EP1105483A1

EP1105483A1 - Genes involved in the molecular paths for tumour suppression and /or resistance to viruses

Info

Publication number: EP1105483A1
Application number: EP99965353A
Authority: EP
Inventors: Robert Amson; Adam Telerman
Original assignee: Molecular Engines Laboratories
Current assignee: Molecular Engines Laboratories
Priority date: 1998-08-05
Filing date: 1999-06-18
Publication date: 2001-06-13
Also published as: JP2002524041A; CA2339322A1; FR2782085B1; US6956110B1; FR2782085A1; WO2000008147A1

Abstract

The invention concerns genes involved in the molecular paths for tumour suppression and/or resistance to viruses, and whereof the cell expression is in particular induced or inhibited during apoptosis and/or tumour suppression.

Description

GENES INVOLVED IN THE MOLECULAR PATHWAYS OF TUMOR SUPPRESSION AND / OR VIRUS RESISTANCE

The present invention relates to the detection of genes involved in the molecular pathways of tumor suppression and / or resistance to viruses.

The present invention was made possible by the isolation of cDNA corresponding to messenger RNAs expressed or repressed during tumor suppression and / or during the process of apoptosis induced by the p53 suppressor gene.

One of the most important suppressor genes involved in apoptosis is the p53 gene. In its normal function, this gene controls cell growth and the process of apoptosis; in particular, it is this gene which blocks cell growth and which must induce the apoptotic process in order to avoid the development of cancer. It has thus been demonstrated that mice nullizygous for p53 were much more sensitive to the formation of tumors. It has also been demonstrated that, in cancers, the p53 gene is very often altered and leads to the production of proteins incapable of conveying the message of apoptosis. It is this feature which has been implemented in the context of the present invention.

Indeed, the present invention is based on the observation that it is not possible, or at least that it seems very difficult, to set up a direct substitution therapy during a dysfunction of the p53 gene. Indeed, the mutated p53 as it is in cancer will cancel the physiological effect of normal p53. It was therefore necessary to give up, at least initially, a substitution therapy acting directly at the level of p53.

The present invention has therefore endeavored to study the genes located upstream and downstream of p53 in order to “bypass” the difficulty mentioned above. In order to isolate the genes activated or inhibited by normal p53 (wild-type p53), a global raking of gene expression was carried out in a malignant line (K562) and a derived cell (KS) with a suppression of the phenotype. malignant, more particularly in a cell expressing normal p53 (KS) in its function and in a cell not expressing p53 (K562). The comparison of the expressed genes (messenger RNA expressed in the two types of cell) made it possible to highlight genes expressed differently, that is to say expressed in one of the cells whereas they are not it in the other (genes can be turned on or off).

It is easy to deduce that these genes are involved in the cancerization process, in one case by their absence, and, in the other case, by their presence.

For this differential study, the method used is the method described in 1992 by Liang and Pardee (Differential display o eukaryotic mRNA by mean of a polymerase chain reaction).

The approach to the problem according to the present invention made it possible to isolate sequences directly linked to a function. Consequently, unlike the random sequencing of ESTs, the sequences are sequences whose function is known and which are involved in the process of suppressing the malignant phenotype and / or of apoptosis induced by the suppressor gene p53 and / or in the resistance to viruses.

Thus, the present invention relates to new sequences and the genes comprising them as well as the use of these sequences, both at the diagnostic level and at the therapy level, as well as for the production of models intended for testing anti products. -cancerous and anti-viral.

The present invention firstly relates to a nucleotide sequence corresponding to a gene comprising:

(a) a sequence according to one of IND.SEQ 1 to 15 or an equivalent gene which comprises: (b) a sequence hybridizing with one of the sequences according to (a),

(c) a sequence having at least 80% homology with (a) or (b), or

(d) a sequence coding for a protein coded by a gene according to (a), (b) or (c) or for an equivalent protein, and their application in particular in the suppression of cancer and / or resistance to viruses as well as in therapeutic monitoring.

