NO和H2O2在光/暗调控蚕豆气孔运动中的作用及其相互关系

借助表皮条分析和激光扫描共聚焦显微镜技术,对NO和H2O2在光/暗调控蚕豆(Vicia faba L.)气孔运动中的作用及其相互关系进行了探索.结果显示,光下外源NO供体硝普钠(SNP)和H2O2促进气孔关闭的效应明显大于暗中,暗中NO专一性清除剂2,4-羧基苯-4,4,5,5-四甲基咪唑-1-氧-3-氧化物(cPTIO)、一氧化氮合酶(NOS)抑制剂NG-氮-L-精氨酸-甲酯(L-NAME)和H2O2清除剂抗坏血酸(Vc)、过氧化氢酶(CAT)对气孔开度的效应明显大于光下,而且光下蚕豆保卫细胞NO和H2O2水平比暗中明显降低.上述结果表明,光/暗通过影响保卫细胞NO和H2O2的水平调控气孔运动.研究还发现,光下H2O2既诱导NO水平增加,也诱导气孔关闭,cPTIO和L-NAME有效地逆转H2O2的这些效应;光下SNP既诱导H2O2水平增加,也诱导气孔关闭,SNP的上述效应又被Vc和CAT有效逆转.这些结果表明,NO和H2O2在生成及效应上均存在明显的相互作用.另外,L-NAME显著逆转暗和光下H2O2处理对气孔关闭和NO生成的效应表明,蚕豆保卫细胞中可能存在NOS,暗和光下H2O2处理可能通过提高NOS的活性促进NO水平增加,进而诱导气孔关闭.     

NO和H2O2在光／暗调控蚕豆气孔运动中的作用及其相互关系

借助表皮条分析和激光扫描共聚焦显微镜技术,对NO和H_2O_2在光/暗调控蚕豆(Vicia faba L.)气孔运动中的作用及其相互关系进行了探索。结果显示,光下外源NO供体硝普钠(SNP)和H_2O_2促进气孔关闭的效应明显大于暗中,暗中NO专一性清除剂2,4-羧基苯-4,4,5,5-四甲基咪唑-1-氧-3-氧化物(cPTIO)、一氧化氮合酶(NOS)抑制剂N~G-氮-L-精氨酸-甲酯(L-NAME)和H_2O_2清除剂抗坏血酸(Vc)、过氧化氢酶(CAT)对气孔开度的效应明显大于光下,而且光下蚕豆保卫细胞NO和H_2O_2水平比暗中明显降低。上述结果表明,光/暗通过影响保卫细胞NO和H_2O_2的水平调控气孔运动。研究还发现,光下H_2O_2既诱导NO水平增加,也诱导气孔关闭,cPTIO和L-NAME有效地逆转H_2O_2的这些效应;光下SNP既诱导H_2O_2水平增加,也诱导气孔关闭,SNP的上述效应又被Vc和CAT有效逆转。这些结果表明,NO和H_2O_2在生成及效应上均存在明显的相互作用。另外,L-NAME显著逆转暗和光下H_2O_2处理对气孔关闭和NO生成的效应表明,蚕豆保卫细胞中可能存在NOS,暗和光下H_2O_2处理可能通过提高NOS的活性促进NO水平增加,进而诱导气孔关闭。     

植物气孔运动过程中的信号转导机制

气孔运动的信号转导机制一直是科研工作者研究的一个热点,文章就光、CO2、ABA、H2O2、NO、蛋白激酶、蛋白磷酸酶等对保卫细胞气孔运动的影响,介绍气孔运动机制的研究进展。     

UV-B辐射对蚕豆叶片气孔运动的间接效应与NO和H2O2有关

0.2 W.m-2的UV-B辐射不仅能诱导整体蚕豆叶片气孔导度和开度的显著降低,而且能明显降低蚕豆叶肉光合活性,但该强度的UV-B辐射却不能明显影响离体表皮条的气孔开度.说明0.2W.m-2的UV-B主要通过间接途径调控了蚕豆叶片气孔运动.借助药理学试验和激光扫描共聚焦显微镜技术,进一步对该间接效应过程中是否有NO和H2O2的参与进行了探讨.结果显示:NO专一性清除剂cPT IO和一氧化氮合酶(NO S)抑制剂L-NAM E均能有效地抑制UV-B辐射诱导的叶片气孔关闭和保卫细胞内源NO水平的升高;H2O2清除剂抗坏血酸(A SC)和过氧化氢酶(CAT)也能有效地逆转UV-B辐射诱导的气孔关闭和保卫细胞内源H2O2含量的升高.另外,外源NO或H2O2处理也能有效地诱导叶片气孔关闭.结果说明0.2W.m-2的UV-B辐射对蚕豆叶片气孔关闭的间接诱导与NO和H2O2有关.     

