Gasotransmitters are small, labile, endogenously-produced gaseous molecules that play important roles in cellular signaling [
1]. Hydrogen sulfide (H
2S) is the newest member of the gasotransmitter family. Historically, it was considered to be highly toxic and hazardous to the environment [
2]. However, H
2S has recently emerged as a critical physiological gaseous signaling molecule that is produced enzymatically in all mammalian species at low micromolar levels via the action of cysteine metabolic enzymes: cystathionine-γ-lyase (CSE), cystathionine-β-synthase (CBS), and 3-mercaptopyruvate sulfutransferase (3-MST) [
3]. Because of this discovery, the biological and physiological role of H
2S has been re-evaluated. As such, an extensive amount of work has been conducted over the last several decades and has led to the discovery that H
2S possesses a number of physiological actions.
In 1989, while investigation the effects of acute H
2S poisoning in the brain, Warenycia
et al.[
4] first reported that H
2S was produced endogenously. Soon after this discovery, other investigators started to take a closer look at H
2S and evidence soon emerged to demonstrate its physiological importance. For instance, Skrajny
et al.[
5] found increased levels of serotonin and reduced levels of norepinephrine in the frontal cortex of a rat when chronically exposed to 20 ppm of H
2S and in 1996, Abe
et al.[
6] suggested that H
2S was an endogenous neuromodulator, as they showed that physiological concentrations of H
2S enhanced
N-methyl-D-aspartate (NMDA) receptor-mediated responses and aided in the induction of hippocampal long-term potentiation. Shortly after, Hosoki
et al.[
7] reported that an H
2S-producing enzyme was present in the vasculature and proposed that H
2S may be an endogenous smooth muscle relaxant. Since these initial offerings, studies have begun to characterize its biological profile and therapeutic potential. Over the last several years, a great amount of work by investigators all over the world have led to the suggestion that H
2S is a powerful signaling molecule with a diverse physiological profile. Moreover, because of its physiological actions, H
2S has been reported to protect the heart, brain, liver, kidney, and lungs against a variety of pathological stimuli, including ischemia/reperfusion (I/R) injury [
8‐
17].
First European conference on the biology of hydrogen sulfide
The First European Conference on the Biology of Hydrogen Sulfide was held at Smolenice Castle on the outskirts of Bratislava, Slovakia from June 15 to 18, 2012. The Institute of Molecular Physiology and Genetics from the Slovak Academy of Sciences sponsored this conference. Dr Karol Ondrias from the Slovak Academy of Sciences served as the Conference Chairman and Dr Matthew Whiteman from the University of Exeter served as Honorary Chairman and Chairman of the International Advisory Committee. Together with the rest of the members of the International Advisory Committee, Drs Ondrias and Whiteman organized an outstanding scientific program consisting of 12 plenary lectures, 34 short oral presentations, and 15 poster presentations.
The meeting started with a Keynote Lecture delivered by Dr Rui Wang from Lakehead University in Thunder Bay, Ontario, Canada. In his lecture, Dr Wang discussed several recent findings regarding where inside the eukaryotic cell H2S is produced and how this intracellular compartmentalization is realized. He also discussed the functional consequences of H2S production in response to difference stimuli. Dr Wang’s lecture was followed by a very nice welcome reception where the attendees were inundated with local Slovakian cuisine.
Day 2 of the conference began with a session focused on the effects of H
2S on heart and vascular physiology. Dr Y.Z. Zhu from Fudan University in Shanghai China began the session by detailing recent work on the involvement of H
2S in the cardiovascular disorder processes and the prospects of new therapeutic strategies based on the regulation of endogenous H
2S production [
18]. This session was highlighted by Dr David Lefer from Emory University in Atlanta GA who presented recent work investigating the role of cystathionine gamma lyase derived H
2S in the development of pressure-induced heart failure. He also presented novel and exciting data regarding the effects of oral H
2S therapy on preventing cardiac dysfunction following the induction of heart failure.