It should be recalled that the sequences 1 to 15 constitute only part of the genes in question, but that the present invention covers both the nucleotide sequence corresponding to the entire gene as fragments of this gene, in particular when they code for an equivalent protein as will be described below.

The nucleotide sequences can be either DNA or RNA OR sequences in which some of the nucleotides are unnatural, either to improve their pharmacological properties or to allow their identification.

The sequences mentioned in (b) are essentially the total or partial complementary sequences (in particular for the cases mentioned above).

Thus, the invention also relates to the nucleotide sequences of the genes having a strong homology with the genes mentioned above, preferably a homology greater than 80% on the essential parts of said genes, ie in general at least 50% of the sequence, preferably the homology on these parts will be greater than 90%.

Finally, when said genes code for a protein, the present invention also relates to the sequences coding for the same protein, taking into account the degeneration of the genetic code, but also for equivalent proteins, that is to say producing the same effects. , in particular proteins deleted and / or having undergone point mutations.

The sequences according to the present invention are more particularly the sequences which are induced or inhibited during cellular apoptosis, in particular those induced by p53 and / or p21 and / or TSAP3 (HUMSIAH) and / or antisense-TSIP2 (antisens-PSl) . In other words, these sequences correspond to genes whose cellular expression is activated by at least one of the transfectants chosen from the group comprising the p21 transfectants, the TSAP3 transfectants and the TSIP2 antisense transfectants.

Said genes are grouped in TSAP or "Tumor Suppressor Activated Pathway ", and named TSAP 9 to TSAP 22 corresponding to IND.SEQ 1 to 14, and TSIP or" Tumor Suppressor Inhibited Pathvay ", and called TSIP 3, corresponding to IND.SEQ 15.

The characteristics of the sequences are collated in the attached tables.

The nucleotide sequences corresponding to the TSAP genes are sequences expressed during the apoptosis process while when they are not expressed the oncogenesis process continues. It is therefore interesting:

- detect any abnormality in the corresponding gene, which can lead to greater susceptibility to oncogenesis, and

- to be able to plan a replacement therapy.

It should also be remembered that these genes can intervene in processes other than tumor suppression processes; indeed, p53 is in a way the guardian of the integrity of the genome, under these conditions the TSAP or TSIP genes are undoubtedly also involved in this control function, it is therefore all of the possible alterations in the genome which can be accountable for previous detection and therapy. On the contrary, the TSIP genes are expressed during oncogenesis and this expression is reduced or even inhibited during apoptosis and tumor suppression, it is therefore here also interesting to detect the possible anomaly of TSIP and also to predict a inhibition / blocking therapy.

Replacement therapy may be carried out by gene therapy, that is to say by introducing the TSAP gene with the elements which allow its expression in vivo. The principles of gene therapy are known. One can use particular vectors, viral or non-viral, for example adenovirus, retrovirus, herpes virus or poxvirus. Most of the time, these vectors are used in defective forms which will serve as vehicles for the expression of TSAP with or without integration. The vectors can also be synthetic, that is to say mimic viral sequences, or else consist of DNA or naked RNA according to the technique developed in particular by the company VICAL. In most cases, it will be necessary to provide targeting elements ensuring expression of specific tissues or organs, in fact, it is not possible to envisage activating an uncontrolled apoptosis phenomenon.

The present invention therefore relates to all of the vectors described above.

The present invention also relates to cells transformed with an expression vector as described above as well as the protein obtainable by culturing transformed cells.

Expression systems for producing proteins can be either eukaryotic systems such as the foregoing vectors or prokaryotic systems in bacteria cells.

One of the advantages of the present invention is that it has demonstrated the involvement of several genes in apoptosis; thus, the overexpression of one of the genes by gene therapy may, for some of them, lead to apoptosis only the cells in which other deregulated genes are already expressed, that is to say malignant cells.

