Rho1和Rgf1建立了一种新的肌动蛋白依赖性信号,可独立于微管和Tea1-Tea4复合物决定酵母的生长极。

IF 9.8 1区 生物学 Q1 Agricultural and Biological Sciences
PLoS Biology Pub Date : 2024-11-07 eCollection Date: 2024-11-01 DOI:10.1371/journal.pbio.3002491
Patricia Garcia, Ruben Celador, Tomas Edreira, Yolanda Sanchez
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引用次数: 0

摘要

细胞不对称始于细胞表面选择一个离散点,该点可触发 Rho-GTPases 激活和细胞骨架的局部组装,从而建立新的生长区。裂殖酵母的圆柱形是由微管(MT)组织的,微管在细胞顶端输送标志性的 Tea1-Tea4 复合物,以确定生长极。然而,只有少数tea1Δ细胞弄错了生长方向,这表明它们能够探测到自己的生长点。在这里,我们发现Rgf1(Rho1-GEF)和Tea4是同一个复合体的成分,而且Rgf1对Rho1的活性是在细胞顶端强化Tea4所必需的。此外,在缺乏 Tea1 的细胞中,正确生长点的选择取决于 Rgf1 和正确极化的肌动蛋白细胞骨架,两者都是在极点激活 Rho1 的必要条件。我们提出了一种由 Rgf1-Rho1 驱动的肌动蛋白依赖性机制,该机制可独立于 MT 和 Tea1-Tea4 复合物标记极点。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Rho1 and Rgf1 establish a new actin-dependent signal to determine growth poles in yeast independently of microtubules and the Tea1-Tea4 complex.

Cellular asymmetry begins with the selection of a discrete point on the cell surface that triggers Rho-GTPases activation and localized assembly of the cytoskeleton to establish new growth zones. The cylindrical shape of fission yeast is organized by microtubules (MT) that deliver the landmark Tea1-Tea4 complex at the cell tips to define the growth poles. However, only a few tea1Δ cells mistaken the direction of growth, indicating that they manage to detect their growth sites. Here, we show that Rgf1 (Rho1-GEF) and Tea4 are components of the same complex and that Rgf1 activity toward Rho1 is required for strengthen Tea4 at the cell tips. Moreover, in cells lacking Tea1, selection of the correct growth site depends on Rgf1 and on a correctly polarized actin cytoskeleton, both necessary for Rho1 activation at the pole. We propose an actin-dependent mechanism driven by Rgf1-Rho1 that marks the poles independently of MTs and the Tea1-Tea4 complex.

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来源期刊
PLoS Biology
PLoS Biology BIOCHEMISTRY & MOLECULAR BIOLOGY-BIOLOGY
CiteScore
15.40
自引率
2.00%
发文量
359
审稿时长
3-8 weeks
期刊介绍: PLOS Biology is the flagship journal of the Public Library of Science (PLOS) and focuses on publishing groundbreaking and relevant research in all areas of biological science. The journal features works at various scales, ranging from molecules to ecosystems, and also encourages interdisciplinary studies. PLOS Biology publishes articles that demonstrate exceptional significance, originality, and relevance, with a high standard of scientific rigor in methodology, reporting, and conclusions. The journal aims to advance science and serve the research community by transforming research communication to align with the research process. It offers evolving article types and policies that empower authors to share the complete story behind their scientific findings with a diverse global audience of researchers, educators, policymakers, patient advocacy groups, and the general public. PLOS Biology, along with other PLOS journals, is widely indexed by major services such as Crossref, Dimensions, DOAJ, Google Scholar, PubMed, PubMed Central, Scopus, and Web of Science. Additionally, PLOS Biology is indexed by various other services including AGRICOLA, Biological Abstracts, BIOSYS Previews, CABI CAB Abstracts, CABI Global Health, CAPES, CAS, CNKI, Embase, Journal Guide, MEDLINE, and Zoological Record, ensuring that the research content is easily accessible and discoverable by a wide range of audiences.
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