1999
DOI: 10.1074/jbc.274.40.28128
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Mechanism of S-Nitrosothiol Formation and Degradation Mediated by Copper Ions

Abstract: Experimental evidence is presented supporting a mechanism of S-nitrosothiol formation and degradation mediated by copper ions using bovine serum albumin, human hemoglobin and glutathione as models. We found that Cu 2؉ , but not Fe 3؉ , induces in the presence of NO a fast S-nitrosation of bovine serum albumin and human hemoglobin, and the reaction is prevented by thiol blocking reagents. During the reaction, Cu ؉ is accumulated and accounts for destabilization of the S-nitrosothiol formed. In contrast, glutath… Show more

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Cited by 141 publications
(105 citation statements)
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“…1C, detection of total Gpc-1 protein was unaffected by ascorbate (GPC ϩ Ascorbate), whereas the S1 epitope was destroyed (GPC-S1 ϩ Ascorbate). Re-S-nitrosylation with NO is dependent on a Cu 2ϩ /Cu ϩ redox cycle (34). Accordingly, when NO donor and Cu 2ϩ were provided after ascorbate treatment, the S1 epitope was partially restored (GPC-S1 ϩ Ascorbate ϩ SNP ϩ CuCl 2 ).…”
Section: Resultsmentioning
confidence: 94%
See 1 more Smart Citation
“…1C, detection of total Gpc-1 protein was unaffected by ascorbate (GPC ϩ Ascorbate), whereas the S1 epitope was destroyed (GPC-S1 ϩ Ascorbate). Re-S-nitrosylation with NO is dependent on a Cu 2ϩ /Cu ϩ redox cycle (34). Accordingly, when NO donor and Cu 2ϩ were provided after ascorbate treatment, the S1 epitope was partially restored (GPC-S1 ϩ Ascorbate ϩ SNP ϩ CuCl 2 ).…”
Section: Resultsmentioning
confidence: 94%
“…Then, by using NO released from the intrinsic SNO groups, anMan-containing HS-oligosaccharides are generated by deaminative cleavage at the GlcNH 3 ϩ residues. The triggering mechanism for NO release remains unknown, but both S-nitrosylation and NO release are dependent on a Cu 2ϩ /Cu ϩ redox cycle (34). The redox state of the cell may therefore regulate NO release.…”
Section: Polyamine Uptake By Proliferating Cells Correlates With Nodementioning
confidence: 99%
“…Studies have shown that in the presence of NO, Cu 2+ ion induces a fast S-nitrosation of bovine serum albumin and human hemoglobin, and this reaction is prevented by thiol blocking reagents. During this reaction, Cu 2+ is accumulated and causes destabilization of the S-nitrosothiols formed (Stubauer et al, 1999). In another study it was shown that lower concentration Fe 2+ favored formation and stabilization of S-nitrosothiols however higher concentrations (higher than 10µM) abolished the effect.…”
Section: $ S-nitrosothiol Catabolismmentioning
confidence: 96%
“…It appears that the success of the biotin switch assay is quite dependent on the contamination of this and other metals in the solutions. It is known that reduced copper can reduce RSNO [25,29,30,42,43]. The mechanism for the decomposition of S-nitrosothiols by Cu(I) ions likely involves the one-electron reduction of the RSNO group to give the free thiol, NO and Cu(II).…”
Section: Discussionmentioning
confidence: 99%