| Literature DB >> 27246459 |
Feng-Chun Lo1, Chang-Chih Hsieh1, Manuel Maestre-Reyna2, Chin-Yu Chen3, Tzu-Ping Ko4, Yih-Chern Horng5, Yei-Chen Lai1, Yun-Wei Chiang6, Chih-Mao Chou7, Cheng-Hung Chiang8, Wei-Ning Huang9, Yi-Hung Lin8, D Scott Bohle10, Wen-Feng Liaw11.
Abstract
Molecular mechanisms underlying the repair of nitrosylated [Fe-S] clusters by the microbial protein YtfE remain poorly understood. The X-ray crystal structure of YtfE, in combination with EPR, magnetic circular dichroism (MCD), UV, and (17) O-labeling electron spin echo envelope modulation measurements, show that each iron of the oxo-bridged Fe(II) -Fe(III) diiron core is coordinatively unsaturated with each iron bound to two bridging carboxylates and two terminal histidines in addition to an oxo-bridge. Structural analysis reveals that there are two solvent-accessible tunnels, both of which converge to the diiron center and are critical for capturing substrates. The reactivity of the reduced-form Fe(II) -Fe(II) YtfE toward nitric oxide demonstrates that the prerequisite for N2 O production requires the two iron sites to be nitrosylated simultaneously. Specifically, the nitrosylation of the two iron sites prior to their reductive coupling to produce N2 O is cooperative. This result suggests that, in addition to any repair of iron centers (RIC) activity, YtfE acts as an NO-trapping scavenger to promote the NO to N2 O transformation under low NO flux, which precedes nitrosative stress.Entities:
Keywords: nitric oxide; non-heme diiron; protein structures; proteins
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Year: 2016 PMID: 27246459 DOI: 10.1002/chem.201600990
Source DB: PubMed Journal: Chemistry ISSN: 0947-6539 Impact factor: 5.236