The present invention also relates, as a medicament, to a compound ensuring the cellular expression of at least one of the preceding nucleotide sequences when it is induced during apoptosis and / or tumor suppression, in particular TSAP 9 genes to TSAP 22, or on the contrary ensuring the inhibition of cellular expression of at least one cell sequence as described above when it is inhibited during apoptosis and / or tumor suppression, in particular TSIP 3. It may for example be an activated nucleotide ensuring the blocking of the nucleotide sequence or else a monoclonal antibody raised against the protein (s) encoded by the nucleotide sequence.

Furthermore, it is possible to provide other approaches than gene therapy, in particular the use of nucleotide sequences in sense or antisense strategy, that is to say which can block the expression of TSIP or, on the contrary, acting by upstream, promoting the expression of TSAP.

It is also possible to provide a direct replacement strategy by providing proteins corresponding to TSAP or inhibitory antibodies. corresponding to TSIP.

Finally, it is possible to provide for the use of non-protein molecules whose activity will be to activate TSAP or mimic the action of its expression product or else to inhibit TSIP or else to block the action of its expression product.

These products can be easily tested on the modified cells which are described in the examples by introducing the products to be tested into cell culture and by detecting the appearance of the apoptotic phenomenon. In DNA, RNA or protein strategies, the products are of course developed according to the sequences which are described.

The present invention relates in particular to the use of the above drugs as an anti-cancer agent.

However, the product of the TSAP 9 to 22 and TSLP 3 genes is also useful as an antiviral agent, as will appear on reading the example. The present invention therefore also relates to the use of the above drugs as an antiviral agent.

In addition, the present invention relates, as a diagnostic agent for determining the predisposition to cancer, all or part of the sequences according to the invention to be used as a nucleotide probe or as an amplification primer, but also as a diagnostic agent for determining the predisposition to cancer an antigen corresponding to all or part of the proteins encoded by the sequence according to the invention or the corresponding antibodies, optionally after culture.

The diagnostic methods are known, they can be, for example, techniques of microsequencing of the variable parts after isolation and possible amplification, or detection methods of the RFLP type, or simple amplification in particular. Differential techniques can, in particular, make it possible to highlight the difference between normal and abnormal TSAP (or TS P). The invention also relates to models implementing the above sequences.

Furthermore, it should be emphasized that the inventors have evidence, by extension of the sequences in accordance with the invention initially highlighted, of the homologies presented by the said extended sequences with sequences corresponding to known proteins.

More particularly, in addition to the homology of TSAP 9 with a mouse chaperonin containing the TCP-1 gene (9), the inventors have found a strong homology which TSAP 13 has with the p40.5 subunit of the human proteasome

(10, 11) and a strong homology presented by TSAP 21 with syntaxin 11 belonging to the group of proteins SNARE (12).

Chaperonins are involved in the folding process and the assembly of proteins in the eukaryotic cytosol. They are suspected of slowing down this folding by trapping intermediaries who would otherwise aggregate. Among the proteins on which chaperonin containing the TCP-1 gene homologous to TSAP 9 would act, mention may be made of actin, tubulin and the capsid protein of the hepatitis B virus. The proteasome, like the ubiquitin, is the main component of the major proteolytic system responsible for the breakdown of many intracellular proteins, including aberrant proteins resulting from mutations or environmental stress. The p40.5 subunit of the human proteasome 26S has recently been demonstrated, as well as its counterpart in the yeast Nas7p. In humans, the mRNA corresponding to the above subunit is more particularly expressed in the pancreas, the placenta, the testes, the heart and the skeletal muscle. It also appears that yeast cells deficient in Nas7p are particularly sensitive to heat stress. This helps to suggest that the function of the 26S proteasome is degraded during heat stress.

SNARE proteins (Soluble N-ethylmaleimide-sensitiye factor-attachment protein receptor) are proteins whose differential expression and associations are involved in the organization of the membrane compartments of cells. These proteins are specifically localized in the region of the Golgi apparatus, endosomes and lysosomes, which suggests that they play a role in regulating membrane exchanges from these organelles. More particularly, syntaxin 11 would be localized in the post-Golgi region.

