Hydrogen sulfide mediates vasoactivity in an O2-dependent manner

Hydrogen sulfide (H(2)S) has recently been shown to have a signaling role in vascular cells. Similar to nitric oxide (NO), H(2)S is enzymatically produced by amino acid metabolism and can cause posttranslational modification of proteins, particularly at thiol residues. Molecular targets for H(2)S include ATP-sensitive K(+) channels, and H(2)S may interact with NO and heme proteins such as cyclooxygenase. It is well known that the reactions of NO in the vasculature are O(2) dependent, but this has not been addressed in most studies designed to elucidate the role of H(2)S in vascular function. This is important, since H(2)S reactions can be dramatically altered by the high concentrations of O(2) used in cell culture and organ bath experiments. To test the hypothesis that the effects of H(2)S on the vasculature are O(2) dependent, we have measured real-time levels of H(2)S and O(2) in respirometry and vessel tension experiments, as well as the associated vascular responses. A novel polarographic H(2)S sensor developed in our laboratory was used to measure H(2)S levels. Here we report that, in rat aorta, H(2)S concentrations that mediate rapid contraction at high O(2) levels cause rapid relaxation at lower physiological O(2) levels. At high O(2), the vasoconstrictive effect of H(2)S suggests that it may not be H(2)S per se but, rather, a putative vasoactive oxidation product that mediates constriction. These data are interpreted in terms of the potential for H(2)S to modulate vascular tone in vivo.     

Adaptation of teleosts to very high salinity

Hydrogen sulfide (H(2)S), nitric oxide (NO) and nitrite (NO(2)(-)) are formed in vivo and are of crucial importance in the tissue response to hypoxia, particularly in the cardiovascular system, where these signaling molecules are involved in a multitude of processes including the regulation of vascular tone, cellular metabolic function and cytoprotection. This report summarizes current advances on the mechanisms by which these signaling pathways act and may have evolved in animals with different tolerance to hypoxia, as presented and discussed during the scientific sessions of the annual meeting of the Society for Experimental Biology in 2011 in Glasgow. It also highlights the need and potential for a comparative approach of study and collaborative effort to identify potential link(s) between the signaling pathways involving NO, nitrite and H(2)S in the whole-body responses to hypoxia.     

Cysteine S-nitrosylation protects protein-tyrosine phosphatase 1B against oxidation-induced permanent inactivation

Protein S-nitrosylation mediated by cellular nitric oxide (NO) plays a primary role in executing biological functions in cGMP-independent NO signaling. Although S-nitrosylation appears similar to Cys oxidation induced by reactive oxygen species, the molecular mechanism and biological consequence remain unclear. We investigated the structural process of S-nitrosylation of protein-tyrosine phosphatase 1B (PTP1B). We treated PTP1B with various NO donors, including S-nitrosothiol reagents and compound-releasing NO radicals, to produce site-specific Cys S-nitrosylation identified using advanced mass spectrometry (MS) techniques. Quantitative MS showed that the active site Cys-215 was the primary residue susceptible to S-nitrosylation. The crystal structure of NO donor-reacted PTP1B at 2.6 A resolution revealed that the S-NO state at Cys-215 had no discernible irreversibly oxidized forms, whereas other Cys residues remained in their free thiol states. We further demonstrated that S-nitrosylation of the Cys-215 residue protected PTP1B from subsequent H(2)O(2)-induced irreversible oxidation. Increasing the level of cellular NO by pretreating cells with an NO donor or by activating ectopically expressed NO synthase inhibited reactive oxygen species-induced irreversible oxidation of endogenous PTP1B. These findings suggest that S-nitrosylation might prevent PTPs from permanent inactivation caused by oxidative stress.     

