高温胁迫下水稻叶片的蛋白响应及其基因型和生育期差异

doi:10.3724/SP.J.1006.2011.00820

摘要/Abstract

摘要： 高温已经成为水稻产量的主要限制因素，且其影响由于全球温室效应的加剧而呈扩大趋势。本研究在鉴定耐热水稻基因型的基础上，从生理学和蛋白质组学上进行耐性机理研究。结果表明，苗期或抽穗期高温处理导致结实率、SPAD值、株高、根长和生物量下降，丙二醛、过氧化氢、超氧阴离子含量增加和超氧化物歧化酶活性提高。同时，高温胁迫对热敏感品种明恢63的影响大于对耐热品种密阳46的影响。蛋白质组学分析表明，高温使光合作用相关蛋白、能量类蛋白、代谢类蛋白表达量下降，抗逆相关蛋白表达量上升。另外，蛋白试验结果佐证了密阳46的耐热性以及水稻抽穗期对高温的敏感性。本研究还首次发现抗逆相关蛋白2-cys过氧化物酶BAS1的表达量在高温下上升。

关键词: 水稻, 高温, 耐热性, 基因型, 蛋白质组学

Abstract: High temperature has become a major disastrous factor affecting rice productivity, and the temperature stress becomes more severe due to the global warming effect. The present study was carried out to identify the rice genotypes with high heat tolerance and understand the tolerant mechanisms of both physiology and proteomics. The results showed that seed setting rate, SPAD value, plant height, root length and biomass were dramatically reduced under high temperature, while contents of malondialdehyde, hydrogen peroxide and superoxide anions, and activity of superoxide dismutase were greatly increased, irrespectively of growth stage. Moreover, Minghui 63 (a heat-sensitive genotype) was much more affected by heat stress than Milyang 46 (a heat-tolerant genotype). Proteomic analysis showed that high temperature resulted in down-regulation of the proteins related to photosynthesis, energy and metabolism, while resistance-related proteins were up-regulated. The results also confirmed the heat tolerance of Milyang 46 and the heat sensitivity of the rice plants at heading stage. The up-regulation of anti-stress protein, 2-cys peroxiredoxin BAS1, under heat stress was first reported in this study.

Key words: Rice, High temperature, Thermo-tolerance, Genotype, Proteomics

周伟辉, 薛大伟, 张国平. 高温胁迫下水稻叶片的蛋白响应及其基因型和生育期差异[J]. 作物学报, 2011, 37(05): 820-831.

ZHOU Wei-Hui, XUE Da-Wei, ZHANG Guo-Beng. Protein Response of Rice Leaves to High Temperature Stress and Its Difference of Genotypes at Different Growth Stage[J]. Acta Agron Sin, 2011, 37(05): 820-831.

