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ROLE OF TYROSYL-DNA PHOSPHODIESTERASE (TDP 1) ON REPAIR OF 3′-PHOSPHOGLYCOLATE (3′- PG) TERMINATED DNA DOUBLE-STRAND BREAKS (DSBS) AND IN RESPONSE TO OXIDATIVE STRESSZhou, Tong 29 November 2012 (has links)
DNA DSBs are most toxic to cells because they can lead to genomic rearrangements and even cell death. Most DSBs induced by ionizing radiation or radiomimetic drugs such as calicheamicin and bleomycin, bear 3′-phosphate or 3′- PG moieties that must be removed to allow subsequent gap filling and ligation. DSBs can be repaired by two main pathways: the homologous recombination (HR) pathway and the non-homologous end-joining (NHEJ) pathway, NHEJ is the primary repair pathway in mammalian cells. While HR repairs single strand breaks (SSBs) or DSBs accurately by using an undamaged copy of the sequence mostly at late S phase and G2 phase, the NHEJ pathway repairs DSBs without the requirement for sequence homology in a processing that may be error-free or error- prone and is most active at G1 phase. TDP1 is a DNA repair enzyme in both pathways, It associates with DNA SSB repair proteins XRCC1 and DNA ligase III and plays a role in processing of topoisomerase I- mediated SSBs. Our early results suggested that TDP1 also can remove protruding 3’- PG and other 3’ blocks from DSBs ends in vitro. A homozygous H493R mutation in the active site of TDP1 causes spinocerebellar ataxia with axonal neuropathy (SCAN1), a rare autosomal recessive genetic disease with neurological symptoms including peripheral neuropathy. DNA damage and misrepair can be determined by measuring the incidence of chromosomal aberrations such as rings, breaks, dicentrics, acentric fragments, and translocations in metaphase cells, and micronuclei in interphase cells. To assess the possible role of TDP1 in DSB repair in intact cells, the radiosensitivity of SCAN1 cells was determined by using a dose-fractionation method of irradiation. The data indicated that, when exposed to fractionated radiation doses, the SCAN1 cells were more sensitive than normal cells. Moreover, following treatment of cells with calicheamicin, SCAN1 cells showed a significantly higher incidence of dicentric chromosomes, acentric fragments, and micronuclei compared to normal cells, indicating that calicheamicin-induced DSBs were repaired less accurately and less efficiently, or more slowly in SCAN1 cells than in normal cells. All these results are consistent with a role for TDP1 in repair of 3’-PG DSBs in vivo. Oxidative stress is thought to induce replicative senescence and DNA damage in mouse embryo fibroblasts (MEFs). To determine the possible roles of oxidative stress on Tdp1-deficient MEFs, Tdp1-knockout MEFs and normal MEFs were cultured in 20% oxygen (atmospheric) and 3% (physiological) oxygen. The data from growth assays indicated that normal MEFs showed replicative senescence in 20% oxygen but not in 3% oxygen. Tdp1-knockout MEFs showed very poor growth compared to Tdp1 normal MEFs in both oxygen conditions, clearly suggesting an influence of repair of Tdp1 on oxidative stress induced DNA-DSBs in MEFs. Taken together, our results indicated that TDP1 is capable of removing protruding 3’-PG from DSB ends in intact cells. Moreover, DSBs induced by oxidative stress were repaired more slowly or inefficiently in MEFs when Tdp1 is absent, resulting in cell cycle arrest and poor cell growth.
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Nonhomologous end-joining: TDP1-mediated processing, ATM-mediated signalingHawkins, Amy 13 November 2009 (has links)
This thesis investigates two separate features of nonhomologous end-joining (NHEJ) DNA repair: end processing, and DNA repair kinase signaling. DNA end processing was investigated in a mouse model of hereditary spinocerebellar ataxia with axonal neuropathy (SCAN1), a congenital neurodegenerative disease. SCAN1 is caused by a homozygous H493R mutation in the active site of tyrosyl-DNA phosphodiesterase (TDP1). To address how the H493R mutation elicits the specific pathologies of SCAN1 and to further elucidate the role of TDP1 in processing DNA end modifications, we generated a Tdp1 knockout mouse and characterized their behavior and specific repair deficiencies in extracts of embryonic fibroblasts from these animals. While Tdp1(-/-) mice appear phenotypically normal, extracts from Tdp1(-/-) fibroblasts exhibited deficiencies in processing 3'-phosphotyrosyl single-strand breaks and 3'-phosphoglycolate (PG) double-strand breaks (DSBs). Supplementing Tdp1(-/-) extracts with H493R TDP1 partially restored processing of 3'-phosphotyrosyl single-strand breaks, but with evidence of persistent covalent adducts between TDP1 and DNA, consistent with a proposed intermediate-stabilization effect of the SCAN1 mutation. However, H493R TDP1 supplementation had no effect on PG termini on 3' overhangs of DSBs; these remained completely unprocessed. Altogether, these results suggest that for 3'-PG overhang lesions, the SCAN1 mutation confers loss of function, while for 3'-phosphotyrosyl lesions, the mutation uniquely stabilizes a reaction intermediate. Furthermore, there is evidence that TDP1 also localizes to mitochondria, and mitochondrial DNA damage should not be excluded from significantly contributing to SCAN1 pathology. The effect of ATM signaling on NHEJ was investigated via a novel vector that allows for inducing I-SceI-mediated DNA DSBs that can then be analyzed for NHEJ repair events by fluorescence- and PCR-based methods. Using highly specific DNA kinase inhibitors and the repair cassette, we showed that inhibiting ATM reduced NHEJ by 80% in a U87 glioma model. Analysis of the PCR products from the NHEJ repair vector by PsiI restriction cleavage allowed for assessment of the fidelity of the NHEJ repair: inhibiting ATM reduced high-fidelity NHEJ by 40%. Together, these results suggest that ATM is critical for NHEJ of I-SceI DSBs and for high-fidelity repair, possibly due to ATM's effects on chromatin architecture surrounding the DSB.
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