植物对非生物胁迫的响应机制研究
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摘要
从激素、渗透调节物质、活性氧清除系统和蛋白质4个方面综述了植物应对非生物胁迫的机制,并展望了植物应对非生物胁迫今后的研究方向,为提高植物的抗逆性研究提供了理论依据。
The response mechanism of plants to abiotic stresses was summarized from several aspects of hormone,osmotic regulation,reactive oxygen scavenging and protein,and the future research direction of response mechanism of plants to abiotic stresses was looked forward,so as to provide theoretical basis for improving the resistance of plants.
The response mechanism of plants to abiotic stresses was summarized from several aspects of hormone,osmotic regulation,reactive oxygen scavenging and protein,and the future research direction of response mechanism of plants to abiotic stresses was looked forward,so as to provide theoretical basis for improving the resistance of plants.
引文
[1]YANG X W,WANG X Y,JI L,et al.Overexpression of a Miscanthus lutarioriparius NAC gene Ml NAC5 confers enhanced drought and cold tolerance in Arabidopsis[J].Plant Cell Rep,2014,34(6):943-958.
[2]POPKO J,HANSCH R,MENDEL R R,et al.The role of abscisic acid and auxin in the response of poplar to abiotic stress[J].Plant Biol,2010,12(2):242-258.
[3]WILKINSON S,DAVIES W J.Drought,ozone,ABA and ethylene:New insights from cell to plant to community[J].Plant Cell Environ,2010,33(4):510-525.
[4]LEE S C,LUAN S.ABA signal transduction at the crossroad of biotic and abiotic stress responses[J].Plant Cell Environ,2012,35(1):53-60.
[5]LIM C W,LUAN S,LEE S C.A prominent role for RCAR3-mediated ABA signaling in response to Pseudomonas syringae pv.tomato DC3000 infection in Arabidopsis[J].Plant Cell Physiol,2014,55(10):1691-1703.
[6]CUTLER S R,RODRIGUEZ P L,FINKELSTEIN R R,et al.Abscisic acid:Emergence of a core signaling network[J].Annu Rev Plant Biol,2010,61:651-679.
[7]PARK S Y,FUNG P,NISHIMURA N,et al.Abscisic acid inhibits type 2C protein phosphatases via the PYR/PYL family of START proteins[J].Science,2009,324(5930):1068-1071.
[8]LIM C W,BAEK W,JUNG J,et al.Function of ABA in stomatal defense against biotic and drought stresses[J].Int J Mol Sci,2015,16(7):15251-15270.
[9]陶均,李玲.高等植物脱落酸生物合成的酶调控[J].植物学通报,2002,19(6):675-683.
[10]SANEOKA H,ISHIGURO S,MOGHAIEB J.Effect of salinity and abscisi cacid on accumulation of glycinebetaine and betaineal dehyde dehydrogenase m RNA in Sorghum leaves(Sorghum bicolor)[J].J Plant Physiol,2001,58(7):853-859.
[11]WAN L Y,ZHANG J F,ZHANG H W,et al.Transcriptional activation of Os DERF1 in Os ERF3 and Os AP2-39 negatively modulates ethylene synthesis and drought tolerance in rice[J].PLo S One,2011,6(9):1-14.
[12]WANG N N,SHIH M C,LI N.The GUS reporter-aided analysis of the promoter activities of Arabidopsis ACC synthase genes At ACS4,At ACS5,and At ACS7 induced by hormones and stresses[J].J Exp Bot,2005,56(413):909-920.
[13]CAO W H,LIU J,ZHOU Q Y,et al.Expression of tobacco ethylene receptor NTHK1 alters plant responses to salt stress[J].Plant Cell Environ,2006,29(7):1210-1219.
[14]ZHOU H L,CAO W H,CAO Y R,et al.Roles of ethylene receptor NTHK1domains in plant growth,stress response and protein phosphorylation[J].FEBS Lett,2006,580(5):1239-1250.
[15]SHABALA S.Ionic and osmotic components of salt stress specifically modulate net ion fluxes from bean leaf mesophyll[J].Plant Cell and Environment,2000,23(8):825-837.
