A P Dicks1, D L Williams. 1. Department of Chemistry, Durham University, Durham DH1 3LE, UK. D.L.H.Williams@durham.ac.uk
Abstract
BACKGROUND: We have recently shown that S-nitrosothiols (RSNOs) decompose in aqueous buffer to give nitric oxide, an important signalling molecule, and the corresponding disulphides. This occurs by reaction with Cu+ generated from Cu2+ (supplied as hydrated Cu2+) by thiolate reduction. To establish whether these reactions are feasible in vivo, we set out to determine whether Cu2+ bound to an amino acid, a tripeptide or to human serum albumin (HSA) could serve as a Cu+ source for generation of NO from S-nitrosothiols. RESULTS: Experiments with Cu2+ bound to the tripeptide Gly-Gly-His or to two histidine molecules or to HSA showed that Cu+ was released (and trapped with neocuproine) when the copper source was treated with a thiol at pH 7.4. RSNO decomposition was achieved with all three copper sources, although not as rapidly as with added hydrated Cu2+. Decomposition was also catalyzed by ceruloplasmin. CONCLUSIONS: These results show clearly that amino-acid- and protein-bound Cu2+ can be reduced by thiolate ion to Cu+, which will generate NO from RSNO species, thus providing a realistic model for these reactions in vivo.
BACKGROUND: We have recently shown that S-nitrosothiols (RSNOs) decompose in aqueous buffer to give nitric oxide, an important signalling molecule, and the corresponding disulphides. This occurs by reaction with Cu+ generated from Cu2+ (supplied as hydrated Cu2+) by thiolate reduction. To establish whether these reactions are feasible in vivo, we set out to determine whether Cu2+ bound to an amino acid, a tripeptide or to humanserum albumin (HSA) could serve as a Cu+ source for generation of NO from S-nitrosothiols. RESULTS: Experiments with Cu2+ bound to the tripeptideGly-Gly-His or to two histidine molecules or to HSA showed that Cu+ was released (and trapped with neocuproine) when the copper source was treated with a thiol at pH 7.4. RSNO decomposition was achieved with all three copper sources, although not as rapidly as with added hydrated Cu2+. Decomposition was also catalyzed by ceruloplasmin. CONCLUSIONS: These results show clearly that amino-acid- and protein-bound Cu2+ can be reduced by thiolate ion to Cu+, which will generate NO from RSNO species, thus providing a realistic model for these reactions in vivo.
Authors: Achala de Mel; Noora Naghavi; Brian G Cousins; Innes Clatworthy; George Hamilton; Arnold Darbyshire; Alexander M Seifalian Journal: J Mater Sci Mater Med Date: 2013-11-30 Impact factor: 3.896
Authors: Moshood K Morakinyo; Itai Chipinda; Justin Hettick; Paul D Siegel; Jonathan Abramson; Robert Strongin; Bice S Martincigh; Reuben H Simoyi Journal: Can J Chem Date: 2012-08-22 Impact factor: 1.118