention also relates to a process for the preparation of the new peptides mentioned above by synthesis which comprises either the step-by-step addition of the chosen peptide residues, with the addition or the removal of any protective groups from the amino and carboxyl functions, or addition of selected peptide residues in order to produce fragments followed by condensation of said fragments into an appropriate amino acid sequence, with addition or elimination of the protective groups chosen. The invention also relates to a process for the preparation of an amino acid sequence in accordance with the description above, characterized in that: a cell host cultivated beforehand with a suitable vector containing is cultivated in an appropriate culture medium a previously defined nucleic acid,

- The amino acid sequence produced by said transformed microorganism is recovered from the above culture medium after lysis of the latter's cell membrane.

The process for preparing a determined amino acid sequence can be characterized in particular by culturing E.coli transformed with a recombinant vector described above and by stopping the culture at the end of the exponential growth phase of said E.coli, and recovery of the amino acid sequence determined from the culture medium free of other proteins and exocellular enzymes capable of being secreted by E.coli.

The process for the preparation of a determined amino acid sequence can also be applied to a yeast transformed by a recombinant vector as described above, this yeast being placed in culture in an appropriate medium and said culture being stopped at the end of the exponential phase. growth of the yeast used.

The invention also relates to antibodies directed against the above amino acid sequences. In particular, the invention relates to monoclonal antibodies. Such monoclonal antibodies can be produced by the hybridoma technique, the general principle of which is recalled below.

Firstly, one of the above amino acid sequences is inoculated into a chosen animal, the B lymphocytes of which are then capable of producing antibodies against this amino acid sequence. these antibody-producing lymphocytes are then fused with "immortal" yelomatous cells to give rise to hybridomas. From the heterogeneous mixture of cells thus obtained, a selection is then made of the cells capable of producing a particular antibody and of multiplying indefinitely. Each hybridoma is multiplied in the form of an olone, each leading to the production of a monoclonal antibody whose recognition properties with respect to the amino acid sequences of the invention can be tested, for example on an affinity column.

The invention also relates to a method of in vitro screening of the above-mentioned amino acid sequences, from a biological sample capable of containing them. Such a screening method according to the invention can be carried out either using the above-mentioned monoclonal antibodies, or using the oligonucleotide probes described above.

The abovementioned biological sample is taken either from fluid tissues, such as blood, or from organs, the latter type of sample making it possible in particular to obtain fine sections of tissue on which the above-mentioned antibodies are subsequently fixed. The screening method according to the invention, proceeding by means of the abovementioned antibodies notably comprises the following steps:

- bringing at least one of the antibodies specifically recognizing an amino acid sequence of the invention into contact with the aforementioned biological sample;

- Detection, using any appropriate means, of any munological complexes i formed between the amino acid sequences and the above-mentioned antibodies.

Advantageously, the antibodies used for the implementation of such a method are labeled in particular in an enzymatic or radioactive manner.

Such a method according to the invention can in particular be carried out according to the ELISA method (enzyme linked sorbent assay) which comprises the following steps:

- Fixing 'a predetermined amount of labeled antibodies using an enzyme label on a solid support, such as a well of a microplate;

- addition of the biological sample (in liquid form) to said support; incubation for a time sufficient to allow the immunological reaction between said antibodies and the amino acid sequences mentioned above;

- addition of a specific substrate for the enzymatic activity released during the previous immunological reaction;

- Detection, using any suitable means, of the degradation of the substrate by the enzyme; and

- correlation of the quantity of enzymes released with the quantity of amino acid sequences present. According to another embodiment of the screening method of the invention, the above-mentioned antibodies are not labeled and the detection of the immunological complexes formed between the amino acid sequences and said antibodies is carried out using a labeled immunoglobulin recognizing said complexes. the screening method according to the invention can also be carried out by an immunoenzymatic technique according to a mechanism of competition between the amino acid sequences likely to be contained in the biological sample, and predetermined quantities of these same sequences of amino acids, vis-à-vis the above-mentioned antibodies. In the latter case, the amino acid sequences of the invention in a predetermined amount are advantageously labeled using an enzymatic marker.

The invention is in no way limited to the embodiments described above for the in vitro screening of the amino acid sequences of the invention, this screening can be carried out using any other immunological method, in particular immunoenzymatic currently known. .

The invention also relates to a method of in vitro screening of the amino acid sequences of the invention carried out from a biological sample capable of containing nucleic acids coding for said amino acid sequences, characterized in that it includes: - contacting at least one of the oligonucleotide probes described above with _the above-mentioned biological sample; - Detection using any appropriate means of any hybridization complexes formed between the probes and the abovementioned nucleic acids.

The abovementioned biological sample is, prior to the implementation of the screening, treated so that the cells which it contains are lysed, and in that the genomic material contained in said cells is fragmented using restriction enzymes such as EcoRI, Ba HI etc.

Advantageously, the oligonucleotide probes are labeled using an enzymatic or radioactive marker. These probes are placed on an appropriate support, in particular on a nitrocellulose or other filter, for example nylon, on which is then added the biological sample treated as indicated above.

The subject of the invention is also a method of in vitro diagnosis of diseases correlated with amino acid sequence contents of the invention situated outside the domain delimited by the extreme values generally corresponding to the physiological state of a healthy individual, by implementing one of the screening methods in _. vitro mentioned above.

The presence of small amounts, or even the complete absence, of the amino acid sequences of the invention in the biological samples tested, or on the contrary the overexpression of said sequences in the cells of the sample, indicates a probable imbalance between the factors anti-oncogenic and oncogenic of these cells, and this in favor of the latter, likely to trigger a cancerous pathology, in particular by loss inhibition of contact between the cells of the tissue or organ from which the sample was taken.

A subject of the invention is also kits or kits for implementing the above-mentioned in vitro screening methods.

By way of example, such kits include in particular: a determined quantity of at least one of the above-mentioned monoclonal antibodies capable of giving rise to a specific immunological reaction with one of the amino acid sequences of the invention;

advantageously, a medium suitable for the formation of an immunological reaction between the amino acid sequences and the abovementioned antibodies, advantageously reagents allowing the detection of the immunological complexes produced during the abovementioned immunological reaction.

In the context of implementing an in vitro screening method using oligonucleotide probes, the kits used include, for example:

a determined quantity of at least one of the above-mentioned oligonucleotide probes capable of giving rise to a hybridization reaction with one of the above-mentioned nucleic acids coding for the amino acid sequences of the invention,

advantageously a medium suitable for the formation of a hybridization reaction between the nucleic acids and the above-mentioned probes; advantageously, reagents allowing the detection of the hybridization complexes produced during the above-mentioned hybridization reaction.

The amino acid sequences according to the invention have interesting reverting properties.

To highlight these properties, we proceed as follows:

one of the normal and mutated RAPIA, RAPIB or RAP2 nucleotide sequences is inserted into a eukaryotic expression vector with a strong promoter such as LTR,

transfections are carried out using the above vector on cells which have been previously transformed by the RAS gene,

these cells are co-transfected with the RAPIA or RAPIB or RAP2 gene and a gene for resistance to an antibiotic, for example neomycin, as a selection marker,

- we express RAPIA or RAPIB or RAP2 in these cells and we can observe a phenotypic reversion,

- cells which have a normal reverting phenotype are isolated, analyzed and the expression of the RAPIA or RAPIB or RAP2 gene (on the one hand in RNA and on the other hand in proteins) directly responsible for reversion is observed.

