Measurement and biological significance of the volatile sulfur compounds hydrogen sulfide,methanethiol and dimethyl sulfide in various biological matrices

This review deals with the measurement of the volatile sulfur compounds hydrogen sulfide, methanethiol and dimethyl sulfide in various biological matrices of rats and humans (blood, serum, tissues, urine, breath, feces and flatus). Hydrogen sulfide and methanethiol both contain the active thiol (–SH) group and appear in the free gaseous form, in the acid-labile form and in the dithiothreitol-labile form. Dimethyl sulfide is a neutral molecule and exists only in the free form. The foul odor of these sulfur volatiles is a striking characteristic and plays a major role in bad breath, feces and flatus. Because sulfur is a biologically active element, the biological significance of the sulfur volatiles are also highlighted. Despite its highly toxic properties, hydrogen sulfide has been lately recommended to become the third gasotransmitter, next to nitric oxide and carbon monoxide, based on high concentration found in healthy tissues, such as blood and brain. However, there is much doubt about the reliability of the assay methods used. Many artifacts in the sulfide assays exist. The methods to detect the various forms of hydrogen sulfide are critically reviewed and compared with findings of our group. Recent findings that free gaseous hydrogen sulfide is absent in whole blood urged the need to revisit its role as a blood-borne signaling molecule.     

气体信号分子硫化氢在植物中的生理功能及作用机制

硫化氢（hydrogen sulfide,H2S）是继一氧化氮（nitric oxide,NO）和一氧化碳（carbon monoxide,CO）之后发现的第3种气体信号分子,它能参与生物体内的多种生理生化过程并发挥特定功能。在动物体内,H2S能够调节血管及神经系统功能。植物也能通过产生内源H2S来提高对环境的适应能力,缓解多种逆境胁迫造成的损伤和毒害,参与特定的生理代谢过程,诸如参与气孔运动和延缓衰老等。本文从H2S产生和代谢途径、已发现的生理功能和信号转导机制等方面综述H2S在植物中的最新研究进展,同时也探讨了H2S与其它信号分子的相互作用以及H2S对蛋白质的修饰机制。     

Gaseous messengers in the nervous system

Nitric oxide is the first gaseous messenger whose functions were comprehensively studied in different systems of organism. Recently, new data on the physiological role of other endogenous gases: carbon monoxide and hydrogen sulfide, appeared. The role of gases in gastrointestinal tract and cardiovascular system have been established; however, data on their function and mechanisms of action in nervous system are insufficient. This article highlights the current information on the role of gaseous messengers in central and peripheral nervous system.     

Ligand binding properties of bacterial hemoglobins and flavohemoglobins

Bacterial hemoglobins and flavohemoglobins share a common globin fold but differ otherwise in structural and functional aspects. The bases of these differences were investigated through kinetic studies on oxygen, carbon monoxide, and nitric oxide binding. The novel bacterial hemoglobins from Clostridium perfringens and Campylobacter jejuni and the flavohemoglobins from Bacillus subtilis and Salmonella enterica serovar Typhi have been analyzed. Examination of the biochemical and ligand binding properties of these proteins shows a clear distinction between the two groups. Flavohemoglobins show a much greater tendency to autoxidation compared to bacterial hemoglobins. The differences in affinity for oxygen, carbon monoxide, and nitric oxide between bacterial hemoglobins and flavohemoglobins are mainly due to differences in the association rate constants. The second-order rate constants for oxygen and carbon monoxide binding to bacterial hemoglobins are severalfold higher than those for flavohemoglobins. A similar trend is observed for NO association with the oxidized iron(III) form of the proteins. No major differences are observed among the values obtained for the dissociation rate constants for the two groups of bacterial proteins studied, and these constants are all rather similar to those for myoglobin. Taken together, our data suggest that differences exist between the mechanisms of ligand binding to bacterial hemoglobins and flavohemoglobins, suggesting different functions in the cell.     

Conformation, co-operativity and ligand binding in human hemoglobin.

There does not appear to be any co-operativity manifest in the four combination rate constants for the binding of nitric oxide to deoxyhemoglobin. The time-course of the observed reaction is best fitted by statistically related rates, and the numerical relation between the rate constants for the binding of the fourth molecule of carbon monoxide and the fourth molecule of nitric oxide, which can be obtained independently, also argues for a statistical relation between the nitric oxide binding rate constants.In spite of the absence of co-operativity, the normal T → R transition occurs on nitric oxide binding, as demonstrated by the release of 8-hydroxy-1,3,6-pyrene trisulfonate, and the R-state shows the normal enhancement of reactivity towards carbon monoxide as compared with the T-state (30-fold).Competition experiments between carbon monoxide and nitric oxide in which the two ligands react simultaneously with deoxyhemoglobin suggest that the switching point (T → R) occurs on the average after 2.7 molecules of nitric oxide have been bound (in 0.05 m-2,2-bis(hydroxymethyl)-2,2′,2″-nitrilotriethanol, pH 7) and after 3 molecules of carbon monoxide (in 0.05 m-phosphate, PH 7).     