It would be interesting to be able to determine whether the molecular pathways in which the sequences in accordance with the invention are involved have common points with the molecular pathways in which the above proteins are involved, which would make it possible to envisage new modes of action on the above sequences for therapeutic or diagnostic purposes, for example.

Figure 1 shows the extended TSAP 13 sequence (SEQ ED No. 5). The underlined part corresponds to the sequence as originally updated by the inventors. The bold characters correspond to the sequence showing 100% homology with the p40.5 subunit of the human 26S proteasome.

Figure 2 shows the extended TSAP 21 sequence (SEQ ID No. 13). The underlined part corresponds to the sequence as originally updated by the inventors. Bold characters correspond to the sequence showing 100% homology with syntaxin 11 of the SNARE protein group

Other characteristics of the invention will appear on reading the example below.

MATERIALS AND METHODS Cell cultures

K562, KS cells. KS2 and KS3 were used as models. The K562 line is a tumor line, derived from a chronic erythromyeloid type leukemia. It is characterized in particular by a Philadelphia chromosome which contains the translocation (9,22), where there is a rearrangement of the bcr gene with the proto-oncogene abl. This line also has an abnormal karyotype and overexpresses the oncogenes myc and pim-1. These lines are described in reference A. Telerman et al. : A model for tumor suppression using H-1 parvovirus, Proc. Natl. Acad. Sci. USA, Vol. 90, pp. 8702-8706, September 1993. In summary, a K562 monoclone was infected with the parvovirus H-1.

This infection caused a massive death in cell culture. After maintaining this culture for a period of two months, the KS clone was isolated. The same experiment carried out a second time provided, after three months of incubation, the clones KS2 and KS3.

Using the same approach, the inventors derived from a population of malignant cells U937 the lines US3 and US4 which are resistant to parvovirus H-1 and which exhibit a suppression of the malignant phenotype. These lines are described in reference (7).

Ml myeloid leukemia cells and Ml cells were stably transfected with a temperature-sensitive mutant val 135 p53

(LTR6). These cells are cultured on RPMI 1640 medium with 10% FCS at 5% of

CO ₂ at 37 ° C (3). For the modification of the temperature, the cultures are placed in a second incubator at 32 ° C.

Line U937 transfected with p21 ^WAF1 : the complete coding part of the cDNA of the p21 ^WAF1 gene was cloned into the vector pBK-RSV (Stratagene, La JoUa, California). 3.5 million U937 cells were transfected with 20 micrograms of DNA / 30 micrograms Lipofectin (Life Technologies).

The stable transfectants were selected using 1.5 mg / ml of

G418 (Sigma). The characteristics of this line describe in particular a suppression of the malignant phenotype. Line U937 transfected with TSIP2 (PSI) in the antisense position: the complete coding part of the cDNA of the TSIP2 gene (PSI) was cloned in the antisense position in the vector pBK-RSV (Stratagene, La Jolla, California). 3 million cells

U937 were transfected with 20 micrograms of DNA / 30 micrograms

Lipofectin (Life Technologies). The stable transfectants were selected using 1.5 mg / ml of

G418 (Sigma). The characteristics of this line, describing in particular a slowdown in growth, activation of apoptosis and suppression of the malignant phenotype, have been described in reference (8).

Line U937 transfected with TSAP3 (ΗUMSIAH): the complete coding part of the cDNA of the TSAP3 gene has been cloned into the vector pBK-RSV

(Stratagene, La Jolla, California). 3 million U937 cells were transfected with 20 micrograms of DNA / 30 micrograms Lipofectin (Life Technologies). The stable transfectants were selected using 1.5 mg / ml of G418 (Sigma). The characteristics of this line include in particular an activation of apoptosis and a suppression of the malignant phenotype.