More specifically, in order to address the functional study of proteins produced from the RAPIA and RAP2 genes, two types of tools, antibodies and overproductive cell lines, have been developed;

- the cDNAs corresponding to the RAPIA and RAP2 genes were inserted into eukaryotic expression vectors and transferred by transfection into different cell lines, for example fibroblastic cells in culture of murine origin N.IH3T3 in the case of RAPIA and RATl in the case of RAP2. The RAP2 gene cDNA does not seem to confer any particular phenotype when it is expressed in normal fibroblasts. On the other hand, its overexpression in lines transformed by the oncogenes li¬ ras and Ki-ras is correlated with a phenotypic reversion of these cells towards an untransformed phenotype;

- rabbit polyclonal antibodies have been generated against the proteins RAPIA and RAP2 or peptides derived from their sequence. The antibodies obtained specifically recognize the RAPIA or RAP2 proteins and show no cross-reaction with the H-ras protein; the use of these antibodies to immunoprecipitate the RAP2 protein in cell lines overexpressing the has shown that c ^"is a membrane protein. It is synthesized as a precursor that is rapidly modified to give birth to the form mature of the protein; it is relatively stable in vivo with a metabolic half-life of around 12-24 h.

The amino acid sequences of the invention having the reversion properties indicated above are capable of being used for the therapeutic treatment of diseases linked to the RAS genes or of diseases in which the RAP gene could be involved, either by mutation, or by bad expression in certain cells.

To do this, the gene which codes for one of the amino acid sequences of the invention is introduced into an expression vector, which must be compatible with the cells to which it is intended to direct them and whose promoters must also be compatible with said cells.

The vector is then targeted so that it goes to be fixed in the targeted cells, so that they phagocytize it and that it is released and expressed in said cells.

EXAMPLE 1: CLONING AND SEQUENCING OF ACIDS

NUCLEIC RAPIA AND RAP2:

1) Isolation of human cDNA clones homologous to the Drosophila Dras-3 gene:

A cDNA library constructed in phage A gt10 is used from AR.m of human B lymphocyte cells (Raji line) and screened under weakly stringent hybridization conditions (defined below in the paragraph entitled " Materials and methods ") with the complete insert of Drosophila Dras-3 DNA.

15 phages are isolated from 100,000 recombinant phages. The EcoRI inserts are purified, subjected to cross-hybridization reactions with one another under strongly stringent conditions (defined below in the section entitled "Materials and methods") and are partially sequenced. We can thus identify two categories of clones, 14 deriving from the same gene and a fifteenth deriving from another neighboring gene.

The first family clone is designated by RAPIA and the second family clone by RAP2.

Human genomic DNA from the placenta has been hydrolyzed by enzymes from following restriction BamHI, EcorI and HindIII, and columns A, B, C, D, E and F correspond respectively to: column A BamHI column B Ba HI + EcoRI column C BamHI + HindIII column D HindIII column E HindIII + EcoRI column F EcoRI then hybridized with EcoRI inserts respectively from the cDNA of the RAPIA and RAP2 clones.

Figure 4 shows the hybridization profile of the cellular genes RAPIA (1) and RAP2 (2).

The size of the fragments determined by the HindIII marker is shown on the left in kilo base pairs.

2) Nucleotide sequence of the cDNAs of RAPIA and RAP2: The nucleotide sequence of the inserts of 1450 base pairs and 980 base pairs of the cDNAs of RAPIA and RAP2 is determined.

The amino acid sequences encoded by these clones are shown in Figures 1 and 3 respectively.

FIGS. 1 and 3 also show the nucleic acid sequences coding for RAPIA and RAP2 respectively.

The RAPIA and RAP2 proteins consist respectively of peptide sequences of 184 and 183 amino acids, including the initial methionine, and have a calculated molecular weight of 20,900 and 20,700d, respectively.

3) Ho ologies between the RAPIA and RAP2 proteins and the Dras-3, K-ras, ral and R-ras proteins: The homologies between on the one hand the protein RAP1 and, on the other hand, the protein Dras-3 of Drosophila and the proteins K-ras, ral and R-ras are respectively 66.5%, 53%, 44% and 41%.

With regard to the most conserved region of the ras proteins, of amino acid 1 to 84, the percentages are 78.5% for the Dras-3 protein of Drosophila, 59.5% for K-ras, 56 % for ral and 63% for R-ras.

A global cellular comparison for the RAP2 protein leads to a 48% homology with Dras-3 of Drosophila, 46% with K-ras, 38% with ral and 37% with R-ras.

When only the first 84 amino acids are considered, these percentages are 63 for Dra's-3, 52 K-ras and ral, 56% for R-ras.

FIG. 5 shows the alignments of the RAPIA and RAP2 proteins with the human protein K-ras (exon 4B) and the Dras-3 protein of Drosophila. The reference numbering is that of the K-ras protein.

In this FIG. 5, the attachment regions of the GTP are framed. The region of the effector is underlined by 1 solid line and the region of attachment to the intracellular membrane is underlined in dotted lines.

Four domains involved in the binding site to the guanine nucleotides of ras proteins (Barbacid, M. (1987) Annual Review of Biochemistry, 56, 779-827) and corresponding to the amino acid sequences 10 to 17, 57 to 63, 113 to 120 and 143 to 147 are highly conserved among the proteins RAP, K-ras and Dras-3. The RAPIA and RAP2 proteins, like the Dras-3 protein, have a threonine in position 61 in place of a glutamine present in all ras proteins and the proteins close to the non-oncogenic ras proteins known to date.

The domain of residues 32 to 42, for the ras proteins - which corresponds to the domain involved in the interaction with an effector - is identical in the protein RAPIA and ras, and differs from an amino acid in the protein RAP2 compared to the ras protein.

The C-Terminal region of ras proteins is characterized by the sequence Cys-AAX, in which A is an amino aliphatic acid and X has the ino acid C-Terminal (Powers et al., (1984) Cell, 36, 607- 612). This sequence is necessary for post-translational lipid binding and anchoring in the plasma membrane (Fujiyama et al. (1986) Proc. Natl. Acad. Sci. USA, 83, 1266-1270). 5) Transcription of the RAPIA and RAP2 genes:

The transcription of the RAPIA and RAP2 genes is carried out by transfer of RNA to the membrane after gel electrorophoresis according to the technique designated by "Northern Blot". The conditions used for the "Northern Blot" are recalled below in the paragraph entitled "Materials and methods".

With a probe from RAPIA, three RNA sequences (that is to say three transcripts) of 1.600, 2.700 and 5.400 nucleotides are highlighted.

With a probe originating from RAP2, three RNA sequences, of 2,200, 2,500 and 4,600 nucleotides, are highlighted. The probe originating from RAPIA is a polynucleotide delimited by the Pstl-BglII fragment of the sequence (19) and the first end of which, corresponding to the restriction by PstI, is shown in FIG. 7, and the second end of which corresponds to the restriction by BglII, is 520 base pairs to the right of the first end.

The probe originating from RAP2 is a polynucleotide delimited by the HindII-PstI fragment of the sequence 21 and the first end of which corresponds to the restriction by HindII is shown in FIG. 9 and the second end, corresponding to the restriction by PstI, is located 340 base pairs to the right of the first end.

FIG. 6 shows the study of the transcripts of RAPIA (column 1) and of RAP2 (column 2) after electrophoresis and transfer of polyA + mRNA extracted from human lymphocytes. The size of the different RNAs is mentioned on the left in kilobase.

6) Materials and methods: cloning and sequencing of RAPIA and RAP2 cDNAs:

To identify the RAP cDNAs, a human library, constructed in the phage Agt10, was screened with an EcoRI insert of 700 base pairs from the Drosophila cDNA clone Dras-3 (Schetjer et al., (1985 ) EMBO J., 4, 407-412). The hybridization was carried out under weakly stringent conditions: namely hybridization at 60 ° C. in 5 x SSC, 5 x Denhardt, 0.1% SDS, 100 μg / ml of salmon sperm DNA. The last wash is done in 2 x SSC and 0.1% SDS at 60 ° C for about 15 min.

The highly stringent conditions used for the cross-hybridization of the EcoRI inserts are as follows: the hybridization is carried out under the following conditions: 5 x SSC, 5 x Denhardt, 0.1% SDS and 100 μg / ml of sperm DNA salmon at 65 ^C C.

