Mutations of the ATM and NBS1 genes are responsible for the inherited Ataxia-Telangiectasia and Nijmegen Breakage Syndrome, both of which are associated with a predisposition to cancer. A related syndrome, the Ataxia-Telangiectasia-like disorder, is due to mutations of the MRE11 gene. However, the role of this gene in cancer development has not been established. Here we describe an often homozygous mutation of the poly(T)11 repeat within human MRE11 intron 4 that leads to aberrant splicing, impairment of wild-type MRE11 expression and generation of a truncated protein. This mutation is present in mismatch repair-deficient, but not proficient, colorectal cancer cell lines and primary tumours and is associated with reduced expression of the MRE11-NBS1-RAD50 complex, an impaired S-phase checkpoint and abrogation of MRE11 and NBS1 ionizing radiation-induced nuclear foci. Our findings identify MRE11 as a novel and major target for inactivation in mismatch repair-defective cells and suggest its impairment may contribute to the development of colorectal cancer.
Our results suggest that besides energy deficiency, mitochondrial biogenesis per se is a maladaptive response in MIC and, possibly, in other metabolic cardiomyopathies.
The abnormal activation of the epidermal growth factor (EGF) pathway is one of the most common findings in human cancer, and a number of molecular devices of laboratory and clinical relevance have been designed to block this transduction pathway. Because of the large number of cellular events that might be regulated through the activation of the four EGF receptor family members, it is possible that screening methodologies for the identification of new molecular targets working downstream of these pathways may provide new tools for cancer diagnosis and potentially prevention and therapy. In searching for EGF target genes, we have identified ERG1.2, the mouse homolog of the solid tumor-associated gene STAG1. Both in humans and in mice, it belongs to a new gene family that can give origin to several protein isoforms through alternative splicing and/or multiple translation starts. Sequence analysis and experimental data suggest that ERG1.2 is likely to function as a membrane-bound protein interacting with downstream signaling molecules through WW- and SH3-binding domains. ERG1.2 is a cell-cycle-regulated gene, and both ERG1.2 and STAG1 are induced by EGF and other growth factors at the transcript and protein levels. Finally, we have demonstrated that, besides prostate cancer and renal cell carcinoma, STAG1 was also overexpressed in breast and ovarian cancer cell lines and in breast primary tumors. Although in most cases STAG1 overexpression is probably due to the abnormal activation of the EGF pathway, we have also demonstrated genetic amplification and rearrangement of its locus in one breast cancer cell line and one primary ovarian cancer, suggesting that STAG1 might be a direct molecular target in the carcinogenetic process. Thus its overexpression might be regarded not only as a tumor marker but also as a potentially pathogenetic event.
Epididymal sperm cells, incubated with plasmid DNA, showed a spontaneous tendency to interact with the exogenous nucleic acid. We have investigated the molecular basis of such interaction. Exogenous DNA is taken up by sperm cells over a 15- to 20-min period and is specifically localized on the nuclear area of the sperm head. DNA was reversibly bound to spermatozoa since it can be competed out by excess of cold competitor DNA or by other polyanions as heparin and dextran sulphate. By contrast, poly-L-lysine, a polycation, favours the uptake. DNA molecules of large size (7 kb) were preferentially taken up as compared to smaller ones (150-750 bp). Acidic proteins were also taken up and concentrated, as for DNA, at the nuclear level. These data strongly suggested that ionic interactions may occur between foreign molecules and a substrate located in the sperm head. On the basis of Southwestern analysis, a sperm head protein(s) of 30-35 KD is identified as potential substrate for exogenous DNA binding. Moreover, we have found that seminal plasma contains factor(s) which abolish sperm permeability, exerting a powerful inhibitor effect on DNA uptake. The presence of a specific binding protein for the DNA and of a factor inhibiting such interaction support the existence of a mechanism controlling, through specific factors, the sperm-DNA interaction.
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