What Part of NO Don't You Understand? Some Answers to the Cardinal Questions in Nitric Oxide Biology

Nitric oxide (NO) regulates biological processes through signaling mechanisms that exploit its unique biochemical properties as a free radical. For the last several decades, the key aspects of the chemical properties of NO relevant to biological systems have been defined, but it has been a challenge to assign these to specific cellular processes. Nevertheless, it is now clear that the high affinity of NO for transition metal centers, particularly iron, and the rapid reaction of NO with oxygen-derived free radicals can explain many of its biological and pathological properties. Emerging studies also highlight a growing importance of the secondary metabolites of NO-dependent reactions in the post-translational modification of key metabolic and signaling proteins. In this minireview, we emphasize the current understanding of the biochemistry of NO and place it in a biological context.     

Interrelation between NO and H2O2 formation and their role in the regulation of ion homeostasis of cells

The review deals with some problems of formation, utilization and functioning two of the most important and the lest cytotoxic active oxidative metabolites--NO and H2O2. The interrelation of NO and H2O2 cellular metabolism is reviewed. There are literature data regarding NO and H2O2 significance in the cellular signalling transduction and tissues paracrine regulation. The peculiar attention is dedicated to NO and H2O2 significance in the smooth muscle cells ion homeostasis regulation particularly in the uterus. As well there are the own author's data evidencing about the composite and ambiguous concentration-dependent physiological action of these metabolites. Varying in level in the cells NO and H2O2 may have a cyclic character similar to the oscillations of some other signaling molecules concentrations, evidently playing an important role in the mechanisms of cellular signal transduction and in the paracrine system.     

A functionally coupled mu3-like opiate receptor/nitric oxide regulatory pathway in human multi-lineage progenitor cells

Ongoing studies from our group support the existence and biological importance of a distinct cellular signaling pathway involving endogenously synthesized, chemically authentic, l-morphine, its cognate mu(3) opiate receptor subtype, and constitutive NO synthase. Based on prior studies indicating evolutionary conservation and adaptation of morphinergic/NO-coupled signaling to mediate autocrine/paracrine control of cellular functions, our goal was to determine whether a functionally competent mu(3) opiate receptor/NO-coupled regulatory pathway exists in human multilineage progenitor cells (MLPC) prepared from umbilical cord blood. Real-time PCR analysis indicated significant expression of mu(3) opiate receptor-encoding RNA by undifferentiated human MLPC, in the absence of traditional mu(1) opioid receptor-encoding RNA expression. Unpredictably, confirmatory RT-PCR analyses indicated cellular expression of a splice variant of the previously characterized mu(3) opiate receptor-encoding mRNA. Pharmacological analyses provided critical validating evidence of functional mu(3)-like opiate receptor/NO-coupled signaling within primary cultures of undifferentiated human MLPC via morphine-evoke real-time release of NO. Control analyses indicated that morphine-stimulated NO release was markedly inhibited by prior treatment with the opiate antagonist l-naloxone or the constitutive NO synthase inhibitor N(G)-nitro-l-arginine methyl ester and unresponsive to stimulation by the opioid peptide methionine enkephalin. Complementary microarray analysis demonstrated that traditional mu(1), delta, and kappa opioid receptor gene expression is not detected in both undifferentiated and differentiated MLPC. Chemical differentiation of MLPC into neuronal progenitor cells effected significant phenotypic expression of a variety of neurally-associated genes. Our data provide compelling evidence in support of both the evolutionary primacy and primordial regulatory role of mu(3)-like opiate receptor/NO signaling in embryogenesis.     

