燕麦对盐碱胁迫的响应机制及缓解措施研究进展
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摘要
土壤盐碱化的日益严峻,直接制约着农牧业的健康发展,培育耐盐碱作物或饲草是解决这一矛盾的有效途径。燕麦是重要的粮饲兼用作物,具有一定的耐盐碱性。研究燕麦的耐盐碱机制,对开发和有效利用盐碱地有重要的现实意义。文章从种子萌发、光合特性、抗氧化酶系统、渗透调节物质、离子吸收分布和分子机制等角度综述了燕麦对盐碱胁迫的响应机制,并概述了目前缓解燕麦盐碱胁迫的可行措施,展望了未来的研究趋势。
引文
[1]Chinnusamy V,Jagendorf A,Zhu J K.Understanding and improving salt tolerance in plants[J].Crop Science,2005,45(2):437-448.
[2]Niu D L,Wang Q J.Research progress on saline-alkali field control[J].Chinese Journal of Soil Science,2002,33(6):449-455.
[3]李扬汉.禾本科作物的形态与解剖[M].上海:科学技术出版社,1979:461-476.
[4]林叶春,曾昭海,任长忠,等.局部根区灌溉对裸燕麦光合特征曲线及叶绿素荧光特性的影响[J].作物学报,2012,38(06):1062-1070.
[5]蔡天革,王鹏,唐凤德.盐胁迫对燕麦种子萌发和幼苗抗氧化酶的影响[J].辽宁大学学报(自然科学版),2016,43(01):74-78
[6]蔺军.黑麦和燕麦种子萌发期耐盐性、抗旱性比较[J].中国草食动物科学,2016,36(04):31-34
[7]Zhao G Q,Ma B L,Ren C Z.Salinity Effects on Yield and Yield Components of Contrasting Naked Oat Genotypes[J].Journal of plant nutrition,2009,32(10-12):1619-1632.
[8]Han L P,Liu H T,Yu S H,et al.Potential application of oat for phytoremediation of salt ions in coastal saline-alkali soil[J].Ecological Engineering,2013,61:274-281.
[9]武俊英,刘景辉,翟利剑,等.不同品种燕麦种子萌发和幼苗生长的耐盐性[J].生态学杂志,2009,28(10):1960-1965.
[10]罗志娜,赵桂琴,刘欢.24个燕麦品种种子萌发耐盐性综合评价[J].草原与草坪,2012,32(01):34-38,41.
[11]芦翔,汪强,赵惠萍,等.盐胁迫对不同燕麦品种种子萌发和出苗影响的研究[J].草业科学,2009,26(07):77-81.
[12]李焕春,栗艳芳,王博,等.不同燕麦品种对NaCl胁迫的响应及其耐盐阈值[J].北方农业学报,2018,46(03):13-17.
[13]刘建新,王金成,刘秀丽,等.燕麦种子萌发和幼苗抗逆生理特性对不同浓度碱性盐处理的响应[J].干旱区地理,2016,39(05):1018-1024.
[14]孙仁国,赵桂琴,胡凯军,等.盐胁迫对燕麦地上干物质积累及灌浆期光合特性的影响[J].中国草地学报,2010,32(05):15-20.
[15]刘建新,王金成,王瑞娟,等.盐、碱胁迫对燕麦幼苗光合作用的影响[J].干旱地区农业研究,2015,33(06):155-160.
[16]白健慧.燕麦对盐碱胁迫的生理响应机制研究[D].内蒙古农业大学,2016.101.
[17]高彩婷,刘景辉,张玉芹,等.短期盐胁迫下燕麦幼苗的生理响应[J].草地学报,2017,25(02):337-343.
[18]刘凤歧,刘杰淋,朱瑞芬,等.4种燕麦对NaCl胁迫的生理响应及耐盐性评价[J].草业学报,2015,24(01):183-189.
[19]刘建新,王金成,王瑞娟,等.旱盐交叉胁迫对燕麦幼苗生长和渗透调节物质的影响[J].水土保持学报,2012,26(03):244-248.
