Chimeric tumor suppressor 1, a p53-derived chimeric tumor suppressor gene, kills p53 mutant and p53 wild-type glioma cells in synergy with irradiation and CD95 ligand.

Adenoviral chimeric tumor suppressor 1 (CTS1) gene transfer was evaluated as a novel approach of somatic gene therapy for malignant glioma. CTS1 is an artificial p53-based gene designed to resist various pathways of p53 inactivation. Here, we report that an adenovirus encoding CTS1 (Ad-CTS1) induces growth arrest and loss of viability in all glioma cell lines examined, in the absence of specific cell cycle changes. In contrast, an adenovirus encoding wild-type p53 (Ad-p53) does not consistently induce apoptosis in the same cell lines. Electron microscopic analysis of Ad-CTS1-infected glioma cells reveals complex cytoplasmic pathology and delayed apoptotic changes. Ad-CTS1 induces prominent activation of various p53 target genes, including p21 and MDM-2, but has no relevant effects on BCL-2 family protein expression. Although Ad-CTS1 strongly enhances CD95 expression at the cell surface, endogenous CD95/CD95 ligand interactions do not mediate CTS1-induced cell death. This is because Ad-CTS1 promotes neither caspase activation nor mitochondrial cytochrome c release and because the caspase inhibitors, z-val-Ala-DL-Asp-fluoromethylketone (zVAD)-fmk or z-Ile-Glu-Thr-Asp- fluoromethylketone (z-IETD)-fmk, do not block CTS1-induced cell death. Ad-CTS1 synergizes with radiotherapy and CD95 ligand in killing glioma cells. In summary, Ad-CTS1 induces an unusual type of cell death that appears to be independent of BCL-2 family proteins, cytochrome c release, and caspases. CTS1 gene transfer is a promising strategy of somatic gene therapy for malignant glioma.

Human fibulin-4: analysis of its biosynthetic processing and mRNA expression in normal and tumour tissues.

Here, we report the identification of a human orthologue of fibulin-4, along with analysis of its biosynthetic processing and mRNA expression levels in normal and tumour tissues. Comparative sequence analysis of fibulin-4 cDNAs revealed apparent polymorphisms in the signal sequence that could account for previously reported inefficient secretion in fibulin-4 transfectants. In vitro translation of fibulin-4 mRNA revealed the presence of full-length and truncated polypeptides, the latter apparently generated from an alternative translation initiation site. Since this polypeptide failed to incorporate into endoplasmic reticulum membrane preparations, it was concluded that it lacked a signal sequence and thus could represent an intracellular form of fibulin-4. Using fluorescence in situ hybridisation analysis, the human fibulin-4 gene was localised to chromosome 11q13, this region being syntenic to portions of mouse chromosomes 7 and 19. Considering the fact that translocations, amplifications and other rearrangements of the 11q13 region are associated with a variety of human cancers, the expression of human fibulin-4 was evaluated in a series of colon tumours. Reverse transcription-polymerase chain reaction analysis of RNA from paired human colon tumour and adjacent normal tissue biopsies showed that a significant proportion of tumours had approximately 2-7-fold increases in the level of fibulin-4 mRNA expression. Taken together, results reported here suggest that an intracellular form of fibulin-4 protein may exist and that dysregulated expression of the fibulin-4 gene is associated with human colon tumourigenesis.

MBP1: a novel mutant p53-specific protein partner with oncogenic properties.

Using a yeast two-hybrid screening strategy with a common tumour-derived p53 mutant as bait, we identified several mutant p53-interacting partners including the known proteins wild-type (wt) p53, hUBC9 and GBP/PIAS1. In addition, a novel protein partner was identified which we have termed MBP1, for Mutant p53-Binding Protein 1. MBP1 is a new member of the emerging fibulin gene family, which currently comprises fibulin-1, fibulin-2 and S1-5. Expression of MBP1 mRNA is differentially regulated both temporally during development of the mouse embryo and in a tissue-specific manner within the adult. Specific interaction between MBP1 and mutant p53 was illustrated by both two-hybrid analysis in yeast and co-immunoprecipitation in mammalian cells. MBP1 displayed the following order of binding specificity towards different p53 forms: H175 > G281 > H273 > or = W248>wt p53. Thus, MBP1 appears to bind preferentially to p53 mutants of the 'structural' rather than 'contact' class, reflecting a potential bias towards those mutants having a significant alteration in conformation from that assumed by wt p53. We propose that MBP1 is the product of a candidate oncogene as rates of both neoplastic transformation and tumour cell growth were shown to be significantly enhanced when the protein is ectopically overexpressed. Furthermore, MBP1 may play a role in determining if a 'gain of function' effect is seen with certain p53 mutants.

Definition of a p53 transactivation function-deficient mutant and characterization of two independent p53 transactivation subdomains.

