气体信号分子调控植物发育和响应逆境胁迫的生理与分子机制

doi:10.11924/j.issn.1000-6850.2013-1139

摘要/Abstract

摘要： NO、CO和H2S气体信号分子及其生物学作用已成为当前生命科学领域中激素和信号转导研究的热点。当前，人们正在深入探讨这3种气体信号分子在植物生命活动中的作用。总结了植物内源性气体信号分子的产生方式，参与调节种子萌发、根系发育、叶绿素合成、光合作用、气孔运动、物质代谢、衰老等植物生长发育的过程；以及其在植物应答盐、极端温度、渗透、干旱、重金属等逆境胁迫中的作用。同时，讨论了气体信号分子调控植物生长发育的特点，以及可能的交叉作用途径，并对该领域后续的研究工作进行了展望。

关键词: 总IgG水平, 总IgG水平

Abstract: The gasotransmitters, such as NO, CO and H2S and their biological function have become a research hotspot in terms of the hormone and signal transduction in life sciences. At present, the role of these three gasotransmitters in the life of plant has been discussed. This paper summarizes the production of endogenous gasotransmitters and their roles involved in the process of plant growth and development, such as seed germination, root development, chlorophyll biosynthesis, photosynthesis, stomatal movements, substance metabolism and senescence regulation. The function mechanisms of them in the plants to respond to various environmental stresses, for instance, salt-stress, extreme temperatures, osmotic stress, drought-stress, heavy metal stress and other abiotic stresses has been summarized in this paper. Meanwhile, it was discussed that the characteristics of them in the regulation of plant growth and development, possible cross-pathway and the prospect of subsequent research work in this field.

陈桢雨孟丹周思敏安敏敏罗玉明杨立明. 气体信号分子调控植物发育和响应逆境胁迫的生理与分子机制[J]. 中国农学通报, 2014, 30(6): 260-267.

