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Although many types of ancient bacteria and archea rely on hydrogen sulfide (H2S) for their energy production, eukaryotes generate ATP in an oxygen-dependent fashion. We hypothesize that endogenous H2S remains a regulator of energy production in mammalian cells under stress conditions, which enables the body to cope with energy demand when oxygen supply is insufficient. Cystathionine γ-lyase (CSE) is a major H2S-producing enzyme in the cardiovascular system that uses cysteine as the main substrate. Here we show that CSE is localized only in the cytosol, not in mitochondria, of vascular smooth-muscle cells (SMCs) under resting conditions, revealed by Western blot analysis and confocal microscopy of SMCs transfected with GFP-tagged CSE plasmid. After SMCs were exposed to A23187, thapsigargin, or tunicamycin, intracellular calcium level was increased, and CSE translocated from the cytosol to mitochondria. CSE was coimmunoprecipitated with translocase of the outer membrane 20 (Tom20) in mitochondrial membrane. Tom20 siRNA significantly inhibited mitochondrial translocation of CSE and mitochondrial H2S production. The cysteine level inside mitochondria is approximately three times that in the cytosol. Translocation of CSE to mitochondria metabolized cysteine, produced H2S inside mitochondria, and increased ATP production. Inhibition of CSE activity reversed A23187-stimulated mitochondrial ATP production. H2S improved mitochondrial ATP production in SMCs with hypoxia, which alone decreased ATP production. These results suggest that translocation of CSE to mitochondria on specific stress stimulations is a unique mechanism to promote H2S production inside mitochondria, which subsequently sustains mitochondrial ATP production under hypoxic conditions.

Hydrogen sulfide (H2S) and nitric oxide (NO) are major gasotransmitters produced in endothelial cells (ECs), contributing to the regulation of vascular contractility and structural integrity. Their interaction at different levels would have a profound impact on angiogenesis. Here, we showed that H2S and NO stimulated the formation of new microvessels. Incubation of human umbilical vein endothelial cells (HUVECs‐926) with NaHS (a H2S donor) stimulated the phosphorylation of endothelial NO synthase (eNOS) and enhanced NO production. H2S had little effect on eNOS protein expression in ECs. L‐cysteine, a precursor of H2S, stimulated NO production whereas blockage of the activity of H2S‐generating enzyme, cystathionine gamma‐lyase (CSE), inhibited this action. CSE knockdown inhibited, but CSE overexpression increased, NO production as well as EC proliferation. LY294002 (Akt/PI3‐K inhibitor) or SB203580 (p38 MAPK inhibitor) abolished the effects of H2S on eNOS phosphorylation, NO production, cell proliferation and tube formation. Blockade of NO production by eNOS‐specific siRNA or nitro‐L‐arginine methyl ester (L‐NAME) reversed, but eNOS overexpression potentiated, the proliferative effect of H2S on ECs. Our results suggest that H2S stimulates the phosphorylation of eNOS through a p38 MAPK and Akt‐dependent pathway, thus increasing NO production in ECs and vascular tissues and contributing to H2S‐induced angiogenesis.

Brassinin, a sulfur-containing phytoalexin, exerts anticancer and anti-inflammatory effects. Hydrogen sulfide (H2S) is an important gasotransmitter with significant cardioprotective properties. The effects of brassinin on H2S signaling and vascular smooth muscle cell (SMC) functions remain unexplored. This study found that brassinin protected against angiotensin II (Ang II)-induced SMC dysfunctions. These effects included the attenuation of excessive cell proliferation, migration, and oxidative stress; and upregulation of smooth muscle contractile protein expressions; and down-regulation of inflammatory gene expressions. Notably, brassinin did not directly release H2S under the tested conditions; instead, it stimulated endogenous H2S synthesis in cultured SMCs by inducing the expression of cystathionine gamma-lyase (CSE), a key H2S-generating enzyme. Further mechanistic investigations revealed that brassinin may bind to the transcription factor C/EBPβ and enhance its interaction with the CSE promoter, thereby upregulating CSE transcription. In conclusion, our findings demonstrate that brassinin protects against SMC dysfunction, at least in part, by activating H2S signaling rather than acting as a direct H2S donor. These results provide new insights into the potential of brassinin as a therapeutic agent for improving vascular health and preventing cardiovascular diseases.

