硫化氢在植物中的生理功能及作用机制

硫化氢(H₂S)是继一氧化氮(NO)和一氧化碳(CO)之后第3个气体信号分子, 在植物体内参与许多重要的生理活动, 能够促进植物光合作用和有机物的积累, 缓解各种生物和非生物胁迫并促进植物生长发育。该文综述了植物体内H₂S的物理化学性质、产生机制、主要生理功能和作用机制以及与其它信号分子的互作关系, 并展望了H₂S信号分子的研究前景。     

Emission of Hydrogen Sulfide by Leaf Tissue in Response to l-Cysteine

Leaf discs and detached leaves exposed to l-cysteine emitted a volatile sulfur compound which was proven by gas chromatography to be H₂S. This phenomenon was demonstrated in all nine species tested (Cucumis sativus, Cucurbita pepo, Nicotiana tabacum, Coleus blumei, Beta vulgaris, Phaseolus vulgaris, Medicago sativa, Hordeum vulgare, and Gossypium hirsutum). The emission of volatile sulfur by cucumber leaves occurred in the dark at a similar rate to that in the light. The emission of leaf discs reached the maximal rate, more than 40 picomoles per minute per square centimeter, 2 to 4 hours after starting exposure to l-cysteine; then it decreased. In the case of detached leaves, the maximum occurred 5 to 10 h after starting exposure. The average emission rate of H₂S during the first 4 hours from leaf discs of cucurbits in response to 10 millimolar l-cysteine, was usually more than 40 picomoles per minute per square centimeter, i.e. 0.24 micromoles per hour per square decimeter. Leaf discs exposed to 1 millimolar l-cysteine emitted only 2% as much as did the discs exposed to 10 millimolar l-cysteine. The emission from leaf discs and from detached leaves lasted for at least 5 and 15 hours, respectively. However, several hours after the maximal emission, injury of the leaves, manifested as chlorosis, was evident. H₂S emission was a specific consequence of exposure to l-cysteine; neither d-cysteine nor l-cystine elicited H₂S emission. Aminooxyacetic acid, an inhibitor of pyridoxal phosphate dependent enzymes, inhibited the emission. In a cell free system from cucumber leaves, H₂S formation and its release occurred in response to l-cysteine. Feeding experiments with [³⁵S]l-cysteine showed that most of the sulfur in H₂S was derived from sulfur in the l-cysteine supplied and that the H₂S emitted for 9 hours accounted for 7 to 10% of l-cysteine taken up. ³⁵S-labeled SO₃²⁻ and SO₄²⁻ were found in the tissue extract in addition to internal soluble S²⁻. These findings suggest the existence of a sulfur cycle which converts l-cysteine to SO₄²⁻ through cysteine desulfhydration.     

Increased Growth and Germination Success in Plants following Hydrogen Sulfide Administration

This study presents a novel way of enhancing plant growth through the use of a non-petroleum based product. We report here that exposing either roots or seeds of multicellular plants to extremely low concentrations of dissolved hydrogen sulfide at any stage of life causes statistically significant increases in biomass including higher fruit yield. Individual cells in treated plants were smaller (∼13%) than those of controls. Germination success and seedling size increased in, bean, corn, wheat, and pea seeds while time to germination decreases. These findings indicated an important role of H₂S as a signaling molecule that can increase the growth rate of all species yet tested. The increased crop yields reported here has the potential to effect the world''s agricultural output.     

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。     

Redox Biochemistry of Hydrogen Sulfide

H₂S, the most recently discovered gasotransmitter, might in fact be the evolutionary matriarch of this family, being both ancient and highly reduced. Disruption of γ-cystathionase in mice leads to cardiovascular dysfunction and marked hypertension, suggesting a key role for this enzyme in H₂S production in the vasculature. However, patients with inherited deficiency in γ-cystathionase apparently do not present vascular pathology. A mitochondrial pathway disposes sulfide and couples it to oxidative phosphorylation while also exposing cytochrome c oxidase to this metabolic poison. This report focuses on the biochemistry of H₂S biogenesis and clearance, on the molecular mechanisms of its action, and on its varied biological effects.     

植物排放甲烷的研究进展

甲烷是一种重要的大气痕量气体,参与全球变暖和大气化学作用。传统上已知的甲烷生物排放源只有专性厌氧的原核生物即甲烷产生菌。然而近年来有研究发现,植物在好氧条件下能通过一种未知的机理排放甲烷,即非微生物机制产生甲烷。本文对植物排放甲烷的研究进展进行了综述,并提出了今后应加强研究的方面。     

Effect of Hydrogen Sulfide Donor on Antioxidant State of Wheat Plants and Their Resistance to Soil Drought

Russian Journal of Plant Physiology - Effects of plant treatment with a donor of hydrogen sulfide—sodium hydrosulfide—on the state of antioxidative and osmoprotective systems of young...     