参考文献

[1] Gupta K J, Fernie A R, Kaiser W M, et al. On the origins of nitric oxide[J]. Trends Plant Sci,2011(16):160-168.
[2] Baudouin E, Frendo P, Le Gleuher M, et al. A Medicago sativa haem oxygenase gene is preferentially expressed in root nodules[J]. J. Exp. Bot,2004(55):43-47.
[3] álvarez C, Calo L, Romero L C, et al. An O-Acetylserine(thiol) lyase homolog with L-Cysteine desulfhydrase activity regulates cysteine homeostasis in Arabidopsis[J].Plant Physiology,2010,152 (2):656-669.
[4] Wildt J, Kley D, Rockel A, et al. Emission of NO from several higher plant species[J]. Journal of Geophysical Research,1997,102 (D5):5919-5927.
[5] Ralf C, Helmut S, Wolfgang S. Emission of carbon monoxide from submerged rice fields into the atmosphere[J]. Atmospheric Environment (1967),1988,22(4):821-823.
[6] Wilson L G, Bressan R A, Filner P. Light-dependent emission of hydrogen sulfide from plants[J]. Plant Physiology,1978,61(2): 184-189.
[7] Beauchamp R O, Bus J S, Popp J A, et al. A critical review of the literature on hydrogen sulfide toxicity[J]. Crit. Rev. Toxicol,1984 (13):25-97.
[8] Vreman H J, Wong R J, Sanesi C A, et al. Simultaneous production of carbon monoxide and thiobarbituric acid reactive substances in rat tissue preparations by an iron-ascorbate system[J]. Can J Physiol Pharmacol,1998(76):1057-1065.
[9] García-Mata C, Lorenzo L. Gasotransmitters are emerging as new guard cell signaling molecules and regulators of leaf gas exchange [J]. Plant Science,2013(201-202):66-73.
[10] Stamler J S, Singel D J, Loscalzo J. Biochemistry of nitric oxide and its redox-activated forms[J]. Science,1992(258):1898-1902.
[11] Ryter S W, Alam J, Choi A M K. Heme oxygenase-1/carbon monoxide: from basic science to therapeutic applications[J]. Physiol. Rev,2006(86):583-650.
[12] Xuan W, Xu S, Yuan X, et al. Carbon monoxide: a novel and pivotal signal molecule in plants?[J]. Plant Signal. Behav,2008(3): 381-382.
[13] Shekhawat G S, Verma K. Haem oxygenase (HO): an overlooked enzyme of plant metabolism and defence[J]. J. Exp. Bot,2010(61): 2255-2270.
[14] Bai X G, Yang L M, Tian M H, et al. Nitric oxide enhances desiccation tolerance of recalcitrant antiaris toxicaria seeds via protein s-nitrosylation and carbonylation[J]. PLoS ONE,2011,6(6): e20714.
[15] Bai X G, Chen J H, Kong X X, et al. Carbon monoxide enhances the chilling tolerance of recalcitrant Baccaurea ramiflora seeds via nitric oxide-mediated glutathione homeostasis[J]. Free Radical Biology and Medicine,2012,53(4):710-720.
[16] Zhong G L, Ming G, Ping L. Hydrogen sulfide is a mediator in H2O2-induced seed germination in Jatropha Curcas[J].Acta Physiol Plant,2012(34):2207-2213.
[17] Sunita Y, Anisha D, Satish C B. Nitric oxide accumulation and actin distribution during auxin-induced adventitious root development in sunflower[J]. Scientia Horticulturae,2011,129(1):159-166.
[18] Xuan W, Zhu F Y, Xu S, et al. The heme oxygenase/carbon monoxide system is involved in the auxin-induced cucumber adventitious rooting process[J]. Plant Physiology,2008,148(2): 881-893.
[19] Xuan W, Xu S, Li M Y, et al. Nitric oxide is involved in hemin-induced cucumber adventitious rooting process[J]. Journal of Plant Physiol,2012(169):1032-1039.
[20] Zhang H, Tang J, Liu X P, et al. Hydrogen sulfide promotes root organogenesis in ipomoea batatas, salix matsudana and glycine max [J]. Journal of Integrative Plant Biology,2009,51(12):1086-1094.
[21] Ding F, Wang X F, Shi Q H, et al. Exogenous Nitric oxide alleviated the inhibition of photosynthesis and antioxidant enzyme activities in iron-deficient chinese cabbage (brassica chinensis L.) [J]. Agricultural Sciences in China,2008,7(2):168-179.
[22] Kong W W, Zhang L P, Guo K, et al. Carbon monoxide improves adaptation of Arabidopsis to iron deficiency[J]. Plant Biotechnology Journal,2010,8(1):88-99.
[23] Chen J, Wu F H, Wang W H, et al. Hydrogen sulphide enhances photosynthesis through promoting chloroplast biogenesis, photosynthetic enzyme expression, and thiol redox modification in Spinacia oleracea seedlings[J]. J. Exp. Bot,2011,62(13):4481-4493.
[24] Zhao X, Qiao X R, Yuan J, et al. Nitric oxide inhibits blue light-induced stomatal opening by regulating the K + influx in guard cells[J]. Plant Science,2012(184):29-35.
[25] She X P, Song X G. Carbon Monoxide-induced stomatal closure involves generation of hydrogen peroxide in vicia faba guard cells [J]. Journal of Integrative Plant Biology,2008,50(12):1539-1548.
[26] Liu J, Hou Z H, Liu G H, et al. Hydrogen sulfide may function downstream of nitric oxide in ethylene-induced stomatal closure in vicia faba L[J]. Journal of Integrative Agriculture,2012,11(10): 1644-1653.
[27] Andrea G, Susana P, Juan J. Guiamet,et al.Chloroplast functionality has a positive effect on nitric oxide level in soybean cotyledons[J]. Plant Physiology and Biochemistry,2013(66):26-33.
[28] Zhang L P, Shao H B, Long X H, et al.Gene regulation of iron-deficiency responses is associated with carbon monoxide and heme oxydase-1 in chlamydomonas reinhardtii[J]. PLoS ONE,2013, 8(1):e53835.
[29] Roksana H, Wills R B H, Penta P, et al. Effect of nitric oxide (NO) and associated control treatments on the metabolism of fresh-cut apple slices in relation to development of surface browning[J]. Postharvest Biology and Technology,2013(78):16-23.
[30] Ma W, Andries S, Robin K, et al. Leaf senescence signaling: The Ca2 +-conducting arabidopsis cyclic nucleotide gated Channel2 acts through nitric oxide to repress senescence programming[J]. Plant Physiology,2010,154(2):733-743.
