中国农业科学 ›› 2017, Vol. 50 ›› Issue (14): 2670-2682.doi: 10.3864/j.issn.0578-1752.2017.14.004
李佳佳1,郑双雨1,孙根楼1,张文明1,王晓波1,邱丽娟2
收稿日期:
2016-12-26
出版日期:
2017-07-16
发布日期:
2017-07-16
通讯作者:
王晓波,E-mail:wxbphd@163.com。邱丽娟,E-mail:qiulijuan@caas.cn
作者简介:
李佳佳,E-mail:lijia6862@163.com
基金资助:
LI JiaJia1, ZHENG ShuangYu1, SUN GenLou1, ZHANG WenMing1, WANG XiaoBo1, QIU LiJuan2
Received:
2016-12-26
Online:
2017-07-16
Published:
2017-07-16
摘要: 大豆是重要的经济作物,是植物油脂和蛋白质的重要来源。近年来,因全球气候变化引起的高温胁迫频发,危及到大豆生长的各个时期,成为制约大豆产量和品质的重要因素之一。为了揭示大豆耐高温性的遗传机理,建立综合高效大豆耐高温评价体系,促进大豆耐高温特性的遗传改良,现对大豆响应高温胁迫的生理生化基础和分子调控机制进行综述。相较于适温条件,高温胁迫可使大豆植株发生叶片增厚、气孔导度下降、细胞膜透性增加、细胞微观组织结构受损以及渗透调节物质(脯氨酸、可溶性糖和可溶性蛋白)含量变化和抗氧化防御系统关键酶活性丧失等生理异常反应,导致植株光合、蒸腾和呼吸作用及物质含量等一系列生理生化过程紊乱。高温胁迫还造成大豆花粉形态异常,绒毡层细胞结构松散、空泡化和自溶化,花粉活力及其萌发率明显下降,花粉败育率增高,致使大豆结荚率和结实率显著降低,进而影响大豆籽粒的正常发育、蛋白的积累和产量形成等,最终导致减产;高温胁迫对大豆籽粒外观品质性状也能造成一定损伤,进而对其经济价值带来不利影响。高温胁迫从转录、翻译和代谢水平影响大豆正常的生理代谢调控。目前,已通过高通量测序等方法鉴定出多个与大豆高温胁迫响应相关的转录因子、蛋白及代谢产物,但与水稻、拟南芥的研究相比仍存在较大差距;初步建立了以花粉活力和多项生理指标为基础的大豆耐高温鉴定方法,但在生产上尚缺乏系统高效耐高温评价体系,耐高温大豆育种工作进展缓慢。国内在大豆耐高温预防措施、耐高温综合评鉴体系建立、优异耐高温大豆种质资源筛选及耐高温关键功能基因挖掘等方面仍然存在挑战。为应对极端生态环境给大豆生产造成的不利影响,未来应通过建立综合高效大豆耐高温评价技术体系,提高大豆优异种质资源鉴定水平,重点解析大豆耐高温的分子遗传机理、挖掘耐高温关键基因,结合常规育种和分子育种技术培育综合性状优异的耐高温大豆新品种,以实现大豆品种耐高温性与高产、优质的统一。
李佳佳,郑双雨,孙根楼,张文明,王晓波,邱丽娟. 大豆响应高温胁迫的生理和分子遗传机理研究现状与展望[J]. 中国农业科学, 2017, 50(14): 2670-2682.
LI JiaJia, ZHENG ShuangYu, SUN GenLou, ZHANG WenMing, WANG XiaoBo, QIU LiJuan. Advances and Perspectives in Research of Physiological and Molecular Mechanism of Soybean Response to High Temperature Stress[J]. Scientia Agricultura Sinica, 2017, 50(14): 2670-2682.
[1] PATEL D, FRANKLIN K A. Temperature-regulation of plant architecture. Plant Signaling Behavior, 2009, 4(7): 577-579.
[2] NAHAR K, HASANUZZAMAN M, FUJITA M. 12-Heat stress responses and thermotolerance in soybean. Abiotic & Biotic Stresses in Soybean Production 20161: 261-284. ,
[3] PENG S B, HUANG J L, 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. Proceedings of the National Academy of Sciences, USA, 2004, 101(27): 9971-9975.
