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胸腺嘧啶缺乏致死时,大肠杆菌中复制叉停滞的修复和错误修复。

Stalled replication fork repair and misrepair during thymineless death in Escherichia coli.

机构信息

Department of Microbiology, University of Illinois at Urbana-Champaign, Urbana, IL 61801, USA.

出版信息

Genes Cells. 2010 Jun;15(6):619-34. doi: 10.1111/j.1365-2443.2010.01405.x. Epub 2010 Apr 30.

DOI:10.1111/j.1365-2443.2010.01405.x
PMID:20465561
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3965187/
Abstract

Starvation for DNA precursor dTTP, known as 'thymineless death' (TLD), kills bacterial and eukaryotic cells alike. Despite numerous investigations, toxic mechanisms behind TLD remain unknown, although wrong nucleotide incorporation with subsequent excision dominates the explanations. We show that kinetics of TLD in Escherichia coli is not affected by mutations in DNA repair, ruling out excision after massive misincorporation as the cause of TLD. We found that the rate of DNA synthesis in thymine-starved cells decreases exponentially, indicating replication fork stalling. Processing of stalled replication forks by recombinational repair is known to fragment the chromosome, and we detect significant chromosomal fragmentation during TLD. Moreover, we report that, out of major recombinational repair functions, only inactivation of recF and recO relieves TLD, identifying the poisoning mechanism. Inactivation of recJ and rep has slight effect, while the recA, recBC, ruvABC, recG and uvrD mutations all accelerate TLD, identifying the protection mechanisms. Our epistatic analysis argues for two distinct pathways protecting against TLD: RecABCD/Ruv repairs the double-strand breaks, whereas UvrD counteracts RecAFO-catalyzed toxic single-strand gap processing.

摘要

由于缺乏 DNA 前体 dTTP,细菌和真核细胞会出现“无胸腺嘧啶死亡”(TLD)现象。尽管已经进行了大量研究,但 TLD 的毒性机制仍不清楚,尽管错误核苷酸的掺入及其后续的切除占据了主导地位。我们发现,大肠杆菌中 TLD 的动力学不受 DNA 修复突变的影响,这排除了大量错误掺入后切除作为 TLD 原因的可能性。我们发现,在缺乏胸苷的细胞中,DNA 合成的速度呈指数下降,表明复制叉停滞。重组修复处理停滞的复制叉会导致染色体片段化,我们在 TLD 过程中检测到明显的染色体片段化。此外,我们报告称,在主要的重组修复功能中,只有 recF 和 recO 的失活能缓解 TLD,从而确定了毒性机制。recJ 和 rep 的失活仅有轻微影响,而 recA、recBC、ruvABC、recG 和 uvrD 的突变则加速了 TLD,从而确定了保护机制。我们的上位性分析表明,有两种不同的途径可以防止 TLD:RecABCD/Ruv 修复双链断裂,而 UvrD 则拮抗 RecAFO 催化的毒性单链缺口加工。

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