Disulfide bond as a switch for copper-zinc superoxide dismutase activity in asthma

Loss of superoxide dismutase (SOD) activity is a defining biochemical feature of asthma. However, mechanisms for the reduced activity are unknown. We hypothesized that loss of asthmatic SOD activity is due to greater susceptibility to oxidative inactivation. Activity assays of blood samples from ast...

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Veröffentlicht in:	Antioxidants & redox signaling 2013-02, Vol.18 (4), p.412-423
Hauptverfasser:	Ghosh, Sudakshina, Willard, Belinda, Comhair, Suzy A A, Dibello, Patricia, Xu, Weiling, Shiva, Sruti, Aulak, Kulwant S, Kinter, Michael, Erzurum, Serpil C
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Sprache:	eng
Schlagworte:	Adult Amino Acid Sequence Asthma - blood Asthma - enzymology Blood Platelets - enzymology Case-Control Studies Cystine - chemistry Dithiothreitol - chemistry Erythrocytes - enzymology Female Glutathione - metabolism Humans Hydrogen Peroxide - chemistry Male Molecular Sequence Data Original Research Communications Oxidants - chemistry Oxidation-Reduction Oxidative Stress Peptide Fragments - chemistry Reducing Agents - chemistry Superoxide Dismutase - blood Superoxide Dismutase - chemistry
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container_title	Antioxidants & redox signaling
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creator	Ghosh, Sudakshina Willard, Belinda Comhair, Suzy A A Dibello, Patricia Xu, Weiling Shiva, Sruti Aulak, Kulwant S Kinter, Michael Erzurum, Serpil C
description	Loss of superoxide dismutase (SOD) activity is a defining biochemical feature of asthma. However, mechanisms for the reduced activity are unknown. We hypothesized that loss of asthmatic SOD activity is due to greater susceptibility to oxidative inactivation. Activity assays of blood samples from asthmatics and healthy controls revealed impaired dismutase activity of copper-zinc SOD (CuZnSOD) in asthma. CuZnSOD purified from erythrocytes or airway epithelial cells from asthmatic was highly susceptible to oxidative inactivation. Proteomic analyses identified that inactivation was related to oxidation of cysteine 146 (C146), which is usually disulfide bonded to C57. The susceptibility of cysteines pointed to an alteration in protein structure, which is likely related to the loss of disulfide bond. We speculated that a shift to greater intracellular reducing potential might account for the change. Strikingly, measures of reduced and oxidized glutathione confirmed greater reducing intracellular state in asthma, compared with controls. Similarly, greater free thiol in CuZnSOD was confirmed by ~2-fold greater N-ethylmaleimide binding to C146 in asthma as compared with controls. Greater reducing potential under a chronic inflammatory state of asthma, thus, leads to susceptibility of CuZnSOD to oxidative inactivation due to cleavage of C57-C146 disulfide bond and exposure of usually unavailable cysteines. Vulnerability of CuZnSOD influenced by redox likely amplifies injury and inflammation during acute asthma attacks when reactive oxygen species are explosively generated. Overall, this study identifies a new paradigm for understanding the chemical basis of inflammation, in which redox regulation of thiol availability dictates protein susceptibility to environmental and endogenously generated reactive species.
doi_str_mv	10.1089/ars.2012.4566
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However, mechanisms for the reduced activity are unknown. We hypothesized that loss of asthmatic SOD activity is due to greater susceptibility to oxidative inactivation. Activity assays of blood samples from asthmatics and healthy controls revealed impaired dismutase activity of copper-zinc SOD (CuZnSOD) in asthma. CuZnSOD purified from erythrocytes or airway epithelial cells from asthmatic was highly susceptible to oxidative inactivation. Proteomic analyses identified that inactivation was related to oxidation of cysteine 146 (C146), which is usually disulfide bonded to C57. The susceptibility of cysteines pointed to an alteration in protein structure, which is likely related to the loss of disulfide bond. We speculated that a shift to greater intracellular reducing potential might account for the change. Strikingly, measures of reduced and oxidized glutathione confirmed greater reducing intracellular state in asthma, compared with controls. Similarly, greater free thiol in CuZnSOD was confirmed by ~2-fold greater N-ethylmaleimide binding to C146 in asthma as compared with controls. Greater reducing potential under a chronic inflammatory state of asthma, thus, leads to susceptibility of CuZnSOD to oxidative inactivation due to cleavage of C57-C146 disulfide bond and exposure of usually unavailable cysteines. Vulnerability of CuZnSOD influenced by redox likely amplifies injury and inflammation during acute asthma attacks when reactive oxygen species are explosively generated. 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However, mechanisms for the reduced activity are unknown. We hypothesized that loss of asthmatic SOD activity is due to greater susceptibility to oxidative inactivation. Activity assays of blood samples from asthmatics and healthy controls revealed impaired dismutase activity of copper-zinc SOD (CuZnSOD) in asthma. CuZnSOD purified from erythrocytes or airway epithelial cells from asthmatic was highly susceptible to oxidative inactivation. Proteomic analyses identified that inactivation was related to oxidation of cysteine 146 (C146), which is usually disulfide bonded to C57. The susceptibility of cysteines pointed to an alteration in protein structure, which is likely related to the loss of disulfide bond. We speculated that a shift to greater intracellular reducing potential might account for the change. Strikingly, measures of reduced and oxidized glutathione confirmed greater reducing intracellular state in asthma, compared with controls. Similarly, greater free thiol in CuZnSOD was confirmed by ~2-fold greater N-ethylmaleimide binding to C146 in asthma as compared with controls. Greater reducing potential under a chronic inflammatory state of asthma, thus, leads to susceptibility of CuZnSOD to oxidative inactivation due to cleavage of C57-C146 disulfide bond and exposure of usually unavailable cysteines. Vulnerability of CuZnSOD influenced by redox likely amplifies injury and inflammation during acute asthma attacks when reactive oxygen species are explosively generated. 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subjects	Adult Amino Acid Sequence Asthma - blood Asthma - enzymology Blood Platelets - enzymology Case-Control Studies Cystine - chemistry Dithiothreitol - chemistry Erythrocytes - enzymology Female Glutathione - metabolism Humans Hydrogen Peroxide - chemistry Male Molecular Sequence Data Original Research Communications Oxidants - chemistry Oxidation-Reduction Oxidative Stress Peptide Fragments - chemistry Reducing Agents - chemistry Superoxide Dismutase - blood Superoxide Dismutase - chemistry
title	Disulfide bond as a switch for copper-zinc superoxide dismutase activity in asthma
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