Intrinsic and extrinsic determinants of conditional localization of Mms6 to magnetosome organelles in Magnetospirillum magneticum AMB-1.

IF 2.7 3区 生物学 Q3 MICROBIOLOGY
Journal of Bacteriology Pub Date : 2024-06-20 Epub Date: 2024-05-31 DOI:10.1128/jb.00008-24
Carson D Bickley, Juan Wan, Arash Komeili
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引用次数: 0

Abstract

Magnetotactic bacteria are a diverse group of microbes that use magnetic particles housed within intracellular lipid-bounded magnetosome organelles to guide navigation along geomagnetic fields. The development of magnetosomes and their magnetic crystals in Magnetospirillum magneticum AMB-1 requires the coordinated action of numerous proteins. Most proteins are thought to localize to magnetosomes during the initial stages of organelle biogenesis, regardless of environmental conditions. However, the magnetite-shaping protein Mms6 is only found in magnetosomes that contain magnetic particles, suggesting that it might conditionally localize after the formation of magnetosome membranes. The mechanisms for this unusual mode of localization to magnetosomes are unclear. Here, using pulse-chase labeling, we show that Mms6 translated under non-biomineralization conditions translocates to pre-formed magnetosomes when cells are shifted to biomineralizing conditions. Genes essential for magnetite production, namely mamE, mamM, and mamO, are necessary for Mms6 localization, whereas mamN inhibits Mms6 localization. MamD localization was also investigated and found to be controlled by similar cellular factors. The membrane localization of Mms6 is dependent on a glycine-leucine repeat region, while the N-terminal domain of Mms6 is necessary for retention in the cytosol and impacts conditional localization to magnetosomes. The N-terminal domain is also sufficient to impart conditional magnetosome localization to MmsF, altering its native constitutive magnetosome localization. Our work illuminates an alternative mode of protein localization to magnetosomes in which Mms6 and MamD are excluded from magnetosomes by MamN until biomineralization initiates, whereupon they translocate into magnetosome membranes to control the development of growing magnetite crystals.IMPORTANCEMagnetotactic bacteria (MTB) are a diverse group of bacteria that form magnetic nanoparticles surrounded by membranous organelles. MTB are widespread and serve as a model for bacterial organelle formation and biomineralization. Magnetosomes require a specific cohort of proteins to enable magnetite formation, but how those proteins are localized to magnetosome membranes is unclear. Here, we investigate protein localization using pulse-chase microscopy and find a system of protein coordination dependent on biomineralization-permissible conditions. In addition, our findings highlight a protein domain that alters the localization behavior of magnetosome proteins. Utilization of this protein domain may provide a synthetic route for conditional functionalization of magnetosomes for biotechnological applications.

磁孢菌 AMB-1 中 Mms6 在磁体细胞器中条件定位的内在和外在决定因素。
磁小体细菌是一类多种多样的微生物,它们利用装在细胞内脂质磁小体细胞器中的磁性颗粒来引导沿地磁场导航。磁小孢子菌 AMB-1 中磁小体及其磁性晶体的发育需要大量蛋白质的协调作用。人们认为,在细胞器生物形成的初始阶段,大多数蛋白质都会定位到磁小体上,与环境条件无关。然而,磁铁矿塑造蛋白 Mms6 只存在于含有磁性颗粒的磁小体中,这表明它可能在磁小体膜形成后有条件地定位。这种不寻常的磁小体定位模式的机制尚不清楚。在这里,我们利用脉冲追逐标记技术表明,当细胞转移到生物矿化条件下时,在非生物矿化条件下翻译的 Mms6 会转移到预先形成的磁小体上。磁铁矿产生所必需的基因(即 mamE、mamM 和 mamO)是 Mms6 定位所必需的,而 mamN 则抑制 Mms6 定位。还对 MamD 的定位进行了研究,发现它也受类似细胞因素的控制。Mms6 的膜定位依赖于一个甘氨酸-亮氨酸重复区域,而 Mms6 的 N 端结构域是保留在细胞质中的必要条件,并影响磁小体的条件定位。N 端结构域也足以赋予 MmsF 条件性磁小体定位,改变其原生组成型磁小体定位。我们的研究揭示了蛋白质定位到磁小体的另一种模式,在这种模式中,Mms6 和 MamD 被 MamN 排除在磁小体之外,直到生物矿化开始,然后它们转位到磁小体膜中,控制生长中的磁铁矿晶体的发育。重要意义磁小体细菌(MTB)是一个多样化的细菌群体,它们形成由膜细胞器包围的磁性纳米颗粒。MTB 广泛分布,是细菌细胞器形成和生物矿化的典范。磁小体需要一组特定的蛋白质才能形成磁铁矿,但这些蛋白质如何定位到磁小体膜上尚不清楚。在这里,我们利用脉冲追逐显微镜研究了蛋白质定位,发现了一个取决于生物矿化允许条件的蛋白质协调系统。此外,我们的研究结果还强调了一个能改变磁小体蛋白质定位行为的蛋白质结构域。利用这一蛋白质结构域可以为磁小体的条件功能化提供一条合成途径,从而实现生物技术应用。
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
Journal of Bacteriology
Journal of Bacteriology 生物-微生物学
CiteScore
6.10
自引率
9.40%
发文量
324
审稿时长
1.3 months
期刊介绍: The Journal of Bacteriology (JB) publishes research articles that probe fundamental processes in bacteria, archaea and their viruses, and the molecular mechanisms by which they interact with each other and with their hosts and their environments.
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