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.

Strand breaks arising from the repair of the 5-bromodeoxyuridine-substituted template and methyl methanesulphonate-induced lesions can explain the formation of sister chromatid exchanges

Abstract: 5-Bromodeoxyuridine (BrdU)-induced sister chromatid exchanges (SCEs) are mainly determined during replication on a BrdU-substituted template. The BrdU, once incorporated, is rapidly excised as uracil (U), and the gap is repaired with the incorporation of BrdU from the medium, which leads to further repair. During the second S period in BrdU medium, this process continues as the strand acts as template. Experiments suggest that 3-amino-benzamide (3AB) delays the ligation of the gaps formed after U excision, resulting in enhanced SCE levels during the second cycle of BrdU incorporation. When normal templates of G1 cells are treated before BrdU introduction with methyl methanesulphonate (MMS), 3AB in the first cycle doubles the MMS-induced SCEs but has no effect on them during the second cycle. When the BrdU-substituted template is treated with MMS in G1 of the second cycle, 3AB again doubles the SCEs due to MMS and also enhances the SCEs resulting from delays in ligation of the gaps following U excision in the BrdU-substituted template. The repair processes of MMS lesions that are sensitive to 3AB and lead to SCEs take place rapidly, while the repair process of late repairing lesions that lead to SCEs appear to be insensitive to 3AB. A model for SCE induction is proposed involving a single-strand break or gap as the initial requirement for SCE initiation at the replicating fork. Subsequent events represent natural stages in the repair process of a lesion, ensuring replication without loss of genetic information. G1 cells treated with methylnitrosourea (MNU) and grown immediately in BrdU medium rapidly lose the O6-methylguanine from their DNA and the rate of loss is BrdU-dose dependent. The rapid excision of the U lesions can explain the effect of BrdU concentration on SCE reduction following both MNU or MMS treatment.

Glutathione S-transferase mu genotype, diet, and smoking as determinants of sister chromatid exchange frequency in lymphocytes.

Abstract: Polymorphisms in inherited metabolic traits and intake of dietary antioxidants have been reported to be associated with risk for the development of lung cancer in smokers. This increased risk of lung cancer is presumably attributable to the accumulation of DNA damage. We conducted a study to investigate whether genetic metabolic variants and antioxidant consumption affected the sister chromatid exchange (SCE) level in lymphocytes. Study subjects were 78 friends and spouses of cases from a case-control study of lung cancer designed to investigate the association of metabolic polymorphisms with lung cancer. The metabolic traits studied included glutathione S-transferase class mu and variants of P-450 isoenzymes CYP1A1 and CYP2D6. Intake of antioxidants including vitamins A, C, and E and selenium was determined through the administration of a validated, semiquantitative food frequency questionnaire. Detailed information on smoking, family history of cancer, medical history, and environmental and occupational exposures was also obtained in an interviewer-administered questionnaire. Smoking status was found to be significantly associated with SCE frequency. In addition SCE frequency decreased with the period of time since quitting smoking. The presence of one or more glutathione S-transferase class mu alleles was associated with significantly lower SCE. Higher intake of vitamin A and selenium was also inversely associated with SCE level. Thus, the results suggest that glutathione S-transferase class mu and the intake of vitamin A and selenium may modulate the accumulation of chromosomal damage in lymphocytes.

Investigations of the frequency of DNA strand breakage and cross-linking and of sister chromatid exchange in the lymphocytes of electric welders exposed to chromium- and nickel-containing fumes.

Abstract: A total of 39 electric welders exposed to chromium and nickel were compared with 18 controls standardized for age, smoking habits and sex with respect to the frequency of sister chromatid exchange (SCE) and of DNA strand breakage and cross-linking (measured by the method of alkaline filter elution) in their blood lymphocytes. A significant correlation was found between the frequency of SCE and of individual DNA strand breakage and the concentration of chromium in the urine. Less DNA from the welders than from the control group was eluted through the two filter types used (polycarbonate and polyvinylidene fluoride filters). This must be interpreted as resulting from the presence of DNA-protein cross-links, which has the secondary effect of leading to a relative reduction in the measurable frequency of strand breakage amongst the welders. The present results are in good agreement with in vitro and in vivo investigations that confirm the importance of DNA-protein cross-links for the carcinogenic effect of chromium.