[16]KISHOR P B K,SREENIVASULU N.Is proline accumulation per se correlated with stress tolerance or is proline homeostasis a more critical issue?[J].Plant Cell Environ,2014,37(2):300-311.
[17]SZABADOS L,SAVOURE A.Proline:A multifunctional amino acid[J].Trends Plant Sci,2009,15(2):89-97.
[18]NATARAJAN S K,ZHU W D,LIANG X W,et al.Proline dehydrogenase is essential for proline protection against hydrogen peroxide induced cell death[J].Free Radical Biol Med,2012,53(5):1181-1191.
[19]邓凤飞,杨双龙,龚明.细胞信号分子对非生物胁迫下植物脯氨酸代谢的调控[J].植物生理学报,2015,51(10):1573-1582.
[20]WU H H,ZOU Y N,RAHMAN M M,et al.Mycorrhizas alter sucrose and proline metabolism in trifoliate orange exposed to drought stress[J].Sci Rep,2017,7:42389.
[21]全先庆,张渝洁,单雷,等.脯氨酸在植物生长和非生物胁迫耐受中的作用[J].生物技术通讯,2007,18(1):159-162.
[22]黄亚成,秦云霞.植物中活性氧的研究进展[J].中国农学通报,2012,28(36):219-226.
[23]李国婧.超氧阴离子的产生及其在植物体内作用的研究[J].生物技术世界,2012(4):24-25.
[24]张梦如,杨玉梅,成蕴秀,等.植物活性氧的产生及其作用和危害[J].西北植物学报,2014,34(9):1916-1926.
[25]薛鑫,张芊,吴金霞.植物体内活性氧的研究及其在植物抗逆方面的应用[J].生物技术通报,2013(10):6-11.
[26]MIURA C,SUGAWARA K,NERIYA Y,et al.Functional characterization and gene expression profiling of superoxide dismutase from plant pathogenic phytoplasma[J].Gene,2012,510(2):107-112.
[27]NEILL S J,DESIKAN R,CLARKE A,et al.Hydrogen peroxide and nitric oxide as signalling molecules in plants[J].J Exp Bot,2002,53(372):1237
[28]田敏,饶龙兵,李纪元.植物细胞中的活性氧及其生理作用[J].植物生理学通讯,2005,41(2):235-241.
[29]ALSCHER R G,ERTURK N,HEATH L S.Role of superoxide dismutases(SODs)in controlling oxidative stress in plants[J].J Exp Bot,2002,53(372):1331-1341.
[30]MA C L,WANG P P,CAO Z Y,et al.Cloing and differential gene expression of two catalases in Suaeda salsa in response to salt stress[J].Acta Botanica Sinica,2003,45(1):93-97.
[31]夏更寿,王加真,李建龙.光盐交互胁迫下台湾沟叶结缕草叶绿体色素、抗氧化酶动态变化[J].安徽农业大学学报,2008,35(4):601-606.
[32]张强,李建龙,晏笳,等.温度胁迫对亚热带常用草坪草活性氧代谢相关酶的影响[J].草业科学,2004,21(10):83-86.
[33]李志刚,张玉霞,董丽杰.沙生牧草和盐生牧草抗氧化特性比较[J].中国草地学报,2007,29(5):115-118.
[34]CHIVASA S,HAMILTON J M,PRINGLE R S,et al.Proteomic analysis of differentially expressed proteins in fungal elicitor-treated Arabidopsis cell cultures[J].J Exp Bot,2006,57(7):1553-1562.
[35]ASANO T,KIMURA M,NISHIUCHI T.The defense response in Arabidopsis thaliana against Fusarium sporotrichioides[J].Proteome Sci,2012,10(1):1-10.
[36]WU Y Q,MIRZAEI M,PASCOVICI D,et al.Quantitative proteomic analysis of two different rice varieties reveals that drought tolerance is correlated with reduced abundance of photosynthetic machinery and increased abundance of Clp D1 protease[J].Journal of proteomics,2016,143:73-82.
[37]LEE D G,AHSAN N,LEE S H,et al.A proteomic approach in analyzing heat-responsive proteins in rice leaves[J].Proteomics,2007,7(18):3369-3383.