The washing is carried out with 0.1% SSC and 0.1% SDS at 65 ° C for 30 min.

The nucleotide sequence of the complete EcoRI insert of the RAPIA and RAP2 clones is determined using the M13 vectors by the dideoxy nucleotide chain termination method (Messing, J. (1983) Methods Enzymol., 101, 20-78 ). 7) Northern and Southern Blot analysis:

The technique designated by "Southern Blot" is carried out as described in the article by Southern, E. (1975) J. Mol. Biol., 98, 503. 10 μg of human placental DNA digested with restriction endonucleases are subjected to electrophoresis on a 0.8% agarose gel, transferred to a nitrocellulose filter and hybrids with the EcoRI insert. of each of the RAPIA and RAP2 clones.

Hybridization is carried out under the following conditions: 5 x SSC, 5 x Denhardt, 0.1% SDS and 100 μg / ml of salmon sperm DNA at 65 ° C.

The washing is carried out using 0.1% SSC and 0.1% SDS at 65 ° C for 30 min.

Regarding the technique designated by

"Northern Blot" to determine the RNA sequences, cytoplasmic RNAs are prepared from peripheral blood lymphocytes (Perry et al.,

(1972) BBA, 262, 220-226).

5 μg of polyA * DNA are fractionated on 1% formaldehyde and agarose gels, before transfer on nylon membranes (marketed under the name Pall), and the filters are hybridized with the probes originating from RAPIA and RAP2, defined above.

All the probes are marked with ³² P by the random initiation technique (A ersham) to obtain an activity of approximately 3 × 10 ⁸ CPM / μg. Hybridizations are carried out in 50% formamide at 42 ° C. according to the method described in the article by Maniatis et al., (1982) Molecular cloning, Cold Spring Harbor Laboratory. EXAMPLE 2_ CLONING AND RAPIB SEQUENCING:

The RAPIA cDNA insert is used to screen a human cDNA library prepared in the phage ΛgtlO.

The RAPIA insert is marked with ³² P and makes it possible to identify a phage whose insert (of 2100 bp), after subcloning, is sequenced.

The nucleic acid sequence and the amino acid sequence encoded by this nucleic acid are shown in Figure 2.

The search for homology on the one hand between this amino acid sequence and the proteins RAPIA and RAP2, shows that this amino acid sequence has a homology of 95% with respect to RAPIA and 61% with respect to RAP2.

This amino acid sequence will subsequently be designated by RAPIB. It has a calculated molecular weight of 20,800 d.

EXAMPLE 3 _. PRODUCTION OF THE RAPIA PROTEIN IN A BACTERIAL EXPRESSION VECTOR: a) The RAPIA cDNA is subcloned for the purpose of its amplification, in the vector PUC8, at the EcoRI site. After culture, the cDNA is extracted and subjected to the restriction enzyme Bgl2, then to EcoRI, and a DNA fragment is thus recovered which corresponds to the complete region coding for the protein RAPIA.

The EcoRI / Bgl2 fragment is cloned into the phage M13Mpl1 at the BamHI and EcoRI sites, which makes it possible, after culturing the phage, to recover the single-stranded DNA.

Site-directed mutagenesis is carried out using a synthetic oligonucleotide of the following sequence: 5 'CAGATCACATATGCGTGAGTAC 3', this oligonucleotide being previously phosphorylated by the polynucleotide kinase.

An NDE1 site is thus introduced upstream of the ATG corresponding to the initiation of the RAPIA protein.

Recombinant M13Mpl1 is then prepared. To do this, the double-stranded DNA of M13Mpl1 is cut with the restriction enzyme NDE1 ^' and the NDE1 site is repaired using the enzyme of Kleno.

Then cut with the restriction enzyme HindIII. The fragment thus obtained is then linked to the vector M13Mpl1 cut with EcoRI-HindIII, the EcoRI site of the above vector having been repaired by the Klenow enzyme before ligation.

Site-directed mutagenesis is carried out using the synthetic oligonucleotide of following sequence phosphorylated by the polynucleotide kinase: 5 'CCAGTGAATTCTATGCGTGAG 3'

This oligonucleotide makes it possible to insert a C at the ligation site of M13Mpl1 and of RAPIA and thus reconstitute an EcoRI site. The phage M13Mpl1 containing the sequence RAPIA is thus obtained. The RAPIA insert can be isolated by cutting the phage at the EcoRI and HindIII sites. b) Next, double-stranded DNA of Ml3Mpl1 is prepared. Cut with EcoRI and HindIII to prepare the RAPIA insert for cloning into a bacterial expression vector.

For example, the one described in the article Tucker et al., EMBO J., vol. 5, 6, p. 1351-1358 (1986). More precisely, the vector used is the vector ptac-cHras.

The vector ptac-Hcras can be obtained from the vector pKM-tael according to the construction described in the above-mentioned article by Tucker. As for the vector pKM-tael, it can be obtained according to the construction described in the article by Hermann A. De Boer et al., PNAS, vol. 80, p. 21-25, January 1983.

The ptac-Hcras vector is subjected to the restriction enzyme HindIII, then to EcoRI, in a partial manner in order to keep a fragment of approximately 300 base pairs EcoRI-EcoRI which contains the inducible tac promoter.

The EcoRI-HindIII fragment of RAPIA is inserted into the vector thus prepared and a ligation is carried out. Using the vector obtained, a strain of E. coli, such as those known under the designation PRI & M15, or HB101 - PDMI vector is then transformed. c) The RAPIA protein is then expressed in the following manner.

From a culture which lasts about 12 hours, we seed with 1/100 of the culture medium and let grow about 3 hours by subsequently inducing approximately 12 hours with IPTG, at a concentration of 50 μM.

The RAPIA protein expressed by the E. coli strain is then recovered according to conventional techniques. This protein is in soluble form.

EXAMPLE 4 PRODUCTION OF THE RAPIA MUTE PROTEIN IN POSITION 61 IN AN EXPRESSION VECTOR:

The procedure is carried out as indicated in paragraph a) of Example 3, that is to say until obtaining a phage M13Mpl1 containing the sequence RAPIA cloned at the EcoRI and HindIII sites.

The single-stranded DNA of the phage M13Mpl1 is prepared by site-directed mutagenesis using the following synthetic oligonucleotides phosphorylated by the polynucleotide kinase:

5 'GAT-ACT-GCA-GGG-CAA-GAG 3' (A) (to transform threonine "61" into glutamine)

5 'GAT-ACT-GCA-GGG-GTA-GAG 3' (B) (to transform threonine "61" into valine)

Thus, at position 61, a glutamine is introduced in place of threonine in the context of the oligonucleotide (A) and a valine in place of threonine in the context of the oligonucleotide (B).

The respective double strand DNAs of each of the two RAPIA sequences modified as indicated above are then prepared, then cut with the enzymes EcoRI and HindIII, then cloned into the expression vector as indicated in paragraph .b) of Example 3 .

The two modified proteins are obtained according to paragraph c) of Example 3. EXAMPLE 5 PRODUCTION OF RAPIA MUTE PROTEIN IN

POSITION 35 IN AN EXPRESSION VECTOR:

The procedure is as indicated in Example 4. The site-directed mutagenesis is carried out using

The following synthetic oligonucleotide phosphorylated by the polynucleotide kinase:

5 'TAT GAC CCA GCG ATA GAA GAT 3' to transform threonine "35" into alanine. EXAMPLE 6 PRODUCTION OF RAPIA MUTE PROTEIN IN

POSITION 12 IN AN EXPRESSION VECTOR:

The procedure is as indicated in Example 4. The site-directed mutagenesis is carried out using

1 Synthetic oligonucleotide following phosphorylated by the polynucleotide kinase:

5 'CTT GGT TCA GTA GGC GTT 3' to transform glycine "12" into valine.

