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志贺氏菌铁转运系统的遗传学与环境调控

Genetics and environmental regulation of Shigella iron transport systems.

作者信息

Wyckoff Elizabeth E, Boulette Megan L, Payne Shelley M

机构信息

Section of Molecular Genetics and Microbiology, Institute for Cellular and Molecular Biology, University of Texas, Austin, TX 78712, USA.

出版信息

Biometals. 2009 Feb;22(1):43-51. doi: 10.1007/s10534-008-9188-x. Epub 2009 Jan 7.

DOI:10.1007/s10534-008-9188-x
PMID:19130265
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3293496/
Abstract

Shigella spp. have transport systems for both ferric and ferrous iron. The iron can be taken up as free iron or complexed to a variety of carriers. All Shigella species have both the Feo and Sit systems for acquisition of ferrous iron, and all have at least one siderophore-mediated system for transport of ferric iron. Several of the transport systems, including Sit, Iuc/IutA (aerobactin synthesis and transport), Fec (ferric di-citrate uptake), and Shu (heme transport) are encoded within pathogenicity islands. The presence and the genomic locations of these islands vary considerably among the Shigella species, and even between isolates of the same species. The expression of the iron transport systems is influenced by the concentration of iron and by environmental conditions including the level of oxygen. ArcA and FNR regulate iron transport gene expression as a function of oxygen tension, with the sit and iuc promoters being highly expressed in aerobic conditions, while the feo ferrous iron transporter promoter is most active under anaerobic conditions. The effects of oxygen are also seen in infection of cultured cells by Shigella flexneri; the Sit and Iuc systems support plaque formation under aerobic conditions, whereas Feo allows plaque formation anaerobically.

摘要

志贺氏菌属具有摄取三价铁和二价铁的转运系统。铁可以以游离铁的形式被摄取,也可以与多种载体结合。所有志贺氏菌都有用于摄取二价铁的Feo和Sit系统,并且都至少有一种铁载体介导的摄取三价铁的系统。包括Sit、Iuc/IutA(气杆菌素合成和转运)、Fec(三价柠檬酸铁摄取)和Shu(血红素转运)在内的几种转运系统由致病岛编码。这些致病岛的存在及其基因组位置在志贺氏菌属之间甚至同一物种的不同分离株之间都有很大差异。铁转运系统的表达受铁浓度和包括氧气水平在内的环境条件影响。ArcA和FNR根据氧气张力调节铁转运基因的表达,sit和iuc启动子在有氧条件下高表达,而feo二价铁转运蛋白启动子在厌氧条件下最活跃。氧气的影响在弗氏志贺氏菌感染培养细胞中也可见;Sit和Iuc系统在有氧条件下支持噬斑形成,而Feo在厌氧条件下允许噬斑形成。

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