Study of differential cDNAs

To carry out the tests under standard experimental conditions and to obtain total reproducibility of the results, the following modifications to the original protocol (1) were made:

PolyA + mRNA is still used twice purified on an oligodT column using Fast Track (Invitrogen, San Diego CA). After reverse transcription (M-MLV Reverse Transcriptase, Gibco BRL) on 0.05 μg of polyA + using 20 μM of each of the dNTPs (Boehringer-Mannheim), no added dNTPs are added to the final PCR mixture. A “hot start” at 94 ° C for 5 minutes is carried out before the PCR (GeneAmp PCR System 9600 Perkin Elmer Cetus). The samples are quickly cooled on ice water. A touch down (2) of 10 cycles of 50 ° C to 40 ° C is carried out (94 ° C 30 seconds - 50 ° C 1 minute - 72 ° C 30 seconds), followed by 35 cycles (94 ° C 30 seconds - 40 ° C 1 minute - 72 ° C 30 seconds) and a final extension of 5 minutes at 72 ° C. PCR products are separated on 6% non-denaturing polyacrylamide gels (4). The gels are exposed without drying. Each differential presentation is performed by comparing M1S6 and LTR6 at 37 ° C and after 4 hours of incubation of the two cell lines at 32 ° C.

The differential presentation procedure is repeated in 3 different experiments to confirm perfect reproducibility. The differentially expressed bands are cut from the gel, eluted and re-amplified (1). PCR products are subcloned using the TA-cloning system (Invitrogen, San Diego CA) following the directions provided.

For each ligation reaction, 10 recombinant clones are sequenced using the ABI automatic system.

RNA extraction, analyzes and Northern blots probes Total RNA is extracted with Trizol (Life Technologies). The polyl + RNAs are prepared using the OligotexdT kit (Qjagen, CA). 30 μg of total RNA or 2 μg of polyA + RNA are separated on 1% agarose 1 x MOPS / 2% formaldehyde gel, transferred to nylon membrane (Hybond N +, Appligène, France) as described above ( 5). The Northern blots are hybridized with probes labeled with P ³² on the TSAP and TSEP inserts and washed as described previously (5). To verify the induction of wild p53 function, the Northern blots are hybridized with a cyclin G probe (6). As a control for the quantity of mRNA loaded, the bots are hybridized with a ^" GAPDH probe. Different Northern blots (Clontech CA) are used under identical conditions and hybridized for control with a β-actin probe. The Northern blots are exposed for 10 days to - 80 ° C.

Example 1 The aim sought is to characterize the molecular pathways which lead to the suppression of cancer.

In order to develop a model, the following hypothesis was made: if it were possible to select, from a tumor which is sensitive to the cytopathic effect of parvovirus Hl, the cells which were resistant, this resistance could be due to a change in their malignant phenotype. This could be demonstrated for the KS cells selected from the K562 erythroid leukemia cells. Unlike the parental line K562, the KS, KS2 and KS3 clones are resistant to the cytopathic effect of the parvovirus H-1. In addition, the KS, KS2 and KS3 cells have a reduction in their tumorigenicity by 90%, while cultivated in "soft agar", these same KS lines have a reduction in their tumorigenicity in vivo when injected into Scid immunosuppressed mice - Scid. At the molecular level, it was noted that this suppression of the malignant phenotype went hand in hand with a re-expression of the suppressor gene p53.

15 cDNAs differentially expressed between K562 and KS cells were isolated. TSAP 9 is homologous to chaperonins.

Table 1 brings together the characterized molecules, showing the primers as well as the sizes of the mRNAs detected by Northern blot. Of these 15 molecules, all are induced in KS cells, except TSIP 3, the expression of which is inhibited during the suppression of the malignant phenotype.

In transfection experiments, it has also been demonstrated that resistance to the cytopathic effect of parvovirus H1 goes hand in hand with intact function of the p53 gene and that cells transfected with p53 mutants become sensitive to the cytopathic effect of parvovirus. Hl.

The 15 molecules that we isolated therefore encode genes whose overexpression (TSAP 9 - TSAP 22) or inhibition (TSIP 3) is associated not only with the suppression of cancer but also with resistance to the parvovirus H-1. These genes therefore code for molecules that are part of the molecular pathways for cancer suppression and are potential suppressor genes.