Homocysteine to Hydrogen Sulfide or Hypertension

Hyperhomocysteinemia, an increased level of plasma homocysteine, is an independent risk factor for the development of premature arterial fibrosis with peripheral and cerebro-vascular, neurogenic and hypertensive heart disease, coronary occlusion and myocardial infarction, as well as venous thromboembolism. It is reported that hyperhomocysteinemia causes vascular dysfunction by two major routes: (1) increasing blood pressure and, (2) impairing the vasorelaxation activity of endothelial-derived nitric oxide. The homocysteine activates metalloproteinases and induces collagen synthesis and causes imbalances of elastin/collagen ratio which compromise vascular elastance. The metabolites from hyperhomocysteinemic endothelium could modify components of the underlying muscle cells, leading to vascular dysfunction and hypertension. Homocysteine metabolizes in the body to produce H₂S, which is a strong antioxidant and vasorelaxation factor. At an elevated level, homocysteine inactivates proteins by homocysteinylation including its endogenous metabolizing enzyme, cystathionine γ-lyase. Thus, reduced production of H₂S during hyperhomocysteinemia exemplifies hypertension and vascular diseases. In light of the present information, this review focuses on the mechanism of hyperhomocysteinemia-associated hypertension and highlights the novel modulatory role of H₂S to ameliorate hypertension.     

Hydrogen Sulfide and Pathophysiology of the CNS

Neurophysiology - The literature data and results of our research team concerning the physiological and pathological effects of hydrogen sulfide, a gas transmitter that has recently attracted...     

Production of Hydrogen Sulfide by Streptomyces odorifer

By use of various trapping systems, as well as lead acetate papers, Streptomyces odorifer was shown to produce hydrogen sulfide. Other sulfur-containing compounds may be produced by S. odorifer, but the amounts obtained were too small for detailed analysis. It was suggested that hydrogen sulfide might be a part of the earthy-odor complex produced by S. odorifer.     

his-Linked Hydrogen Sulfide Locus in Salmonella typhimurium

Investigation of strains of Salmonella typhimurium having extended his deletion mutations indicates that a genetic site (or sites) affecting H₂S production is located in the region of the chromosome adjacent to the operator end of the his operon. This site is co-transducible with the his genes. Experimental data indicate that the site is also present on an F'his factor derived from S. typhimurium, FS401. Evidence is presented for the existence of another site affecting H₂S production which is not linked to his.     

Transient Kinetic Analysis of Hydrogen Sulfide Oxidation Catalyzed by Human Sulfide Quinone Oxidoreductase

The first step in the mitochondrial sulfide oxidation pathway is catalyzed by sulfide quinone oxidoreductase (SQR), which belongs to the family of flavoprotein disulfide oxidoreductases. During the catalytic cycle, the flavin cofactor is intermittently reduced by sulfide and oxidized by ubiquinone, linking H₂S oxidation to the electron transfer chain and to energy metabolism. Human SQR can use multiple thiophilic acceptors, including sulfide, sulfite, and glutathione, to form as products, hydrodisulfide, thiosulfate, and glutathione persulfide, respectively. In this study, we have used transient kinetics to examine the mechanism of the flavin reductive half-reaction and have determined the redox potential of the bound flavin to be −123 ± 7 mV. We observe formation of an unusually intense charge-transfer (CT) complex when the enzyme is exposed to sulfide and unexpectedly, when it is exposed to sulfite. In the canonical reaction, sulfide serves as the sulfur donor and sulfite serves as the acceptor, forming thiosulfate. We show that thiosulfate is also formed when sulfide is added to the sulfite-induced CT intermediate, representing a new mechanism for thiosulfate formation. The CT complex is formed at a kinetically competent rate by reaction with sulfide but not with sulfite. Our study indicates that sulfide addition to the active site disulfide is preferred under normal turnover conditions. However, under pathological conditions when sulfite concentrations are high, sulfite could compete with sulfide for addition to the active site disulfide, leading to attenuation of SQR activity and to an alternate route for thiosulfate formation.     

