Heterogeneity of Subcellular Diffusion in Bacteria Based on Spatial Segregation of Ribosomes and Nucleoids.

Pub Date : 2022-01-01 DOI:10.1159/000526846
Simon Dersch, Daniel A O Rotter, Peter L Graumann
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引用次数: 3

Abstract

It has long become clear that in spite of generally lacking internal membrane systems, bacteria contain well-structured subcellular structures of usually filamentous proteins, and a preferred 3D arrangement of their chromosome(s). Some of these systems are set up by so-called cytoskeletal elements, or by polar landmark proteins, but the mechanism of specific localization is still unclear in most cases. Intriguingly, apart from such spatially organizing systems, the bacterial cytoplasm has unusual properties in terms of the diffusion of molecules, which varies between different sites within the cell. In many bacteria, chromosomes are compacted into centrally located nucleoids, being orderly folded as opposed to consisting of random coils of DNA. In these bacteria, there is a separation of transcription and translation, such that transcription by RNA polymerase occurs on the nucleoids, and translation takes place mostly at the cell poles and directly underneath the cell membrane, because 70S ribosomes accumulate at sites surrounding the nucleoids. Interestingly, accumulation of ribosomes appears to slow down diffusion of enzymes, noticeable for larger enzyme complexes, while nucleoids provide areas of confined motion for DNA-binding proteins, yet acceleration zones for non-DNA-binding proteins. Crowded regions at the cell poles set up zones of higher concentration of the translation machinery, shortening diffusion distances for rate-limiting translation factor/ribosome interactions, and of metabolic enzymes, possibly speeding up pathways containing low concentrations of metabolites. Thus, heterogeneous diffusion adds another layer of subcellular organization on top of cytoskeletal elements.

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基于核糖体和类核空间分离的细菌亚细胞扩散异质性。
长期以来,人们已经清楚,尽管细菌通常缺乏内部膜系统,但细菌含有结构良好的亚细胞结构,通常是丝状蛋白质,以及它们的染色体的首选3D排列。其中一些系统是由所谓的细胞骨架元件或极性地标蛋白建立的,但在大多数情况下,特异性定位的机制仍不清楚。有趣的是,除了这种空间组织系统外,细菌细胞质在分子扩散方面具有不同寻常的特性,这在细胞内不同部位之间是不同的。在许多细菌中,染色体被压缩成位于中心的类核,有序折叠,而不是由随机的DNA线圈组成。在这些细菌中,转录和翻译是分离的,因此RNA聚合酶的转录发生在类核上,而翻译主要发生在细胞极点和直接在细胞膜下面,因为70S核糖体聚集在类核周围的位置。有趣的是,核糖体的积累似乎减缓了酶的扩散,这对于较大的酶复合物来说是显而易见的,而类核为dna结合蛋白提供了限制运动的区域,但为非dna结合蛋白提供了加速区。细胞两极的拥挤区域建立了翻译机制的高浓度区域,缩短了限速翻译因子/核糖体相互作用和代谢酶的扩散距离,可能加速了含有低浓度代谢物的途径。因此,异质扩散在细胞骨架元素之上增加了另一层亚细胞组织。
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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