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Thiol Oxidation (thiol + oxidation)

Distribution by Scientific Domains
Medical Sciences40%

Selected Abstracts

Thiol oxidation of cell signaling proteins: Controlling an apoptotic equilibrium

JOURNAL OF CELLULAR BIOCHEMISTRY, Issue 1 2004
Janet V. Cross
Abstract Studies of cell signal transduction have predominantly focused on regulation of protein function by phosphorylation. However, recent efforts have begun to uncover another layer of regulation mediated by direct oxidation of cysteine residues in signaling proteins. Typically induced during signaling responses accompanied by generation of reactive oxygen species, these thiol modifications have a variety of functional consequences for target proteins. Using specific signaling protein targets as examples, we discuss how thiol oxidation generally activates pro-apoptotic signaling pathways while inhibiting pathways that promote cell survival. We propose a model in which thiol oxidation acts to control the equilibrium between survival and apoptosis, fine tuning cellular responses that play a central role in the apoptotic decision-making process. We identify areas of focus for future work, including a better understanding of specificity in thiol oxidation events, and a critical need for approaches to examine these modifications under physiologically relevant signaling conditions. © 2004 Wiley-Liss, Inc. [source]

The thioredoxin-independent isoform of chloroplastic glyceraldehyde-3-phosphate dehydrogenase is selectively regulated by glutathionylation

FEBS JOURNAL, Issue 1 2007
Mirko Zaffagnini
In animal cells, many proteins have been shown to undergo glutathionylation under conditions of oxidative stress. By contrast, very little is known about this post-translational modification in plants. In the present work, we showed, using mass spectrometry, that the recombinant chloroplast A4 -glyceraldehyde-3-phosphate dehydrogenase (A4 -GAPDH) from Arabidopsis thaliana is glutathionylated with either oxidized glutathione or reduced glutathione and H2O2. The formation of a mixed disulfide between glutathione and A4 -GAPDH resulted in the inhibition of enzyme activity. A4 -GAPDH was also inhibited by oxidants such as H2O2. However, the effect of glutathionylation was reversed by reductants, whereas oxidation resulted in irreversible enzyme inactivation. On the other hand, the major isoform of photosynthetic GAPDH of higher plants (i.e. the AnBn -GAPDH isozyme in either A2B2 or A8B8 conformation) was sensitive to oxidants but did not seem to undergo glutathionylation significantly. GAPDH catalysis is based on Cys149 forming a covalent intermediate with the substrate 1,3-bisphosphoglycerate. In the presence of 1,3-bisphosphoglycerate, A4 -GAPDH was fully protected from either oxidation or glutathionylation. Site-directed mutagenesis of Cys153, the only cysteine located in close proximity to the GAPDH active-site Cys149, did not affect enzyme inhibition by glutathionylation or oxidation. Catalytic Cys149 is thus suggested to be the target of both glutathionylation and thiol oxidation. Glutathionylation could be an important mechanism of regulation and protection of chloroplast A4 -GAPDH from irreversible oxidation under stress. [source]

Mutual changes of thioredoxin and nitrosothiols during biliary cirrhosis: Results from humans and cholestatic rats,

HEPATOLOGY, Issue 2 2007
Ignazio Grattagliano
Cholestasis is associated with changes in NO metabolism and thiol oxidation. Thioredoxin contributes to regulate vascular tone and intracellular redox status by cleaving nitrosothiols and maintaining ,SH groups. This study investigated the changes in circulating thioredoxin and nitrosothiols and the relationship with protein sulfhydryls (PSH), hepatic concentrations, hyaluronate, and histology in patients with primary biliary cirrhosis (PBC) and in rats with bile duct ligation (BDL). PSH in erythrocytes were significantly decreased in stage III and IV PBC and at day 10 after BDL. Compared with controls, erythrocyte thioredoxin levels were higher in stage I through III PBC and lower in stage IV patients. Serum thioredoxin levels were significantly higher in PBC stages I and II and lower in stages III and IV. Serum nitrosothiols were higher in all PBC patients and inversely related to thioredoxin and hyaluronate. In rats, serum, hepatic, and mitochondrial thioredoxin had initially increased after BDL (day 1-3) and then decreased. After day 7 BDL, nitrosothiols were 10-fold increased in serum and liver, and even higher in mitochondria. In the liver, thioredoxin was inversely related to both nitrosothiols and PSH. In rats, the difference in time average changes from baseline among serum, hepatic, and erythrocyte thioredoxin suggests that most of circulating thioredoxin originates from the liver. Conclusion: Our findings indicate that cholestasis is associated with significant mutual and interrelated changes between circulating and hepatic thioredoxin and nitrosothiols. The increase of hepatic, mitochondrial, and circulating nitrosothiols with ongoing cholestasis suggests an active participation of NO in both liver injury and extrahepatic changes. (HEPATOLOGY 2007;45:331,339.) [source]

Thiol oxidation of cell signaling proteins: Controlling an apoptotic equilibrium

JOURNAL OF CELLULAR BIOCHEMISTRY, Issue 1 2004
Janet V. Cross
Abstract Studies of cell signal transduction have predominantly focused on regulation of protein function by phosphorylation. However, recent efforts have begun to uncover another layer of regulation mediated by direct oxidation of cysteine residues in signaling proteins. Typically induced during signaling responses accompanied by generation of reactive oxygen species, these thiol modifications have a variety of functional consequences for target proteins. Using specific signaling protein targets as examples, we discuss how thiol oxidation generally activates pro-apoptotic signaling pathways while inhibiting pathways that promote cell survival. We propose a model in which thiol oxidation acts to control the equilibrium between survival and apoptosis, fine tuning cellular responses that play a central role in the apoptotic decision-making process. We identify areas of focus for future work, including a better understanding of specificity in thiol oxidation events, and a critical need for approaches to examine these modifications under physiologically relevant signaling conditions. © 2004 Wiley-Liss, Inc. [source]

The Physiology of Endothelial Xanthine Oxidase: From Urate Catabolism to Reperfusion Injury to Inflammatory Signal Transduction

MICROCIRCULATION, Issue 3 2002
AVEDIS MENESHIAN
ABSTRACT Xanthine oxidoreductase (XOR) is a ubiquitous metalloflavoprotein that appears in two interconvertible yet functionally distinct forms: xanthine dehydrogenase (XD), which is constitutively expressed in vivo; and xanthine oxidase (XO), which is generated by the posttranslational modification of XD, either through the reversible, incremental thiol oxidation of sulfhydryl residues on XD or the irreversible proteolytic cleavage of a segment of XD, which occurs at low oxygen tension and in the presence of several proinflammatory mediators. Functionally, both XD and XO catalyze the oxidation of purines to urate. However, whereas XD requires NAD+ as an electron acceptor for these redox reactions, thereby generating the stable product NADH, XO is unable to use NAD+ as an electron acceptor, requiring instead the reduction of molecular oxygen for this purine oxidation and generating the highly reactive superoxide free radical. Nearly 100 years of study has documented the physiologic role of XD in urate catabolism. However, the rapid, posttranslational conversion of XD to the oxidantgenerating form XO provides a possible physiologic mechanism for rapid, posttranslational, oxidant-mediated signaling. XO-generated reactive oxygen species (ROS) have been implicated in various clinicopathologic entities, including ischemia/reperfusion injury and multisystem organ failure. More recently, the concept of physiologic signal transduction mediated by ROS has been proposed, and the possibility of XD to XO conversion, with subsequent ROS generation, serving as the trigger of the microvascular inflammatory response in vivo has been hypothesized. This review presents the evidence and basis for this hypothesis. [source]