[20]刘建新,王金成,贾海燕.燕麦幼苗对盐胁迫和碱胁迫的生理响应差异[J].水土保持学报,2015,29(05):331-336.
[21]Oraby H F,El-Tohamy M F,Kamel A M,et al.Changes in the concentration of avenanthramides in response to salinity stress in CBF 3 transgenic oat[J].Journal of Cereal Science,2017,76:263-270.
[22]Wakeel A,Farooq M,Qadir M,et al.Potassium substitution by sodium in plants[J].Critical Reviews in Plant Sciences,2011,30(4):401-413.
[23]Wang B,Song F B.Physiological responses and adaptive capacity of oats to saline-alkali stress.Ecology and Environment[J].Ecology & Environment,2006,15(3):625-629.
[24]Mu Y G,Liu J X,Mu CS,et al.Effects of NaCl Stress on the Growth and Physiological Changes in Oat (Avena sativa) Seedlings[J].Notulae Botanicae Horti Agrobotanici Cluj-Napoca,2015,43(2):468-472.
[25]李倩,刘景辉,武俊英,等.盐胁迫对燕麦质膜透性及Na+、K+吸收的影响[J].华北农学报,2009,24(06):88-92.
[26]萨如拉,刘景辉,刘伟,等.碱性盐胁迫对燕麦矿质离子吸收与分配的影响[J].麦类作物学报,2014,34(02):261-266.
[27]刘建新,王金成,王瑞娟,等.混合盐碱胁迫对燕麦幼苗矿质离子吸收和光合特性的影响[J].干旱地区农业研究,2017,35(01):178-184,239.
[28]王波,张金才,宋凤斌,等.燕麦对盐碱胁迫的生理响应[J].水土保持学报,2007(03):86-89.
[29]Han L P,Wang W H,Eneji,A E,et al.Phytoremediating coastal saline soils with oats:accumulation and distribution of sodium,potassium,and chloride ions in plant organs[J].Journal of cleaner production,2015,90:73-81.
[30]Zhang J L,Shi H.Physiological and molecular mechanisms of plant salt tolerance[J].photosynthesis research,2013,115(1):1-22.
[31]王霞霞,李龑,唐杰伟,等.盐胁迫对燕麦种子萌发期蛋白质组影响的研究[J].华北农学报,2015,30(03):48-53.
[32]Bai J,Qin Y,Liu J,et al.Proteomic response of oat leaves to long-term salinity stress[J].Environmental Science & Pollution Research,2016,24(4):1-13.
[33]Bai J,Liu J,Jiao W,et al.Proteomic analysis of salt-responsive proteins in oat roots (Avena sativa L.)[J].Journal of the Science of Food and Agriculture,2016,96(11):3867-3875.
[34]Wu B,Hu Y N,Huo P J,et al.Transcriptome analysis of hexaploid hulless oat in response to salinity stress[J].Plos One,2017,12(2):1-16.
[35]高彩婷,刘景辉,徐寿军,等.燕麦盐胁迫响应基因的差异表达与生理响应的关系[J].西北植物学报,2015,35(07):1385-1393.
[36]张胜博,刘景辉,李立军,等.燕麦AsNAC1耐盐基因的克隆及初步验证[J].北方农业学报,2016,44(05):1-7.
[37]陈新,张宗文,吴斌.裸燕麦萌发期耐盐性综合评价与耐盐种质筛选[J].中国农业科学,2014,47(10):2038-2046.
[38]Oraby H,Ahmad R.Physiological and biochemical changes of CBF 3 transgenic oat in response to salinity stress[J].Plant Science,2012,185-186(4):331-339.
[39]李海萍,周青平,颜红波,等.硝普钠对燕麦幼苗苗期盐胁迫缓解作用的生理机制[J].草业科学,2014,31(09):1739-1745.
[40]刘建新,王金成,王瑞娟,等.碱胁迫下NO和Ca2+对裸燕麦(Avenanuda)幼苗生理特性的影响[J].中国沙漠,2016,36(03):695-701.