EXAMPLE 7 PRODUCTION OF RAPIA MUTE PROTEIN IN

POSITION 17 IN AN EXPRESSION VECTOR: The procedure is as indicated in Example 4. The site-directed mutagenesis is carried out using

The following synthetic oligonucleotide phosphorylated by the polynucleotide kinase:

5 'CGT TGG GAA GAA TGC TCT GAC A 3' to transform serine "17" into asparagine.

EXAMPLE 8 PRODUCTION OF RAPIA MUTE PROTEIN

POSITION 168 IN AN EXPRESSION VECTOR:

The procedure is as indicated in Example 4. The site-directed mutagenesis is carried out using the following synthetic oligonucleotide phosphorylated by the polynucleotide kinase:

5 'GAT AAA TAG GTA AAC ACC AGT 3' to introduce a stop codon in place of lysine 168. EXAMPLE 9 PRODUCTION OF THE RAPIB PROTEIN IN AN EXPRESSION VECTOR:

The EcoRI-KpNI fragment of the RAPIB fragment is cloned into phage M13Mpl1 at the EcoRI and BamHI sites.

Directed mutagenesis is carried out using a synthetic oligonucleotide following phosphorylated by the polynucleotide kinase: ¹⁰ 5 ′ AAG CTT GCA TAT GCG TGA GT 3 ′ and thus an NDE1 site is introduced upstream of the ATG corresponding to the initiation of the RAPIB protein.

Recombinant M13Mpl1 is then prepared. To do this, is cut by the restriction enzyme NdeI ^15, the double-stranded DNA M13Mpll and repairs the site NdeI using Klenow enzyme.

Then cut with the restriction enzyme

HindIII. The fragment obtained is then ligated to the vector M13Mpl1 cut with EcoRI-

2 ° HindIII, the EcoRI site of the above vector having been repaired by the Klenow enzyme before ligation.

Site-directed mutagenesis is then performed to introduce a C to the ligation site of M13Mpl1 and RAPIB. The EcoRI site is thus reconstituted. This ~~ site-directed mutagenesis is carried out using the synthetic oligonucleotide of following sequence phosphorylated by the polynucleotide kinase: 5 'CCA GTG AAT TCT ATG CGT GAG 3'

This gives the M13Mpll ³⁰ phage containing the sequence RAPIB. The RAPIB insert can be isolated by cutting the phage at EcoRI and HindIII sites and inserted into an expression vector such as the ptac vector. Obtaining the RAPIB protein is performed as described in paragraph c) ³⁵ Example 3. EXAMPLE 10 PRODUCTION OF RAP2 MUTE PROTEIN IN POSITION 12 IN A BACTERIAL EXPRESSION VECTOR:

The procedure is carried out as indicated in paragraph a) of Example 3, that is to say until the phage M13Mpl1 containing the sequence RAP2 cloned at the EcoRI and HindIII sites is obtained.

The following synthetic oligonucleotide phosphorylated by the polynucleotide kinase: 5 'CGG AGG GCA TAT GCG CGA GTA 3' is used to introduce an NDE1 site, and the oligonucleotide of following sequence phosphorylated by the polynucleotide kinase: 5 'CCA GTG AAT TCT ATG CGC GAG 3 'is used to insert a C at the ligation site of M13Mpl1 and RAPIA and thus reconstitute an EcoRI site.

The single-stranded DNA of the phage M13Mpl1 is prepared by site-directed mutagenesis using the following synthetic oligonucleotides phosphorylated by the polynucleotide kinase: 5 'GCT GGG CTC GGT CGG GGTA GGC A 3 * to transform the glycine "12" into valine.

The double stranded DNA of the modified RAP2 sequence as indicated above is prepared, then cut with the enzymes EcoRI and HindIII, then cloned into the expression vector ptac32 described in "Biochemical Properties of Ha-ras Encoded p21 Mutants and Mechanism of the Autophosphorylation Reaction "(The Journal of Biological Chemistry, vol. 263, No. 24, p. 11792-11799, 1988), as indicated in paragraph b) of Example 3.

Obtaining the modified protein in an E. coli strain, such as those known under the designation of PRIΔM15 OR HB101 + PDMI, is carried out according to paragraph c) of Example 3. EXAMPLE 11: PRODUCTION OF THE RAP2 MUTE PROTEIN IN

POSITION 35 IN A BACTERIAL EXPRESSION VECTOR:

, 5 From the phage M13Mpl1 containing the sequence RAP2 cloned at the EcoRI and HindIII sites, obtained as indicated in the previous example, the single-stranded DNA of the phage M13Mpl1 is prepared by site-directed mutagenesis using the following synthetic oligonucleotides

10 phosphorylated by the polynucleotide kinase: 5 'TAC GAC CCC GCC ATC GAG GAC 3 "to transform threonine" 35 "into alanine.

Obtaining the modified protein is carried out as indicated in the previous example.

EXAMPLE 12: EXPRESSION OF THE RAPIA GENE OR OF THE RAP2 GENE IN THE VETR-RAP A AND VETR-RAP2 VECTOR:

1) The RAPIA gene and the RAP2 gene were respectively expressed in a retrovirus-type expression vector constructed as follows:

20 from the initial vector A *.

Vector A * is a modification of vector A, in which the EcoRI site of PBR322 has been destroyed.

This vector was obtained by ligation of the

25 4.5 Kb HindIII-EcoRI fragment of the Harvey virus (nucleotides 3495-2540) (Soeda, E. and Yasuda, S. (1985), RNA Tumor Viruses: Molecular Biology of Tu or Viruses. Cold Spring Harbor Laboratory Press , Cold Spring Harbor, NY, Second edition, pp.

30 928-939), to the 3.3 Kb EcoRI-Ba HI fragment of this same virus (nucleotides 2540-378). After ligation, the viral fragment was inserted between the HindIII and BamHI sites of pBR 322.

35 The initial vector A * is represented by a circle in Figures 12a), 12b) and 12c).

In FIG. 12a) the SacII / EcoRI fragment of the initial vector A * is represented by a strong line opposite which a dotted arc of circle has been drawn (inside the vector).

The initial vector A * is cut by EcoRI and the Klenow enzyme is made to act to obtain blunt ends. The EcoRI site is thus destroyed and is represented below by EcoRI crossed out with a cross

Then cut with SacII and recover the 1600 bp SacII / Ec ^ I fragment.

2) In FIG. 12b), the Pstl / SacII fragment of the vector A * has been represented by a strong line, opposite which we have drawn (inside the vector) an arc of a circle in solid lines.

The initial vector A * is cut with PstI and SacII to recover the 3736 bp Pstl / SacII fragment.

3) In FIG. 12c), the Pstl / HindIII fragment of the vector A * has been represented by a strong line, opposite which we have drawn (inside the vector) a dotted arc of a circle: solid dot lines .

The initial vector A * is cut with HindIII; Klenow's enzyme is acted on to obtain blunt ends, then cut with PstI. The HindIII site is thus destroyed and is represented in the rest of the text by Hip_ClII.

The Pstl / Hip-élI fragment of 5626 bp is recovered. 4) The following fragments obtained in 1), 2) and 3) above are then ligated:

- SacII / Ec ^ I

- Pstl / SacII

to obtain the intermediate construction shown in Figure 12d).

In this intermediate construction, the fragment between HindIII on the one hand and Ecj_? FI / Hip-II on the other hand contains a sequence designated by "enhancer", or stimulating sequence, represented by "E" in FIG. 12d).

5) The intermediate construction is cut with Pstl / HindlII. The Pstl / HindIII fragment of 6345 bp is recovered, containing on the one hand the LTR3 '(which will serve for the polyadenylation site of the RNA) and on the other hand the region of the "enhancer".

