Using methodology developed herein, it is found that reactive persulfides and polysulfides are formed endogenously from both small molecule species and proteins in high amounts in mammalian cells and tissues. These reactive sulfur species were biosynthesized by two major sulfurtransferases: cystathionine β-synthase and cystathionine γ-lyase. Quantitation of these species indicates that high concentrations of glutathione persulfide (perhydropersulfide >100 μM) and other cysteine persulfide and polysulfide derivatives in peptides/proteins were endogenously produced and maintained in the plasma, cells, and tissues of mammals (rodent and human). It is expected that persulfides are especially nucleophilic and reducing. This view was found to be the case, because they quickly react with H 2 O 2 and a recently described biologically generated electrophile 8-nitroguanosine 3′,5′-cyclic monophosphate. These results indicate that persulfides are potentially important signaling/effector species, and because H 2 S can be generated from persulfide degradation, much of the reported biological activity associated with H 2 S may actually be that of persulfides. That is, H 2 S may act primarily as a marker for the biologically active of persulfide species.thiol redox | hydrogen sulfide | electrophilic signaling | polysulfidomics H ydrogen sulfide (H 2 S) has been suggested to be an endogenous small molecule signaling species (1) by unknown mechanisms. Our laboratory recently showed that the presence of hydrogen sulfide anion (HS − ) may be responsible for the regulation and metabolism of various important electrophilic species [e.g., 8-nitroguanosine 3′,5′-cyclic GMP (8-nitro-cGMP)] (2). However, these studies also indicated that reactive intermediates other than HS − likely react with the electrophiles of interest. These previous studies alluded to the generation of a more reactive sulfur species capable of reacting with electrophiles, such as 8-nitro-cGMP. As reported herein, it was determined that reactive sulfur intermediates, such as hydropersulfides (RSSH) and polysulfides [RS(S) n H and RS(S) n SR], are formed in appreciable amounts during sulfur amino acid metabolism and possess important chemical and biological properties. Some of these sulfide species have long been known as sulfane sulfur compounds, which were suggested to exist endogenously in mammalian systems (1,(3)(4)(5). Reports also indicated that a hydropersulfide moiety with the general molecular formula RSSH may be formed on specific protein cysteine (Cys) residues, most typically of sulfur-transferring enzymes (i.e., sulfurtransferases) during enzymatic reactions (1, 5). Although such persulfide chemical reactivity is thought to be involved in the catalytic activity of particular enzymes (e.g., rhodanese, Cys desulfurases, and sulfide:quinone oxidoreductase) (6, 7), the more general physiological function and occurrence of Cys persulfides (CysSSH) and related species in cells and tissues, especially mammals, were unclear. Moreover, the exact chemical nature ...
Cysteine hydropersulfide (CysSSH) occurs in abundant quantities in various organisms, yet little is known about its biosynthesis and physiological functions. Extensive persulfide formation is apparent in cysteine-containing proteins in Escherichia coli and mammalian cells and is believed to result from post-translational processes involving hydrogen sulfide-related chemistry. Here we demonstrate effective CysSSH synthesis from the substrate l-cysteine, a reaction catalyzed by prokaryotic and mammalian cysteinyl-tRNA synthetases (CARSs). Targeted disruption of the genes encoding mitochondrial CARSs in mice and human cells shows that CARSs have a crucial role in endogenous CysSSH production and suggests that these enzymes serve as the principal cysteine persulfide synthases in vivo. CARSs also catalyze co-translational cysteine polysulfidation and are involved in the regulation of mitochondrial biogenesis and bioenergetics. Investigating CARS-dependent persulfide production may thus clarify aberrant redox signaling in physiological and pathophysiological conditions, and suggest therapeutic targets based on oxidative stress and mitochondrial dysfunction.
The signaling pathway of nitric oxide (NO) depends mainly on guanosine 3',5'-cyclic monophosphate (cGMP). Here we report the formation and chemical biology of a nitrated derivative of cGMP, 8-nitroguanosine 3',5'-cyclic monophosphate (8-nitro-cGMP), in NO-mediated signal transduction. Immunocytochemistry demonstrated marked 8-nitro-cGMP production in various cultured cells in an NO-dependent manner. This finding was confirmed by HPLC plus electrochemical detection and tandem mass spectrometry. 8-Nitro-cGMP activated cGMP-dependent protein kinase and showed unique redox-active properties independent of cGMP activity. Formation of protein Cys-cGMP adducts by 8-nitro-cGMP was identified as a new post-translational modification, which we call protein S-guanylation. 8-Nitro-cGMP seems to regulate the redox-sensor signaling protein Keap1, via S-guanylation of the highly nucleophilic cysteine sulfhydryls of Keap1. This study reveals 8-nitro-cGMP to be a second messenger of NO and sheds light on new areas of the physiology and chemical biology of signal transduction by NO.