参考文献

[1]Wilkins M R, Williams K L, Appel R D, Hochstrasser D F. Proteome Research, New Frontiers in Functional Genomics. Berlin: Springer, 1997. pp 304-331
[2]Süle A, Vanrobaeys F, Hajós G, Van Beeumen J, Devreese B. Proteomic analysis of small heat shock protein isoforms in barley shoots. Phytochemistry, 2004, 65: 1853-1863
[3]Xu C P, Huang B R. Root proteomic responses to heat stress in two Agrostis grass species contrasting in heat tolerance. J Exp Bot, 2008, 59: 4183-4194
[4]Yan S P, Zhang Q Y, Tang Z C, Su W A, Sun W N. Comparative proteomic analysis provides new insights into chilling stress responses in rice. Mol Cell Proteomics, 2006, 5: 484-496
[5]Pinheiro C, Kehr J, Ricardo C P. Effects of water stress on lupin stem protein analysed by two-dimensional gel electrophoresis. Planta, 2005, 221: 716-728
[6]Wang S B, Chen F, Sommerfeld M, Hu Q. Proteomic analysis of molecular response to oxidative stress by the green alga Haematococcus pluvialis (Chlorophyceae). Planta, 2004, 220: 17-29
[7]Yan S, Tang Z, Su W, Sun W. Proteomic analysis of salt stress-responsive proteins in rice root. Proteomics, 2005, 5: 235-244
[8]Labra M, Gianazza E, Waitt R, Eberini I, Sozzi A, Grassi F, Agradi E. Zea mays L. protein changes in response to potassium dichromate treatments. Chemosphere, 2006, 62: 1234-1244
[9]Salekdeh G H, Siopongco J, Wade L J, Ghareyazie B, Bennett J. Proteomics analysis of rice leaves during drought stress and recovery. Proteomics, 2002, 2: 1131-1145
[10]Imin N, Kerim T, Weinman J J, Rolfe B G. Characterisation of rice anther proteins expressed at the young microspore stage. Proteomics, 2001, 1: 1149-1161
[11]Salekdeh G H, Siopongco J, Wade L J, Ghareyazieb B, Bennett J. A proteomics approach to analyzing drought- and salt-responsiveness in rice. Field Crops Res, 2002, 76: 199-219
[12]Agrawal G K, Rakwal R, Yonekura M, Kubo A, Saji H. Proteome analysis of differentially displayed proteins as a tool for investigating ozone stress in rice (Oryza sativa L.) seedlings. Proteomics, 2002, 2: 947-959
[13]Shen S, Jing Y, Kuang T. Proteomics approach to identify wound-response related proteins from rice leaf sheath. Proteomics, 2003, 3: 527-535
[14]Peng S, Huang J, Sheehy J E, Laza R C, Visperas R M, Zhong X H, Centeno G S, Khush G S, Cassman K G. Rice yields decline with higher night temperature from global warming. Proc Natl Acad Sci USA, 2004, 101: 9971-9975
[15]Grover A, Chandramouli A, Agarwal S, Katiyar-Agarwal S, Agarwal M, Sahi C. Transgenic rice for tolerance against abiotic stresses. In: Datta S K ed. Rice Improvement in the Genomic Era. USA: Hawarth Press, 2009. pp 237-267
[16]Lee D G, Ahsan N, Lee S, Kang K Y, Bahk J D, Lee I, Lee B. A proteomic approach in analyzing heat-responsive proteins in rice leaves. Proteomics, 2007, 7: 3369-3383
[17]Han F, Chen H, Li X J, Yang M F, Liu G S, Shen S H. A comparative proteomic analysis of rice seedlings under various high-temperature stresses. Biochim Biophys Acta, 2009, 1794: 1625-1634
[18]Satake T, Yoshida S. High temperature induced sterility in indica rices at flowering. Jpn J Crop Sci, 1978, 47: 6-17
[19]Jagadish S V K, Muthurajan R, Oane R, Wheeler T R, Heuer S, Bennett J, Craufurd P Q. Physiological and proteomic approaches to address heat tolerance during anthesis in rice (Oryza sativa L.). J Exp Bot, 2010, 61: 143-156
[20]Lin S K, Chang M C, Tsai Y C, Lur H S. Proteomic analysis of the expression of proteins related to rice quality during caryopsis development and the effect of high temperature on expression. Proteomics, 2005, 5: 2140-2156
[21]Yoshida S, Forna D A, Cock J H, Gomez K A. Laboratory Manual for Physiological Studies of Rice. Philippines: International Rice Research Institute, 1976. pp 62-63
[22]Xu C-C(许长成), Zhao S-J(赵世杰), Zou Q(邹琦). Interference factors of thiobarbituric acid determination in plant membrane lipid peroxidation. Plant Physiol Commun (植物生理学通讯), 1993, 29(5): 361-363 (in Chinese)
[23]Ruan H-H(阮海华), Shen W-B(沈文飚), Ye M-B(叶茂炳), Xu L-L(徐朗莱). Effects of nitric oxide on oxidative injury in wheat leaves under salt stress. Chin Sci Bull(科学通报), 2001, 46(23): 1993-1997 (in Chinese)
[24]Lin C C, Kao C H. Abscisic acid induced changes in cell wall peroxidase activity and hydrogen peroxide level in roots of rice seedlings. Plant Sci, 2001, 160: 323-329