In order to better define the p53 / p21 activation pathways, the inventors studied:

- activation of these TSAP / inhibition of TSIP in the thermosensitive p53 model developed in Moshe Oren,

- activation of these TSAP / inhibition of TSIP in the model where the U937 cells are transfected with the p21 gene,

- activation of new TSAP / inhibition of TSIP in the model where U937 cells are transfected with the TSAP3 gene, and - activation of these new TSAP TSIP in the model where cells

U937 are transfected with the TSIP2 gene (PSI) in the antisense position.

Table 1 below reports the results of differential expressions analyzed by Northern blot of the various probes (TSAP9-

TSAP22, TSEP3) of the K562 / KS model as well as of the other U937 / US3-US4 models, that is to say in a tumor suppression model in which the p21 gene is activated by the independent p53 pathway. These cDNAs are therefore activated in two different cellular systems for tumor suppression (the erythroleukemia model K562 / KS and the myelomonocytic model U937 / US).

From this table, it can be seen that in most of the cases, the genes expressed differently in the K562 / KS model are also differentially expressed in the U937 US3-US4 model. There is therefore a molecular machinery for tumor suppression common to different types of Cancer. This conclusion is also valid for the Ml LTR-6 model. It should be noted in the latter case that the absence of signals in certain TSAP-TSIPs is probably due to the fact that the experiments were carried out in two heterologous systems (human probes on mouse RNA).

TABLE 1

* the numbers and the sequences of the primers in 5 ′ correspond to those reported by Bauer et al.

0 HUMKGIDD human mRNA for ORF (human equivalent of mouse chaperonin containing the TCP-1 gene (t-polypeptide complex).

⁰ Proteasome p40.5 subunit (Nas7p)

^Δ Syntaxine 11 SNARE TABLE 1 (continued)

EXP DEFF. = Differential expression

NO EXPR. DEFF. = No differential expression Table 2 below summarizes the differential expression of certain TSAP and TSIP clones in different lines of transfectants.

It emerges from this table that, in the majority of cases, the p21 transfectants or TSAP3 transfectants or antisense-TSIP2 transfectants are capable of activating the molecular machinery for tumor suppression common to the U937 / US and K562 / KS systems.

TABLE 2

Table 3 below summarizes the differential expression characteristics of the cDNA clones by Northern blot.

TABLE 3

D: Differential expression N: No differential expression

0: Chaperonin containing the TCP1 ° gene: Subunit p40.5 of the proteasome (Nas 7p) ^Δ : Syntaxine 11 SNARE REFERENCES

(1) Liang P. & Pardee A.B. (1992) Science, 257, 967-971

(2) Don R.H., Cox P.T., Wainwright B.J., Baker K. & Mattick J.S. (1991) Nucl. . Acids Res., 19, 4008

(3) Yonish-Rouach E., Resnitzky D., Lotem J., Sachs L., Kimchi A. & Oren M. (1991) Nature 352, 345-347

(4) Bauer D., Muller H., Reich J., Riedet H., Ahrenkiel V., Warthoe P. & Strauss M. (1993) Nucl. Acids Res. 21, 4272-4280 (5) Sambrook J., Fritsch E.F. & Maniatis T. (1989) Molecular Cloning: a laboratory manual

(6) Okamoto K. & Beach D. (1994) EMBO J., 13, 4816-4822

(7) NemaniM., Linares-Cruz G., Bruzzoni-Giovanelli H., Roperch J.-P., Tuynder M., Bougueleret L., Cherif D., Medhioub M., Pasturaud P., Alvaro V., Der Sarkissan H., Cazes L., Le Paslier D., Le Gall L, Israeli D., Dausset

