Functional characterization of Fur from the strict anaerobe Clostridioides difficile provides insight into its redox-driven regulatory capacity

Ángela Fernández-Otal, Jorge Guío, Cristina Sarasa-Buisan, M. Luisa Peleato, María F. Fillat, Ángel Lanas, M. Teresa Bes
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Abstract

Clostridioides (formerly Clostridium) difficile is a leading cause of infectious diarrhea associated with antibiotic therapy. The ability of this anaerobic pathogen to acquire enough iron to proliferate under iron limitation conditions imposed by the host largely determines its pathogenicity. However, since high intracellular iron catalyzes formation of deleterious reactive hydroxyl radicals, iron uptake is tightly regulated at the transcriptional level by the ferric uptake regulator Fur. Several studies relate lacking a functional fur gene in C. difficile cells to higher oxidative stress sensitivity, colonization defect and less toxigenicity, although Fur does not appear to directly regulate either oxidative stress response genes or pathogenesis genes. In this work, we report the functional characterization of C. difficile Fur and describe an additional oxidation sensing Fur-mediated mechanism independent of iron, which affects Fur DNA-binding. Using electrophoretic mobility shift assays, we show that Fur binding to the promoters of fur, feoA and fldX genes, identified as iron and Fur-regulated genes in vivo, is specific and does not require co-regulator metal under reducing conditions. Fur treatment with H2O2 produces dose-dependent soluble high molecular weight species unable to bind to target promoters. Moreover, Fur oligomers are dithiotreitol sensitive, highlighting the importance of some interchain disulfide bond(s) for Fur oligomerization, and hence for activity. Additionally, the physiological electron transport chain NADPH-thioredoxin reductase/thioredoxin from Escherichia coli reduces inactive oligomerized C. difficile Fur that recovers activity. In conjunction with available transcriptomic data, these results suggest a previously underappreciated complexity in the control of some members of the Fur regulon that is based on Fur redox properties and might be fundamental for the adaptive response of C. difficile during infection.

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对难辨梭状芽孢杆菌(Clostridioides difficile)中的呋喃(Fur)进行功能表征,有助于深入了解其氧化还原驱动的调控能力。
艰难梭状芽孢杆菌(原艰难梭状芽孢杆菌)是与抗生素治疗相关的感染性腹泻的主要病因。这种厌氧病原体在宿主施加的铁限制条件下获得足够铁以增殖的能力在很大程度上决定了其致病性。然而,由于细胞内高铁催化形成有害的活性羟基自由基,铁吸收在转录水平上受到铁吸收调节因子 Fur 的严格调控。一些研究表明,在艰难梭菌细胞中缺乏功能性呋喃基因会导致较高的氧化应激敏感性、定植缺陷和较低的致毒性,尽管呋喃似乎并不直接调控氧化应激反应基因或致病基因。在这项工作中,我们报告了艰难梭菌Fur的功能特性,并描述了Fur介导的一种独立于铁的额外氧化感应机制,该机制会影响Fur的DNA结合。通过电泳迁移试验,我们发现呋喃与呋喃、feoA 和 fldX 基因启动子的结合是特异性的,在还原条件下不需要协同调控金属。用 H2O2 处理呋喃会产生剂量依赖性的可溶性高分子量物种,无法与目标启动子结合。此外,Fur 低聚物对二硫苏糖醇敏感,这突出表明了某些链间二硫键对 Fur 低聚物化的重要性,因此对其活性也很重要。此外,来自大肠杆菌的生理电子传递链 NADPH-硫氧还原酶/硫氧还原酶可还原失去活性的低聚糖艰难梭菌绒毛,使其恢复活性。结合现有的转录组数据,这些结果表明,Fur调控子的某些成员的控制具有以前未被充分认识到的复杂性,这种复杂性基于Fur的氧化还原特性,可能是艰难梭菌在感染期间做出适应性反应的基础。
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