Structural Characteristics of the Redox-sensing Coiled Coil in the Voltage-gated H+ Channel |
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| Authors: | Yuichiro Fujiwara Kohei Takeshita Atsushi Nakagawa Yasushi Okamura |
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| Affiliation: | From the ‡Department of Physiology, Graduate School of Medicine.;§Research Center for State-of-the-Art Functional Protein Analysis, Institute for Protein Research, and ;¶Graduate School of Frontier Biosciences, Osaka University, Osaka 565-0871, Japan |
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| Abstract: | ![]()
Oxidation is an important biochemical defense mechanism, but it also elicits toxicity; therefore, oxidation must be under strict control. In phagocytotic events in neutrophils, the voltage-gated H+ (Hv) channel is a key regulator of the production of reactive oxygen species against invading bacteria. The cytoplasmic domain of the Hv channel forms a dimeric coiled coil underpinning a dimerized functional unit. Importantly, in the alignment of the coiled-coil core, a conserved cysteine residue forms a potential intersubunit disulfide bond. In this study, we solved the crystal structures of the coiled-coil domain in reduced, oxidized, and mutated (Cys → Ser) states. The crystal structures indicate that a pair of Cys residues forms an intersubunit disulfide bond dependent on the redox conditions. CD spectroscopy revealed that the disulfide bond increases the thermal stability of the coiled-coil protein. We also reveal that two thiol modifier molecules are able to bind to Cys in a redox-dependent manner without disruption of the dimeric coiled-coil assembly. Thus, the biochemical properties of the cytoplasmic coiled-coil domain in the Hv channel depend on the redox condition, which may play a role in redox sensing in the phagosome. |
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| Keywords: | Biosensors Ion Channels Oxidation-Reduction Protein Structure Proton Transport Coiled Coil Proton Channel Ion Channel Structure-Function Ion Channel Biophysics Redox |
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