PCH-2 与 CMT-1 合作校对减数分裂同源物相互作用。

PCH-2 collaborates with CMT-1 to proofread meiotic homolog interactions.

机构信息

Department of Molecular, Cell and Developmental Biology, University of California, Santa Cruz, Santa Cruz, California, United States of America.

出版信息

PLoS Genet. 2020 Jul 30;16(7):e1008904. doi: 10.1371/journal.pgen.1008904. eCollection 2020 Jul.

DOI:10.1371/journal.pgen.1008904

PMID:32730253

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7433886/

Abstract

The conserved ATPase, PCH-2/TRIP13, is required during both the spindle checkpoint and meiotic prophase. However, its specific role in regulating meiotic homolog pairing, synapsis and recombination has been enigmatic. Here, we report that this enzyme is required to proofread meiotic homolog interactions. We generated a mutant version of PCH-2 in C. elegans that binds ATP but cannot hydrolyze it: pch-2E253Q. In vitro, this mutant can bind a known substrate but is unable to remodel it. This mutation results in some non-homologous synapsis and impaired crossover assurance. Surprisingly, worms with a null mutation in PCH-2's adapter protein, CMT-1, the ortholog of p31comet, localize PCH-2 to meiotic chromosomes, exhibit non-homologous synapsis and lose crossover assurance. The similarity in phenotypes between cmt-1 and pch-2E253Q mutants suggest that PCH-2 can bind its meiotic substrates in the absence of CMT-1, in contrast to its role during the spindle checkpoint, but requires its adapter to hydrolyze ATP and remodel them.

摘要

保守的 ATP 酶 PCH-2/TRIP13 在纺锤体检查点和减数分裂前期都需要。然而，其在调节减数分裂同源物配对、联会和重组方面的具体作用一直是个谜。在这里，我们报告称，该酶需要校对减数分裂同源物相互作用。我们在秀丽隐杆线虫中生成了一种 PCH-2 的突变体版本，该突变体可以结合 ATP 但不能水解它：pch-2E253Q。在体外，这种突变体可以结合已知的底物，但无法对其进行重塑。这种突变导致一些非同源联会和交叉保证受损。令人惊讶的是，p31comet 的同源物 CMT-1 的 PCH-2 衔接蛋白缺失突变体中的线虫将 PCH-2 定位到减数分裂染色体上，表现出非同源联会并失去交叉保证。cmt-1 和 pch-2E253Q 突变体之间的表型相似性表明，PCH-2 可以在没有 CMT-1 的情况下结合其减数分裂底物，与它在纺锤体检查点的作用形成对比，但需要其衔接蛋白来水解 ATP 并重塑它们。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9d79/7433886/02b15dcfd3fc/pgen.1008904.g001.jpg

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PCH-2 与 CMT-1 合作校对减数分裂同源物相互作用。

PCH-2 collaborates with CMT-1 to proofread meiotic homolog interactions.

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