Genetics animates structure: leveraging genetic interactions to study the dynamics of ribosome biogenesis.

IF 1.8 4区生物学 Q3 GENETICS & HEREDITY

Current Genetics Pub Date : 2021-10-01 DOI:10.1007/s00294-021-01187-y

Joshua J Black, Arlen W Johnson

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引用次数: 6

Abstract

The assembly of eukaryotic ribosomes follows an assembly line-like pathway in which numerous trans-acting biogenesis factors act on discrete pre-ribosomal intermediates to progressively shape the nascent subunits into their final functional architecture. Recent advances in cryo-electron microscopy have led to high-resolution structures of many pre-ribosomal intermediates; however, these static snapshots do not capture the dynamic transitions between these intermediates. To this end, molecular genetics can be leveraged to reveal how the biogenesis factors drive these dynamic transitions. Here, we briefly review how we recently used the deletion of BUD23 (bud23∆) to understand its role in the assembly of the ribosomal small subunit. The strong growth defect of bud23∆ mutants places a selective pressure on yeast cells for the occurrence of extragenic suppressors that define a network of functional interactions among biogenesis factors. Mapping these suppressing mutations to recently published structures of pre-ribosomal complexes allowed us to contextualize these suppressing mutations and derive a detailed model in which Bud23 promotes a critical transition event to facilitate folding of the central pseudoknot of the small subunit. This mini-review highlights how genetics can be used to understand the dynamics of complex structures, such as the maturing ribosome.

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遗传学激活结构:利用遗传相互作用来研究核糖体生物发生的动力学。

真核核糖体的组装遵循装配线般的途径，其中许多反式生物发生因子作用于离散的核糖体前中间体，逐步将新生亚基塑造成最终的功能结构。低温电子显微镜的最新进展导致了许多核糖体前中间体的高分辨率结构;然而，这些静态快照并不能捕获这些中间体之间的动态转换。为此，分子遗传学可以用来揭示生物发生因素如何驱动这些动态转变。在这里，我们简要回顾了我们最近如何使用BUD23 (BUD23∆)的缺失来了解其在核糖体小亚基组装中的作用。bud23∆突变体的强烈生长缺陷对酵母细胞施加了选择性压力，导致外基因抑制因子的出现，而外基因抑制因子定义了生物发生因子之间的功能相互作用网络。将这些抑制突变映射到最近发表的核糖体前复合物的结构，使我们能够将这些抑制突变置于背景中，并推导出一个详细的模型，其中Bud23促进了一个关键的过渡事件，以促进小亚基中心假结的折叠。这篇小综述强调了如何利用遗传学来理解复杂结构的动力学，如成熟的核糖体。

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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来源期刊

Current Genetics 生物-遗传学

CiteScore

6.00

自引率

0.00%

发文量

审稿时长

1 months

期刊介绍： Current Genetics publishes genetic, genomic, molecular and systems-level analysis of eukaryotic and prokaryotic microorganisms and cell organelles. All articles are peer-reviewed. The journal welcomes submissions employing any type of research approach, be it analytical (aiming at a better understanding), applied (aiming at practical applications), synthetic or theoretical. Current Genetics no longer accepts manuscripts describing the genome sequence of mitochondria/chloroplast of a small number of species. Manuscripts covering sequence comparisons and analyses that include a large number of species will still be considered.