[25]Li J Y, Jiang A L, Zhang W. Salt stress-induced programmed cell death in rice root tip cells. J Integr Plant Biol, 2007, 49: 481-486
[26]Wang J-Y(王经源), Chen S-Y(陈舒奕), Liang Y-Y(梁义元), Lin W-X(林文雄). Improvement of ISO-DALT electrophoresis system. J Fujian Agric & For Univ (福建农林大学学报), 2006, 35(2): 187-190 (in Chinese with English abstract)
[27]Yu C-L(余初浪), Yan S-P(严顺平), Sun W-N(孙卫宁), Yang L(杨玲). High-resolution two-dimensional electrophoresis for total proteins in rice roots, leaves and suspension cells. Chin J Rice Sci (中国水稻科学), 2006, 20(5):549-552 (in Chinese with English abstract)
[28]Yan J X, Wait R, Berkelman T, Harry R A, Westbrook J A, Wheeler C H, Dunn M J. A modified silver staining protocol for visualization of proteins compatible with matrix-assisted laser desorption/ionization and electrospray ionization-mass pectrometry. Electrophoresis, 2000, 21: 3666-3672
[29]Neuhoff V，Arnold N，Taube D，Ehrhardt W. Improved staining of proteins in polyacrylamide gels including isoelectric focusing gels with clear background at nanogram sensitivity using Coomassie Brilliant Blue G-250 and R-250. Electrophoresis, 1988, 9: 255-262
[30]Makino A, Mae T, Ohira K. Photosynthesis and ribulose-1,5-bisphosphate carboxylase/oxygenase in rice leaves from emergence through senescence. Planta, 1985, 166: 414-420
[31]Bose A, Ghosh B. Effect of heat stress on ribulose 1,5-bisphosphate carboxylase in rice. Phytochemistry, 1995, 38: 1115-1118
[32]Hankamer B，Barber J，Boekema F J．Structure and membrane organization of photosystem II in green plants. Annu Rev Plant Physiol Plant Mol Biol, 1997, 48: 64l-671
[33]James B. Crystal structure of the oxygen-evolving complex of photosystem II. Inorg Chem, 2008, 47: 1700-1710
[34]Ahsan N, Lee D G, Lee K W, Alam I, Lee S H, Bahk J D, Lee B H. Glyphosate-induced oxidative stress in rice leaves revealed by proteomic approach. Plant Physiol Biochem, 2008, 46: 1062-1070
[35]Ahsan N, Lee D G, Lee S H, Kang K Y, Bahk J D, Choi M S, Lee I J, Renaut J, Lee B H. A comparative proteomic analysis of tomato leaves in response to waterlogging stress. Physiol Plant, 2007, 131: 555-570
[36]Wang Z Y, Freire E, McCarty R E. Influence of nucleotide binding site occupancy on the thermal stability of the F1 portion of the chloroplast ATP synthase. J Biol Chem, 1993, 268: 20785-20790
[37]Ahsan N, Donnart T, Nouri M Z, Komatsu S. Tissue-speci?c defense and thermo-adaptive mechanisms of soybean seedlings under heat stress revealed by proteomic approach. J Proteome Res, 2010, 9: 4189-4204
[38]Girardini J E, Dissous C, Serra E. Schistosoma mansoni ferredoxin NADP(H) oxidoreductase and its role in detoxi?cation. Mol Biochem Parasitol, 2002, 124: 37-45
[39]Wang C, Wesener S R, Zhang H L, Cheng Y Q. An FAD-dependent pyridine nucleotide-disul?de oxidoreductase is involved in disul?de bond formation in FK228 snticancer depsipeptide. Chem Biol, 2009. 16: 585-593
[40]Majoul T, Bancel E, Triboï E, Hamidal J B, Branlard G. Proteomic analysis of the effect of heat stress on hexaploid wheat grain: Characterization of heat-responsive proteins from total endosperm. Proteomics, 2003, 3: 175-183
[41]Rainwater D T, Gossetp D R, Millhollon E P, Hanna H Y, Banks S W, Lucas M C. The relationship between yield and the antioxidant defense system in tomatoes grown under heat stress. Free Radical Res, 1996, 25: 421-435
[42]Ai Q(艾青), Mou T-M(牟同敏). Progresses in rice heat tolerance. Hubei Agric Sci (湖北农业科学), 2008, 47(1): 107-111 (in Chinese with English abstract)
[43]Farrell T C, Fox K M, Williams R L, Fukai S. Genotypic variation for cold tolerance during reproductive development in rice: screening with cold air and cold water. Field Crops Res, 2006, 98: 178-194
[44]Dietz K J, Horling F, Konig J, Baier M. The function of the chloroplast 2-cysteine peroxiredoxin in peroxide detoxification and its regulation. J Exp Bot, 2002, 53: 1321-1329
[45]Baier M, Dietz K J. Alkyl hydroperoxide reductases: The way out of the oxidative breakdown of lipids in chloroplasts. Trends Plant Sci, 1999, 4: 166-168
[46]Baier M. Dietz K J. Protective function of chloroplast 2-cysteine peroxiredoxin in photosynthesis: Evidence from transgenic Arabidopsis. Plant Physiol, 1999, 119: 1407-1414

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed