Impaired genomic stability and increased oxidative stress exacerbate different features of Ataxia-telangiectasia.

Ataxia-telangiectasia (A-T) is a multisystem, cancer-predisposing genetic disorder caused by deficiency of the ATM protein. To dissect the A-T phenotype, we augmented specific features of the human disease by generating mouse strains that combine Atm deficiency with dysfunction of other proteins. Increasing oxidative stress by combining deficiencies in Atm and superoxide dismutase 1 (Sod1) exacerbated growth retardation and markedly reduced the mean survival time following ionizing radiation. In contrast, increasing genomic instability by combining deficiencies of Atm and the mismatch repair protein Mlh1 caused a moderate increase in radiation sensitivity and dramatic increase in aggressive lymphomas, compared with thes Atm-/- single knockout. Remarkably, Atm, Mlh1 or Mlh1/Atm single or double heterozygosity did not significantly affect the life span of the various genotypes. Mlh1/Atm double null tumors were polyclonal, whereas the tumors in other genotypes were mono- or oligoclonal, demonstrating the high predisposition of thymocytes with this genotype to become malignant. Chromosomal aberrations in the tumors were localized mainly in chromosomes 12 and 15. The genomic region on chromosome 15, which contains the gene for the c-Myc oncoprotein, was commonly amplified, and elevated levels of the c-Myc protein were subsequently observed in the tumors. Our data suggest that impaired genomic instability is an important contributing factor to cancer predisposition in A-T, whereas oxidative stress is more important in the radiation sensitivity and growth retardation facets of this disease.

Cadherins expression during gamete maturation and fertilization in the rat.

A role for adhesion molecules in gamete fusion, preceding fertilization, has been previously suggested. We investigated the presence of cadherins, Ca(2+) dependent cell-cell adhesion molecules, in rat oocytes and spermatozoa using an anti-pan-cadherin antibody and specific antibodies against the 3 classical cadherins: E- (epithelial), P- (placental), and N- (neural) cadherins. Electrophoretic separation was performed on samples of lysed oocytes of different stages: germinal vesicle oocytes, metaphase II eggs, newly fertilized and 2-cell embryos, as well as spermatozoa from testes, caput and cauda epididymis and ejaculate. Localization of cadherins was determined on intact, gametes by immunocytochemistry, using confocal microscopy. Immunoblotting with the pan-cadherin antibody revealed a major band of approximately 120 kD in all oocyte and sperm extracts. Oocytes presented E-cadherin at appropriate molecular weight but N-cadherin only as a specific 40 kD band. In sperm lysate, at all stages, both E- and N-cadherin were demonstrated as major protein bands but a series of lower molecular weight proteins (that may represent protein degradation) were also detected. Immunohistochemical evaluation showed that E- and N-cadherins are already present on the plasma membrane of immature unfertilized oocytes, although their concentration increases after fertilization in early cleavage stage embryos. Cadherin localization on spermatozoa changed during maturation from a dispersed pattern over the entire head plasma membrane of testicular spermatozoa to a restricted equatorial and post-acrosomal plasma membrane staining in ejaculated spermatozoa. These findings suggest a specific cadherin organization at the fusogenic domains of both gametes.