An emerging aspect of redox signaling is the pathway mediated by electrophilic byproducts, such as nitrated cyclic nucleotide (for example, 8-nitroguanosine 3′,5′-cyclic monophosphate (8-nitro-cGMP)) and nitro or keto derivatives of unsaturated fatty acids, generated via reactions of inflammation-related enzymes, reactive oxygen species, nitric oxide and secondary products. Here we report that enzymatically generated hydrogen sulfide anion (HS−) regulates the metabolism and signaling actions of various electrophiles. HS− reacts with electrophiles, best represented by 8-nitro-cGMP, via direct sulfhydration and modulates cellular redox signaling. The relevance of this reaction is reinforced by the significant 8-nitro-cGMP formation in mouse cardiac tissue after myocardial infarction that is modulated by alterations in HS− biosynthesis. Cardiac HS−, in turn, suppresses electrophile-mediated H-Ras activation and cardiac cell senescence, contributing to the beneficial effects of HS− on myocardial infarction–associated heart failure. Thus, this study reveals HS−-induced electrophile sulfhydration as a unique mechanism for regulating electrophile-mediated redox signaling.
A nitrated guanine nucleotide, 8-nitroguanosine 3,5-cyclic monophosphate (8-nitro-cGMP), is formed via nitric oxide (NO) and causes protein S-guanylation. However, intracellular 8-nitro-cGMP levels and mechanisms of formation of 8-nitrocGMP and S-guanylation are yet to be identified. In this study, we precisely quantified NO-dependent formation of 8-nitrocGMP in C6 glioma cells via liquid chromatography-tandem mass spectrometry. Treatment of cells with S-nitroso-Nacetylpenicillamine led to a rapid, transient increase in cGMP, after which 8-nitro-cGMP increased linearly up to a peak value comparable with that of cGMP at 24 h and declined thereafter. Markedly high levels (>40 M) of 8-nitro-cGMP were also evident in C6 cells that had been stimulated to express inducible NO synthase with excessive NO production. The amount of 8-nitro-cGMP generated was comparable with or much higher than that of cGMP, whose production profile slightly preceded 8-nitro-cGMP formation in the activated inducible NO synthase-expressing cells. These unexpectedly large amounts of 8-nitro-cGMP suggest that GTP (a substrate of cGMP biosynthesis), rather than cGMP per se, may undergo guanine nitration. Also, 8-nitro-cGMP caused S-guanylation of KEAP1 in cells, which led to Nrf2 activation and subsequent induction of antioxidant enzymes, including heme oxygenase-1; thus, 8-nitro-cGMP protected cells against cytotoxic effects of hydrogen peroxide. Proteomic analysis for endogenously modified KEAP1 with matrix-assisted laser desorption/ionization time-of-flighttandem mass spectrometry revealed that 8-nitro-cGMP S-guanylated the Cys 434 of KEAP1. The present report is therefore the first substantial corroboration of the biological significance of cellular 8-nitro-cGMP formation and potential roles of 8-nitro-cGMP in the Nrf2-dependent antioxidant response.Nitric oxide (NO) plays diverse physiological roles in vascular regulation, neuronal transmission, inflammation, and host defense against microbial pathogens. In vascular and neuronal systems, NO performs these functions mainly through a cGMPdependent mechanism (1, 2), but the presence and contribution of other pathways that are not directly linked to cGMP have also been suggested to operate in certain aspects of NO signaling occurring in various cells and tissues in different organisms (3-5). Among these other mechanisms is chemical modification of biomolecules, including nitrosylation and nitration of amino acids, proteins, and lipids, this modification being induced by NO-derived reactive nitrogen oxide species (RNOS), 3 such as peroxynitrite (ONOO Ϫ ) and nitrogen dioxide (NO 2 ) (3-5).RNOS cause nitration of nucleic acids in addition to amino acids, proteins, and lipids. We previously found that nitrated guanine derivatives, including 8-nitroguanine and 8-nitroguanosine, formed in cultured cells and in tissues from murine viral pneumonia and human lung disease (6 -8). An important finding was that 8-nitroguanosine possessed a unique redox activity, which suggested a critical biological rol...
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