The effects of carbon monoxide and hydrogen sulfide on transmembrane ion transport

The activity of electroneutral ion transport in response to the effect of the gasotransmitters carbon monoxide and hydrogen sulfide was investigated. It was shown that phenylephrine, an activator of receptorregulated calcium uptake, enhanced the relaxing action of carbon monoxide and hydrogen sulfide. In contrast, inhibition of the membrane potassium conductance, especially its voltage-dependent component, decreased the myogenic effects of carbon monoxide in the smooth muscles. The effects of hydrogen sulfide depended on its concentration and the means of activation of the cell transport systems. Furthermore, sodium-dependent components of the membrane conductivity are also involved in the effects of this gasotransmitter on ion transport systems in addition to the calcium and potassium conductance. This expands the range of the potential gasotransmitter-affected targets of signaling pathways, which may result in either activation or inhibition of cell functions. The consequences of such impacts on the functionally significant responses of cells, organs, and systems should be taken into account in various physiological and pathological states.     

NO- and H2S brain systems of the Japanese shore crab Hemigrapsus sanguineus under conditions of anoxia

The topography and dynamics of the activity of the enzymes of the synthesis of nitric oxide (NO) and hydrogen sulfide (H₂S) in the brain of the shore crab Hemigrapsus sanguineus after 1, 6, and 12 h of anoxia was studied histochemically and immunocytochemically. Changes in the activity and number of NO- and CBS-immune-positive cells that take place due to anoxia and the intensity of which depends on the duration of the influence were revealed. The fact that the balance between the nitric oxide and hydrogen sulfide systems in the brain of the crabs H. sanguineus is preserved indicates the joint participation of those systems in the central regulation of adaptive mechanisms under the influence of anoxia and, apparently, plays an important role in the adaptation of these hydrobionts to oxygen deficit.     

植物中硫化氢的生理功能及其分子机理

在动物中已经发现,硫化氢(H2S)可能是继NO和CO之后的第三种气体信号分子,参与各种生理调节作用。植物中很早就发现有H2S释放的现象,但是其生理功能一直不明。最近的研究表明,低浓度H2S能参与调节植物的气孔运动和光合作用、缓解非生物胁迫的伤害以及促进植物的生长发育等。本文综述了近年来有关H2S的植物生理调节作用和分子机理的研究进展,并对H2S作为信号分子的可能性进行了展望。     

Nitric oxide effect on coloncyte metabolism: Co-action of sulfides and peroxide

Luminal levels of nitric oxide/nitrite are high in colitis. Whether nitric oxide is injurious or protective to human colonocytes is unknown and the role of nitric oxide in the genesis of colitis unclear. The aims were to establish whether nitric oxide was injurious to oxidation of substrates (n-butyrate and D-glucose) in isolated human and rat colonocytes both alone and in the presence of hydrogen sulfide and hydrogen peroxide, agents implicated in cell damage of colitis. Nitric oxide generation from S-nitrosoglutathione was measured by nitrite appearance. Colonocytes were isolated and incubated with [1-¹⁴C] butyrate or [6-¹⁴C] glucose and 2.6 M nitric oxide, 1.5 mM sodium hydrogen sulfide or 2.5 mM hydrogen peroxide. Acyl-CoA esters were measured by high performance liquid chromatography, ¹⁴CO₂ radiochemically and lactate/ketones by enzymic methods. Results indicate that nitric oxide very significantly (p < .001) reduced acyl-CoA formation but did not impair ¹⁴CO₂ generation. Peroxide and sulfide with nitric oxide resulted in significant reduction (p < 0.01) of substrate oxidation to CO₂. Sulfide significantly stimulated release of nitric oxide from S-nitrosoglutathione. The principal conclusion is that nitric oxide diminishes CoA metabolism in colonocytes. CoA depletion has been observed in chronic human colitis for which a biochemical explanation has been lacking. For acute injurious action in human colonocytes nitric oxide requires co-action of peroxide and sulfide to impair oxidation of substrates in cells. From current observations treatment of colitis should aim to reduce simultaneously nitric oxide, peroxide and sulfide generation in the colon.     