[38]HAJHEIDARI M,ABDOLLAHIAN-NOGHABI M,ASKARI H,et al.Proteome analysis of sugar beet leaves under drought stress[J].Proteomics,2005,5(4):950-960.
[39]CHITTETI B R,PENG Z H.Proteome and phosphoproteome differential expression under salinity stress in rice(Oryza sativa)roots[J].Journal of proteome research,2007,6(5):1718-1727.
[40]CHIVASA S,HAMILTON J M,PRINGLE R S,et al.Proteomic analysis of differentially expressed proteins in fungal elicitor-treated Arabidopsis cell cultures[J].J Exp Bot,2006,57(7):1553-1562.
[41]方献平,王淑珍,赵芸,等.植物应答生物逆境的蛋白质组学研究进展[J].分子植物育种,2014,12(3):584-602.
[42]FERNANDEZ-BAUTISTA N,FERNANDEZ-CALVINO L,MU N~OZ A,et al.HOP3 a new regulator of the ER stress response in Arabidopsis with possible implications in plant development and response to biotic and abiotic stresses[J].Plant Signal Behav,2017,12(5):1317421.
[43]YU X W,LIU Y M,WANG S,et al.A chickpea stress-responsive NAC transcription factor,Car NAC5,confers enhanced tolerance to drought stress in transgenic Arabidopsis[J].Plant Growth Reg,2016,79(2):187-197.
[44]YU X W,LIU Y M,WANG S,et al.Car NAC4,a NAC-type chickpea transcription factor conferring enhanced drought and salt stress tolerances in Arabidopsis[J].Plant Cell Rep,2016,35(3):613-627.
[45]LIU Y M,YU X W,LIU S S,et al.A chickpea NAC-type transcription factor,Car NAC6,confers enhanced dehydration tolerance in Arabidopsis[J].Plant Mol Biol Rep,2017,35(1):83-96.
[46]WANG K,ZHONG M,WU Y,et al.Overexpression of a chrysanthemum transcription factor gene Dg NAC1 improves the salinity tolerance in chrysanthemum[J].Plant Cell Rep,2017,36(4):1-11.
[47]WANG F B,TONG W J,ZHU H,et al.A novel Cys2/His2 zinc finger protein gene from sweetpotato,Ib ZFP1,is involved in salt and drought tolerance in transgenic Arabidopsis[J].Planta,2016,243(3):783-797.
[48]LI Y Y,CHEN Q Z,NAN H Y,et al.Overexpression of Gm FDL19 enhances tolerance to drought and salt stresses in soybean[J].PLo S One,2017,12(6):179554.
[2]POPKO J,HANSCH R,MENDEL R R,et al.The role of abscisic acid and auxin in the response of poplar to abiotic stress[J].Plant Biol,2010,12(2):242-258.
[3]WILKINSON S,DAVIES W J.Drought,ozone,ABA and ethylene:New insights from cell to plant to community[J].Plant Cell Environ,2010,33(4):510-525.
[4]LEE S C,LUAN S.ABA signal transduction at the crossroad of biotic and abiotic stress responses[J].Plant Cell Environ,2012,35(1):53-60.
[5]LIM C W,LUAN S,LEE S C.A prominent role for RCAR3-mediated ABA signaling in response to Pseudomonas syringae pv.tomato DC3000 infection in Arabidopsis[J].Plant Cell Physiol,2014,55(10):1691-1703.
[6]CUTLER S R,RODRIGUEZ P L,FINKELSTEIN R R,et al.Abscisic acid:Emergence of a core signaling network[J].Annu Rev Plant Biol,2010,61:651-679.
[7]PARK S Y,FUNG P,NISHIMURA N,et al.Abscisic acid inhibits type 2C protein phosphatases via the PYR/PYL family of START proteins[J].Science,2009,324(5930):1068-1071.
[8]LIM C W,BAEK W,JUNG J,et al.Function of ABA in stomatal defense against biotic and drought stresses[J].Int J Mol Sci,2015,16(7):15251-15270.
[9]陶均,李玲.高等植物脱落酸生物合成的酶调控[J].植物学通报,2002,19(6):675-683.