[4] DJANAGUIRAMAN M, PRASAD P V V, BOYLE D L, SCHAPAUGH W T. High-temperature stress and soybean leaves: leaf anatomy and photosynthesis. Crop Science, 2011, 51(5): 2125-2131.
[5] 徐如强, 孙其信, 张树榛. 小麦光合作用与耐热性的关系初探. 中国种业, 1997, 46(1): 28-29.
XU R Q, SUN Q X, ZHANG S Z. Preliminary study on the relationship between photosynthesis and heat tolerance in wheat. China Seed Industry, 1997, 46(1): 28-29. (in Chinese)
[6] 马德华, 庞金安, 霍振荣, 李淑菊. 黄瓜对不同温度逆境的抗性研究. 中国农业科学, 1999, 32(5): 28-35.
MA D H, PANG J A, HUO Z R, LI S J. Study on the resistance of cucumber to temperature stress. Scientia Agricultura Sinica, 1999, 32(5): 28-35. (in Chinese)
[7] 吴韩英, 寿森炎, 朱祝军. 高温胁迫对甜椒光合作用和叶绿素荧光的影响. 园艺学报, 2001, 28(6): 517-521.
WU H Y, SHOU S Y, ZHU Z J. Effects of high temperature stress on photosynthesis and chlorophyll fluorescence in sweet pepper (Capsicum fructescens L.). Acta Horticulturae Sinica, 2001, 28(6): 517-521. (in Chinese)
[8] 潘宝贵, 王述彬, 刘金兵, 曹碚生, 袁希汉. 高温胁迫对不同辣椒品种苗期光合作用的影响. 江苏农业学报, 2006, 22(2): 137-140.
PAN B G, WANG S B, LIU J B, CAO B S, YUAN X H. Effect of heat stress on photosynthesis of pepper cultivars at seedling stage. Jiangsu Journal of Agricultura Science, 2006, 22(2): 137-140. (in Chinese)
[9] PRASAD P V V, BOOTE K J, ALLEN L H, THOMAS J M G. Effects of elevated temperature and carbon dioxide on seed-set and yield of kidney bean (Phaseolus vulgaris L.). Global Change Biology, 2002, 8(8): 710-721.
[10] PRASAD P V V, BOOTE K J, ALLEN L H, SHEEHY J E, THOMAS J M G. Species, ecotype and cultivar differences in spikelet fertility and harvest index of rice in response to high temperature stress. Field Crops Research, 2006, 95(2-3): 398-411.
[11] PRASAD P V V, PISIPATI S R, MUTAVA R N, TUINSTRA M R. Sensitivity of grain sorghum to high temperature stress during reproductive development. Crop Science, 2008, 48(48): 1911-1917.
[12] DJANAGUIRAMAN M, PRASAD P V V. Ethylene production under high temperature stress causes premature leaf senescence in soybean. Functional Plant Biology, 2010, 37(11): 1071-1084.
[13] DJANAGUIRAMAN M, PRASAD P V V, AL-KHATIB K. Ethylene perception inhibitor 1-MCP decreases oxidative damage of leaves through enhanced antioxidant defense mechanisms in soybean plants grown under high temperature stress. Environmental and Experimental Botany, 2011, 71(2): 215-223.
[14] DJANAGUIRAMAN M, PRASAD P V V, BOYLE D L, SCHAPAUGH W T. Soybean pollen anatomy, viability and pod set under high temperature stress. Journal of Agronomy and Crop Science, 2012, 199(3): 171-177.
[15] DJANAGUIRAMAN M, PRASAD P V V, SCHAPAUGH W T. High day- or nighttime temperature alters leaf assimilation, reproductive success, and phosphatidic acid of pollen grain in soybean [Glycine max (L.) Merr.]. Crop Science, 2013, 53(4): 1594-1604.
[16] 李合生. 现代植物生理学(第2版). 北京: 高等教育出版社. 2007: 348-352.