外源NO和H2O2对洋葱鳞片外表皮气孔开度的调控

以洋葱(Allium cepa L.)肉质鳞片外表皮为材料,研究不同浓度及不同处理时间的外源NO和H2O2对洋葱鳞片外表皮上气孔开度的调节作用,并结合NO清除剂血红蛋白(Hb)和H2O2清除剂过氧化氢酶(CAT)研究调控过程中NO和H2O2的相互关系.结果显示:单独施用不同浓度的NO和H2O2均可诱导洋葱鳞片外表皮气孔不同程度关闭,并且浓度越大时间越长,其诱导气孔关闭效应越明显;NO和H2O2共同施用所诱导气孔关闭的效应大于其单独施用效应;Hb和CAT能明显减弱NO和H2O2诱导的气孔关闭.研究表明,NO和H2O2能有效诱导洋葱鳞片上气孔关闭,存在明显的浓度效应和时间效应,且两者可能互相依赖,具有协同效应.     

H_2O_2介导H_2S诱导的拟南芥气孔关闭

以拟南芥（Arabidopsis thaliana）为材料,研究了过氧化氢（H2O2）在硫化氢（H2S）调控气孔运动信号转导中的作用。结果表明,光下H2S的供体硫氢化钠（NaHS）能够诱导拟南芥气孔关闭;且能够显著提高叶片和保卫细胞胞质H2O2含量;H2O2的清除剂AsA和H2O2合成酶的抑制剂可不同程度地抑制NaHS诱导的拟南芥气孔关闭及叶片和保卫细胞胞质H2O2水平的升高;NaHS对AtrbohD、AtrbohF、Atpao2和Atpao4突变体气孔关闭、叶片和保卫细胞胞质H2O2水平升高的诱导作用要明显的小于野生型,但对AtPAO2和AtPAO4过表达株系叶片和保卫细胞H2O2水平的升高较野生型显著。据此推测,来源于NADPH氧化酶、细胞壁过氧化物酶和多胺氧化酶途径的H2O2参与H2S诱导的拟南芥气孔关闭。     

拟南芥保卫细胞中茉莉酸甲酯诱导的H2O2产生与MAPK信号转导体系的可能关系

蛋白激酶MEK1/2的专一抑制剂PD98059可抑制茉莉酸甲酯(MeJA)诱导的拟南芥保卫细胞中H2O2的产生和气孔的关闭.MeJA和H2O2诱导气孔关闭后,再用PD98059处理,可使关闭的气孔重新开放,同样,外源PD98059处理,能使MeJA诱导增强的H2O2探针的荧光强度降低.此结果表明,类属于MAPKK的蛋白激酶MEK1/2参与了MeJA诱导的拟南芥气孔关闭的信号转导过程,其作用机制可能是通过调节MeJA诱导保卫细胞产生和积累H2O2而起作用.     

H2S位于H2O2下游参与乙烯诱导拟南芥气孔关闭过程

H2O2和H2S是植物体内重要的信号分子,二者均参与乙烯诱导的拟南芥气孔关闭过程。以拟南芥野生型及其突变体为材料研究了H2O2和H2S在乙烯诱导拟南芥气孔关闭过程中的相互关系。结果表明,乙烯能够诱导野生型拟南芥叶片H2S含量及L-/D-半胱氨酸脱巯基酶(L-/D-CDes)活性显著增加,促进气孔关闭,但对H2O2合成突变体AtrbohD、AtrbohF、Atpao2和Atpao4植株叶片无显著作用;乙烯亦可引起H2S合成突变体Atl-cdes和Atd-cdes气孔保卫细胞H2O2水平的显著增加,但对其气孔运动没有显著作用。此外,H2O2清除剂和合成抑制剂均能抑制乙烯诱导的拟南芥叶片H2S含量和L-/D-CDes活性的增加及气孔开度的减小;而H2S清除剂和合成抑制剂虽能抑制乙烯诱导的气孔关闭,却不能改变乙烯对拟南芥叶片气孔保卫细胞H2O2的作用效应。由此表明H2S位于H2O2下游介导乙烯诱导拟南芥气孔关闭过程。     

