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CsrA 对铁储存的调节支持大肠杆菌的指数生长。

Regulation of Iron Storage by CsrA Supports Exponential Growth of Escherichia coli.

机构信息

Department of Microbiology and Cell Science, Institute of Food and Agricultural Sciences, University of Florida, Gainesville, Florida, USA.

Department of Biochemistry and Molecular Biology, Center for RNA Molecular Biology, The Pennsylvania State University, University Park, Pennsylvania, USA.

出版信息

mBio. 2019 Aug 6;10(4):e01034-19. doi: 10.1128/mBio.01034-19.

DOI:10.1128/mBio.01034-19
PMID:31387901
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6686035/
Abstract

The global regulatory protein CsrA coordinates gene expression in response to physiological cues reflecting cellular stress and nutrition. CsrA binding to the 5' segments of mRNA targets affects their translation, RNA stability, and/or transcript elongation. Recent studies identified probable mRNA targets of CsrA that are involved in iron uptake and storage in , suggesting an unexplored role for CsrA in regulating iron homeostasis. Here, we assessed the impact of CsrA on iron-related gene expression, cellular iron, and growth under various iron levels. We investigated five new targets of CsrA regulation, including the genes for 4 ferritin or ferritin-like iron storage proteins (ISPs) and the stress-inducible Fe-S repair protein, SufA. CsrA bound with high affinity and specificity to , and mRNAs and inhibited their translation, while it modestly activated expression. Furthermore, CsrA was found to regulate cellular iron levels and support growth by repressing the expression of genes for ISPs, most importantly, ferritin B (FtnB) and bacterioferritin (Bfr). Iron starvation did not substantially affect cellular levels of CsrA or its small RNA (sRNA) antagonists, CsrB and CsrC. disruption led to increased resistance to the lethal effects of HO during exponential growth, consistent with a regulatory role in oxidative stress resistance. We propose that during exponential growth and under minimal stress, CsrA represses the deleterious expression of the ISPs that function under oxidative stress and stationary-phase conditions (FtnB, Bfr, and Dps), thus ensuring that cellular iron is available to processes that are required for growth. Iron is an essential micronutrient for nearly all living organisms but is toxic in excess. Consequently, the maintenance of iron homeostasis is a critical biological process, and the genes involved in this function are tightly regulated. Here, we explored a new role for the bacterial RNA binding protein CsrA in the regulation of iron homeostasis. CsrA was shown to be a key regulator of iron storage genes in , with consequential effects on cellular iron levels and growth. Our findings establish a model in which robust CsrA activity during the exponential phase of growth leads to repression of genes whose products sequester iron or divert it to unnecessary stress response processes. In so doing, CsrA supports growth under iron-limiting laboratory conditions and may promote fitness in the competitive iron-limited environment of the host large intestine.

摘要

全球调节蛋白 CsrA 响应反映细胞应激和营养的生理信号,协调基因表达。CsrA 与 mRNA 靶标 5' 片段的结合影响它们的翻译、RNA 稳定性和/或转录延伸。最近的研究确定了 CsrA 可能参与铁摄取和储存的 mRNA 靶标,这表明 CsrA 在调节铁稳态方面具有尚未探索的作用。在这里,我们评估了 CsrA 对不同铁水平下与铁相关的基因表达、细胞内铁和生长的影响。我们研究了 CsrA 调节的五个新靶标,包括 4 种铁蛋白或铁蛋白样铁储存蛋白 (ISP) 的基因和应激诱导的 Fe-S 修复蛋白 SufA。CsrA 与 、 和 mRNA 具有高亲和力和特异性结合,并抑制它们的翻译,同时适度激活 表达。此外,发现 CsrA 通过抑制 ISP 基因的表达来调节细胞内铁水平并支持生长,最重要的是,铁蛋白 B (FtnB) 和细菌铁蛋白 (Bfr)。铁饥饿对 CsrA 或其小 RNA (sRNA) 拮抗剂 CsrB 和 CsrC 的细胞水平没有显著影响。缺失导致指数生长过程中对 HO 致命效应的抗性增加,与氧化应激抗性的调节作用一致。我们提出,在指数生长和最小应激下,CsrA 抑制在氧化应激和静止期条件下起作用的 ISP 的有害表达(FtnB、Bfr 和 Dps),从而确保细胞内铁可用于生长所需的过程。铁是几乎所有生物体的必需微量元素,但过量则有毒。因此,维持铁稳态是一个关键的生物学过程,参与该功能的基因受到严格调控。在这里,我们探索了细菌 RNA 结合蛋白 CsrA 在调节铁稳态中的新作用。CsrA 被证明是 中铁储存基因的关键调节剂,对细胞内铁水平和生长有影响。我们的发现建立了一个模型,即在生长指数期 CsrA 活性较强时,会抑制那些将铁隔离或使其转向不必要的应激反应过程的产物的基因表达。这样,CsrA 支持在缺铁的实验室条件下的 生长,并可能促进在宿主大肠竞争缺铁的环境中的适应性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c1b6/6686035/afc4ad981306/mBio.01034-19-f0009.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c1b6/6686035/ce0684868983/mBio.01034-19-f0005.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c1b6/6686035/615b7e978d79/mBio.01034-19-f0006.jpg
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