Further characterization of the role of Pso2 in the repair of DNA interstrand cross-link-associated double-strand breaks in Saccharomyces cerevisiae.

DNA interstrand cross-links (ICL) are thought to be one of the most lethal forms of DNA damage. Therefore, they present a colossal challenge for the DNA damage response and repair pathways. In Saccharomyces cerevisiae, ICL repair utilizes factors from all of the three major repair groups: nucleotide excision repair (RAD3 epistasis group), post-replication repair (RAD6 epistasis group) and recombinational repair (RAD52 epistasis group). Moreover, there are additional factors significantly influencing the repair of ICL in this organism. These have been designated PSO1-10 based on the psoralen sensitive phenotype of the corresponding mutants. Phenotype of the pso2 mutant suggests that Pso2 is not involved in incision step of ICL repair, but it rather functions in some downstream event such as processing of DNA ends created during generation of ICL-associated double-strand breaks (DSB). In order to address the question whether function of Pso2 in the repair of ICL-associated DSB could be mediated through protein-protein interactions, we have conducted a comprehensive two-hybrid screen examining a possibility of interaction of Pso2 with Yku70, Yku80, Nej1, Lif1, Dnl4, Rad50, Mre11, Xrs2, Rad51, Rad52, Rad54, Rad55, Rad57, Rad59 and Rdh54. Here we show that Pso2 associates with none of the above DSB repair proteins, suggesting that this protein very likely does not act in the repair of ICL-associated DSB via crosstalk with DSB repair machinery. Instead, its function in this process seems to be rather individual.

Disruption of the RAD51 gene sensitizes S. cerevisiae cells to the toxic and mutagenic effects of hydrogen peroxide.

The RAD51 gene was disrupted in three different parental wild-type strains to yield three rad51 null strains with different genetic background. The rad51 mutation sensitizes yeast cells to the toxic and mutagenic effects of H2O2, suggesting that Rad51-mediated repair, similarly to that of RecA-mediated, is relevant to the repair of oxidative damage in S. cerevisiae. Moreover, pulsed-field gel electrophoresis analysis demonstrated that increased sensitivity of the rad51 mutant to H2O2 is accompanied by its decreased ability to repair double-strand breaks induced by this agent. Our results show that ScRad51 protects yeast cells from H2O2-induced DNA double-strand breakage.

Increased DNA double strand breakage is responsible for sensitivity of the pso3-1 mutant of Saccharomyces cerevisiae to hydrogen peroxide.

Escherichia coli endonuclease III (endo III) is the key repair enzyme essential for removal of oxidized pyrimidines and abasic sites. Although two homologues of endo III, Ntgl and Ntg2, were found in Saccharomyces cerevisiae, they do not significantly contribute to repair of oxidative DNA damage in vivo. This suggests that an additional activity(ies) or a regulatory pathway(s) involved in cellular response to oxidative DNA damage may exist in yeast. The pso3-1 mutant of S. cerevisiae was previously shown to be specifically sensitive to toxic effects of hydrogen peroxide (H2O2) and paraquat. Here, we show that increased DNA double strand breakage is very likely the basis of sensitivity of the pso3-1 mutant cells to H2O2. Our results, thus, indicate an involvement of the Pso3 protein in protection of yeast cells from oxidative stress presumably through its ability to prevent DNA double strand breakage. Furthermore, complementation of the repair defects of the pso3-1 mutant cells by E. coli endo III has been examined. It has been found that expression of the nth gene in the pso3-1 mutant cells recovers survival, decreases mutability and protects yeast genomic DNA from breakage following H2O2 treatment. This might suggest some degree of functional similarity between Pso3 and Nth.

Repair of oxidative DNA damage--an important factor reducing cancer risk. Minireview.

Oxygen free radicals formed during normal aerobic cellular metabolism generate a variety of DNA lesions including modified bases, abasic sites and single strand breaks with blocked 3' termini. If left unrepaired, these damages may contribute to a number of degenerative processes, including cancer and aging. In most organisms, the repair of oxidative DNA lesions is supposed to be handled by the base excision repair (BER) pathway. BER is a multistep process that involves the sequential activity of several proteins, many of them were isolated and functionally characterized using the simple prokaryotic and lower eukaryotic model systems, Escherichia coli and Saccharomyces cerevisiae, respectively. As the amino acid sequence of DNA repair proteins is often well conserved from bacteria to man, our understanding of BER in higher eukaryotes drives extensively from the microbial models, namely from the yeast S. cerevisiae. Thus, results obtained on a simple yeast model are a source of new information, which can be used as a paradigm for all eukaryotic cells.