Gas biology: small molecular medicine

Semenza, Gregg L.; Prabhakar, Nanduri R.

doi:10.1007/s00109-012-0877-0

Cited by 6 publications

(8 citation statements)

References 18 publications

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“…Most recently, H 2 S has emerged as a third gasotransmitter, with key roles in the nervous and cardiovascular systems and regulation of cellular and whole body metabolism (reviewed in [14,15]). The literature on the biology of these three gases is now so vast that these and other reviews must act as a surrogate for the relevant papers: [16-20]. In the microbial world too, all three gases have important long-recognised roles: NO is an intermediate in denitrification [21] and is detoxified by pathogens [22,23], CO is an unusual carbon and energy source [24], and H 2 S is well known to all microbiologists as a product of anoxic sulfate respiration [25].…”

Section: Introduction and Chronologymentioning

confidence: 99%

Gasotransmitters, poisons, and antimicrobials: it's a gas, gas, gas!

Tinajero-Trejo¹,

Jesse²,

Poole³

2013

F1000Prime Rep

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We review recent examples of the burgeoning literature on three gases that have major impacts in biology and microbiology. NO, CO and H2S are now co-classified as endogenous gasotransmitters with profound effects on mammalian physiology and, potentially, major implications in therapeutic applications. All are well known to be toxic yet, at tiny concentrations in human and cell biology, play key signalling and regulatory functions. All may also be endogenously generated in microbes. NO and H2S share the property of being biochemically detoxified, yet are beneficial in resisting the bactericidal properties of antibiotics. The mechanism underlying this protection is currently under debate. CO, in contrast, is not readily removed; mounting evidence shows that CO, and especially organic donor compounds that release the gas in biological environments, are themselves effective, novel antimicrobial agents.

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Section: Introduction and Chronologymentioning

confidence: 99%

Gasotransmitters, poisons, and antimicrobials: it's a gas, gas, gas!

Tinajero-Trejo¹,

Jesse²,

Poole³

2013

F1000Prime Rep

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“…With the remarkable sensitivity and the fast speed to hypoxic response, the carotid body plays a unique role in O 2 sensing [ 19 ]. Carotid bodies are small sensory organs located at the bifurcation of the common carotid artery [ 14 , 19 ]. Changes in O 2 levels of arterial blood rapidly active the carotid bodies, which in turn transduce sensory information to brainstem neurons [ 14 ].…”

Section: H 2 S and Hypoxic Sensing In The Cmentioning

confidence: 99%

“…Carotid bodies are small sensory organs located at the bifurcation of the common carotid artery [ 14 , 19 ]. Changes in O 2 levels of arterial blood rapidly active the carotid bodies, which in turn transduce sensory information to brainstem neurons [ 14 ]. The final response in the central nervous system regulates vital functions including breathing, heart rate, and blood pressure to increase ventilation and systemic delivery of oxygen [ 15 ].…”

Section: H 2 S and Hypoxic Sensing In The Cmentioning

confidence: 99%

“…Endogenous H 2 S levels have been reported in different mammalian systems, ranging from 50 to 160 μ M [ 6 , 7 ]. The enzymatic production of endogenous H 2 S were identified, mostly composed of cystathionine β -synthase (CBS) [ 8 – 10 ], cystathionine γ -lyase (CSE) [ 11 – 13 ], and 3-mercaptopyruvate sulfurtransferase (MST) [ 14 – 16 ].…”

Section: Introductionmentioning

confidence: 99%

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Interaction of Hydrogen Sulfide with Oxygen Sensing under Hypoxia

Teng

Zhang

et al. 2015

Oxidative Medicine and Cellular Longevity

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Based on the discovery of endogenous H2S production, many in depth studies show this gasotransmitter with a variety of physiological and pathological functions. Three enzymes, cystathionine β-synthase (CBS), cystathionine γ-lyase (CSE), and 3-mercaptopyruvate sulfurtransferase (MST), are involved in enzymatic production of H2S. Emerging evidence has elucidated an important protective role of H2S in hypoxic conditions in many mammalian systems. However, the mechanisms by which H2S senses and responses to hypoxia are largely elusive. Hypoxia-inducible factors (HIFs) function as key regulators of oxygen sensing, activating target genes expression under hypoxia. Recent studies have shown that exogenous H2S regulates HIF action in different patterns. The activation of carotid bodies is a sensitive and prompt response to hypoxia, rapidly enhancing general O2 supply. H2S has been identified as an excitatory mediator of hypoxic sensing in the carotid bodies. This paper presents a brief review of the roles of these two pathways which contribute to hypoxic sensing of H2S.

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“…Secondly, they exert their biological actions via a variety of interactions with macromolecules: covalent binding of gases to prosthetic metal complexes in receptor proteins; non-covalent binding to the regulatory subunits of proteins; and space occupancy in and around the protein structure that impedes the access of other gases to the functionally critical protein motifs. Recent evidence suggest that NO, CO, H 2 S, and CO 2 function as signaling molecules that also play critical roles in mediating the biological effects of changes in O 2 availability (Semenza and Prabhakar, 2012). …”

Section: Introductionmentioning

confidence: 99%

TRP channels: sensors and transducers of gasotransmitter signals

Takahashi¹,

Kozai²,

Mori³

2012

Front. Physio.

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The transient receptor potential (trp) gene superfamily encodes cation channels that act as multimodal sensors for a wide variety of stimuli from outside and inside the cell. Upon sensing, they transduce electrical and Ca2+ signals via their cation channel activities. These functional features of TRP channels allow the body to react and adapt to different forms of environmental changes. Indeed, members of one class of TRP channels have emerged as sensors of gaseous messenger molecules that control various cellular processes. Nitric oxide (NO), a vasoactive gaseous molecule, regulates TRP channels directly via cysteine (Cys) S-nitrosylation or indirectly via cyclic GMP (cGMP)/protein kinase G (PKG)-dependent phosphorylation. Recent studies have revealed that changes in the availability of molecular oxygen (O2) also control the activation of TRP channels. Anoxia induced by O2-glucose deprivation and severe hypoxia (1% O2) activates TRPM7 and TRPC6, respectively, whereas TRPA1 has recently been identified as a novel sensor of hyperoxia and mild hypoxia (15% O2) in vagal and sensory neurons. TRPA1 also detects other gaseous molecules such as hydrogen sulfide (H2S) and carbon dioxide (CO2). In this review, we focus on how signaling by gaseous molecules is sensed and integrated by TRP channels.

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Gas biology: small molecular medicine

Cited by 6 publications

References 18 publications

Gasotransmitters, poisons, and antimicrobials: it's a gas, gas, gas!

Gasotransmitters, poisons, and antimicrobials: it's a gas, gas, gas!

Interaction of Hydrogen Sulfide with Oxygen Sensing under Hypoxia

TRP channels: sensors and transducers of gasotransmitter signals

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