Nitric oxide and hydrogen sulfide crosstalk during heavy metal stress in plants

Gases such as ethylene, hydrogen peroxide (H₂O₂), nitric oxide (NO), carbon monoxide (CO) and hydrogen sulfide (H₂S) have been recognized as vital signaling molecules in plants and animals. Of these gasotransmitters, NO and H₂S have recently gained momentum mainly because of their involvement in numerous cellular processes. It is therefore important to study their various attributes including their biosynthetic and signaling pathways. The present review provides an insight into various routes for the biosynthesis of NO and H₂S as well as their signaling role in plant cells under different conditions, more particularly under heavy metal stress. Their beneficial roles in the plant's protection against abiotic and biotic stresses as well as their adverse effects have been addressed. This review describes how H₂S and NO, being very small-sized molecules, can quickly pass through the cell membranes and trigger a multitude of responses to various factors, notably to various stress conditions such as drought, heat, osmotic, heavy metal and multiple biotic stresses. The versatile interactions between H₂S and NO involved in the different molecular pathways have been discussed. In addition to the signaling role of H₂S and NO, their direct role in posttranslational modifications is also considered. The information provided here will be helpful to better understand the multifaceted roles of H₂S and NO in plants, particularly under stress conditions.     

Biochemical insight into physiological effects of H₂S: reaction with peroxynitrite and formation of a new nitric oxide donor, sulfinyl nitrite

The reaction of hydrogen sulfide (H2S) with peroxynitrite (a key mediator in numerous pathological states) was studied in vitro and in different cellular models. The results show that H2S can scavenge peroxynitrite with a corresponding second order rate constant of 3.3 ± 0.4 × 103 M?1·s?1 at 23°C (8 ± 2 × 103 M?1·s?1 at 37°C). Activation parameters for the reaction (ΔH?, ΔS? and ΔV?) revealed that the mechanism is rather associative than multi-step free-radical as expected for other thiols. This is in agreement with a primary formation of a new reaction product characterized by spectral and computational studies as HSNO? (thionitrate), predominantly present as sulfinyl nitrite, HS(O)NO. This is the first time a thionitrate has been shown to be generated under biologically relevant conditions. The potential of HS(O)NO to serve as a NO donor in a pH-dependent manner and its ability to release NO inside the cells has been demonstrated. Thus sulfide modulates the chemistry and biological effects of peroxynitrite by its scavenging and formation of a new chemical entity (HSNO?) with the potential to release NO, suppressing the pro-apoptotic, oxidative and nitrative properties of peroxynitrite. Physiological concentrations of H?S abrogated peroxynitrite-induced cell damage as demonstrated by the: (i) inhibition of apoptosis and necrosis caused by peroxynitrite; (ii) prevention of protein nitration; and (iii) inhibition of PARP-1 [poly(ADP-ribose) polymerase 1] activation in cellular models, implying that a major part of the cytoprotective effects of hydrogen sulfide may be mediated by modulation of peroxynitrite chemistry, in particular under inflammatory conditions.     

The hypothesis of the main role of H2S in coupled sulphide-nitroso signalling pathway

As a part of the nitroso signalling pathway, nitroso-compounds serve as stores and carriers of NO; as part of the sulphide signalling pathway, bound sulfane-sulphur compounds serve as stores and carriers of H2S. Here we hypothesise a coupled sulphide-nitroso signalling pathway, in which H2S plays a main role. H2S releases NO from the endogenous S-nitroso-compounds nitroso-cysteine, nitroso-acetylcysteine and nitroso-albumin. Relaxation of noradrenaline-precontracted aortic rings by H2S is also enhanced in the presence of nitroso-albumin, which may implicate the involvement of the nitroso signalling pathway. Pretreatment of albumin, cysteine, N-acetylcysteine and lipids with H2S results in binding of sulphur to these compounds creating thus new-modified sulphur compounds that release NO from nitroso-compounds directly and/or through released H2S, which suggests sulphide-nitroso signalling pathway participation. This hypothesis is supported by the observation that the pretreatment of noradrenaline-precontracted aortic rings with H2S significantly enhanced relaxation induced by nitroso-glutathione in the absence of H2S. We assume that the NO release from nitroso-compounds directly by H2S or indirectly by the H2S-induced sulphur-bound compounds represents coupled sulphide-nitroso signalling, which may explain some of the numerous biological effects of H2S that are shared with NO.     