硫化氢神经生物学作用的研究进展

硫化氢(hydrogen sulfide,H_2S)作为继一氧化碳、一氧化氮后的第三种新型气体信号分子,得到了研究者们的广泛关注。H_2S在生物机体内发挥了重要的神经生物学作用。本综述主要总结H_2S的神经保护作用和神经调质功能及其机制,并介绍近几年人们对H_2S在神经系统疾病中的作用的研究进展。     

In vivo exposure to carbon monoxide causes delayed impairment of activation of soluble guanylate cyclase by nitric oxide in rat brain cortex and cerebellum

Carbon monoxide induces delayed neurological and neuropathological alterations, including memory loss and cognitive impairment. The bases for the delay remain unknown. Activation of soluble guanylate cyclase by nitric oxide modulates some forms of learning and memory. Carbon monoxide binds to soluble guanylate cyclase, activating it but interfering with its activation by nitric oxide. The aim of this work was to assess whether exposure of rats to carbon monoxide alters the activity of soluble guanylate cyclase or its modulation by nitric oxide in cerebellum or cerebral cortex. Rats exposed chronically or acutely to carbon monoxide were killed 24 h or 7 days later. Acute carbon monoxide exposure decreased cyclic guanosine monophosphate (cGMP) content and reduced activation of soluble guanylate cyclase by nitric oxide. Cortex was more sensitive than cerebellum to chronic exposure, which reduced activation of soluble guanylate cyclase by nitric oxide in cortex. In cerebellum, chronic exposure induced delayed impairment of soluble guanylate cyclase activation by nitric oxide. Acute exposure effects were also stronger at 7 days than at 24 h after exposure. This delayed impaired modulation of soluble guanylate cyclase by nitric oxide may contribute to delayed memory loss and cognitive impairment in humans exposed to carbon monoxide.     

H₂S signalling through protein sulfhydration and beyond

Hydrogen sulfide (H(2)S) has recently emerged as a mammalian gaseous messenger molecule, akin to nitric oxide and carbon monoxide. H(2)S is predominantly formed from Cys or its derivatives by the enzymes cystathionine β-synthase and cystathionine γ-lyase. One of the mechanisms by which H(2)S signals is by sulfhydration of reactive Cys residues in target proteins. Although analogous to protein nitrosylation, sulfhydration is substantially more prevalent and usually increases the catalytic activity of targeted proteins. Physiological actions of sulfhydration include the regulation of inflammation and endoplasmic reticulum stress signalling as well as of vascular tension.     

The regulatory effect of endogenous hydrogen sulfide on pulmonary vascular structure and gasotransmitters in rats with high pulmonary blood flow

The study aimed to explore the regulatory effect of endogenous hydrogen sulfide (H(2)S), a novel gasotransmitter, on pulmonary vascular structure and gasotransmitters in rats with high pulmonary blood flow. Thirty-two Sprague-Dawley rats were randomly divided into a sham group, shunt group, sham+PPG (propargylglycine, an inhibitor of cystathionine-gamma-lyase) group and shunt+PPG group. Rats in the shunt and shunt+PPG groups underwent abdominal aorta-inferior vena cava shunting. Rats in the shunt+PPG and sham+PPG groups were intraperitoneally injected with PPG. After 4 weeks of shunting, mean pulmonary artery pressure (MPAP) and pulmonary vascular structural remodeling (PVSR) were evaluated. H(2)S, nitric oxide (NO) and carbon monoxide (CO) contents were measured in lung tissues. Meanwhile, nitric oxide synthase (eNOS), heme oxygenase (HO-1) and proliferative cell nuclear antigen (PCNA) protein expressions and ERK activation were evaluated. After 4 weeks of shunting, rats showed PVSR with increased lung tissue H(2)S and NO content but decreased CO content. After the PPG treatment, MPAP further increased and PVSR was aggravated. Meanwhile, PCNA expression and ERK activation were augmented with decreased lung tissue CO and HO-1 protein production but increased lung tissue NO production and eNOS expression. H(2)S exerted a protective effect on PVSR, and the inhibition of the NO/NOS pathway and the augmentation of the CO/HO pathway might be involved in the mechanisms by which H(2)S regulates PVSR in rats with high pulmonary flow.     