The biological and medical importance of hydrogen sulfide (H2S) has been recognized for decades. The aim of this bibliometric study is to analyze the quantity and quality of publications in H2S biology and medicine (H2SBM) based on the databases of Web of Science and Google Scholar. A total of 5881 publications published between 1990 and 2016 were analyzed. The number of H2SBM papers published before 2004 was below 100 annually, but thereafter this number rapidly increased and peaked in 2015 with more than 7-fold increase. All publications related to H2SBM research achieved a total h-index of 136 and were cited 123,074 times. The most published disciplines in H2S biomedicine research were the cardiovascular system (8.5%), neuroscience (6.5%), and gastroenterology hepatology (4.7%). The country with the greatest number of publications in the H2SBM research field was the USA with 1765 (30.0%) publications, followed by China with 995 (16.9%) publications and Japan with 555 (9.4%) publications. The top 3 most published institutes were National University of Singapore, Peking University in China, and University of Groningen in Netherlands. Nitric Oxide Biology and Chemistry was the most exploited journal for H2SBM publications with 461 articles, followed by FASEB Journal with 200 publications and Antioxidants Redox Signaling with 116 publications. The most highly cited publications and researchers in H2SBM research were also unmasked from this bibliometric analysis. Collectively, H2SBM publications exhibit a continuous trend of increase, reflecting the increased H2SBM research intensity and diversity globally.

Oxygen-sensitive accumulation and degradation, two opposite but intrinsically linked events, of heme proteins in mitochondria affect mitochondrial functions, including bioenergetics and oxygen-sensing processes. Cystathionine β-synthase (CBS) contains a prosthetic heme group and catalyzes the production of hydrogen sulfide in mammalian cells. Here we show that CBS proteins were present in liver mitochondria at a low level under normoxia conditions. Ischemia/hypoxia increased the accumulation of CBS proteins in mitochondria. The normalization of oxygen partial pressure accelerated the degradation of CBS proteins. Lon protease, a major degradation enzyme in mitochondrial matrix, recognized and degraded mitochondrial CBS by specifically targeting at the oxygenated heme group of CBS proteins. The accumulation of CBS in mitochondria increased hydrogen sulfide production, which prevented Ca ²⁺-mediated cytochrome c release from mitochondria and decreased reactive oxygen species generation. Mitochondrial accumulation of heme oxygenase-1, another heme protein, was also regulated by oxygen level and Lon protease in the same mechanism as for CBS. Our findings provide a fundamental and general mechanism for oxygen-sensitive regulation of mitochondrial functions by linking oxygenation level to the accumulation/degradation of mitochondrial heme proteins.

Hydrogen sulfide (H S) is a novel gasotransmitter in both mammals and plants. H S plays important roles in various plant developmental processes and stress responses. Leaf senescence is the last developmental stage and is a sequential degradation process that eventually leads to leaf death. A mutation of the H S-producing enzyme-encoding gene L-cysteine desulfhydrase1 ( ) leads to premature leaf senescence but the underlying mechanisms are not clear. In this present study, wild-type, defective mutant ( ) and over-expression ( ) plants were used to investigate the underlying mechanism of H S signaling in energy production and leaf senescence under drought stress. The mutant was more sensitive to drought stress and displayed accelerated leaf senescence, while the leaves of contained adequate chlorophyll levels, accompanied by significantly increased drought resistance. Under drought stress, the expression levels of β- , and were significantly downregulated in and significantly upregulated in , and ε showed the opposite trend. Senescence-associated gene ( ) correlated with age-dependent senescence and participated in the drought resistance of . , which was induced by environmental factors, responded positively to drought stress in plants, while there was no significant difference in the expression between and . Using transmission electron microscopy, the mitochondria of were severely damaged and bubbled in older leaves, while had complete mitochondrial structures and a homogeneous matrix. Additionally, mitochondria isolated from increased the H S production rate, H S content and ATPase activity level, as well as reduced swelling and lowered the ATP content in contrast with wild-type and significantly. Therefore, at subcellular levels, H S appeared to determine the ability of mitochondria to regulate energy production and protect against cellular aging, which subsequently delayed leaf senescence under drought-stress conditions in plants.

Studies of nitric oxide over the past two decades have highlighted the fundamental importance of gaseous signaling molecules in biology and medicine. The physiological role of other gases such as carbon monoxide and hydrogen sulfide (H₂S) is now receiving increasing attention. Here we show that H₂S is physiologically generated by cystathionine γ-lyase (CSE) and that genetic deletion of this enzyme in mice markedly reduces H₂S levels in the serum, heart, aorta, and other tissues. Mutant mice lacking CSE display pronounced hypertension and diminished endothelium-dependent vasorelaxation. CSE is physiologically activated by calcium-calmodulin, which is a mechanism for H₂S formation in response to vascular activation. These findings provide direct evidence that H₂S is a physiologic vasodilator and regulator of blood pressure.