[41]刘建新,王金成,王瑞娟,等.外源过氧化氢提高燕麦耐盐性的生理机制[J].草业学报,2016,25(02):216-222.
[42]刘建新,王金成,王瑞娟,等.燕麦幼苗对盐胁迫的响应及过氧化氢对响应的调节[J].生态学杂志,2015,34(09):2506-2511.
[43]麦靖雯,黎瑞君,张巨明.植物根际促生菌研究综述[J].现代农业科技,2018(12):179-180,183.
[44]邱天,张丽辉.植物促生菌促进盐生环境植物生长的研究进展[J].北方园艺,2017(24):198-204.
[45]辛树权,高扬,赵骥民.含ACC脱氨酶PGPR菌株的分离及其对燕麦耐盐性的影响[J].长春师范学院学报,2011,30(08):58-62.
[46]吉云秀,黄晓东.不同盐分条件下植物促生菌对燕麦和黑麦草幼苗的促生效应[J].中国土壤与肥料,2008(02):65-68.
[47]刘佳莉,方芳,史煦涵,等.2株盐碱地燕麦根际促生菌的筛选及其促生作用研究[J].草业学报,2013,22(02):132-139.
[48]Xun F F,Xie B M,Liu S S,et al.Effect of plant growth-promoting bacteria (PGPR) and arbuscular mycorrhizal fungi (AMF) inoculation on oats in saline-alkali soil contaminated by petroleum to enhance phytoremediation[J].Environmental Science and Pollution Research,2015,22(1):598-608.
[49]卢培娜,刘景辉,赵宝平,等.菌肥对盐碱地土壤特性及燕麦根系分泌物的影响[J].作物杂志,2017(05):85-92.
[50]王佺珍,刘倩,高娅妮,等.植物对盐碱胁迫的响应机制研究进展[J].生态学报,2017,37(16):5565-5577.
[51]Sapre S,Gontia-Mishra I,Tiwari S.Klebsiella sp.confers enhanced tolerance to salinity and plant growth promotion in oat seedlings (Avena sativa)[J].Microbiological Research,2018,206:25-32.
[52]Chang P,Gerhardt K E,Huang,et al.Plant Growth-Promoting Bacteria Facilitate the Growth of Barley and Oats in Salt-Impacted Soil:Implications for Phytoremediation of Saline Soils[J].International journal of phytoremediation,2014,16(11):1133-1147.
[2]Niu D L,Wang Q J.Research progress on saline-alkali field control[J].Chinese Journal of Soil Science,2002,33(6):449-455.
[3]李扬汉.禾本科作物的形态与解剖[M].上海:科学技术出版社,1979:461-476.
[4]林叶春,曾昭海,任长忠,等.局部根区灌溉对裸燕麦光合特征曲线及叶绿素荧光特性的影响[J].作物学报,2012,38(06):1062-1070.
[5]蔡天革,王鹏,唐凤德.盐胁迫对燕麦种子萌发和幼苗抗氧化酶的影响[J].辽宁大学学报(自然科学版),2016,43(01):74-78
[6]蔺军.黑麦和燕麦种子萌发期耐盐性、抗旱性比较[J].中国草食动物科学,2016,36(04):31-34
[7]Zhao G Q,Ma B L,Ren C Z.Salinity Effects on Yield and Yield Components of Contrasting Naked Oat Genotypes[J].Journal of plant nutrition,2009,32(10-12):1619-1632.
[8]Han L P,Liu H T,Yu S H,et al.Potential application of oat for phytoremediation of salt ions in coastal saline-alkali soil[J].Ecological Engineering,2013,61:274-281.
[9]武俊英,刘景辉,翟利剑,等.不同品种燕麦种子萌发和幼苗生长的耐盐性[J].生态学杂志,2009,28(10):1960-1965.
[10]罗志娜,赵桂琴,刘欢.24个燕麦品种种子萌发耐盐性综合评价[J].草原与草坪,2012,32(01):34-38,41.