PTPases抑制剂对外源NO调控蚕豆气孔运动的影响

以蚕豆(Vicia fabaL.)气孔保卫细胞为材料,研究了酪氨酸蛋白磷酸酶(protein tyrosine phosphatases,PTPases)的抑制剂氧化苯胂(phenylarsine oxide,PAO)、钒酸钠(NaVO3)和Zn2 对外源一氧化氮(NO)调控蚕豆气孔运动的影响。结果表明,NO供体硝普钠(sodium nitroprusside,SNP)能诱导蚕豆气孔关闭,其效应在0.001~0.1 mmol.L-1浓度范围内随着SNP浓度的增大而增强;不同浓度的PAO、NaVO3和Zn2 对光诱导的气孔张开几乎没有影响,但都可以抑制黑暗或SNP诱导的气孔关闭,表明酪氨酸蛋白磷酸酶参与NO调控蚕豆气孔运动的信号转导过程,在NO调控蚕豆气孔运动中起着重要的作用。     

几种信号类物质对蚕豆气孔运动的效应

用表皮生物分析方法,研究H2O2、NO和多胺对蚕豆叶片气孔开放和关闭的单独及其综合效应.其结果表明:H2O2和NO明显促进气孔关闭,抑制气孔开放.腐胺(Put)效应相对较弱,与H2O2和NO未表现出明显叠加效应.     

Cytokinin- and auxin-induced stomatal opening is related to the change of nitric oxide levels in guard cells in broad bean

The relationship between cytokinin- and auxin-induced stomatal opening and nitric oxide (NO) levels in guard cells in broad bean was studied. Results indicate that cytokinins and auxins reduced the levels of NO in guard cells and induced stomatal opening in darkness. In addition, cytokinins not only reduced NO levels in guard cells caused by sodium nitroprusside (SNP) in light but also abolished NO that had been generated by dark, and then promoted the closed stomata reopening, as did NO scavenger 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide. However, unlike cytokinins, auxins not only had incapability to reduce NO levels by SNP but also could not abolish NO having been generated by dark, so auxins could not promote the closed stomata to reopen. The above-mentioned effects of auxins were similar to that of nitric oxide synthase (enzyme commission 1.14.13.39) inhibitor N ^G-nitro- l -Arg-methyl ester. Hence, it is concluded that cytokinins reduced probably the levels of NO in guard cells via scavenging, and auxins reduced NO levels through restraining NO generation in all probability, and then induced stomatal opening in darkness.     

Nitric oxide inhibits blue light-specific stomatal opening via abscisic acid signaling pathways in Vicia guard cells

Recent evidence suggests that nitric oxide (NO) acts as an intermediate of ABA signal transduction for stomatal closure. However, NO's effect on stomatal opening is poorly understood even though both opening and closing activities determine stomatal aperture. Here we show that NO inhibits stomatal opening specific to blue light, thereby stimulating stomatal closure. NO inhibited blue light-specific stomatal opening but not red light-induced opening. NO inhibited both blue light-induced H(+) pumping and H(+)-ATPase phosphorylation. The NO scavenger 2-carboxyphenyl-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide (c-PTIO) restored all these inhibitory effects. ABA and hydrogen peroxide (H(2)O(2)) inhibited all of these blue light-specific responses in a manner similar to NO. c-PTIO partially restored the ABA-induced inhibition of all of these opening responses but did not restore inhibition of the responses by H(2)O(2). ABA, H(2)O(2) and NO had slight inhibitory effects on the phosphorylation of phototropins, which are blue light receptors in guard cells. NO inhibited neither fusicoccin-induced H(+) pumping in guard cells nor H(+) transport by H(+)-ATPase in the isolated membranes. From these results, we conclude that both NO and H(2)O(2) inhibit blue light-induced activation of H(+)-ATPase by inhibiting the component(s) between phototropins and H(+)-ATPase in guard cells and stimulate stomatal closure by ABA.     

Carbon Monoxide-induced Stomatal Closure Involves Generation of Hydrogen Peroxide in Vicia faba Guard Cells

Here the regulatory role of CO during stomatal movement In Vicla faba L. was surveyed. Results Indicated that, like hydrogen peroxide (H2O2), CO donor Hematin induced stomatal closure in dose- and time-dependent manners. These responses were also proven by the addition of gaseous CO aqueous solution with different concentrations, showing the first time that CO and H2O2 exhibit the similar regulation role in the atomatal movement. Moreover, our data showed that ascorbic acid (ASA, an important reducing substrate for H2O2 removal) and diphenylene iodonium (DPI, an inhibitor of the H2O2-generating enzyme NADPH oxidase) not only reversed stomatal closure by CO, but also suppressed the H2O2 fluorescence induced by CO, implying that CO induced-atomatal closure probably involves H2O2 signal. Additionally, the CO/NO scavenger hemoglobin (Hb) and CO specific synthetic inhibitor ZnPPIX, ASA and DPI reversed the darkness-induced stomatal closure and H2O2 fluorescence. These results show that, perhaps like H2O2, the levels of CO in guard cells of V. faba are higher In the dark than in light, HO-1 and NADPH oxidase are the enzyme systems responsible for generating endogenous CO and H2O2 in darkness respectively, and that CO is involved in darkness-induced H2O2 synthesis in V. faba guard cells.     

