Seeing gene expression in cells: the future of structural biology.

Faculty reviews Pub Date : 2021-11-15 eCollection Date: 2021-01-01 DOI:10.12703/r-01-000004
Wei Dai, Seth A Darst, Christine M Dunham, Robert Landick, Gregory Petsko, Albert Weixlbaumer
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引用次数: 1

Abstract

Although much is known about the machinery that executes fundamental processes of gene expression in cells, much also remains to be learned about how that machinery works. A recent paper by O'Reilly et al. reports a major step forward in the direct visualization of central dogma processes at submolecular resolution inside bacterial cells frozen in a native state. The essential methodologies involved are cross-linking mass spectrometry (CLMS) and cryo-electron tomography (cryo-ET). In-cell CLMS provides in vivo protein interaction maps. Cryo-ET allows visualization of macromolecular complexes in their native environment. These methods have been integrated by O'Reilly et al. to describe a dynamic assembly in situ between a transcribing RNA polymerase (RNAP) and a translating ribosome - a complex known as the expressome - in the model bacterium Mycoplasma pneumoniae 1. With the application of improved data processing and classification capabilities, this approach has allowed unprecedented insights into the architecture of this molecular assembly line, confirming the existence of a physical link between RNAP and the ribosome and identifying the transcription factor NusA as the linking molecule, as well as making it possible to see the structural effects of drugs that inhibit either transcription or translation. The work provides a glimpse into the future of integrative structural cell biology and can serve as a roadmap for the study of other molecular machineries in their native context.

Abstract Image

观察细胞中的基因表达:结构生物学的未来。
尽管我们对细胞中执行基因表达基本过程的机制了解很多,但关于这一机制是如何工作的,我们还需要了解很多。O'Reilly等人最近发表的一篇论文报道了在以亚分子分辨率直接可视化处于天然状态的细菌细胞内的中心法则过程方面取得的重大进展。所涉及的基本方法是交联质谱(CLMS)和低温电子断层扫描(cryo-ET)。细胞内CLMS提供体内蛋白质相互作用图。Cryo-ET允许在其原生环境中可视化大分子复合物。O'Reilly等人整合了这些方法,描述了模型细菌肺炎支原体1中转录RNA聚合酶(RNAP)和翻译核糖体(一种称为表达体的复合体)之间的动态原位组装。随着改进的数据处理和分类能力的应用,这种方法使人们对这条分子装配线的结构有了前所未有的了解,证实了RNAP和核糖体之间存在物理联系,并确定了转录因子NusA作为连接分子,同时也使人们有可能看到抑制转录或翻译的药物的结构效应。这项工作为整合结构细胞生物学的未来提供了一瞥,并可以作为研究其他分子机制在其原生环境中的路线图。
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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