Hydrogen sulfide,a signaling molecule in plant stress responses

Gaseous molecules, such as hydrogen sulfide(H_2S)and nitric oxide(NO), are crucial players in cellular and(patho)physiological processes in biological systems. The biological functions of these gaseous molecules, which were first discovered and identified as gasotransmitters in animals, have received unprecedented attention from plant scientists in recent decades. Researchers have arrived at the consensus that H_2S is synthesized endogenously and serves as a signaling molecule throughout the plant life cycle.However, the mechanisms of H_2S action in redox biology is still largely unexplored. This review highlights what we currently know about the characteristics and biosynthesis of H_2S in plants. Additionally,we summarize the role of H_2S in plant resistance to abiotic stress. Moreover, we propose and discuss possible redox-dependent mechanisms by which H_2S regulates plant physiology.     

NO news is good news for plants

The organization of redox signaling and the use of nitric oxide (NO) to transmit information, modulate biological processes or create cellular damage are highly complex. Recent reports provide an exceptional picture of NO production, of the regulation of NO bioactivity through detoxification reactions and of biochemical events by which NO transduces signals into cellular responses, in particular during disease resistance. Furthermore, other exciting reports on NO function in germination, growth and reproduction support the view that NO is a 'do it all' molecule that plays a crucial role during the entire lifespan of the plant.     

Signal transduction by nitric oxide in cellular stress responses

Nitric oxide (NO) has received wide attention as a biological signaling molecule that uses cyclic GMP as a cellular second messenger. Other work has supported roles for cysteine oxidation or nitrosylation as signaling events. Recent studies in bacteria and mammalian cells now point to the existence of at least two other pathways independent of cGMP. For the E. coli SoxR protein, signaling occurs by nitrosylation of its binuclear iron-sulfur clusters, a reaction that is unprecedented in gene activation. In intact cells, these nitrosylated centers are very rapidly replaced by unmodified iron-sulfur clusters, a result that points to the existence of an active repair pathway for this type of protein damage. Exposure of mammalian cells to NO elicits an adaptive resistance that confers elevated resistance of the cells to higher levels of NO. This resistance in many cell types involves the important defense protein heme oxygenase 1, although the mechanism by which this enzyme mediates NO resistance remains unknown. Induction of heme oxygenase in some cell types occurs through the stabilization of its mRNA. NO-induced stabilization of mRNA is mediated by pre-existing proteins and points to the existence of an important new signaling pathway that counteracts the damage and stress exerted by this free radical.     

Tumor necrosis factor α (TNF-α)-induced prostaglanding E2 release is mediated by the activation of cyclooxygenase-2 (COX-2)transcription via NFκB in human gingival fibroblasts

Nitric oxide (NO) has received wide attention as a biological signaling molecule that uses cyclic GMP as a cellular second messenger. Other work has supported roles for cysteine oxidation or nitrosylation as signaling events. Recent studies in bacteria and mammalian cells now point to the existence of at least two other pathways independent of cGMP. For the E. coli SoxR protein, signaling occurs by nitrosylation of its binuclear iron-sulfur clusters, a reaction that is unprecedented in gene activation. In intact cells, these nitrosylated centers are very rapidly replaced by unmodified iron-sulfur clusters, a result that points to the existence of an active repair pathway for this type of protein damage. Exposure of mammalian cells to NO elicits an adaptive resistance that confers elevated resistance of the cells to higher levels of NO. This resistance in many cell types involves the important defense protein heme oxygenase 1, although the mechanism by which this enzyme mediates NO resistance remains unknown. Induction of heme oxygenase in some cell types occurs through the stabilization of its mRNA. NO-induced stabilization of mRNA is mediated by pre-existing proteins and points to the existence of an important new signaling pathway that counteracts the damage and stress exerted by this free radical.     