There is emerging evidence that members of the gasotransmitter family can interact with each other. For instance, NO and H
2S have been suggested to collaborate in regulating vascular homeostasis and vasodilation. Additional evidence suggests that NO can increase CGL activity acutely, and that chronic exposure to NO up-regulates CGL expression. Moreover, at low concentrations H
2S has been shown to enhance the release of NO from vascular endothelium and increase the vasorelaxant effect of the NO donor sodium nitroprusside [
19]. Furthermore, a 10 fold increase in H
2S levels have been reported with administration of NO donors [
20], suggesting a synergistic relationship between NO and H
2S. Dr Andreas Papapetropoulos from the University of Patras in Greece detailed very exciting and new results that further demonstrate the interdependence of the gasotransmitters on each other. Specifically, he provided the audience with compelling evidence that angiogenesis and vasodilatation require the simultaneous production of H
2S and NO, suggesting that both are mutually required for the control of vascular function [
21].
Day 2 concluded with two afternoon sessions. The first session focused on the ability of H
2S to regulate respiratory and gastrointestinal function. Dr John Wallace from McMaster University in Hamilton, Ontario, Canada discussed his group’s latest findings regarding the ability of novel H
2S releasing anti-inflammatory drugs to alleviate the development of gastrointestinal (GI) ulcers [
22]. The last session of Day 2 focused on H
2S donors and was highlighted by Dr Mathew Whiteman’s presentation on the use of H
2S donors to treat inflammatory joint disease.
Dr Csabo Szabo from the University of Texas Medical Branch in Galvaston, TX opened the morning session on Day 3 by discussing the role of H
2S deficiency in the pathogenesis of diabetic vascular complications. In his presentation he provided the audience with compelling data suggesting that H
2S deficiency is emerging as a significant pathogenic mechanism in diabetic complication, while H
2S supplementation has the potential to be a novel therapeutic approach [
23]. The session on H
2S and diabetes was followed by a session regarding the interaction of H
2S with the mitochondria. This session was highlighted by Dr Katalin Modis’ (University of Texas Medical Branch in Galvaston, TX) presentation detailed her exciting work demonstrating that H
2S has a physiological role as a positive modulator of mitochondrial electron transport that is dependent on a basal activity of the Krebs cycle [
24].
In the afternoon, Dr Hideo Kimura from the National Institute of Neuroscience in Tokyo, Japan led off a very interesting and stimulating session on the synthesis of hydrogen sulfide. In his talk, Dr Kimura detailed his group’s efforts to identify the endogenous reducing substances (thioredoxin and dihydrolipoic acid) that facilitate the production of H
2S from 3-mercaptopyruvate sulfurtransferase [
25]. This was followed by a very stimulating presentation from the Ondrias group detailing their work suggesting that H
2S induces the release of NO from nitroso groups. Day 3 ended with a very informative session regarding the interaction of H
2S with different ion channels.
The Final Day of the conference ended with several talks discussing the latest findings regarding the role of H2S in the setting of cellular stress and cell proliferation. Additionally, awards were handed out at the conclusion of the conference to several young investigators.
The second international conference on H2S biology and medicine
With the momentum gained at Smolenic Castle in Bratislava, scientists, clinicians, and industry representatives from around the world descended on Atlanta, GA from September 20 – 22, 2012 to attend the Second International Conference on H2S Biology and Medicine. Dr David Lefer from Emory University in Atlanta, GA organized this conference. Together with the rest of the member of the Organizing Committee, Dr Lefer planned a well-balanced scientific program detailing the latest findings concerning the chemistry and biology of H2S. The final program consisted of 30 plenary lectures, 4 short oral presentations, and over 75 poster presentations.
Dr Solomon Snyder from Johns Hopkins University in Baltimore, MD delivered the keynote lecture to start the conference. In his lecture, Dr Solomon eloquently discussed his group’s efforts to characterize sulfhydration, which is the mechanism by which H
2S modifies reactive cysteine residues on targeted proteins. Although analogous to protein nitrosylation, sulfhydration is substantially more prevalent and usually increases the catalytic activity of targeted proteins [
26].