Mitochondrial Sulfide Quinone Oxidoreductase Prevents Activation of the Unfolded Protein Response in Hydrogen Sulfide

Hydrogen sulfide (H₂S) is an endogenously produced gaseous molecule with important roles in cellular signaling. In mammals, exogenous H₂S improves survival of ischemia/reperfusion. We have previously shown that exposure to H₂S increases the lifespan and thermotolerance in Caenorhabditis elegans, and improves protein homeostasis in low oxygen. The mitochondrial SQRD-1 (sulfide quinone oxidoreductase) protein is a highly conserved enzyme involved in H₂S metabolism. SQRD-1 is generally considered important to detoxify H₂S. Here, we show that SQRD-1 is also required to maintain protein translation in H₂S. In sqrd-1 mutant animals, exposure to H₂S leads to phosphorylation of eIF2α and inhibition of protein synthesis. In contrast, global protein translation is not altered in wild-type animals exposed to lethally high H₂S or in hif-1(ia04) mutants that die when exposed to low H₂S. We demonstrate that both gcn-2 and pek-1 kinases are involved in the H₂S-induced phosphorylation of eIF2α. Both ER and mitochondrial stress responses are activated in sqrd-1 mutant animals exposed to H₂S, but not in wild-type animals. We speculate that SQRD-1 activity in H₂S may coordinate proteostasis responses in multiple cellular compartments.     

Enhanced Biological Hydrogen Production from Escherichia coli with Surface Precipitated Cadmium Sulfide Nanoparticles

The precipitation of cadmium sulfide nanoparticles is induced on the surface of Escherichia coli , and the biological hydrogen production efficiency under visible light (VL) irradiation is investigated. When endogenous [Ni–Fe]‐hydrogenase is anaerobically induced, an additional 400 µmol of hydrogen gas is generated within 3 h from the hybrid system suspension (50 mL) under VL irradiation (2000 W m^?2), corresponding to an increase in hydrogen production of ≈30%. The apparent quantum efficiencies of the hybrid system under 470 and 620 nm VL irradiation are 7.93% and 9.59%, respectively, which are higher than those of many photoheterotrophic bacteria. Furthermore, the mechanism of the enhanced hydrogen evolution is investigated. The interaction between photogenerated electrons and cells of E. coli is confirmed by heat‐treatment, electron‐scavenger, and separation studies. The acceleration of pyruvate generation, inhibition of lactate fermentation, increase of formate concentration, stimulation of hydrogenase activity, and elevation of nicotinamide adenine dinucleotide (NAD)H/NAD ratio in the hybrid system are responsible for the enhanced hydrogen production. A feasibility study is also conducted using wastewater and natural sunlight for the hydrogen production by the hybrid system. An additional 120 µmol of hydrogen is generated from the hybrid system within 3 h under these conditions using natural resources.     

Characterization of Hydrogen Sulfide-Producing Bacteria Isolated from Meat and Poultry Plants

A survey of the types of aerobic organisms able to produce H2S on peptone iron agar (Levin, 1968), and commonly occurring in meat and poultry plants, revealed that these could be divided into four distinct groups. The ability of representative strains of each type to grow at low temperatures and cause off-odors on chicken muscle was examined. The results are discussed in relation to the role of these organisms in the psychrophilic spoilage of meat and meat products.     

硫化氢与脊髓损伤治疗

脊髓损伤(spinal cord injury,SCI)是一种由于脊髓外部损伤或内部病变引起的暂时性或永久性的功能损伤,其症状包括肌肉功能损伤、自主运动功能减退或丧失等。目前,流行病学调查发现,我国SCI患病率较高,具有较高的社会和医疗负担。因此,合理引导SCI病人进行治疗和康复尤为重要。硫化氢（hydrogen sulfide,H2S）是一种重要的神经信号分子,近年来H2S对SCI康复的作用机制逐渐成为研究热点,例如一些国内外研究团队对SCI后缺血-再灌注损伤（ischemia reperfusion injury,I/R injury）、降低SCI后氧化应激及抗炎作用等机制,以及SCI康复临床治疗研究均取得了一定的成果。本文通过H2S对SCI康复的机制研究和临床治疗发展进行综述,旨在为后续研究及临床应用提供参考。     

硫化氢与脊髓损伤治疗

脊髓损伤(spinal cord injury,SCI)是一种由于脊髓外部损伤或内部病变引起的暂时性或永久性的功能损伤,其症状包括肌肉功能损伤、自主运动功能减退或丧失等。目前,流行病学调查发现,我国SCI患病率较高,具有较高的社会和医疗负担。因此,合理引导SCI病人进行治疗和康复尤为重要。硫化氢（hydrogen sulfide,H2S）是一种重要的神经信号分子,近年来H2S对SCI康复的作用机制逐渐成为研究热点,例如一些国内外研究团队对SCI后缺血-再灌注损伤（ischemia reperfusion injury,I/R injury）、降低SCI后氧化应激及抗炎作用等机制,以及SCI康复临床治疗研究均取得了一定的成果。本文通过H2S对SCI康复的机制研究和临床治疗发展进行综述,旨在为后续研究及临床应用提供参考。