Analysis of the relationships between ATM and the Rad54 paralogs involved in homologous recombination repair.

Ataxia-telangiectasia is a pleiotropic genomic instability disorder caused by lack or inactivation of the ATM protein kinase and characterized by progressive ataxia, immunodeficiency, ionizing radiation sensitivity and cancer predisposition. ATM mobilizes the cellular response to DNA double strand breaks by phosphorylating key players in this response. Double strand breaks are repaired by either nonhomologous end-joining or homologous recombination (HR) in which the Rad54 and Rad54B paralogs function. Here, we investigated the functional relationships between Atm and the Rad54 proteins by constructing compound genotypes in mice. Mouse strains were generated that combined inactivation of the Atm, Rad54 and Rad54B genes. All mutant genotypes were viable, but obtained at sub-Mendelian ratios. Double mutants for Atm and each Rad54 paralog exhibited reduced body weight and shorter lifespan, but no distinct neurological phenotype. Concomitant inactivation of ATM and Rad54 did not increase IR sensitivity; however, the triple Atm/Rad54/Rad54B mutant exhibited a significant IR hypersensitivity compared to the other genotypes. Interestingly, Atm-/- animals also exhibited hypersensitivity to the crosslinking agent mitomycin C, which was increased by deficiency of either one of the Rad54 paralogs. Our results reveal a differential interaction of the ATM-mediated DNA damage response and Rad54 paralog-mediated HR depending on the DNA damaging agent that initiates the response.

Malfunctioning DNA damage response (DDR) leads to the degeneration of nigro-striatal pathway in mouse brain.

Pronounced neuropathology is a feature of ataxia-telangiectasia (A-T) and Nijmegen breakage syndrome (NBS), which are both genomic instability syndromes. The Nbs1 protein, which is defective in NBS, is a component of the Mre11/RAD50/NBS1 (MRN) complex. This complex plays a major role in the early phase of the cellular response to double strand breaks (DSBs) in the DNA. Among others, MRN is required for timely activation of the protein kinase ATM (A-T mutated), which is disrupted in patients with A-T. Earlier reports show that Atm-deficient mice exhibit severe degeneration of tyrosine hydroxylase (TH)-positive dopaminergic nigro-striatal neurons and their terminals in the striatum. This cell loss is accompanied by a large reduction in immunoreactivity for the dopamine transporter protein (DAT) in the striatum. To test whether Nbs1 inactivation also affects the integrity of the nigro-striatal pathway, we examined this pathway in a murine model with conditional inactivation of the Nbs1 gene in central nervous system (Nbs1-CNS-Δ). We report that this model has a reduction in TH-positive cells in the substantia nigra. This phenomenon was seen at very early age, while Atm-/- mice showed a progressive age-dependent reduction. Furthermore, we observed an age-dependent increase in the level of TH in the striatum of Atm-/- and Nbs1-CNS-Δ mice. In addition to the altered expression of TH, we also found a reduction of DAT in the striatum of both Atm-/- and Nbs1-CNS-Δ mice at 60 days of age. Finally, microglial recruitment and alterations in the levels of various neurotrophic factors were also observed. These results indicate that malfunctioning DNA damage response severely affects the integrity of the nigro-striatal pathway and suggest a new neurodegenerative pathway in Parkinsonian syndromes.

Astrocyte dysfunction associated with cerebellar attrition in a Nijmegen breakage syndrome animal model.

Nijmegen breakage syndrome (NBS) is a genomic instability disorder caused by hypomorphic mutations in the Nbs1 gene. When Nbs1 is conditionally inactivated in the central nervous system of mice (Nbs1-CNS-Δ), they suffer from severe cerebellar atrophy, ataxia, and white matter damage. Here, we show that conditional inactivation of the murine Nbs1 gene has a profound effect on the integrity and the functionality of the glial cells, which suggests their crucial role in the pathogenesis of NBS. Interestingly, in Nbs1-CNS-Δ mice, the dramatic reduction in the numbers of Purkinje and granule cells was also linked to a reduction of microglial cells but not to astrocytes (GFAP+), suggesting an impairment in astrocytic functionality. Nbs1 levels were dramatically reduced in adult astrocyte isolated from Nbs1-CNS-Δ mice, suggesting a major role in cerebellar pathology. In order to investigate the effect of Nbs1 deletion on astrocyte activity, we investigated glutamine synthetase levels in astrocyte and discovered 40% reduction as compared to WT. Furthermore, we found a significant reduction in the secretion of neurotrophic factors, such as brain-derived neurotrophic factor and neurotrophin 3. Understanding the contribution of malfunctioning astrocytes to the etiology of NBS can elucidate a hitherto unknown aspect of this disorder.