The wild-type protein product of the p53 tumor suppressor gene can activate transcription of genes which are involved in mediating either growth arrest, e.g. WAF1 or apoptotis, e.g. BAX and PICG3. Additionally, p53 can repress a variety of promoters, which, in turn, may be responsible for the functional activities exhibited by p53. This study shows that the Q22, S23 double mutation, which is known to inactivate a p53 transactivation subdomain located within the initial 40 residues of the protein, while abrogating transactivation from the WAF1 promoter, only attenuates apoptosis triggering, transactivation from other p53-responsive promoters and repression of promoters by p53. The Q53, S54 double mutation, which inactivates another p53 transactivation subdomain situated between amino acids 43 and 73 results in attenuation of all of the aforementioned p53 activities. In contrast to the Q22, S23 double mutation, this latter mutation set does not alter mdm-2-mediated inhibition and degradation of p53. Finally, mutation of all four residues results in complete abrogation of every p53 activity mentioned above.

Restoration of transcriptional activity of p53 mutants in human tumour cells by intracellular expression of anti-p53 single chain Fv fragments.

We report here the production and the properties of single chain Fv fragments (scFvs) derived from the anti-p53 monoclonal antibodies PAb421 and 11D3. 11D3 is a newly generated monoclonal antibody which exhibits properties very comparable to those of PAb421. The scFvs PAb421 and 11D3 are able to stably associate with p53 and to restore the DNA binding activity of some p53 mutants in vitro. When expressed in p53 -/-human tumour cells, the scFv421 is essentially localized in the cytoplasm in the absence of p53, and in the nucleus when exogenous p53 is present. Thus, p53 is also able to stably associate with an anti-p53 scFv in cells. Cotransfection of p53 -/- human tumour cells with expression vectors encoding the His273 p53 mutant and either scFv leads to restoration of the p53 mutant deficient transcriptional activity. These data demonstrate that, in human tumour cells, these scFvs are able to restore a function essential for the tumour suppressor activity of p53 and may represent a novel class of molecules for p53-based cancer therapy.

A tumor specific single chain antibody dependent gene expression system.

The design of conditional gene expression systems restricted to given tissues or cellular types is an important issue of gene therapy. Systems based on the targeting of molecules characteristic of the pathological state of tissues would be of interest. We have developed a synthetic transcription factor by fusing a single chain antibody (scFv) directed against p53 with the bacterial tetracycline repressor as a DNA binding domain. This hybrid protein binds to p53 and can interact with a synthetic promoter containing tetracycline-operator sequences. Gene expression can now be specifically achieved in tumor cells harboring an endogenous mutant p53 but not in a wild-type p53 containing tumor cell line or in a non-transformed cell line. Thus, a functional transactivator centered on single chain antibodies can be expressed intracellularly and induce gene expression in a scFv-mediated specific manner. This novel class of transcriptional transactivators could be referred as 'trabodies' for transcription-activating-antibodies. The trabodies technology could be useful to any cell type in which a disease related protein could be the target of specific antibodies.

The requirement for the p53 proline-rich functional domain for mediation of apoptosis is correlated with specific PIG3 gene transactivation and with transcriptional repression.

Wild-type p53 is a tumor suppressor gene which can activate or repress transcription, as well as induce apoptosis. The human p53 proline-rich domain localized between amino acids 64 and 92 has been reported to be necessary for efficient growth suppression. This study shows that this property mainly results from impaired apoptotic activity. Although deletion of the proline-rich domain does not affect transactivation of several promoters, such as WAF1, MDM2 and BAX, it does alter transcriptional repression, reactive oxygen species production and sequence-specific transactivation of the PIG3 gene, and these are activities which affect apoptosis. Whereas gel retardation assays revealed that this domain did not alter in vitro the specific binding to the p53-responsive element of PIG3, this domain plays a critical role in transactivation from a synthetic promoter containing this element. To explain this discrepancy, evidence is given for a proline-rich domain-mediated cellular activation of p53 DNA binding.

CTS1: a p53-derived chimeric tumor suppressor gene with enhanced in vitro apoptotic properties.

The clinical potential of the p53 tumor suppressor gene is being evaluated currently for gene therapy of cancer. We have built a variant of wild-type p53, chimeric tumor suppressor 1 (CTS1), in which we have replaced the domains that mediate its inactivation. CTS1 presents some very interesting properties: (a) enhanced transcriptional activity; (b) resistance to the inactivation by oncogenic forms of p53; (c) resistance to the inactivation by MDM2; (d) lower sensitivity to E6-induced degradation; (e) ability to suppress cell growth; and (f ) faster induction of apoptosis. Thus, CTS1 is an improved tumor suppressor and an alternative for the treatment of wild-type p53-resistant human tumors by gene therapy.