Sister chromatid exchange

About: Sister chromatid exchange is a research topic. Over the lifetime, 3187 publications have been published within this topic receiving 90029 citations. The topic is also known as: replication-born DSB repair by SCE & GO:1990414.

The Photochemistry of 5-Bromouracil and 5-lodouracil in DNA

Abstract: Of the synthetic bases which may be incorporated in DNA, two of the most interesting are the thymine analogs, 5-bromouracil and 5-iodouracil. DNAs containing these bases have a number of altered properties which have been used to advantage by molecular biologists.

The relationship between sister-chromatid exchange and perturbations in DNA replication in mutant EM9 and normal CHO cells.

Abstract: The majority of the high (12-fold elevated) baseline sister-chromatid exchanges (SCEs) that occur in the CHO mutant line EM9 appear to be a consequence of incorporated BrdUrd, and they arise during replication of DNA containing BrdUrd in a template strand. In normal CHO cells the alkaline elution patterns of DNA newly replicated on a BrdUrd-containing template are significantly altered compared with those seen during the replication on an unsubstituted template. The nascent DNA synthesized on such an altered template is delayed in reaching mature size, possibly because replication forks are temporarily blocked at sites occurring randomly along the template. Transient blockage of replication forks may be a prerequisite for SCE. The delay in replication on BrdUrd-substituted templates was greater in EM9 cells than in parental AA8 cells and was also greater in AA8 cells treated with benzamide, an inhibitor of poly(ADPR) polymerase, than in untreated AA8 cells. Under these conditions, treatment with benzamide also produced a 7-fold increase in SCEs in AA8. An EM9-derived revertant line that has a low baseline SCE frequency showed less delay in replication on BrdUrd-substituted templates than did EM9. However, under conditions where the template strand contained CldUrd, which was shown to produce 4-fold more SCEs than BrdUrd in AA8 cells, the replication delay in AA8 was not any greater in the CldUrd-substituted cells. Thus, other factors besides the delay appear to be involved in the production of SCEs by the template lesions resulting from incorporation of the halogen-substituted pyrimidine molecules.

Relation between the human fibroblast strain 46BR and cell lines representative of Bloom's syndrome.

Abstract: 46BR is a human fibroblast strain derived from an immunodeficient young female of stunted growth. The diploid fibroblasts as well as a Simian Virus 40-transformed cell line are hypersensitive to killing by many DNA-damaging agents, exhibit a slightly increased level of spontaneous sister chromatid exchange, and show a defect in DNA ligation in vivo . 46BR is now shown to have abnormal DNA ligase I and is similar in this regard to cell lines derived from Bloom9s syndrome patients. In a direct comparison, both 46BR and several Bloom9s syndrome lines were found to be hypersensitive to the cytotoxic effect of simple alkylating agents, 46BR being more markedly sensitive. Bloom9s syndrome lines do not exhibit the strong delay in joining of Okazaki fragments during DNA replication characteristic of 46BR. The cell line 46BR probably has a mutation in the gene encoding DNA ligase I different from those occurring in classical cases of Bloom9s syndrome.

Differential effects of pre- and posttreatment of sodium arsenite on the genotoxicity of methyl methanesulfonate in Chinese hamster ovary cells.

Abstract: Pretreatment of sodium arsenite reduces hypoxanthine-guanine phosphoribosyltransferase mutagenicity and overcomes the inhibition of mitosis and cell proliferation but has no apparent effect on the cytotoxicity and clastogenicity in methyl methanesulfonate (MMS)-treated Chinese hamster ovary cells. Posttreatment of sodium arsenite drastically increases the cytotoxicity, clastogenicity, hypoxanthine-guanine phosphoribosyltransferase mutagenicity, and inhibition of mitosis and cell proliferation induced by MMS. Sodium arsenite either pre- or posttreatment has no apparent effect on the MMS-induced sister chromatid exchanges. The present results indicate that pretreatment of sodium arsenite not only does no harm but may even benefit the MMS-treated cells. On the contrary, posttreatment of sodium arsenite is cogenotoxic.