The above fragment is represented by a strong line, in FIG. 12e), opposite which points (inside the vector) have been drawn according to an arc of a circle.

6) Another vector, designated by J ′, is used. This vector J ′ is obtained from the vector A * and differs from the vector A * by the following two elements:

- the mutation in position 12 no longer exists; the viral fragment of 51bp HindIII / PvuII (nucleotide 1088 to 1139) ^has' been replaced by the corresponding fragment of the mouse Ha-ras cellular gene (Lacal et al (1984):..... Proc Natl Acad Sci USA, vol 81, p. 5305-5309).

- The SacII site present in the Harvey virus at position 940 has been replaced by an EcoRI site. From the vector J ', the fragment containing the LTR5' is isolated. To do this, the vector J ′ is cut by Pstl / EcoRI and the Pstl / EcoRI fragment of 2305 bp is isolated, represented by a line in FIG. 12f), opposite which one has drawn (inside the vector) small solid triangles, in an arc.

7) the EcoRI / HindIII inserts of RAPIA subcloned in pUC8 or of RAP2 subcloned in pUC8 are then linked to the HindIII / PstI fragments of 6345 bp obtained (as indicated in paragraph 5 above) and originating from the vector called " intermediate construction "and Pstl / EcoRI from the vector J '(see paragraph 6 above) of 2305 bp. Results:

The expression vectors described above and containing RAPIA and RAP2 respectively were made to express in different normal or transformed cell lines, in particular by RAS or by other oncogenes.

EXAMPLE 13 EXPRESSION OF THE RAPIA GENE OR OF THE RAP2 GENE IN THE PJ3Q VECTOR:

This vector is described in Land, H.A., Chen, C, Morgenstern, J.P., Parada, L.F., and Weinberg, R.A., Mol. Cell Biol. 6: 1917-1925, 1986.

For RAPIA, cloning into the vector PJ3Ω is done from the EcoRI / Bgl2 insert obtained from the complete cDNA of RAPIA cloned directly into the vector PJ3Q at the EcoRI / Bgl2 sites of this vector. For RAP2, as there is no Bgl2 site, the insert from the RAP2 cDNA cut at the EcoRI / PstI sites, cloned in the plasmid pUC8, is used. From this construction, the EcoRI / HindIII fragment, having 670 bp, emerges. The above-mentioned plasmid pUC8 containing RAP2 is cut with HindIII and repaired with the Klenow enzyme to obtain blunt ends, then cut with EcoRI.

The HindIII site is destroyed and will be designated later by Hindi J.

The EcoRI / Hi ^ II insert (repaired by Klenow) is isolated on agarose gel.

The vector PJ3Ω is cut at the Bgl2 site repaired by Klenow to obtain blunt ends, then cut by EcoRI.

The Bgl2 site is destroyed and will be designated below by Bα_ <È.

The RAP2 insert and the PJ3Ω vector cut at the sites then submitted

to a ligation. Results:

RAPIA and RAP2 clones are made to express in the PJ3Ω vector as described above respectively in different normal or transformed cell lines, in particular by RAS or by other oncogenes.

The reverse cloning of RAPIA and RAP2 respectively into the vector PJ3Ω was also carried out, at the HindIII / EcoRI sites.

For RAPIA, the EcoRI / HindIII insert obtained from the subcloning of RAPIA into pUC8 is linked to the PJ3Ω vector cut at the HindIII / EcoRI sites.

For RAP2, 1 ^* insert EcoRI / HindIII obtained from subcloning into pUC8 RAP2 is linked to vector PJ3Ω cut sites HindIII / EcoRI.

The reverse cloning of RAPIA and RAP2 in the vector PJ3Ω allows the production of antisense messenger RNA which, by hybridization with the messenger RNA endogenous RAPIA and RAP2 genes can inhibit protein synthesis.

This vector can allow the expression of the RAP proteins either after transfection or by infection, the vector having previously been packaged using an "associated" virus ("helper"). EXAMPLE 14 EXPRESSION OF THE RAPIA GENE, THE RAPIB GENE AND THE RAP2 GENE IN THE PEX V3 VECTOR:

This vector is described in Miller, J., and Germain, R.N., J. Exp. Med. 164: 1478-1489, 1986.

For the cloning of RAPIA, as well as that of RAPIB and RAP2, the vector PEX V3 is cut by the enzyme EcoRI.

The EcoRI inserts of the complete cDNAs of RAPIA, RAPIB and RAP2 respectively are directly cloned into the PEX V3 vector cut at the EcoRI site.

For RAPIA, the insert is 1.4 kb, for RAPIB, the insert is 2.1 kb, and for RAP2, the insert is 950 bp.

The correct orientation in the vector, that is to say that it is compatible with the expression of the protein, was determined by carrying out different enzymatic degradations (for example BamHI and pstl) and by the sequencing of restriction fragments including the site. Cloning EcoRI.

RAPIA, RAPIB and RAP2 are expressed respectively in different normal or transformed cell lines.

The cloning was also carried out in the opposite orientation to that indicated above. This makes it possible to obtain a trancript RNA as indicated at the end of Example 13. EXAMPLE 15 EXPRESSION OF THE RAPIA GENE OR THE RAP2 GENE IN THE P ZIP NEO VECTOR:

This vector is described in Constance, L. Cepho, Bryan, E. Roberts, and Richard, C. Mulligan. Cell, vol. 37: 1053-1062, 1984.

RAPIA and RAP2 are cloned at the BamHI site of the above vector, which was previously cut by BamHI and repaired by Klenow to obtain blunt ends. The BamHI site is destroyed and will be designated below by Bah ^ I.

As regards RAPIA, it is previously subcloned into the plasmid pUC8.

The cDNA is cut by EcoRI / HindIII repaired by the Klenow (to obtain blunt ends) and will be The RAPIA insert

is linked by a ligase making it possible to constitute the vector Zip Neo of RAPIA. The vector is oriented (in the direction allowing expression of the protein) by carrying out different enzymatic degradations and by carrying out sequencing at the cloning sites.

For the cloning of RAP2, we proceed as indicated in connection with RAPIA.

The insert Ec ^ I Hjjj_t! K ^ II of RAP2, repaired by Klenow is linked to the vector P Zip Neo cut in BamHI repaired by the Klenow enzyme.

RAPIA and RAP2 clones are made to express in P Zip Neo respectively in different normal or transformed cell lines. EXAMPLE 16: EXPRESSION OF THE RAPIA GENE OR OF THE RAP2 GENE IN THE YEAST VECTOR YEP51:

This vector is described in Broach et al. (1983), Vectors for high - level inducible expression of cloned genes in veast. In Experimental

Manipulation of gene expression, M. Inouye, ed. (New

York: Press Academy) pp. 83-177.

Cloning is carried out as follows: The vector YEP51 is cut by Sali repaired by Klenow, then cut by HindIII.

The Sali site is destroyed and is designated below by S l.

The large fragment Sa ^ Π/ HindIII is purified on gel and is used for cloning.

As regards RAPIA, the insert used comes from subcloning of the RAPIA cDNA (EcoRI / Bgl2 fragment) into the vector pUC8.

This insert is obtained by cutting RAPIA subclone in the vector pUC8 by EcoRI, followed by repair with the enzyme Klenow, then by cutting with HindIII. The EcoRI site is destroyed and

is purified and then bound to

For RAP2, we proceed as indicated with regard to RAPIA.

RAPIA and RAP2 clones are made to express in the vector YEP51 in different yeast strains.

EXAMPLE 17 EXPRESSION OF THE RAPIA GENE OR OF THE RAP2 GENE IN THE YEAST VECTOR PD2 E2

The PD2 E2 vector is described in the literature. This vector already contains a cloned gene which is got rid of by cutting with HindIII, then by purifying on an agarose gel to isolate the vector from the insert. The vector is then repaired by the Klenow enzyme to obtain blunt ends. HindIII sites are destroyed.

