一种双铁蛋白,通过稳定铁过氧物种,作为 Fe[II] 和氧气传感器招募,参与细菌趋化作用。
A di-iron protein recruited as an Fe[II] and oxygen sensor for bacterial chemotaxis functions by stabilizing an iron-peroxy species.
机构信息
Department of Chemistry and Chemical Biology, Cornell University, Ithaca, NY 14853.
Philips Research Institute for Oral Health, Virginia Commonwealth University, Richmond, VA 23298.
出版信息
Proc Natl Acad Sci U S A. 2019 Jul 23;116(30):14955-14960. doi: 10.1073/pnas.1904234116. Epub 2019 Jul 3.
Abstract
Many bacteria contain cytoplasmic chemoreceptors that lack sensor domains. Here, we demonstrate that such cytoplasmic receptors found in 8 different bacterial and archaeal phyla genetically couple to metalloproteins related to β-lactamases and nitric oxide reductases. We show that this oxygen-binding di-iron protein (ODP) acts as a sensor for chemotactic responses to both iron and oxygen in the human pathogen (). The ODP di-iron site binds oxygen at high affinity to reversibly form an unusually stable μ-peroxo adduct. Crystal structures of ODP from and the thermophile () in the Fe[III]-O, Zn[II], and apo states display differences in subunit association, conformation, and metal coordination that indicate potential mechanisms for sensing. In reconstituted systems, iron-peroxo ODP destabilizes the phosphorylated form of the receptor-coupled histidine kinase CheA, thereby providing a biochemical link between oxygen sensing and chemotaxis in diverse prokaryotes, including anaerobes of ancient origin.
摘要
许多细菌都含有缺乏感应结构域的细胞质化学感受器。在这里,我们证明,在 8 个不同的细菌和古菌门中发现的这种细胞质受体与β-内酰胺酶和一氧化氮还原酶相关的金属蛋白酶发生遗传偶联。我们表明,这种与氧结合的二铁蛋白(ODP)作为人类病原体()中对铁和氧的趋化反应的传感器。ODP 的二铁位点以高亲和力结合氧,可逆地形成一种异常稳定的μ-过氧加合物。来自和嗜热菌()的 ODP 的 Fe[III]-O、Zn[II]和apo 状态的晶体结构显示亚基缔合、构象和金属配位的差异,表明了用于感应的潜在机制。在重建的系统中,铁过氧 ODP 使受体偶联组氨酸激酶 CheA 的磷酸化形式失稳,从而为包括起源古老的厌氧菌在内的各种原核生物中的氧感应和趋化作用提供了生化联系。
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