Nitric oxide and reactive oxygen species do not elicit hypersensitive cell death but induce apoptosis in the adjacent cells during the defense response of oat

Nitric oxide (NO) acts as a signaling molecule in many cellular responses in plants and animals. Oat plants (Avena sativa L.) evoke the hypersensitive response (HR), which shares morphological and biochemical features with mammalian apoptosis, such as DNA laddering and heterochromatin condensation, in response to the avirulent crown rust fungus (Puccinia coronata f. sp. avenae). We examined the role of NO and reactive oxygen species (ROS) in the initiation of hypersensitive cell death, which is induced by direct contact with the pathogen, and apoptotic cell death in the adjacent cells. Cytofluorimetric analysis using the fluorescent NO probe DAF and the H2O2 probe DCF demonstrated that NO and H2O2 were generated simultaneously in primary leaves at an early stage of the defense response. The NO scavenger 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide (cPTIO) markedly enhanced H2O2 accumulation detected by 3,3-diaminobenzidine staining and DCF, whereas treatment with the NO donor S-nitroso-N-acetylpenicillamine (SNAP) strongly suppressed it. Superoxide dismutase (SOD) increased NO accumulation, suggesting that endogenous NO may modulate the level of H2O2 by interacting with O2- in the HR lesion. Cytological observation showed that administration of cPTIO, SNAP, or SOD had no effect on elicitation of hypersensitive cell death, but clearly reduced heterochromatin condensation in the nearby cells and DNA laddering. These findings indicate that NO and ROS are not essential mediators for the initiation of hypersensitive cell death. However, NO and O2- but not H2O2 are required for the onset of apoptotic cell death in the adjacent cells, where excess NO may exert its anti-apoptotic function by regulating cellular redox state.     

Hydrogen sulfide potentiates interleukin-1beta-induced nitric oxide production via enhancement of extracellular signal-regulated kinase activation in rat vascular smooth muscle cells

Hydrogen sulfide (H(2)S) and nitric oxide (NO) are endogenously synthesized from l-cysteine and l-arginine, respectively. They might constitute a cooperative network to regulate their effects. In this study, we investigated whether H(2)S could affect NO production in rat vascular smooth muscle cells (VSMCs) stimulated with interleukin-1beta (IL-1beta). Although H(2)S by itself showed no effect on NO production, it augmented IL-beta-induced NO production and this effect was associated with increased expression of inducible NO synthase (iNOS) and activation of nuclear factor (NF)-kappaB. IL-1Beta activated the extracellular signal-regulated kinase 1/2 (ERK1/2), and this activation was also enhanced by H(2)S. Inhibition of ERK1/2 activation by the selective inhibitor U0126 inhibited IL-1beta-induced NF-kappaB activation, iNOS expression, and NO production either in the absence or presence of H(2)S. Our findings suggest that H(2)S enhances NO production and iNOS expression by potentiating IL-1beta-induced NF-kappaB activation through a mechanism involving ERK1/2 signaling cascade in rat VSMCs.     

Structural and functional insights into the heme-binding domain of the human soluble guanylate cyclase α2 subunit and heterodimeric α2β1

Soluble guanylate cyclase (sGC) mediates NO signaling for a wide range of physiological effects in the cardiovascular system and the central nervous system. The α1β1 isoform is ubiquitously distributed in cytosolic fractions of tissues, whereas α2β1 is mainly found in the brain. The major occurrence and the unique characteristic of human sGC α2β1 indicate a special role in the mediation of neuronal communication. We have efficiently purified and characterized the recombinant heme-binding domain of the human sGC α2 subunit (hsGC α2(H)) and heterodimeric α2β1 (hsGC β1(H)-α2(H)) by UV-vis spectroscopy, circular dichrosim spectroscopy, EPR spectroscopy, and homology modeling. The heme dissociation and related NO/CO binding/dissociation of both hsGC α2(H) and hsGC β1(H)-α2(H) were investigated. The two truncated proteins interact with heme noncovalently. The CO binding affinity of hsGC α2(H) is threefold greater than that of human sGC α1(H), whereas the dissociation constant k (1) for dissociation of NO from hsGC α2(H) is sevenfold larger than that for dissociation of NO from hsGC α1(H), although k (2) is almost identical. The results indicate that in comparison with the α1β1 isoform, the brain α2β1 isoform exhibits a distinctly different CO/NO affinity and binding rate in favor of NO signaling, and this is consistent with its physiological role in the activation and desensitization. Molecular modeling and sequence alignments are consistent with the hypothesis that His105 contributes to the different CO/NO binding properties of different isoforms. This valuable information is helpful to understand the molecular mechanism by which human sGC α2β1 mediates NO/CO signaling.     