For the cloning of RAPIA, the insert from the subcloning of the cDNA of RAPIA in pUC8 (EcoRI / Bgl2 fragment) is used. This insert is obtained by cutting pUC8 RAPIA at the HindIII and EcoRI sites and is treated with the Klenow enzyme to obtain blunt ends.

The HindIII and EcoRI sites are destroyed and designated below by Ecj_HQ [./ Hi_ u.II.

Then, the Ec ^ 1 / Hi __ ^ II insert of RAPIA is ligated with the above-mentioned yeast vector.

For RAP2, the same type of construction is used as for RAPIA.

RAPIA and RAP2 clones are made to express in the vector PD2E2 respectively in different strains of yeast. EXAMPLE 18: DETERMINATION OF THE LOCATION

CHROMOSOMIC IN MEN OF THE RAPIA, RAPIB AND GENES

RAP

1) To do this, we proceed as follows:

- preparation of cDNA probes.

The RAP cDNAs are cloned into the plasmid pUC8. Two different fragments are used for the respective localization of each gene (cf. FIG. 10).

For the location of the RAPIA gene, two probes were used comprising the complete cDNA (1.4 kb) or its 5 ′ part comprising the coding region (0.7kb). The two probes used for RAPIB are either the complete cDNA (2, 1kb) or the 5 'part (0.73kb). The two RAP2 gene probes are either the full 0.95kb cDNA or the 0.66kb fragment in the 5 'part.

2) preparation of chromosomes:

High resolution chromosome preparations are obtained from the culture of phytohemagglutinin stimulated blood cells of two healthy men after synchronization with methothrexate according to Yunis et al.

(Yunis, J.J., Sawyer, J.R., Bail, D. .:

15 Characterization of banding patterns of etaphase- prophase G-banded chromosomes and their use in gene apping. Cytogenet. Cell Genêt., 22, 679-683,

(1978).

3) In situ hybridization:

20 The probes are labeled according to the method of • random DNA primers (Kit A ersham, U.K.) 'introduced by Feinberg and Vogelstein (Feinberg, A.P., Vogelstein, B.A .: technique for radiolabeling DNA restriction endonuclease fragments to high

2 specifies activity. Anal. Biochem. , 132, 6-13, 1983). Using 20 μCi [H ³ ] dCTP for 50 ng of cDNA, the activity obtained is from 0.5 to 2 × 10 ⁸ cpm / μg.

These labeled probes are used at concentrations of 20 to 80 ng / l.

³⁰ The hybridization technique described by Harper and Saunders (Harper, ME, Saunders, GF: Localization of single copy DNA sequences on G banded human chromosomes by in situ hybridization. Chromosoma, 83, 431-439, 1981) is slightly

^{~ ~} modified according to the method of Caubet et al. (Caubet, JF, et al., Hu an proto-oncogene c-mos maps to 8qll. Embo J., 4, 2245-2248, 1985).

The plates coated with Kodak NTB2 emulsion are exposed for one and two weeks for autoradiography: G bands are then obtained with the Wright dye.

4) Results:

Two diffferent inserts of each of the RAPIA, RAPIB and RAP2 genes are used respectively for in situ hybridization with respect to human chromosomes to confirm the results of FIG. 10. Only the metaphases having no more than three grains of silver on the chromosomes are photographed and analyzed.

5) Location of RAPIA:

The experiment made either with the 1.4 kb probe or with that of 0.7 kb reveals a single cluster of grains on the chromosome Ipl2-pl3 (6% and 5.5% of the total number) (Table 1).

TABLE 1

IN SITU HYBRIDIZATION OF RAPIA, RAPIB AND RAP2 ON HUMAN CHROMOSOMES

PROBE SIZE N ° OF N ° OF SEED HILLS

MITOSES SEEDS

on chrom. 1 _on chrom. Ipl2pl3

Bβpl A 1.4Kb 143 246 44 (17.8%) 15 (6%)

0.7Kb 120 163 26 (15.9%) 9 (5.5%)

on chrom. 12 on chrom. 12ql4

raplB 2.1Kb 195 292 43 (14.7%) 21 (7.2%)

0.73Kb 131 177 30 (16.9%) 17 (9.6%)

on chrom. 13 on chrom. 13q34

rapl 0.950Kb 138 200 26 (13%) 13 (6.5%)

0.660Kb 60 82 24 (29.2%) 11 (13.4%) No significant secondary signal is observed on other chromosomes (cf. FIG. 11a).

6) Location of RAPIB: In situ hybridization with the probe of 2, lkb or 0.7kb shows a clear accumulation of grains (7.2% and 9.6% of the total) on chromosome 12ql4 (table 1) .

No other significant cluster of grains is present on other chromosomes (Fig. 11b).

7) Location of RAP2:

The two probes of 0.950kb and 0.660kb used in this location show in each case the same cluster of grains on chromosome 13q34 (6.5% and 13.4% of the total (Table 1).

No other minor signal is visible on other chromosomes (figure lie). Conclusion:

No hybridization or secondary signal was seen on the other chromosomes.

With regard to chromosome Ipl2-pl3, no specific deletion is associated with a particular neoplasia. Some translocations of this region are described in elanomas and various blood disorders (Bloomfield, CD., Trent, JM, Van Den Berghe, H .: Report of the committee on structural chromosome changes in neoplasia (HGM10), Cytogenet. Cell. Genet 46, 344-366, 1987).

We can see an apparent close proximity Ipl2pl3 to the N-ras gene, also located on the chromosome.

Regarding the location of the RAPIB gene on chromosome 12ql4, ruptures are described in both the following benign and malignant neoplasms: lipomas (Heim et al., Reciprocal translocation t (3; 12) (q27; ql3) in lipoma. Cancer Genêt. Cytogenet., 23, 301-304, 1986); myxoid liposarcomas (Turcot-Carel et al., Cytogenetic studies of adipose tissue tumors. II. Recurrent reciprocal translocation t (12; 16) (ql3; pll); in myxoid liposarcomas, Cancer Genêt. Cytogenet. 23, 291-299, 1986 );

- pleomorphic adenomas (Bullerdiek et al., Rearrangements of chromosome region 12ql3-ql5 in pleomorphic adenomas of the human salivary gland (PSA). Cytogenet. Cell Genêt., 45, 187-190, 1987 and Mark et al., Cytogenetical observations in 100 human benign pleomorphic adenomas: specificity of the chromosomal aberrations and their relationship to sites of localized oncogenes. Anticancer Res., 6, 299-308, 1986) and leio yomes (Heim et al., A rearrangement between chromosomal regions 12ql3-ql5 and 14q22.24, t (12; 14) (ql3-15; q22-24), may be found in lyomyomas of the uterus (HGM9, Abstracts). Cytogenet. Cell Genêt., 46, 628, 1987).

Regarding the localization of the RAP2 gene, on chromosome 13q34, no specific deletion is associated with neoplasias and some deletions in this region are described in sporadic breast cancer.

Claims

CLAIMS 1. Amino acid sequence characterized in that it contains at least one of the following amino acid sequences:

MREYKLWL (I)

ALTVQFVQG I F VEKYD PTI ED S YRKQVE VDC QQCMLE I L (II)

QFTAMRDLYMKNGQGFALVYSITAQSTFNDLQDLREQILRVKDTEDVPM

(III)

EDERVVGKEQGQNLARQWCNCAFL (IV)

SKINVNEIFYDLVRQINRKTPVEKKKPKKKSCLLL (V)

ALTVQFVQGIFVEKYDPTIEDSYRKQVEVDAQQCMLEIL

(VII)

QFTAMRDLYMKNGQGFALVYSITAQSTFNDLQDLREQILRVKDTDDVPMI (VIII)

EDERVVGKEQGQNLARQWNNCAFL (IX)

SKINVNEIFYDLVRQINRKTPVPGKARKKSSCQLL (X)

MREYKVWL (XI)

ALTVQFVTGTFIEKYDPTIEDFYRKEIEVDSSPSVLEIL

(XII)

QFASMRDLYIKNGQGFILVYSLVNQQSFQDIKPMRDQIIRVKRYEKVPVI (XIII)

ESEREVSSSEGRALAEEWGCPFM (XIV)

SKTMVDELFAEIVRQMNYAAQPDKDDPCCSACNIQ (XV)

2. Amino acid sequence according to claim 1, characterized in that it contains the five sequences of amino acids I, II, III, IV, and V, defined in claim 1.

