Selene Sellés-Baiget, Sara M. Ambjørn, Alberto Carli, Ivo A. Hendriks, Irene Gallina, Norman E. Davey, Bente Benedict, Alessandra Zarantonello, Sampath A. Gadi, Bob Meeusen, Emil P. T. Hertz, Laura Slappendel, Daniel Semlow, Shana Sturla, Michael L. Nielsen, Jakob Nilsson, Thomas C. R. Miller, Julien P. Duxin
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引用次数: 0
摘要
转座DNA合成(TLS)是一个细胞过程,它能绕过DNA复制过程中遇到的DNA病变,并逐渐成为化疗的一个主要靶点。在脊椎动物的DNA聚合酶中,聚合酶κ(Polκ)具有绕过体外小沟DNA加合物的独特能力。然而,细胞也需要 Polκ 来克服主沟 DNA 加合物,但这一要求的基础尚不清楚。在这里,我们将人体细胞中的CRISPR碱基编辑器筛选技术与爪蟾卵提取物中定义的DNA病变的TLS分析相结合,揭示了Polκ在病变旁路过程中的功能和调控。令人震惊的是,我们发现 Polκ 在 TLS 期间有两种主要功能,它们受 Rev1 结合的调控不同。一方面,Polκ对于跨越小沟DNA病变的复制至关重要,这一过程依赖于PCNA泛素化,但与Rev1无关。另一方面,通过与 Rev1 和泛素化 PCNA 的合作作用,Polκ 似乎能稳定 DNA 上的 Rev1-Polζ 延伸复合物,使其延伸穿过主沟 DNA 病变和缺失位点,这一过程与 Polκ 的催化活性无关。总之,我们的工作确定了 Polκ 在 TLS 中的催化和非催化功能,并揭示了 Y-家族 TLS 聚合酶 C 端独特结构域的重要调控机制。
Catalytic and noncatalytic functions of DNA polymerase κ in translesion DNA synthesis
Translesion DNA synthesis (TLS) is a cellular process that enables the bypass of DNA lesions encountered during DNA replication and is emerging as a primary target of chemotherapy. Among vertebrate DNA polymerases, polymerase κ (Polκ) has the distinctive ability to bypass minor groove DNA adducts in vitro. However, Polκ is also required for cells to overcome major groove DNA adducts but the basis of this requirement is unclear. Here, we combine CRISPR base-editor screening technology in human cells with TLS analysis of defined DNA lesions in Xenopus egg extracts to unravel the functions and regulations of Polκ during lesion bypass. Strikingly, we show that Polκ has two main functions during TLS, which are differentially regulated by Rev1 binding. On the one hand, Polκ is essential to replicate across a minor groove DNA lesion in a process that depends on PCNA ubiquitylation but is independent of Rev1. On the other hand, through its cooperative interaction with Rev1 and ubiquitylated PCNA, Polκ appears to stabilize the Rev1–Polζ extension complex on DNA to allow extension past major groove DNA lesions and abasic sites, in a process that is independent of Polκ’s catalytic activity. Together, our work identifies catalytic and noncatalytic functions of Polκ in TLS and reveals important regulatory mechanisms underlying the unique domain architecture present at the C-terminal end of Y-family TLS polymerases.