自噬一种类淀粉样翻译抑制剂调控减数分裂终变期。

Autophagy of an Amyloid-like Translational Repressor Regulates Meiotic Exit.

机构信息

Department of Internal Medicine, Center for Autophagy Research, UT Southwestern Medical Center, Dallas, TX, USA.

出版信息

Dev Cell. 2020 Jan 27;52(2):141-151.e5. doi: 10.1016/j.devcel.2019.12.017.

DOI:10.1016/j.devcel.2019.12.017

PMID:31991104

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7138260/

Abstract

We explored the potential for autophagy to regulate budding yeast meiosis. Following pre-meiotic DNA replication, we blocked autophagy by chemical inhibition of Atg1 kinase or engineered degradation of Atg14 and observed homologous chromosome segregation followed by sister chromatid separation; cells then underwent additional rounds of spindle formation and disassembly without DNA re-replication, leading to aberrant chromosome segregation. Analysis of cell-cycle regulators revealed that autophagy inhibition prevents meiosis II-specific expression of Clb3 and leads to the aberrant persistence of Clb1 and Cdc5, two substrates of a meiotic ubiquitin ligase activated by Ama1. Lastly, we found that during meiosis II, autophagy degrades Rim4, an amyloid-like translational repressor whose timed clearance regulates protein production from its mRNA targets, which include CLB3 and AMA1. Strikingly, engineered Clb3 or Ama1 production restored meiotic termination in the absence of autophagy. Thus, autophagy destroys a master regulator of meiotic gene expression to enable irreversible meiotic exit.

摘要

我们探索了自噬在调节出芽酵母减数分裂中的作用。在减数分裂前的 DNA 复制之后，我们通过化学抑制 Atg1 激酶或工程改造 Atg14 的降解来阻断自噬，并观察到同源染色体的分离，随后是姐妹染色单体的分离；然后，细胞经历了额外的纺锤体形成和拆卸，而没有 DNA 的再复制，导致异常的染色体分离。对细胞周期调节剂的分析表明，自噬抑制阻止了减数分裂 II 特异性 Clb3 的表达，并导致异常持续存在的 Clb1 和 Cdc5，这两种是由 Ama1 激活的减数分裂泛素连接酶的底物。最后，我们发现，在减数分裂 II 期间，自噬降解 Rim4，一种淀粉样翻译抑制剂，其定时清除调节其 mRNA 靶标（包括 CLB3 和 AMA1）的蛋白质产生。引人注目的是，工程化的 Clb3 或 Ama1 的产生恢复了在没有自噬的情况下的减数分裂终止。因此，自噬破坏了一个减数分裂基因表达的主要调节剂，以实现不可逆的减数分裂退出。

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