3. Amino acid sequence according to claim 1, characterized in that it contains the five sequences of amino acids VII, VIII, IX, and X, defined in claim 1.

4. Amino acid sequence according to claim 1, characterized in that it contains the five sequences of amino acids XI, XII, XIII, XIV, and XV, defined in claim 1.

5. Amino acid sequence according to claim 1, characterized in that it contains the chain of amino acids XVI, shown in Figure 1 or is constituted by this chain of amino acids.

6. Amino acid sequence according to claim 1, characterized in that it contains the chain of amino acids XVI shown in Figure 2, or is constituted by this chain of amino acids.

7. Amino acid sequence according to claim 1, characterized in that it contains the chain of amino acids XVIII shown in Figure 3, or is constituted by this chain of amino acids.

8. Amino acid sequence characterized in that it contains at least one of the amino acid sequences encoded by the following nucleotide sequences:

ATG CGT GAG TAC AAG CTA GTG GTC CTT (1)

GCT CTG ACA GTT CAG TTT GTT CAG GGA ATT TTT GTT GAA AAA TAT GAC CCA ACG ATA GAA GAT TCC TAC AGA AAG CAA GTT GAA GTC GAT TGC CAA CAG TGT ATG CTC GAA ATC CTG (2)

CAA TTT ACA GCA ATG AGG GAT TTG TAT ATG AAG AAC GGC CAA GGT TTT GCA CTA GTA TAT TCT ATT ACA GCT CAG TCC

ACG TTT AAC GAC TTA CAG GAC CTG AGG GAA CAG ATT TTA

CGG GTT AAG GAC ACG GAA GAT GTT CCA ATG ATT

(3)

GAA GAT GAG CGA GTA GTT GGC AAA GAG CAG GGC CAG AAT TTA GCA AGA CAG TGG TGT AAC TGT GCC TTT TTA (4)

TCA AAG ATC AAT GTT AAT GAG ATA TTT TAT GAC CTG GTC

AGA CAG ATA AAT AGG AAA ACA CCA GTG GAA AAG AAG AAG

CCT AAA AAG AAA TCA TGT CTG CTG CTC (5)

ATG CGT GAG TAT AAG CTA GTC GTT CTT (6)

GCT TTG ACT GTA CAA TTT GTT CAA GGA ATT TTT GTA GAA

AAA TAC GAT CCT ACG ATA GAA GAT TCT TAT AGA AAG CAA

GTT GAA GTA GAT GCA CAA CAG TGT ATG CTT GAA ATC TTG (7)

CAA TTT ACA GCA ATG AGG GAT TTA TAC ATG AAA AAT GGA

CAA GGA TTT GCA TTA GTT TAT TCC ATC ACA GCA CAG TCC ACA TTT AAC GAT TTA CAA GAC CTG AGA GAA CAG ATT CTT

CGA GTT AAA GAC ACT GAT GAT GTT CCA ATG ATT

(8)

GAA GAT GAA AGA GTT GTA GGG AAG GAA CAA GGT CAA AAT CTA GCA AGA CAA TGG AAC AAC TGT GCA TTC TTA (9)

TCA AAA ATA AAT GTT AAT GAG ATC TTT TAT GAC CTA GTG CGG CAA ATT AAC AGA AAA ACT CCA GTG CCT GGG AAG GCT CGC AAA AAG TCA TCA TGT CAG CTG CTT ^l101 ATG CGC GAG TAC AAA GTG GTG GTG CTG (11)

GCC CTG ACC GTG CAG TTC GTG ACC GGC ACC TTC ATC GAG

AAA TAC GAC CCC ACC ATC GAG GAC TTC TAC CGC AAG GAG

^~ ATC GAG GTG GAT TCG TCG CCG TCG GTG CTG GAG ATC CTG

(12)

CAG TTC GCG TCC ATG CGG GAC CTG TAC ATC AAG AAC GGC

CAG GGC TTC ATC CTC GTC TAC AGC CTC GTC AAC CAG CAG

! 0 AGC TTC CAG GAC ATC AAG CCC ATG CGG GAC ^' CAG ATC ATC

CGC GTG AAG CGG TAT GAG AAA GTG CCA GTC ATC (13)

GAA AGT GAG AGA GAA GTA TCG TCC AGC GAA GGC AGA GCC CTT GCT GAA GAG TGG GGC TGC CCC TTT ATG (14)

15

AGT AAA ACA ATG GTG GAC GAA CTC TTT GCA GAA ATT GTG

AGG CAG ATG AAC TAT GCT GCT CAG CCT GAC AAA GAT GAC

CCA TGC TGT TCT GCA TGT AAC ATA CAA (15)

20

9. Nucleic acid characterized in that it contains at least one of the sequences of nucleotides coding for the amino acid sequences according to claims 1 to 7.

.

10. Nucleic acid characterized in that it contains at least one of the following sequences of nucleotides:

ATG CGT GAG TAC AAG CTA GTG GTC CTT (1)

30 GCT CTG ACA GTT CAG TTT GTT CAG GGA ATT TTT GTT GAA

AAA TAT GAC CCA ACG ATA GAA GAT TCC TAC AGA AAG CAA

GTT GAA GTC GAT TGC CAA CAG TGT ATG CTC GAA ATC CTG (2)

35 CAA TTT ACA GCA ATG AGG GAT TTG TAT ATG AAG AAC GGC

CAA GGT TTT GCA CTA GTA TAT TCT ATT ACA GCT CAG TCC

ACG TTT AAC GAC TTA CAG GAC CTG AGG GAA CAG ATT TTA

CGG GTT AAG GAC ACG GAA GAT GTT CCA ATG ATT (3)

GAA GAT GAG CGA GTA GTT GGC AAA GAG CAG GGC CAG AAT TTA GCA AGA CAG TGG TGT AAC TGT GCC TTT TTA (4)

TCA AAG ATC AAT GTT AAT GAG ATA TTT TAT GAC CTG GTC

AGA CAG ATA AAT AGG AAA ACA CCA GTG GAA AAG AAG AAG

CCT AAA AAG AAA TCA TGT CTG CTG CTC (5)

ATG CGT GAG TAT AAG CTA GTC GTT CTT (6)

GCT TTG ACT GTA CAA TTT GTT CAA GGA ATT TTT GTA GAA

AAA TAC GAT CCT ACG ATA GAA GAT TCT TAT AGA AAG CAA

GTT GAA GTA GAT GCA CAA CAG TGT ATG CTT GAA ATC TTG (7)

CAA TTT ACA GCA ATG AGG GAT TTA TAC ATG AAA AAT GGA CAA GGA TTT GCA TTA GTT TAT TCC ATC ACA GCA CAG TCC ACA TTT AAC GAT TTA CAA GAC CTG AGA GAA CAG ATT CTT CGA GTT AAA GAC ACT GAT GAT GTT CCA ATG (8)

GAA GAT GAA AGA GTT GTA GGG AAG GAA CAA GGT CAA AAT CTA GCA AGA CAA TGG AAC AAC TGT GCA TTC TTA (9)

TCA AAA ATA AAT GTT AAT GAG ATC TTT TAT GAC CTA GTG CGG CAA ATT AAC AGA AAA ACT CCA GTG CCT GGG AAG GCT CGC AAA AAG TCA TCA TGT CAG CTG CTT (10)