[11]芦翔,汪强,赵惠萍,等.盐胁迫对不同燕麦品种种子萌发和出苗影响的研究[J].草业科学,2009,26(07):77-81.
[12]李焕春,栗艳芳,王博,等.不同燕麦品种对NaCl胁迫的响应及其耐盐阈值[J].北方农业学报,2018,46(03):13-17.
[13]刘建新,王金成,刘秀丽,等.燕麦种子萌发和幼苗抗逆生理特性对不同浓度碱性盐处理的响应[J].干旱区地理,2016,39(05):1018-1024.
[14]孙仁国,赵桂琴,胡凯军,等.盐胁迫对燕麦地上干物质积累及灌浆期光合特性的影响[J].中国草地学报,2010,32(05):15-20.
[15]刘建新,王金成,王瑞娟,等.盐、碱胁迫对燕麦幼苗光合作用的影响[J].干旱地区农业研究,2015,33(06):155-160.
[16]白健慧.燕麦对盐碱胁迫的生理响应机制研究[D].内蒙古农业大学,2016.101.
[17]高彩婷,刘景辉,张玉芹,等.短期盐胁迫下燕麦幼苗的生理响应[J].草地学报,2017,25(02):337-343.
[18]刘凤歧,刘杰淋,朱瑞芬,等.4种燕麦对NaCl胁迫的生理响应及耐盐性评价[J].草业学报,2015,24(01):183-189.
[19]刘建新,王金成,王瑞娟,等.旱盐交叉胁迫对燕麦幼苗生长和渗透调节物质的影响[J].水土保持学报,2012,26(03):244-248.
[20]刘建新,王金成,贾海燕.燕麦幼苗对盐胁迫和碱胁迫的生理响应差异[J].水土保持学报,2015,29(05):331-336.
[21]Oraby H F,El-Tohamy M F,Kamel A M,et al.Changes in the concentration of avenanthramides in response to salinity stress in CBF 3 transgenic oat[J].Journal of Cereal Science,2017,76:263-270.
[22]Wakeel A,Farooq M,Qadir M,et al.Potassium substitution by sodium in plants[J].Critical Reviews in Plant Sciences,2011,30(4):401-413.
[23]Wang B,Song F B.Physiological responses and adaptive capacity of oats to saline-alkali stress.Ecology and Environment[J].Ecology & Environment,2006,15(3):625-629.
[24]Mu Y G,Liu J X,Mu CS,et al.Effects of NaCl Stress on the Growth and Physiological Changes in Oat (Avena sativa) Seedlings[J].Notulae Botanicae Horti Agrobotanici Cluj-Napoca,2015,43(2):468-472.
[25]李倩,刘景辉,武俊英,等.盐胁迫对燕麦质膜透性及Na+、K+吸收的影响[J].华北农学报,2009,24(06):88-92.
[26]萨如拉,刘景辉,刘伟,等.碱性盐胁迫对燕麦矿质离子吸收与分配的影响[J].麦类作物学报,2014,34(02):261-266.
[27]刘建新,王金成,王瑞娟,等.混合盐碱胁迫对燕麦幼苗矿质离子吸收和光合特性的影响[J].干旱地区农业研究,2017,35(01):178-184,239.
[28]王波,张金才,宋凤斌,等.燕麦对盐碱胁迫的生理响应[J].水土保持学报,2007(03):86-89.
[29]Han L P,Wang W H,Eneji,A E,et al.Phytoremediating coastal saline soils with oats:accumulation and distribution of sodium,potassium,and chloride ions in plant organs[J].Journal of cleaner production,2015,90:73-81.
[30]Zhang J L,Shi H.Physiological and molecular mechanisms of plant salt tolerance[J].photosynthesis research,2013,115(1):1-22.
[31]王霞霞,李龑,唐杰伟,等.盐胁迫对燕麦种子萌发期蛋白质组影响的研究[J].华北农学报,2015,30(03):48-53.