[31] Huang J J, Han B, Xu S, et al. Heme oxygenase-1 is involved in the cytokinin-induced alleviation of senescence in detached wheat leaves during dark incubation[J]. Journal of Plant Physiology,2011, 168(8):768-775.
[32] Hu L Y, Hu S L, Wu J, et al. Hydrogen sulfide prolongs postharvest shelf life of strawberry and plays an antioxidative role in fruits[J]. Journal of Agricultural and Food Chemistry,2012,60(35):8684-8693.
[33] Zhang H, Hu S L, Zhang Z J, et al. Hydrogen sulfide acts as a regulator of flower senescence in plants[J]. Postharvest Biology and Technology,2011,60(3):251-257.
[34] Bai X G, Yang L M, Yang Y Q, et al. Deciphering the protective role of nitric oxide against salt stress at the physiological and proteomic levels in maize[J]. J. Proteome Res,2011,10(10): 4349-4364.
[35] Zhang C P, Li Y C, Yuan F G, et al. Effects of hematin and carbon monoxide on the salinity stress responses of Cassia obtusifolia L[J]. Plant and Soil,2012,359(1-2):85-105.
[36] Wang Y Q, Li L, Cui W T, et al. Hydrogen sulfide enhances alfalfa (Medicago sativa) tolerance against salinity during seed germination by nitric oxide pathway[J]. Plant and Soil,2012,351 (1-2):107-119.
[37] Yang W, Sun Y, Chen S, et al. The effect of exogenously applied nitric oxide on photosynthesis and antioxidant activity in heat stressed chrysanthemum[J]. Biologia Plantarum,2011,55(4): 737-740.
[38] Li Z G, Gong M, Xie H, et al. Hydrogen sulfide donor sodium hydrosulfide-induced heat tolerance in tobacco(Nicotiana tabacum L) suspension cultured cells and involvement of Ca2+ and calmodulin [J]. Plant Science,2012(185):185-189.
[39] Li Z G, Ding X J, Du P F. Hydrogen sulfide donor sodium hydrosulfide-improved heat tolerance in maize and involvement of proline[J]. Journal of Plant Physiology,2013,Available online 21.
[40] Ke X, Cheng Z, Ma W, et al. Nitric oxide enhances osmoregulation of tobacco (Nicotiana tobacam L.) cultured cells under phenylethanoid glycosides (PEG) 6000 stress by regulating proline metabolism[J]. African Journal of Biotechnology,2013,12(11): 1257-1266.
[41] Liu Y H, Xu S, Ling T F, et al. Heme oxygenase/carbon monoxide system participates in regulating wheat seed germination under osmotic stress involving the nitric oxide pathway[J]. Journal of Plant Physiology,2010,167(16):1371-1379.
[42] Zhang H, Ye Y K, Wang S H, et al. Hydrogen sulfide counteracts chlorophyll loss in sweetpotato seedling leaves and alleviates oxidative damage against osmotic stress[J]. Plant Growth Regul, 2009,58(3):243-250.
[43] Liao W B, Huang G B, Yu J H, et al. Nitric oxide and hydrogen peroxide alleviate drought stress in marigold explants and promote its adventitious root development[J]. Plant Physiology and Biochemistry,2012(58):6-15.
[44] Jin Z P, Shen J J, Qiao Z J, et al. Hydrogen sulfide improves drought resistance in Arabidopsis thaliana[J]. Biochemical and Biophysical Research Communications,2011,414(3):481-486.
[45] Jin Z P, Xue S W, Luo Y N, et al. Hydrogen sulfide interacting with abscisic acid in stomatal regulation responses to drought stress in Arabidopsis[J]. Plant Physiology and Biochemistry,2013(62):41-46.
[46] Zhang H, Jiao H, Jiang C X, et al. Hydrogen sulfide protects soybean seedlings against drought-induced oxidative stress[J]. Acta Physiol Plant,2010,32(5):849-857.
[47] Yang L, Tian D, Todd C D, et al. Comparative Proteome Analyses Reveal that Nitric Oxide Is an Important Signal Molecule in the Response of Rice to Aluminum Toxicity[J]. Journal of Proteome Research,2013,12(3):1316-1330.
[48] Zhou Y, Xu X Y, Chen L Q, et al. Nitric oxide exacerbates Al-induced inhibition of root elongation in rice bean by affecting cell wall and plasma membrane properties[J]. Phytochemistry,2012 (76):46-51.
[49] Wang L N, Yang L M, Yang F J, et al. Involvements of H2O2 and metallothionein in NO-mediated tomato tolerance to copper toxicity [J]. Journal of Plant Physiology,2010,167(15):1298-1306.
[50] Wei Y Y, Zheng Q, Liu Z P, et al. Regulation of tolerance of chlamydomonas reinhardtii to heavy metal toxicity by heme oxygenase-1 and carbon monoxide[J]. Plant Cell Physiol,2011,52 (9):1665-1675.
[51] Shen Q, Jiang M, Li H, et al. Expression of a Brassica napus heme oxygenase confers plant tolerance to mercury toxicity[J]. Plant, Cell & Environment,2011,34(5):752-763.
[52] Cui W T, Li L, Gao Z Z, et al. Haem oxygenase-1 is involved in salicylic acid-induced alleviation of oxidative stress due to cadmium stress in Medicago sativa[J]. J. Exp. Bot,2012,63(15): 5521-5534.
[53] Chen J, Wang W H, Wu F H, et al. Hydrogen sulfide alleviates aluminum toxicity in barley seedlings[J]. Plant and Soil,2013,362 (1-2):301-318.
[54] Wang B L, Shi L, Li Y X, et al. Boron toxicity is alleviated by hydrogen sulfide in cucumber (Cucumis sativus L.) seedlings[J]. Planta,2010,231(6):1301-1309.
[55] Zhang H, Hu L Y, Hu K D, et al. Hydrogen sulfide promotes wheat seed germination and alleviates oxidative damage against copper stress[J]. Journal of Integrative Plant Biology,2008,50(12): 1518-1529.
[56] Zhang H, Tan Z Q, Hu L Y, et al. Hydrogen sulfide alleviates aluminum toxicity in germinating wheat seedlings[J]. Journal of Integrative Plant Biology,2010,52(6):556-567.
[57] Zhang H, Hu L Y, Li P, et al. Hydrogen sulfide alleviated chromium toxicity in wheat[J]. Biologia Plantarum,2010,54(4):743-747.
[58] Wang R. Two's company, three's a crowd: Can H2S be the third endogenous gaseous transmitter?[J]. FASEB Journal,2002,16(13): 1792-1798.