Reactive oxygen species and nitric oxide are involved in ABA inhibition of stomatal opening

Although nitric oxide (NO) and reactive oxygen species (ROS) are essential signalling molecules required for mediation of abscisic acid (ABA)-induced stomatal closure, it is not known whether these molecules also mediate the ABA inhibition of stomatal opening. In this study, we investigated the role of NO and ROS in the ABA inhibition of stomatal opening in Vicia faba. ABA induced both NO and ROS synthesis, and the NO scavenger reduced the ABA inhibition of stomatal opening. Exogenous NO and hydrogen peroxide (H2O2) also inhibited stomatal opening, indicating that NO and ROS are involved in the inhibition signalling process. An inhibitor of nitric oxide synthase (NOS) reversed the ABA inhibition of stomatal opening. Either the NO scavenger or the NOS inhibitor also reversed the process in the H2O2 inhibition of stomatal opening. We found that in the ABA inhibition of stomatal opening, NO is downstream of ROS in the signalling process, and NO is synthesized by a NOS-like enzyme.     

Induction of Stomatal Closure by Vanadate or a Light/Dark Transition Involves Ca2+-Calmodulin-Dependent Protein Phosphorylations

Previous studies indicate that a continual source of adenosine 5[prime]-triphosphate is required for both opening and closing of stomata. However, vanadate (Na3VO4 at 500 [mu]M) as well as a light/dark transition induced stomatal closing in epidermal peels of Commelina communis L., showing that the stoppage or even the decrease of the activity of the plasma membrane H+-adenosine 5[prime]-triphosphatase is sufficient to induce stomatal closure. Furthermore, stomatal closing in response to Na3VO4 or a light/dark transition was suppressed by inhibitors of metabolism (10 [mu]M carbonyl cyanide m-chlorophenylhydrazone) and of protein kinases (20 [mu]M 1-[5-iodonaphthalene-1-sulfonyl]-1H-hexa-hydro-1,4-diaz-epine), calmodulin antagonists (20 [mu]M N-[6-aminohexyl]-5-chloro-1-naphthalenesulfonamide), and the anion channel blocker 5-nitro-2,3-phenylpropyllamino benzoic acid (50 [mu]M). These data suggest that the slow, outward rectifying anion channel, whose opening would be related to the membrane potential, and at least one step requiring a protein phosphorylation by a Ca2+-calmodulin-dependent protein kinase of the myosin light chain kinase type might be implicated in the induction of stomatal closing by vanadate or a light/dark transition.     

Nitric oxide attenuates H(2)O(2)-induced endothelial barrier dysfunction: mechanisms of protection

Nitric oxide (.NO) attenuates hydrogen peroxide (H(2)O(2))-mediated injury in porcine pulmonary artery endothelial cells (PAECs) and modulates intracellular levels of cGMP and cAMP. We hypothesized that.NO attenuates H(2)O(2)-induced PAEC monolayer barrier dysfunction through cyclic nucleotide-dependent signaling mechanisms. To examine this hypothesis, cultured PAEC monolayers were treated with H(2)O(2), and barrier function was measured as transmonolayer albumin clearance. H(2)O(2) caused significant PAEC barrier dysfunction that was attenuated by intracellular as well as extracellular.NO generation.NO increased PAEC cGMP and cAMP levels, but treatment with inhibitors of soluble guanylate cyclase or protein kinase G did not abrogate.NO-mediated barrier protection. In contrast, H(2)O(2) decreased protein kinase A activity, and inhibiting protein kinase A abrogated the protective effect of.NO. H(2)O(2)-induced barrier dysfunction was not associated with decreased levels of cGMP or cAMP. 3-Isobutyl-1-methylxanthine and the cGMP analog 8-bromo-cGMP had little effect on H(2)O(2)-mediated endothelial barrier dysfunction, whereas 8-bromo-cAMP plus 3-isobutyl-1-methylxanthine was protective. These results indicate that.NO modulates vascular endothelial barrier function through cAMP-dependent signaling mechanisms.