Babraham Institute, Babraham Research Campus, Babraham, Cambridge, United Kingdom.
School of Life Sciences, University of Essex, Colchester, United Kingdom.
mBio. 2023 Feb 28;14(1):e0258922. doi: 10.1128/mbio.02589-22. Epub 2023 Jan 16.
Many bacteria of the genus are facultative anaerobes able to reduce a broad range of soluble and insoluble substrates, including Fe(III) mineral oxides. Under anoxic conditions, the bacterium Shewanella oneidensis MR-1 uses a porin-cytochrome complex (Mtr) to mediate extracellular electron transfer (EET) across the outer membrane to extracellular substrates. However, it is unclear how EET prevents generating harmful reactive oxygen species (ROS) when exposed to oxic environments. The Mtr complex is expressed under anoxic and oxygen-limited conditions and contains an extracellular MtrC subunit. This has a conserved CXC motif that inhibits aerobic growth when removed. This inhibition is caused by an increase in ROS that kills the majority of S. oneidensis cells in culture. To better understand this effect, soluble MtrC isoforms with modified CXC were isolated. These isoforms produced increased concentrations of HO in the presence of flavin mononucleotide (FMN) and greatly increased the affinity between MtrC and FMN. X-ray crystallography revealed that the molecular structure of MtrC isoforms was largely unchanged, while small-angle X-ray scattering suggested that a change in flexibility was responsible for controlling FMN binding. Together, these results reveal that FMN reduction in S. oneidensis MR-1 is controlled by the redox-active disulfide on the cytochrome surface. In the presence of oxygen, the disulfide forms, lowering the affinity for FMN and decreasing the rate of peroxide formation. This cysteine pair consequently allows the cell to respond to changes in oxygen level and survive in a rapidly transitioning environment. Bacteria that live at the oxic/anoxic interface have to rapidly adapt to changes in oxygen levels within their environment. The facultative anaerobe Shewanella oneidensis MR-1 can use EET to respire in the absence of oxygen, but on exposure to oxygen, EET could directly reduce extracellular oxygen and generate harmful reactive oxygen species that damage the bacterium. By modifying an extracellular cytochrome called MtrC, we show how preventing a redox-active disulfide from forming causes the production of cytotoxic concentrations of peroxide. The disulfide affects the affinity of MtrC for the redox-active flavin mononucleotide, which is part of the EET pathway. Our results demonstrate how a cysteine pair exposed on the surface controls the path of electron transfer, allowing facultative anaerobic bacteria to rapidly adapt to changes in oxygen concentration at the oxic/anoxic interface.
许多属于 的细菌是兼性厌氧菌,能够还原广泛的可溶性和不溶性底物,包括 Fe(III) 矿物氧化物。在缺氧条件下,细菌 Shewanella oneidensis MR-1 使用孔蛋白-细胞色素复合物 (Mtr) 将细胞外电子转移 (EET) 穿过外膜传递到细胞外底物。然而,当暴露于含氧环境时,EET 如何防止产生有害的活性氧 (ROS) 尚不清楚。Mtr 复合物在缺氧和氧气有限的条件下表达,包含一个细胞外 MtrC 亚基。这个亚基有一个保守的 CXC 基序,当被去除时会抑制有氧生长。这种抑制是由 ROS 的增加引起的,ROS 会杀死培养物中大多数 S. oneidensis 细胞。为了更好地理解这种影响,分离出了具有修饰的 CXC 的可溶性 MtrC 同工型。这些同工型在黄素单核苷酸 (FMN) 的存在下产生了更高浓度的 HO,并大大增加了 MtrC 和 FMN 之间的亲和力。X 射线晶体学揭示了 MtrC 同工型的分子结构基本不变,而小角度 X 射线散射表明,柔韧性的变化负责控制 FMN 结合。总之,这些结果表明,S. oneidensis MR-1 中的 FMN 还原受细胞色素表面上的氧化还原活性二硫键控制。在氧气存在下,二硫键形成,降低了对 FMN 的亲和力并降低了过氧化物形成的速率。因此,该半胱氨酸对允许细胞对氧气水平的变化做出反应并在快速转换的环境中存活。生活在有氧/缺氧界面的细菌必须快速适应其环境中氧气水平的变化。兼性厌氧菌 Shewanella oneidensis MR-1 可以在没有氧气的情况下进行 EET 呼吸,但是暴露在氧气中时,EET 可以直接还原细胞外氧气并产生有害的活性氧,从而损害细菌。通过修饰一种称为 MtrC 的细胞外细胞色素,我们展示了如何防止形成氧化还原活性二硫键导致细胞毒性浓度的过氧化物的产生。二硫键影响 MtrC 对 EET 途径中部分氧化还原活性黄素单核苷酸的亲和力。我们的结果表明,暴露在表面上的半胱氨酸对如何控制电子转移的路径,允许兼性厌氧菌快速适应有氧/缺氧界面处氧气浓度的变化。