Dr Snyder’s lecture was followed by several presentations on the biology and chemistry of H
2S. Highlights from this session included Dr Nicholas Tonk’s (Cold Spring Harbor Laboratory) presentation on his recent work detailing of the effects of H
2S on the endoplasmic reticulum stress response. Specifically, he presented data demonstrating that H
2S reversibly inhibits the activity of protein tyrosine phosphatase 1B, which promotes the activity of protein kinase-like endoplasmic reticulum (ER) kinase (PERK) during the response to ER stress [
27]. With the growing interest in the physiological and biological role of H
2S, there is a need for better detection methods for H
2S levels and signaling. This was a constant point of discussion throughout the meeting. As such, Dr Ming Xian’s (Washington State University in Pullman, WA) presentation on new chemical tools for H
2S research was of particular interest. In his talk, Dr Xian provided evidence that newly developed fluorescent probes provide good selectivity and sensitivity for H
2S [
28].
The afternoon session of Day 1 was dedicated to discussion on the role that H
2S plays in the development and treatment of cardiovascular disease. Dr Frank Sellke from Brown University in Providence, RI led off this session by discussing his labs previous work investigating the impact of H
2S on myocardium in the setting of cold crystalloid cardioplegia and cardiopulmonary bypass [
29]. In his talk, Dr Sellke provided compelling evidence that treatment with H
2S offered myocardial protection via attenuation of caspase-independent apoptosis and autophagy in a porcine model of cardiopulmonary bypass. Later in this session, Dr Suresh Tyagi from the University of Louisville in Louisville, KY summarized his groups’ findings regarding the effects of H
2S on cardiovascular remodeling in response to heart failure [
30]. Day 1 concluded with a reception and presentation of posters.
Day 2 of the conference featured three sessions. The first session of the morning was focused on H2S and the vasculature. Dr Rui Wang from Lakehead University in Thunder Bay, Ontario, Canada started the session with a nice introduction to the effects of H2S on the vascular endothelium. This was followed by Dr Guiseppe Cirino’s (University of Naples, Naples, Italy) presentation on H2S as an endogenous inhibitor of phosphodiesterases and how this affects vascular tone.
The second session of Day 2 was focused on the H2S and gastrointestinal diseases. Presentations in this session from Drs. John Wallace (McMaster University in Hamilton, Ontario, Canada), Mauro Perretti (Queen Mary University), Nathalie Vergnolle (INSERM), and Andre Buret (University of Calgary) detailed the latest findings regarding the role of H2S in the resolution and repair of the GI tract and detailed the latest developments in use of novel H2S releasing drugs to treat GI disorders.
The final session of Day 2 was concentrated on the role of H
2S in shock and sepsis. This session began with a very informative presentation by Dr Konstantin Shatalin (New York University) in which he discussed the role H
2S plays in mediating bacteria defense against antibiotics [
31]. Specifically, Dr Shatalin provided evidence that inactivation of putative cystathionine β-synthase, cystathionine γ-lyase, or 3-mercaptopyruvate sulfurtransferase in
Bacillus anthracis, Pseudomonas aeruginosa, Staphylococcus aureus, and
Escherichia coli suppresses H
2S production, rendering these pathogens highly sensitive to a multitude of antibiotics. Dr Fumito Ichinose from Harvard University in Boston, MA then detailed recent findings from his lab in which they demonstrated that inhaled H
2S prevents inflammation and improves survival in the setting of endotoxemia by altering sulfide metabolism in mice [
32].
The final day of the conference began with presentations selected from submitted abstracts. This forum gave deserving young investigators and trainees the opportunity to present their latest findings in a more formal setting. This session was followed by a second session on H2S and the vasculature. Dr Christopher Peers from the University of Leeds in Leeds, England highlighted this session with his presentation on the regulation of ion channels by H2S. Dr Chris Kevil from LSU-Health Sciences Center in Shreveport, LA delivered the last talk of the conference detailing his groups latest work on the actions of H2S in the setting of high limb ischemia.