Cysteine regulation of protein function – as exemplified by NMDA-receptor modulation

Until recently cysteine residues, especially those located extracellularly, were thought to be important for metal coordination, catalysis and protein structure by forming disulfide bonds – but they were not thought to regulate protein function. However, this is not the case. Crucial cysteine residu...

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Veröffentlicht in:	Trends in Neurosciences 2002-09, Vol.25 (9), p.474-480
Hauptverfasser:	Lipton, Stuart A., Choi, Yun-Beom, Takahashi, Hiroto, Zhang, Dongxian, Li, Weizhong, Godzik, Adam, Bankston, Laurie A.
Format:	Artikel
Sprache:	eng
Schlagworte:	Amino acids Animals catalysis Cysteine - metabolism cysteine residue Humans Models, Molecular Neurology Nitric oxide Nitric Oxide - metabolism NMDA receptors Oxidation-Reduction Protein Structure, Tertiary Proteins Receptors, N-Methyl-D-Aspartate - chemistry Receptors, N-Methyl-D-Aspartate - physiology Redox modulation regulation S-Nitrosothiols - metabolism S-nitrosylation Sulfhydryl Compounds - metabolism Sulfhydryl groups Thiol groups Zinc
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creator	Lipton, Stuart A. Choi, Yun-Beom Takahashi, Hiroto Zhang, Dongxian Li, Weizhong Godzik, Adam Bankston, Laurie A.
description	Until recently cysteine residues, especially those located extracellularly, were thought to be important for metal coordination, catalysis and protein structure by forming disulfide bonds – but they were not thought to regulate protein function. However, this is not the case. Crucial cysteine residues can be involved in modulation of protein activity and signaling events via other reactions of their thiol (sulfhydryl; –SH) groups. These reactions can take several forms, such as redox events (chemical reduction or oxidation), chelation of transition metals (chiefly Zn 2+, Mn 2+ and Cu 2+) or S-nitrosylation [the catalyzed transfer of a nitric oxide (NO) group to a thiol group]. In several cases, these disparate reactions can compete with one another for the same thiol group on a single cysteine residue, forming a molecular switch composed of a latticework of possible redox, NO or Zn 2+ modifications to control protein function. Thiol-mediated regulation of protein function can also involve reactions of cysteine residues that affect ligand binding allosterically. This article reviews the basis for these molecular cysteine switches, drawing on the NMDA receptor as an exemplary protein, and proposes a molecular model for the action of S-nitrosylation based on recently derived crystal structures. Cysteine residues are no longer just for protein structure. Recent evidence shows that reactions of cysteine sulfhydryl groups with nitric oxide, Zn2+ or redox agents can regulate protein function in a manner analogous to phosphorylation.
doi_str_mv	10.1016/S0166-2236(02)02245-2
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This article reviews the basis for these molecular cysteine switches, drawing on the NMDA receptor as an exemplary protein, and proposes a molecular model for the action of S-nitrosylation based on recently derived crystal structures. Cysteine residues are no longer just for protein structure. 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subjects	Amino acids Animals catalysis Cysteine - metabolism cysteine residue Humans Models, Molecular Neurology Nitric oxide Nitric Oxide - metabolism NMDA receptors Oxidation-Reduction Protein Structure, Tertiary Proteins Receptors, N-Methyl-D-Aspartate - chemistry Receptors, N-Methyl-D-Aspartate - physiology Redox modulation regulation S-Nitrosothiols - metabolism S-nitrosylation Sulfhydryl Compounds - metabolism Sulfhydryl groups Thiol groups Zinc
title	Cysteine regulation of protein function – as exemplified by NMDA-receptor modulation
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