"Waste gas is not waste": advance in the research of hydrogen sulfide

The discovery of endogenous gasotransmitters puts forwards a new concept, "waste gas is not waste". Hydrogen sulfide (H(2)S) is considered as a new member of gasotransmitter family, following nitric oxide (NO) and carbon monoxide (CO). Recently, the understanding of H(2)S biological effect and its mechanisms has been deepened, especially the pathophysiological significance of H(2)S in the various diseases such as cardiovascular diseases, neurological diseases, respiratory diseases, endocrine diseases, etc. This article reviews recent progress of basic, clinical and pharmacological researches related to endogenous H(2)S, including the regulatory effects of H(2)S on the cell proliferation, apoptosis, inflammation, angiogenesis and ion channels, the role of endogenous H(2)S pathway in the pathogenesis of various diseases, as well as the study of the H(2)S donor and H(2)S-related drugs.     

Nitrogen monoxide (NO) storage and transport by dinitrosyl-dithiol-iron complexes: long-lived NO that is trafficked by interacting proteins

Nitrogen monoxide (NO) markedly affects intracellular iron metabolism, and recent studies have shown that molecules traditionally involved in drug resistance, namely GST and MRP1 (multidrug resistance-associated protein 1), are critical molecular players in this process. This is mediated by interaction of these proteins with dinitrosyl-dithiol-iron complexes (Watts, R. N., Hawkins, C., Ponka, P., and Richardson, D. R. (2006) Proc. Natl. Acad. Sci. U.S.A. 103, 7670-7675; Lok, H. C., Suryo Rahmanto, Y., Hawkins, C. L., Kalinowski, D. S., Morrow, C. S., Townsend, A. J., Ponka, P., and Richardson, D. R. (2012) J. Biol. Chem. 287, 607-618). These complexes are bioavailable, have a markedly longer half-life compared with free NO, and form in cells after an interaction between iron, NO, and glutathione. The generation of dinitrosyl-dithiol-iron complexes acts as a common currency for NO transport and storage by MRP1 and GST P1-1, respectively. Understanding the biological trafficking mechanisms involved in the metabolism of NO is vital for elucidating its many roles in cellular signaling and cytotoxicity and for development of new therapeutic targets.     

Hydrogen peroxide induces a rapid production of nitric oxide in mung bean (Phaseolus aureus).

Nitric oxide (NO) has recently been identified as an important signaling molecule in plant immune response. The present study aims to investigate the signaling pathway that leads to NO production. Using the NO specific fluorescent dye DAF-2DA, we observed rapid production of NO in mung bean leaves after the addition of 10 mM hydrogen peroxide (H(2)O(2)). NO was probably produced by a NOS-like enzyme in plants, as the NO production was inhibited by l-NAME, a NOS inhibitor. The NOS-like activity in the total leaf protein preparation of mung bean (Phaseolus aureus) was elevated 8.3-fold after 10 mM H(2)O(2) treatment, as demonstrated using the chemiluminescence NOS assay. The NOS-like activity was BH(4) dependent: omitting BH(4) in the reaction mixture of NOS assay reduced the NOS activity by 76%. We also found that the H(2)O(2) induced NO production was mediated via calcium ion flux, as it was blocked in the presence of a calcium ion channel blocker, verapamil. Results from the present study identified H(2)O(2) as an upstream signal that leads to NO production in plants. H(2)O(2) and NO, besides acting as two independent signaling molecules in plant immune response, may interrelate to form an oxidative cell death (OCD) cycle.