Hominini-specific regulation of the cell cycle by stop codon readthrough of FEM1B.

IF 4.3 3区材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-08-15 Epub Date: 2024-08-29 DOI:10.1242/jcs.261921

Md Noor Akhtar, Anumeha Singh, Lekha E Manjunath, Dhruba Dey, Sangeetha Devi Kumar, Kirtana Vasu, Arpan Das, Sandeep M Eswarappa

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Abstract

FEM1B is a substrate-recognition component of the CRL2 E3 ubiquitin-protein ligase. This multi-protein complex targets specific proteins for ubiquitylation, which leads to their degradation. Here, we demonstrate the regulation of FEM1B expression by stop codon readthrough (SCR). In this process, translating ribosomes readthrough the stop codon of FEM1B to generate a C-terminally extended isoform that is highly unstable. A total of 81 nucleotides in the proximal 3'UTR of FEM1B constitute the necessary and sufficient cis-signal for SCR. Also, they encode the amino acid sequence responsible for the degradation of the SCR product. CRISPR-edited cells lacking this region, and therefore SCR of FEM1B, showed increased FEM1B expression. This in turn resulted in reduced expression of SLBP (a target of FEM1B-mediated degradation) and replication-dependent histones (target of SLBP for mRNA stability), causing cell cycle delay. Evolutionary analysis revealed that this phenomenon is specific to the genus Pan and Homo (Hominini). Overall, we show a relatively recently evolved SCR process that relieves the cell cycle from the negative regulation by FEM1B.

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FEM1B的终止密码子通读对细胞周期的特异性调控。

FEM1B 是 CRL2 E3 泛素蛋白连接酶的底物识别元件。这种多蛋白复合物靶向特定蛋白质进行泛素化，从而导致其降解。在这里，我们证明了终止密码子穿越（SCR）对 FEM1B 表达的调控作用。在这一过程中，翻译核糖体会读通 FEM1B 的终止密码子，生成一个 C 端延长的高度不稳定的异构体。FEM1B 近端 3'UTR 中的 81 个核苷酸构成了 SCR 的必要且充分的顺式信号。此外，它们还编码了负责降解 SCR 产物的氨基酸序列。CRISPR编辑的细胞缺乏这一区域，因此也就缺乏FEM1B的SCR，表现出FEM1B的表达增加。这反过来又导致 SLBP（FEM1B 的降解靶标）和复制依赖组蛋白（SLBP 的 mRNA 稳定靶标）的表达减少，造成细胞周期延迟。进化分析表明，这种现象是盘属（Pan）和智人（Hominini）所特有的。总之，我们展示了一个相对新近进化的 SCR 过程，它使细胞周期摆脱了 FEM1B 的负调控。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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