Litcius/Paper detail

Biological Mechanisms of S-Nitrosothiol Formation and Degradation: How Is Specificity of S-Nitrosylation Achieved?

Christopher B. Massa, Ziping Liu, Sheryse Taylor, Ashley P. Pettit, Marena N. Stakheyeva, Е. И. Короткова, Valentina Popova, Elena N. Atochina‐Vasserman, Andrew J. Gow

2021Antioxidants34 citationsDOIOpen Access PDF

Abstract

The modification of protein cysteine residues underlies some of the diverse biological functions of nitric oxide (NO) in physiology and disease. The formation of stable nitrosothiols occurs under biologically relevant conditions and time scales. However, the factors that determine the selective nature of this modification remain poorly understood, making it difficult to predict thiol targets and thus construct informatics networks. In this review, the biological chemistry of NO will be considered within the context of nitrosothiol formation and degradation whilst considering how specificity is achieved in this important post-translational modification. Since nitrosothiol formation requires a formal one-electron oxidation, a classification of reaction mechanisms is proposed regarding which species undergoes electron abstraction: NO, thiol or S-NO radical intermediate. Relevant kinetic, thermodynamic and mechanistic considerations will be examined and the impact of sources of NO and the chemical nature of potential reaction targets is also discussed.

Topics & Concepts

S-NitrosylationThiolCysteineChemistryContext (archaeology)Posttranslational modificationNitric oxideBiomoleculeCombinatorial chemistryBiophysicsBiochemistryBiologyOrganic chemistryEnzymePaleontologyNitric Oxide and Endothelin EffectsRenin-Angiotensin System StudiesRedox biology and oxidative stress