Protein S-sulfhydration is a newly discovered post-translational modification of specific cysteine residue(s) in target proteins, which is involved in a broad range of cellular functions and metabolic pathways. By changing local conformation and the final activity of target proteins, S-sulfhydration is believed to mediate most cellular responses initiated by H2S, a novel gasotransmitter. In comparison to protein S-sulfhydration, nitric oxide-mediated protein S-nitrosylation has been extensively investigated, including its formation, regulation, transfer and metabolism. Although the investigation on the regulatory mechanisms associated with protein S-sulfhydration is still in its infancy, accumulated evidence suggested that protein S-sulfhydration may share similar chemical features with protein S-nitrosylation. Glutathione persulfide acts as a major donor for protein S-sulfhydration. Here, we review the present knowledge on protein S-sulfhydration, and also predict its formation and regulation mechanisms based on the knowledge from protein S-nitrosylation.

The goal of the current study was to investigate the role of exogenous and endogenous hydrogen sulfide (H₂S) on neovascularization and wound healing in vitro and in vivo. Incubation of endothelial cells (ECs) with H₂S enhanced their angiogenic potential, evidenced by accelerated cell growth, migration, and capillary morphogenesis on Matrigel. Treatment of chicken chorioallantoic membranes (CAMS) with H₂S increased vascular length. Exposure of ECs to H₂S resulted in increased phosphorylation of Akt, ERK, and p38. The KATP channel blocker glibenclamide or the p38 inhibitor SB203580 abolished H₂S-induced EC motility. Since glibenclamide inhibited H₂S-triggered p38 phosphorylation, we propose that KATP channels lay upstream of p38 in this process. When CAMs were treated with H₂S biosynthesis inhibitors dl-propylargylglycine or beta-cyano-L-alanine, a reduction in vessel length and branching was observed, indicating that H₂S serves as an endogenous stimulator of the angiogenic response. Stimulation of ECs with vascular endothelial growth factor (VEGF) increased H₂S release, while pharmacological inhibition of H₂S production or KATP channels or silencing of cystathionine gamma-lyase (CSE) attenuated VEGF signaling and migration of ECs. These results implicate endothelial H₂S synthesis in the pro-angiogenic action of VEGF. Aortic rings isolated from CSE knockout mice exhibited markedly reduced microvessel formation in response to VEGF when compared to wild-type littermates. Finally, in vivo, topical administration of H₂S enhanced wound healing in a rat model, while wound healing was delayed in CSE⁻/⁻ mice. We conclude that endogenous and exogenous H₂S stimulates EC-related angiogenic properties through a KATP channel/MAPK pathway.

Hydrogen sulfide (H 2 S) has been traditionally known for its toxic effects on living organisms. The role of H 2 S in the homeostatic regulation of pancreatic insulin metabolism has been unclear. The present study is aimed at elucidating the effect of endogenously produced H 2 S on pancreatic insulin release and its role in diabetes development. Diabetes development in Zucker diabetic fatty (ZDF) rats was evaluated in comparison with Zucker fatty (ZF) and Zucker lean (ZL) rats. Pancreatic H 2 S production and insulin release were also assayed. It was found that H 2 S was generated in rat pancreas islets, catalyzed predominantly by cystathionine γ -lyase (CSE). Pancreatic CSE expression and H 2 S production were greater in ZDF rats than in ZF or ZL rats. ZDF rats exhibited reduced serum insulin level, hyperglycemia, and insulin resistance. Inhibition of pancreatic H 2 S production in ZDF rats by intraperitoneal injection of DL-propargylglycine (PPG) for 4 weeks increased serum insulin level, lowered hyperglycemia, and reduced hemoglobin A1c level ( P <0.05). Although in ZF rats it also reduced pancreatic H 2 S production and serum H 2 S level, PPG treatment did not alter serum insulin and glucose level. Finally, H 2 S significantly increased K ATP channel activity in freshly isolated rat pancreatic β -cells. It appears that insulin release is impaired in ZDF because of abnormally high pancreatic production of H 2 S. New therapeutic approach for diabetes management can be devised based on our observation by inhibiting endogenous H 2 S production from pancreas.