Li H S. Modern Plant Physiology (2th Edition). Beijing: Higher Education Press. 2007: 348-352. (in Chinese)
[17] PUTEH A B, THUZAR M, MONDAL M M A, ABDULLAH N A P, RIDZWAN A M. Soybean [Glycine max (L.) Merr.] seed yield response to high temperature stress during reproductive growth stages. Australian Journal of Crop Science, 2013, 7(10): 1472-1479.
[18] SALEM M A, KAKANI V G, KOTI S, REDDY K R. Pollen-based screening of soybean genotypes for high temperatures. Crop Science, 2007, 47(1): 219-231.
[19] THUZAR M, PUTEH A B, ABDULLAH N A P, LASSIM M B M, JUSOFF K. The effects of temperature stress on the quality and yield of soya bean [Glycine max (L.) Merr.]. Journal of Agricultural Science, 2010, 2(1): 172-179.
[20] LIU X, JIN J, Wang G H, Herbert S J. Soybean yield physiology and development of high-yielding practices in northeast China. Field Crops Research, 2008, 105(3): 157-171.
[21] REDDY K R, KAKANI V G. Screening Capsicum species of different origins for high temperature tolerance by in vitro pollen germination and pollen tube length. Scientia Horticulturae, 2007, 112(2): 130-135.
[22] 舒英杰, 王爽, 陶源, 宋丽茹, 黄丽燕, 周玉丽, 麻浩. 生理成熟期高温高湿胁迫对春大豆种子活力、主要营养成分及种皮结构的影响. 应用生态学报, 2014, 25(5): 1380-1386.
SHU Y J, WANG S, TAO Y, SONG L R, HUAGN L Y, ZHOU Y L, MA H. Effects of high temperature and humidity stress at the physiological maturity stage on seed vigor, main nutrients and coat structure of spring soybean. Chinese Journal of Applied Ecology, 2014, 25(5): 1380-1386. (in Chinese)
[23] 韩永华, 郑易之, 李甜, 高扬. 高温/渗透双重胁迫对大豆某些生理反应具累加效应的初报. 大豆科学, 2001, 20(1): 41-44.
HAN Y H, ZHENG Y Z, LI T, GAO Y. Effect of high temperature or/and osmotic stress on physiological characteristics in seedling of two soybean cultivars. Soybean Science, 2001, 20(1): 41-44. (in Chinese)
[24] 卢琼琼, 宋新山, 严登华. 高温胁迫对大豆幼苗生理特性的影响. 河南师范大学学报(自然科学版) 2012, 40(1): 112-115.
LU Q Q, SONG X S, YAN D H. Effects of high temperature stress on physiological characteristics in soybean seedings. Journal of Henan Normal University (Natural Science Edition), 2012, 40 (1): 112-115. (in Chinese)
[25] NAKANO S, TACARINDUA C R P, NAKASHIMA K, HOMMA K, SHIRAIWA T. Evaluation of the effects of increasing temperature on the transpiration rate and canopy conductance of soybean by using the sap flow method. Journal of Agricultural Meteorology, 2015, 71(2): 98-105.
[26] ZHENG S H, NAKAMOTO H, YOSHIKAWA K, FURUYA T, FUKUYAMA M. Influences of high night temperature on flowering and pod setting in soybean. Plant Production Science, 2002, 5(3): 215-218.
[27] 魏崃, 吴广锡, 唐晓飞, 王伟威, 王兴宇, 刘丽君. 过表达GmHSFA1大豆在干旱条件下对高温的响应. 大豆科学, 2016(2): 257-261.
WEI L, WU G X, TANG X F, WANG W W, WANG X Y, LIU L J. Soybean responses to high temperatures under drought stress in the presence of an over-expressed GmHSFA1 gene. Soybean Science, 2016(2): 257-261. (in Chinese)
[28] DORNBOS D L Jr, MULLEN R E. Influence of stress during soybean seed fill on seed weight, germination, and seedling growth rate. Journal of Plant Science,1991, 71(2): 373-383.