[10]SANEOKA H,ISHIGURO S,MOGHAIEB J.Effect of salinity and abscisi cacid on accumulation of glycinebetaine and betaineal dehyde dehydrogenase m RNA in Sorghum leaves(Sorghum bicolor)[J].J Plant Physiol,2001,58(7):853-859.
[11]WAN L Y,ZHANG J F,ZHANG H W,et al.Transcriptional activation of Os DERF1 in Os ERF3 and Os AP2-39 negatively modulates ethylene synthesis and drought tolerance in rice[J].PLo S One,2011,6(9):1-14.
[12]WANG N N,SHIH M C,LI N.The GUS reporter-aided analysis of the promoter activities of Arabidopsis ACC synthase genes At ACS4,At ACS5,and At ACS7 induced by hormones and stresses[J].J Exp Bot,2005,56(413):909-920.
[13]CAO W H,LIU J,ZHOU Q Y,et al.Expression of tobacco ethylene receptor NTHK1 alters plant responses to salt stress[J].Plant Cell Environ,2006,29(7):1210-1219.
[14]ZHOU H L,CAO W H,CAO Y R,et al.Roles of ethylene receptor NTHK1domains in plant growth,stress response and protein phosphorylation[J].FEBS Lett,2006,580(5):1239-1250.
[15]SHABALA S.Ionic and osmotic components of salt stress specifically modulate net ion fluxes from bean leaf mesophyll[J].Plant Cell and Environment,2000,23(8):825-837.
[16]KISHOR P B K,SREENIVASULU N.Is proline accumulation per se correlated with stress tolerance or is proline homeostasis a more critical issue?[J].Plant Cell Environ,2014,37(2):300-311.
[17]SZABADOS L,SAVOURE A.Proline:A multifunctional amino acid[J].Trends Plant Sci,2009,15(2):89-97.
[18]NATARAJAN S K,ZHU W D,LIANG X W,et al.Proline dehydrogenase is essential for proline protection against hydrogen peroxide induced cell death[J].Free Radical Biol Med,2012,53(5):1181-1191.
[19]邓凤飞,杨双龙,龚明.细胞信号分子对非生物胁迫下植物脯氨酸代谢的调控[J].植物生理学报,2015,51(10):1573-1582.
[20]WU H H,ZOU Y N,RAHMAN M M,et al.Mycorrhizas alter sucrose and proline metabolism in trifoliate orange exposed to drought stress[J].Sci Rep,2017,7:42389.
[21]全先庆,张渝洁,单雷,等.脯氨酸在植物生长和非生物胁迫耐受中的作用[J].生物技术通讯,2007,18(1):159-162.
[22]黄亚成,秦云霞.植物中活性氧的研究进展[J].中国农学通报,2012,28(36):219-226.
[23]李国婧.超氧阴离子的产生及其在植物体内作用的研究[J].生物技术世界,2012(4):24-25.
[24]张梦如,杨玉梅,成蕴秀,等.植物活性氧的产生及其作用和危害[J].西北植物学报,2014,34(9):1916-1926.
[25]薛鑫,张芊,吴金霞.植物体内活性氧的研究及其在植物抗逆方面的应用[J].生物技术通报,2013(10):6-11.
[26]MIURA C,SUGAWARA K,NERIYA Y,et al.Functional characterization and gene expression profiling of superoxide dismutase from plant pathogenic phytoplasma[J].Gene,2012,510(2):107-112.
[27]NEILL S J,DESIKAN R,CLARKE A,et al.Hydrogen peroxide and nitric oxide as signalling molecules in plants[J].J Exp Bot,2002,53(372):1237
[28]田敏,饶龙兵,李纪元.植物细胞中的活性氧及其生理作用[J].植物生理学通讯,2005,41(2):235-241.
[29]ALSCHER R G,ERTURK N,HEATH L S.Role of superoxide dismutases(SODs)in controlling oxidative stress in plants[J].J Exp Bot,2002,53(372):1331-1341.
[30]MA C L,WANG P P,CAO Z Y,et al.Cloing and differential gene expression of two catalases in Suaeda salsa in response to salt stress[J].Acta Botanica Sinica,2003,45(1):93-97.
