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DNA聚合酶
DNA复制
解旋酶
生物
DNA
初级
遗传学
聚合酶
DNA聚合酶Ⅱ
细胞生物学
基因组
DNA钳
细菌圆形染色体
DNA合成
DNA聚合酶Ⅰ
真核细胞DNA复制
分子生物学
过程性
原核DNA复制
DNA聚合酶δ
酶
染色体复制控制
DNA修复
复制蛋白A
机制(生物学)
作者
Jose Pablo Rascon Perez,Ophélie d’Udekem d’Acoz,Nicolas Soubry,Wen-Cheng Xu,Baljyot Singh Parmar,Stephanie C. Weber,Rodrigo Reyes Lamothe,Jose Pablo Rascon Perez,Ophélie d’Udekem d’Acoz,Nicolas Soubry,Wen-Cheng Xu,Baljyot Singh Parmar,Stephanie C. Weber,Rodrigo Reyes Lamothe
标识
DOI:10.1073/pnas.2511725122
摘要
DNA replication requires precise coordination between DNA unwinding and DNA synthesis. In all domains of life, protein–protein interactions at the replisome maintain proximity between the enzymes that catalyze these two activities. Surprisingly, in bacteria, the replicative DNA polymerase (Pol III), responsible for DNA synthesis, is exchanged every few seconds. How processive synthesis is maintained under these conditions has remained unclear. Here, we use single-molecule microscopy in live cells to show that Pol III rapidly rebinds the replisome within seconds of dissociation. This fast recruitment is driven by an interaction with single-stranded DNA–binding protein (SSB), which enhances Pol III target search efficiency by ~20-fold. Disrupting this mechanism alters replisome stoichiometry, causes single-stranded DNA (ssDNA) accumulation, depletes free SSB, and leads to helicase disassembly and DNA breakage, culminating in genome instability. Our findings reveal a mechanism by which fast polymerase recycling sustains continuous DNA replication and genome integrity.
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