J., Sigaux F., Chumakov L, Oren M., Calvo F., Amson R. B., Cohen D. and Telerman A., Activation of the human homologue of the Drosophila sina gene in apoptosis and tumor suppression, Proc. Nati. Acad. Sci. USA (1996) 93, 9039-9057 (8) Roperch J.-P., Alvaro V., Prieur S., Tuynder M., Nemani M., Lethrosne F., Piouffre L., Gendron MG., Israeli D. , Dausset J., Oren M., Amson R., and Telerman A., Inhibition of presenilin 1 expression is promoted by p53 and p21 WAF-1 and results in apoptosis and tumor suppression, Nature Medicine (1998) 4, 835-838 . (9) Kubota et al., 1995, Eur. J. Biochem. 230, 3-16,

(10) Hori et al., 1998, Gene, 216, 113-122,

(11) Baumeister et al., 1998, Cell, Vol. 92, 367-380,

(12) Advani et al., 1998, The Journal of Biological Chemistry, Vol. 273, No. 17, 10317-10324.

Claims

1) Nucleotide sequence corresponding to a gene comprising: (a) a sequence according to one of IND.SEQ 1 to 15 or an equivalent gene which comprises:

(b) a sequence hybridizing with one of the sequences according to (a),

(c) a sequence having at least 80% homology with (a) or (b), or (d) a sequence characterized in that the cellular expression of the gene is induced or inhibited during apoptosis and / or tumor suppression.

2) Sequence according to claim 1, characterized in that apoptosis and or tumor suppression is (are) induced by p53 and or p21.

3) Sequence according to one of claims 1 and 2, characterized in that it is chosen from TSAP 9 to TSAP 22 or an equivalent gene. 4) Sequence according to claim 3, characterized in that apoptosis and / or tumor suppression is (are) induced by p53 and / or p21.

5) Sequence according to claim 1, characterized in that it corresponds to the TSIP 3 gene or an equivalent gene.

6) Sequence according to claim 5, characterized in that the cellular expression of the gene is inhibited during apoptosis and / or tumor suppression.

7) Sequence according to one of claims 1 to 6, characterized in that the cellular expression of the gene is activated by at least one of the transfectants chosen from the group comprising the p21 transfectants, the TSAP3 transfectants and the TSLP2 antisense transfectants .

8) Cellular expression vector of a sequence according to one of claims 1 to 7.

9) Expression vector according to claim 8, characterized in that it is a viral vector. 10) Vector according to claim 9, characterized in that it is an adenovirus, a retrovirus, a herpes virus or a poxvirus.

1 1) Vector according to claim S, characterized in that it is a naked nucleic acid vector.

12) Vector according to one of claims 8 to 11, characterized in that it comprises a sequence ensuring targeting and / or specific tissue expression.

13) Cell transformed with an expression vector according to one of claims 8 to 12.

14) Protein obtainable by cell culture transformed according to claim 13 and coded by the sequence according to one of claims 1 to 7.

15) As a medicament, a vector according to one of claims 8 to 12 or a protein according to claim 14.

16) As a medicament, a compound ensuring the cellular expression of at least one of the nucleotide sequences according to one of claims 1 to 3 or of their products.

17) As a medicament according to claim 15, a nucleotide vector ensuring the cellular expression of said sequence.

18) As a medicament, a compound ensuring the inhibition of cellular expression of at least one cellular gene according to one of claims 1, 5 to 7 or their products.

19) As a medicament according to claim 18, an activated nucleotide ensuring the blocking of the nucleotide sequence.

20) As a medicament according to claim 18, a monoclonal antibody raised against the protein or proteins encoded by the nucleotide sequence.

21) As a medicament intended for the treatment of cancer, a medicament according to one of claims 15 to 20. 22) As an antiviral agent, a medicament according to one of claims 15 to 20.

23) As a diagnostic agent, in particular for determining the predisposition and monitoring of cancers, all or part of the sequences according to one of claims 1 to 7 to be used as a nucleotide probe or as an amplification primer.

24) As a diagnostic agent, in particular for determining the predisposition and the following of cancers, an antigen corresponding to all or part of the proteins encoded by the sequence according to one of claims 1 to 7 or the corresponding antibodies.

25) A model for the detection of anti-cancer, and / or antiviral drug of the cells according to claim 13.