Deborah J. Keszenman scite author profile

In order to analyze the roles of some repair genes in the processing of bleomycin-induced DNA damage and, especially, the interrelationships among the involved repair pathways, we investigated the potentially lethal effect of bleomycin on radiosensitive mutants of Saccharomyces cerevisiae defective in recombination, excision, and R4D6-dependent DNA repair. Using single, double, and triple rad mutants, we analyzed growth kinetics and survival curves as a function of bleomycin concentration. Our results indicate that genes belonging to the three epistasis groups interact in the repair of bleomycin-induced DNA damage to different degrees depending on the concentration of bleomycin. The most important mechanisms involved are recombination and postreplication repair. The initial action of a potentially inducible excision repair gene could provide intermediate substrates for the R4D6-and RAD52-dependent repair processes. Interaction between R4D6 and RADS2 genes was epistatic for low bleomycin concentrations. RA1D3 and RAD52 genes act independently in processing DNA damage induced by high concentrations of bleomycin. The synergistic interaction observed at high concentrations in the triple mutant rad2-6 rad6-1 rad52-1 indicates partial independence of the involved repair pathways, with possible common substrates. On the basis of the present results, we propose a heuristic model of bleomycin-induced DNA damage repair.Bleomycin (BLM) is a radiomimetic glycopeptide antibiotic used extensively in tumor therapy (32,48). This drug binds to DNA and through a free-radical-based mechanism produces DNA base loss and single-and double-strand breaks (43,44). In different lines of eukaryotic cells, BLM produces inhibition of DNA synthesis (10) as well as cell cycle G2 delay (19,38). With phages, bacteria, and yeast cells, it was demonstrated that this drug is recombinogenic and mutagenic (11,23,39,42). Analysis of BLM-induced mutagenesis in repackaged lambda phage suggests SOS repair dependence (33).BLM-induced DNA damage in prokaryotic and eukaryotic cells is partially reparable (3,22,27,40). For human fibroblasts, a long-patch mode of excision repair of BLM-induced damage was recently described (4, 5). Using haploid and diploid radiosensitive strains of Saccharomyces cerevisiae, Moore (22) showed that all rad single mutants sensitive to BLM tested, with the exception of rad1S, are sensitive to X rays. Likewise, BLM-sensitive (blm) mutants exhibit crosssensitivity to ionizing radiation and hydrogen peroxide (26). These results suggest that some aspects of the repair of BLM and ionizing radiation DNA damage in yeast cells may be similar. Furthermore, DNA ligase (the product of the CDC9 gene) is required in the overall process of restoring full-size DNA molecules from DNA fragments produced by BLM (24, 25).We have recently shown that BLM induces at least one error-prone type of repair in S. cerevisiae and that the PS04 (XS9) gene acts as a mutation-triggering factor (39). Furthermore, the combination of UV light and BLM produces di...

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Cellular and molecular effects of bleomycin are modulated by heat shock in Saccharomyces cerevisiae

Keszenman

Candreva

Nunes

2000

Mutation Research/DNA Repair

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Yields of Clustered DNA Damage Induced by Charged-Particle Radiations of Similar Kinetic Energy per Nucleon: LET Dependence in Different DNA Microenvironments

Keszenman

Sutherland

2010

Radiation Research

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To determine the linear energy transfer (LET) dependence of the biological effects of densely ionizing radiation in relation to changes in the ionization density along the track, we measured the yields and spectrum of clustered DNA damages induced by charged particles of different atomic number but similar kinetic energy per nucleon in different DNA microenvironments. Yeast DNA embedded in agarose in solutions of different free radical scavenging capacity was irradiated with 1 GeV protons, 1 GeV/nucleon oxygen ions, 980 MeV/nucleon titanium ions or 968 MeV/nucleon iron ions. The frequencies of double-strand breaks (DSBs), abasic sites and oxypurine clusters were quantified. The total DNA damage yields per absorbed dose induced in non-radioquenching solution decreased with LET, with minor variations in radioquenching conditions being detected. However, the total damage yields per particle fluence increased with LET in both conditions, indicating a higher efficiency per particle to induce clustered DNA damages. The yields of DSBs and non-DSB clusters as well as the damage spectra varied with LET and DNA milieu, suggesting the involvement of more than one mechanism in the formation of the different types of clustered damages.

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DNA damage in cells exhibiting radiation-induced genomic instability

Keszenman

Kolodiuk

Baulch³

2015

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Cells exhibiting radiation-induced genomic instability exhibit varied spectra of genetic and chromosomal aberrations. Even so, oxidative stress remains a common theme in the initiation and/or perpetuation of this phenomenon. Isolated oxidatively modified bases, abasic sites, DNA single strand breaks and clustered DNA damage are induced in normal mammalian cultured cells and tissues due to endogenous reactive oxygen species generated during normal cellular metabolism in an aerobic environment. While sparse DNA damage may be easily repaired, clustered DNA damage may lead to persistent cytotoxic or mutagenic events that can lead to genomic instability. In this study, we tested the hypothesis that DNA damage signatures characterised by altered levels of endogenous, potentially mutagenic, types of DNA damage and chromosomal breakage are related to radiation-induced genomic instability and persistent oxidative stress phenotypes observed in the chromosomally unstable progeny of irradiated cells. The measurement of oxypurine, oxypyrimidine and abasic site endogenous DNA damage showed differences in non-double-strand breaks (DSB) clusters among the three of the four unstable clones evaluated as compared to genomically stable clones and the parental cell line. These three unstable clones also had increased levels of DSB clusters. The results of this study demonstrate that each unstable cell line has a unique spectrum of persistent damage and lead us to speculate that alterations in DNA damage signaling and repair may be related to the perpetuation of genomic instability.

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Roles of Saccharomyces cerevisiae RAD17 and CHK1 checkpoint genes in the repair of double-strand breaks in cycling cells

Bracesco

Candreva

Keszenman

et al. 2007

Radiat Environ Biophys

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Checkpoints are components of signalling pathways involved in genome stability. We analysed the putative dual functions of Rad17 and Chk1 as checkpoints and in DNA repair using mutant strains of Saccharomyces cerevisiae. Logarithmic populations of the diploid checkpoint-deficient mutants, chk1Delta/chk1Delta and rad17Delta/rad17Delta, and an isogenic wild-type strain were exposed to the radiomimetic agent bleomycin (BLM). DNA double-strand breaks (DSBs) determined by pulsed-field electrophoresis, surviving fractions, and proliferation kinetics were measured immediately after treatments or after incubation in nutrient medium in the presence or absence of cycloheximide (CHX). The DSBs induced by BLM were reduced in the wild-type strain as a function of incubation time after treatment, with chromosomal repair inhibited by CHX. rad17Delta/rad17Delta cells exposed to low BLM concentrations showed no DSB repair, low survival, and CHX had no effect. Conversely, rad17Delta/rad17Delta cells exposed to high BLM concentrations showed DSB repair inhibited by CHX. chk1Delta/chk1Delta cells showed DSB repair, and CHX had no effect; these cells displayed the lowest survival following high BLM concentrations. Present results indicate that Rad17 is essential for inducible DSB repair after low BLM-concentrations (low levels of oxidative damage). The observations in the chk1Delta/chk1Delta mutant strain suggest that constitutive nonhomologous end-joining is involved in the repair of BLM-induced DSBs. The differential expression of DNA repair and survival in checkpoint mutants as compared to wild-type cells suggests the presence of a regulatory switch-network that controls and channels DSB repair to alternative pathways, depending on the magnitude of the DNA damage and genetic background.

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