ATG CGC GAG TAC AAA GTG GTG GTG CTG (11) GCC CTG ACC GTG CAG TTC GTG ACC GGC ACC TTC ATC GAG

AAA TAC GAC CCC ACC ATC GAG GAC TTC TAC CGC AAG GAG

ATC GAG GTG GAT TCG TCG CCG TCG GTG CTG GAG ATC CTG (12)

CAG TTC GCG TCC ATG CGG GAC CTG TAC ATC AAG AAC GGC

CAG GGC TTC ATC CTC GTC TAC AGC CTC GTC AAC CAG CAG

AGC TTC CAG GAC ATC AAG CCC ATG CGG GAC CAG ATC ATC

CGC GTG AAG CGG TAT GAG AAA GTG CCA GTC ATC (13)

GAA AGT GAG AGA GAA GTA TCG TCC AGC GAA GGC AGA GCC CTT GCT GAA GAG TGG GGC TGC CCC TTT ATG (14)

AGT AAA ACA ATG GTG GAC GAA CTC TTT GCA GAA ATT GTG AGG CAG ATG AAC TAT GCT GCT CAG CCT GAC AAA GAT GAC CCA TGC TGT TCT GCA TGT AAC ATA CAA (15)

11. Nucleic acid according to claim 10, characterized in that it contains the five sequences of nucleotides (1), (2), (3), (4) and (5), defined in claim 10.

12. Nucleic acid according to claim 10, characterized in that it contains the five sequences of nucleotides (6), (7), (8), (9) and (10), defined in claim 10.

13. Nucleic acid according to claim 10, characterized in that it contains the five sequences of nucleotides (11), (12), (13), (14) and (15), defined in claim 10.

14. Nucleic acid according to claim 10, characterized in that it contains the sequence of nucleotides (16), delimited by the end nucleotides corresponding to the nucleotides located at positions 43 and 594 of Figure 1, or contains the sequence of nucleotides (19) delimited by the end nucleotides corresponding to the nucleotides located in positions 1 and 605 in FIG. 1.

15. Nucleic acid according to claim 10, characterized in that it contains the sequence of nucleotides (17), delimited by the end nucleotides corresponding to the nucleotides located in positions 54 and 605 of Figure 2, or contains the sequence of nucleotides (20) delimited by the end nucleotides corresponding to the nucleotides located at positions 1 and 838 in FIG. 2.

16. Nucleic acid according to claim 10, characterized in that it contains the sequence of nucleotides (18), delimited by the end nucleotides corresponding to the nucleotides located in positions 4 and 552 of Figure 3, or comprises the sequence of nucleotides (21) delimited by the end nucleotides corresponding to the nucleotides located at positions 1 and 558 in FIG. 3.

17. Recombinant nucleic acid characterized in that it contains the nucleic acid according to any one of claims 9 to 16, inserted into a heterologous nucleic acid with respect to the above fragment.

18. Recombinant vector in particular for the cloning and / or the expression in particular of the plasmid, cosmid or phage, characterized in that it contains a recombinant nucleic acid according to claim 17 containing the above-mentioned nucleic acid at one of the sites not essential for its replication.

19. Recombinant vector according to claim

18, characterized in that it contains, in one of its non-essential sites for its replication, elements necessary to promote the expression of an amino acid sequence according to claims 1 to 8, in a cellular host, and optionally a promoter compatible with said cell host, in particular an inducible promoter, and optionally a signal sequence and / or an anchoring sequence.

20. Recombinant vector according to claim

19, in that it contains:

- the elements allowing its insertion into E. Coli,

- the elements allowing the expression by E. Coli of this nucleic acid according to claims 9 to 17, inserted into the vector, and the elements allowing the export of the product resulting from the expression of the aforesaid nucleic acid.

21. A cell host transformed by a recombinant vector according to any one of claims 18 to 20, capable of replicating in said cell host.

22. Cell host according to claim 21, characterized in that it is E. Coli transformed by the vector according to claim 20.

23. Antibody, in particular monoclonal, characterized in that it is directed against an amino acid sequence according to any one of claims 1 to 8.

24. Nucleotide probe characterized in that it hybridizes with one of the nucleic acids according to claims 9 to 17, or with their complementary sequences under the following hybridization conditions:

- for probes capable of hybridizing with nucleic acids (2), (3), (4), (5), (7), (8), (9), (10), fl2), (13 ), (14) and (15) or their complementary sequences, the hybridization conditions are as follows: actual hybridization: 60 ° C, 5X SSC, 5X Denhardt, 0.1% SDS, 100 μg / ml of DNA from salmon sperm; washing: 60 ° C, 2X SSC, 0.1% SDS, 30 min;

- for probes capable of hybridizing with nucleic acids or complementary sequences (1), (6) and (11) the hybridization conditions are as follows: actual hybridization: 45 ° C, 5X SSC, 5X Denhardt , 0.1% SDS, 100 μg / ml sperm DNA ^* from salmon;

1 ° washing: room temperature, 2X SSC, 0.1% SDS, 30mn,

2nd wash: 45 ° C, 2X SSC, 0.1% SDS, 30 min.

25. Method for in vitro screening of amino acid sequences according to any one of claims 1 to 8, in a biological sample capable of containing them, characterized in that it comprises:

- bringing at least one of the antibodies according to claim 23 into contact with the aforementioned biological sample;

- Detection using any appropriate means of any immunological complexes formed between the amino acid sequences and the above-mentioned antibodies.

26. Method for in vitro screening of amino acid sequences according to any one of Claims 1 to 8, in a biological sample capable of containing nucleic acids coding for said amino acid sequences, characterized in that it comprises:

- bringing at least one of the oligonucleotide probes according to claim 24 into contact with the above-mentioned biological sample previously treated;

- Detection using any appropriate means of any hybridization complexes formed between the probes and the abovementioned nucleic acids.

27. An in vitro screening method according to claim 25 or 26, applied to the in vitro diagnosis of diseases correlated to amino acid sequence contents, according to any one of claims 1 to 8, located outside the field delimited by the extreme values generally corresponding to the physiological state of a healthy individual.

28. Kit or kit for the implementation of an in vitro screening method according to claims 25 and 27 comprising: a determined quantity of at least one of the antibodies according to claim 23 capable of giving rise to an immunological reaction with a amino acid sequences to be detected according to claims 1 to 8; advantageously, a medium suitable for the formation of an immunological reaction between the amino acid sequences and the abovementioned antibodies; advantageously reagents allowing the detection of immunological complexes between amino acid sequences and antibodies produced during the above immunological reaction.

29. Kit or kit for the implementation of an in vitro screening method according to claim 26 and 27 comprising:

- a determined quantity of at least one of the oligonucleotide probes according to claim 24, capable of giving rise to a hybridization reaction with one of the nucleic acids coding for an amino acid sequence to be detected according to claims 1 to 8;

advantageously a medium suitable for the formation of a hybridization reaction between the nucleic acids and the above-mentioned probes;

advantageously, reagents allowing the detection of the hybridization complexes produced from the above-mentioned hybridization reaction.

30. A method of preparing an amino acid sequence according to any one of claims 1 to 8, characterized in that: a cell host cultivated beforehand with a suitable vector containing a nucleic acid is cultivated in an appropriate culture medium according to one of claims 9 to 17,

- And the amino acid sequence produced by said transformed cell host is recovered from the above culture medium after lysis of the cell membrane of this cell host.

31. Process for the preparation of a determined amino acid sequence characterized by culturing E. Coli containing a recombinant vector according to claim 20 and by stopping the culture at the end of the exponential phase of growth of said E. Coli, and recovery of the amino acid sequence determined from the culture medium free of other proteins and exocellular enzymes capable of being secreted by E. Coli.