Title of article
Nitric oxide-related species-induced protein oxidation: Reversible, irreversible, and protective effects on enzyme function of papain
Author/Authors
Antti J. V??n?nen، نويسنده , , Esko Kankuri، نويسنده , , Pekka Rauhala، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2005
Pages
10
From page
1102
To page
1111
Abstract
Protein oxidation, irreversible modification, and inactivation may play key roles in various neurodegenerative disorders. Therefore, we studied the effects of the potentially in vivo occurring nitric oxide-related species on two different markers of protein oxidation: protein carbonyl generation on bovine serum albumine (BSA) and loss of activity of a cysteine-dependent protease, papain, in vitro by using Angeliʹs salt, papanonoate, SIN-1, and S-nitrosoglutathione (GSNO) as donors of nitroxyl, nitric oxide, peroxynitrite, and nitrosonium ions, respectively. Angeliʹs salt, SIN-1, and papanonoate (0–1000 μM) all generated a concentration-dependent increase in carbonyl formation on BSA (107, 60, and 45%, respectively). GSNO did not affect carbonyl formation. Papain was inhibited by Angeliʹs salt, SIN-1, papanonoate, and GSNO with IC50 values of 0.62, 2.3, 54, and 80 μM, respectively. Angeliʹs salt (3.16 μM)-induced papain inactivation was only partially reversible, while the effects of GSNO (316 μM) and papanonoate (316 μM) were reversible upon addition of excess DTT. The Angeliʹs salt-mediated DTT-irreversible inhibition of papain was prevented by GSNO or papanonoate pretreatment, hypothetically through mixed disulfide formation or S-nitrosylation of the catalytically critical thiol group of papain. These results, for the first time, compare the generation of carbonyls in proteins by Angeliʹs salt, papanonoate, and SIN-1. Furthermore, these results suggest that S-nitrosothiols may have a novel function in protecting critical thiols from irreversible oxidative damage.
Keywords
thiols , nitric oxide , Peroxynitrite , S-nitrosothiols , Nitroxyl , free radicals , papain , Protein oxidation
Journal title
Free Radical Biology and Medicine
Serial Year
2005
Journal title
Free Radical Biology and Medicine
Record number
520140
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