Gases in the mitochondria

Gasomodulators – nitric oxide, carbon monoxide and hydrogen sulphide – are important physiological mediators that have been implicated in disorders such as neurodegeneration and sepsis. Some of their biological functions involve the mitochondria. In particular, their inhibition of cytochrome c oxidase has received much attention as this can cause energy depletion and cytotoxicity. However, reports that cellular energy production and cell survival are maintained even in the presence of gasomodulators are not uncommon. In both cases, modulation of mitochondrial targets by the gasomodulators appears to be an important event. We provide an overview of the effects of the gasomodulators on the mitochondria.     

Free radical biology and medicine: it's a gas, man!

We review gases that can affect oxidative stress and that themselves may be radicals. We discuss O(2) toxicity, invoking superoxide, hydrogen peroxide, and the hydroxyl radical. We also discuss superoxide dismutase (SOD) and both ground-state, triplet oxygen ((3)O(2)), and the more energetic, reactive singlet oxygen ((1)O(2)). Nitric oxide ((*)NO) is a free radical with cell signaling functions. Besides its role as a vasorelaxant, (*)NO and related species have other functions. Other endogenously produced gases include carbon monoxide (CO), carbon dioxide (CO(2)), and hydrogen sulfide (H(2)S). Like (*)NO, these species impact free radical biochemistry. The coordinated regulation of these species suggests that they all are used in cell signaling. Nitric oxide, nitrogen dioxide, and the carbonate radical (CO(3)(*-)) react selectively at moderate rates with nonradicals, but react fast with a second radical. These reactions establish "cross talk" between reactive oxygen (ROS) and reactive nitrogen species (RNS). Some of these species can react to produce nitrated proteins and nitrolipids. It has been suggested that ozone is formed in vivo. However, the biomarkers that were used to probe for ozone reactions may be formed by non-ozone-dependent reactions. We discuss this fascinating problem in the section on ozone. Very low levels of ROS or RNS may be mitogenic, but very high levels cause an oxidative stress that can result in growth arrest (transient or permanent), apoptosis, or necrosis. Between these extremes, many of the gasses discussed in this review will induce transient adaptive responses in gene expression that enable cells and tissues to survive. Such adaptive mechanisms are thought to be of evolutionary importance.     

内源性硫化氢及其生物学效应

硫化氢(hydrogen sulfide,H2S)是一种具有臭鸡蛋刺激性气味的无色有毒气体,目前被认为是继一氧化氮和一氧化碳之后的第三个气体信号分子,参与体内多种生理及病理过程,具有广泛的生物学效应。H2S已成为当前生物学及医学领域一项崭新的研究课题,受到越来越多科研人员和制药企业的重视。本文就H2S近年来的研究进展做一综述。     

"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.     

硫化氢在糖尿病及其并发症中作用的研究进展

糖尿病及其并发症是覆盖全球的常见疾病,发病率逐年增高。硫化氢是继一氧化氮和一氧化碳之后的第三种气体信号分子,发挥重要病理生理学效应。目前研究发现,硫化氢在调节胰岛β细胞功能、胰岛素抵抗和糖尿病并发症中发挥着重要作用,已经成为糖尿病及其并发症的研究热点。本篇综述就H_2S在糖尿病及其并发症中发挥的病理生理学作用及机制进行了阐述。     

The topography of the NO- and H2S-systems in the brain of the mitten crab Eriocheir japonica (De Haan, 1835) (Decapoda: Varunidae)

The distributions and activities of nitric oxide (NO) and hydrogen sulfide (H₂S) synthesis enzymes in the brain of the mitten crab Eriocheir japonica (Decapoda: Varunidae) from fresh and salt water were studied using histochemical and immunocytochemical methods. In crabs that live in fresh water, the share of NO- and CBS-containing nerve elements in certain brain structures was increased, indicating the joint participation of NO and H₂S in the central regulation of adaptive mechanisms during the formation of a compensatory response to changing environmental conditions. It is assumed that preservation of the balance between nitric oxide and hydrogen sulfide in the brain of E. japonica plays an important role in the adaptation of this species to changes in the chemical composition of the environment.     

Genes,nitric oxide and malaria in African children

The unresolved and complex relationship between nitric oxide and falciparum malaria is reflected in recent genetic and immunohistochemical studies in African children. Different genetic associations, perhaps geographically distinctive, are seen between genetic variants of the inducible nitric oxide gene and various disease manifestations in African populations. The picture might not be complete without considering the emerging roles of carbon monoxide, another endogenous gaseous mediator with similar effects to those of nitric oxide. Only when genetic comparisons from across tropical Africa are examined, in conjunction with the newly recognized complexities in the events of systemic inflammation, will this relationship be understood.