[31]夏更寿,王加真,李建龙.光盐交互胁迫下台湾沟叶结缕草叶绿体色素、抗氧化酶动态变化[J].安徽农业大学学报,2008,35(4):601-606.
[32]张强,李建龙,晏笳,等.温度胁迫对亚热带常用草坪草活性氧代谢相关酶的影响[J].草业科学,2004,21(10):83-86.
[33]李志刚,张玉霞,董丽杰.沙生牧草和盐生牧草抗氧化特性比较[J].中国草地学报,2007,29(5):115-118.
[34]CHIVASA S,HAMILTON J M,PRINGLE R S,et al.Proteomic analysis of differentially expressed proteins in fungal elicitor-treated Arabidopsis cell cultures[J].J Exp Bot,2006,57(7):1553-1562.
[35]ASANO T,KIMURA M,NISHIUCHI T.The defense response in Arabidopsis thaliana against Fusarium sporotrichioides[J].Proteome Sci,2012,10(1):1-10.
[36]WU Y Q,MIRZAEI M,PASCOVICI D,et al.Quantitative proteomic analysis of two different rice varieties reveals that drought tolerance is correlated with reduced abundance of photosynthetic machinery and increased abundance of Clp D1 protease[J].Journal of proteomics,2016,143:73-82.
[37]LEE D G,AHSAN N,LEE S H,et al.A proteomic approach in analyzing heat-responsive proteins in rice leaves[J].Proteomics,2007,7(18):3369-3383.
[38]HAJHEIDARI M,ABDOLLAHIAN-NOGHABI M,ASKARI H,et al.Proteome analysis of sugar beet leaves under drought stress[J].Proteomics,2005,5(4):950-960.
[39]CHITTETI B R,PENG Z H.Proteome and phosphoproteome differential expression under salinity stress in rice(Oryza sativa)roots[J].Journal of proteome research,2007,6(5):1718-1727.
[40]CHIVASA S,HAMILTON J M,PRINGLE R S,et al.Proteomic analysis of differentially expressed proteins in fungal elicitor-treated Arabidopsis cell cultures[J].J Exp Bot,2006,57(7):1553-1562.
[41]方献平,王淑珍,赵芸,等.植物应答生物逆境的蛋白质组学研究进展[J].分子植物育种,2014,12(3):584-602.
[42]FERNANDEZ-BAUTISTA N,FERNANDEZ-CALVINO L,MU N~OZ A,et al.HOP3 a new regulator of the ER stress response in Arabidopsis with possible implications in plant development and response to biotic and abiotic stresses[J].Plant Signal Behav,2017,12(5):1317421.
[43]YU X W,LIU Y M,WANG S,et al.A chickpea stress-responsive NAC transcription factor,Car NAC5,confers enhanced tolerance to drought stress in transgenic Arabidopsis[J].Plant Growth Reg,2016,79(2):187-197.
[44]YU X W,LIU Y M,WANG S,et al.Car NAC4,a NAC-type chickpea transcription factor conferring enhanced drought and salt stress tolerances in Arabidopsis[J].Plant Cell Rep,2016,35(3):613-627.
[45]LIU Y M,YU X W,LIU S S,et al.A chickpea NAC-type transcription factor,Car NAC6,confers enhanced dehydration tolerance in Arabidopsis[J].Plant Mol Biol Rep,2017,35(1):83-96.
[46]WANG K,ZHONG M,WU Y,et al.Overexpression of a chrysanthemum transcription factor gene Dg NAC1 improves the salinity tolerance in chrysanthemum[J].Plant Cell Rep,2017,36(4):1-11.
[47]WANG F B,TONG W J,ZHU H,et al.A novel Cys2/His2 zinc finger protein gene from sweetpotato,Ib ZFP1,is involved in salt and drought tolerance in transgenic Arabidopsis[J].Planta,2016,243(3):783-797.
[48]LI Y Y,CHEN Q Z,NAN H Y,et al.Overexpression of Gm FDL19 enhances tolerance to drought and salt stresses in soybean[J].PLo S One,2017,12(6):179554.