Cell transformation by the middle T-antigen of polyoma virus.

The polyoma virus region expressed early in the lytic cycle encodes three proteins, or T-antigens, that together cause the infected cell to enter the cell cycle and so provide a suitable cellular environment for replication of the viral genome. Under some circumstances infection does not kill the cell, but the T-antigens are still produced, resulting in the cell becoming transformed and tumorigenic. Most of this transforming action is exerted by the middle T-antigen, which has the ability to convert established cell lines to an oncogenic state. Middle T is a membrane bound polypeptide that interacts with a number of the proteins used by tyrosine kinase associated receptors to stimulate mitogenesis, so MT can be considered as a permanently active analogue of a receptor. Through a defined series of interactions, MT assembles a large multi-protein complex at the cell membrane, consisting of MT, the core dimer of protein phosphatase 2A, an src-family tyrosine kinase, and via phosphotyrosines, ShcA, phosphatidylinositol (3') kinase, and phospholipase Cgamma-1. Tyrosine phosphorylation stimulates PI3K and PLCgamma-1 enzymatic activity, and on ShcA creates binding sites for Grb2 with its associated Sos1 and Gab1. This activates p21(ras), and hence, the MAP kinase cascade. Consequently, MT can be used as a model for studying cell transformation and growth factor receptor signalling pathways.

Immunohistochemical expression of p53 in breast carcinoma is associated with the intron 1 BglII polymorphism of the p53 gene.

Breast carcinoma is a public health problem worldwide. It is known that both genetic and environmental factors are important for breast carcinogenesis and that structural and/or functional alterations at p53 gene are commonly observed in breast tumors. In addition, polymorphisms of several genes in either their coding or non-coding sequences have been found related to cancer risk and/or clinicopathological characteristics of tumors. In this study we have evaluated the intron 1 BglII polymorphism of the p53 gene with a PCR-based approach in 117 cases of breast cancer and 102 healthy women and its association with the immunohistochemical expression of p53 in the tumors. The results showed that the presence of the polymorphism (allele 2) is highly associated with the tumor expression of p53 (p<0.0001) and that there is a trend for increased frequency of allele 2 in cases than in controls (p=0.2376). These data suggest that the germ-line variation in the intron 1 of the p53 gene could produce functional or structural changes of the protein that is reflected by its abnormal expression.

Genomic characterization of the human trkC gene.

The trkC gene encodes the high-affinity receptor for neurotrophin 3 and plays an important role in the regulation of the survival and differentiation of the mammalian nervous system and in heart development. Chromosomal rearrangements of trkC have been recently reported in congenital fibrosarcoma and it has been proposed that abnormal activation of this gene might be involved in tumor development. To facilitate the search for new mutations and rearrangements in the human trkC locus we have partially characterized its genomic organization by restriction mapping and have obtained the complete intron-exon structure. Our results show that human trkC consists of 20 exons, including two that encode the inserts present in the extracellular and tyrosine kinase domains, and another two that encode the carboxyl-terminal tail of the truncated TRKC isoform. Analysis of the 5' flanking region revealed the absence of TATA box, a very high content in C/G compatible with a CpG island and the presence of putative binding sites for the AP1, AP2, GC, ATF, BRN2, AML1 and Nkx2.5 transcription factors.