Halas A, Baranowska H, Policińska Z, Jachymczyk W J
Institute of Biochemistry and Biophysics, Polish Academy of Sciences, 5a Pawińskiego Street, PL-02-106 Warsaw, Poland.
Curr Genet. 1997 Apr;31(4):292-301. doi: 10.1007/s002940050208.
The ability of four yeast DNA polymerase mutant strains to carry out the repair of DNA treated with MMS was studied. Mutation in DNA polymerase Rev3, as well as the already known mutation in the catalytic subunit of DNA polymerase delta, were both found to lead to the accumulation of single-strand breaks, which indicates defective repair. A double-mutant strain carrying mutations in DNA polymerase delta and a deletion in the REV3 gene had a complete repair defect, both at permissive (23 degrees C) and restrictive (38 degrees C) temperatures, which was not observed in other pairwise combinations of tested polymerase mutants. Other polymerases are not involved in the repair of exogenous DNA methylation damage, since neither mutation in the DNA polymerase epsilon, nor deletion in the DNA polymerase IV (beta70) gene, caused defective repair. The data obtained suggest that DNA polymerases delta and Rev3p are both necessary to perform repair synthesis in the base-excision repair of methylation damage. The results are discussed in the light of current concepts on the role of DNA polymerase Rev3 in mutagenesis.
研究了四种酵母DNA聚合酶突变菌株对经甲基磺酸甲酯(MMS)处理的DNA进行修复的能力。发现DNA聚合酶Rev3中的突变以及DNA聚合酶δ催化亚基中已知的突变均导致单链断裂的积累,这表明修复存在缺陷。携带DNA聚合酶δ突变和REV3基因缺失的双突变菌株在允许温度(23℃)和限制温度(38℃)下均存在完全修复缺陷,而在测试的其他聚合酶突变体的两两组合中未观察到这种情况。其他聚合酶不参与外源DNA甲基化损伤的修复,因为DNA聚合酶ε中的突变以及DNA聚合酶IV(β70)基因的缺失均未导致修复缺陷。获得的数据表明,DNA聚合酶δ和Rev3p在甲基化损伤的碱基切除修复中进行修复合成都是必需的。根据当前关于DNA聚合酶Rev3在诱变作用中的概念对结果进行了讨论。