[32]Bai J,Qin Y,Liu J,et al.Proteomic response of oat leaves to long-term salinity stress[J].Environmental Science & Pollution Research,2016,24(4):1-13.
[33]Bai J,Liu J,Jiao W,et al.Proteomic analysis of salt-responsive proteins in oat roots (Avena sativa L.)[J].Journal of the Science of Food and Agriculture,2016,96(11):3867-3875.
[34]Wu B,Hu Y N,Huo P J,et al.Transcriptome analysis of hexaploid hulless oat in response to salinity stress[J].Plos One,2017,12(2):1-16.
[35]高彩婷,刘景辉,徐寿军,等.燕麦盐胁迫响应基因的差异表达与生理响应的关系[J].西北植物学报,2015,35(07):1385-1393.
[36]张胜博,刘景辉,李立军,等.燕麦AsNAC1耐盐基因的克隆及初步验证[J].北方农业学报,2016,44(05):1-7.
[37]陈新,张宗文,吴斌.裸燕麦萌发期耐盐性综合评价与耐盐种质筛选[J].中国农业科学,2014,47(10):2038-2046.
[38]Oraby H,Ahmad R.Physiological and biochemical changes of CBF 3 transgenic oat in response to salinity stress[J].Plant Science,2012,185-186(4):331-339.
[39]李海萍,周青平,颜红波,等.硝普钠对燕麦幼苗苗期盐胁迫缓解作用的生理机制[J].草业科学,2014,31(09):1739-1745.
[40]刘建新,王金成,王瑞娟,等.碱胁迫下NO和Ca2+对裸燕麦(Avenanuda)幼苗生理特性的影响[J].中国沙漠,2016,36(03):695-701.
[41]刘建新,王金成,王瑞娟,等.外源过氧化氢提高燕麦耐盐性的生理机制[J].草业学报,2016,25(02):216-222.
[42]刘建新,王金成,王瑞娟,等.燕麦幼苗对盐胁迫的响应及过氧化氢对响应的调节[J].生态学杂志,2015,34(09):2506-2511.
[43]麦靖雯,黎瑞君,张巨明.植物根际促生菌研究综述[J].现代农业科技,2018(12):179-180,183.
[44]邱天,张丽辉.植物促生菌促进盐生环境植物生长的研究进展[J].北方园艺,2017(24):198-204.
[45]辛树权,高扬,赵骥民.含ACC脱氨酶PGPR菌株的分离及其对燕麦耐盐性的影响[J].长春师范学院学报,2011,30(08):58-62.
[46]吉云秀,黄晓东.不同盐分条件下植物促生菌对燕麦和黑麦草幼苗的促生效应[J].中国土壤与肥料,2008(02):65-68.
[47]刘佳莉,方芳,史煦涵,等.2株盐碱地燕麦根际促生菌的筛选及其促生作用研究[J].草业学报,2013,22(02):132-139.
[48]Xun F F,Xie B M,Liu S S,et al.Effect of plant growth-promoting bacteria (PGPR) and arbuscular mycorrhizal fungi (AMF) inoculation on oats in saline-alkali soil contaminated by petroleum to enhance phytoremediation[J].Environmental Science and Pollution Research,2015,22(1):598-608.
[49]卢培娜,刘景辉,赵宝平,等.菌肥对盐碱地土壤特性及燕麦根系分泌物的影响[J].作物杂志,2017(05):85-92.
[50]王佺珍,刘倩,高娅妮,等.植物对盐碱胁迫的响应机制研究进展[J].生态学报,2017,37(16):5565-5577.
[51]Sapre S,Gontia-Mishra I,Tiwari S.Klebsiella sp.confers enhanced tolerance to salinity and plant growth promotion in oat seedlings (Avena sativa)[J].Microbiological Research,2018,206:25-32.
[52]Chang P,Gerhardt K E,Huang,et al.Plant Growth-Promoting Bacteria Facilitate the Growth of Barley and Oats in Salt-Impacted Soil:Implications for Phytoremediation of Saline Soils[J].International journal of phytoremediation,2014,16(11):1133-1147.