[29] GIBSON L R, MULLEN R E. Influence of day and night temperature on soybean seed yields. Crop Science, 1996, 36(1): 98-104.
[30] LOBELL D B, ASNER G P. Climate and management contributions to recent trends in U.S. agricultural yields. Science, 2003, 299(5609): 1032.
[31] KUCHARIK C J, SERBIN S P. Impacts of recent climate change on Wisconsin corn and soybean yield trends. Environmental Research Letters, 2008, 3(3): 10.
[32] 陈晓军, 叶春江, 吕慧颖, 徐民新, 李葳, 张利明, 王超, 罗淑萍, 朱保葛. GmHSFA1基因克隆及其过量表达提高转基因大豆的耐热性. 遗传, 2006, 28(11): 1411-1420.
CHEN X J, YE C J, LV H Y, XU M X, LI W, ZHANG L M, WANG C, LUO S P, ZHU B G. Cloning of GmHSFA1 gene and its over-expression leading to enhancement of heat tolerance in transgenic soybean. Hereditas, 2006, 28(11): 1411-1420. (in Chinese)
[33] LI P S, YU T F, HE G H, CHEN M, ZHOU Y B, CHAI S C, XU Z S, MA Y Z. Genome-wide analysis of the Hsf family in soybean and functional identification of GmHsf-34 involvement in drought and heat stresses. BMC Genomics, 2014, 15(1): 1009.
[34] ZHAGN L, ZHAO H K, DONG Q L, ZHANG Y Y, WANG Y M, LI H Y, XING G J, LI Q Y, DONG Y S. Genome-wide analysis and expression profiling under heat and drought treatments of HSP70 gene family in soybean (Glycine max L.). Frontiers Plant Science, 2015, 6: 773.
[35] 聂腾坤, 赵琳, 李文滨, 丁福全, 李敏敏, 杨雪, 张可欣, 孙晶哲, 杜海龙. 大豆GmGBP1基因对转基因烟草幼苗耐热性的影响. 农业生物技术学报, 2016, 24(3): 313-322.
NIE T K, ZHAO L, LI W B, DING F Q, LI M M, YANG X, ZHANG K X, SUN J Z, DU H L. Effect of soybean (Glycine max) GmGBP1 gene on transgenic tobacco (Nicotiana tabacum) seedlings resistance to heat stress. Journal of Agricultural Biotechnology, 2016, 24(3): 313-322. (in Chinese)
[36] VALDÉS-LÓPEZ O, BATEK J, GOMEZ-HERNANDEZ N, NGUYEN C T, ISIDRA-ARELLANO M C, ZHANG N, JOSHI T, XU D, HIXSON K K, WEITZ K K, ALDRICH J T, PAŠA-TOLI C´ L L, STACEY G. Soybean roots grown under heat stress show global changes in their transcriptional and proteomic profiles. Frontiers Plant Science, 2016, 7(532): 517.
[37] DAS D, ELDAKAK M, PAUDEL B, KIM D W, HEMMATI H, BASU C, ROHILA J S. Leaf proteome analysis reveals prospective drought and heat stress response mechanisms in soybean. Biomed Research International, 2016, 2016(8): 1-23.
[38] XU G L, SINGH S, BARNABY J, BUYER J, REDDY V, SICHER R. Effects of growth temperature and carbon dioxide enrichment on soybean seed components at different stages of development. Plant Physiology and Biochemistry, 2016, 108: 313-322.
[39] CHEBROLU K K, FRITSCHI F B, YE S Q, KRISHNAN H B, SMITH J R, GILLMAN J D. Impact of heat stress during seed development on soybean seed metabolome. Metabolomics, 2016, 12(2): 1-14.
[40] 夏莹莹, 叶航, 马锦林, 江泽鹏, 何小燕. 4个油茶品种的半致死温度与耐热性研究. 中国农学通报, 2012, 28(4): 58-61.
XIA Y Y, YE H, MA J L, JIANG Z P, HE X Y. The study on semi-lethal high temperature and heat tolerance of four camellia oleifera abel clones. Chinese Agricultural Science Bulletin, 2012, 28(4): 58-61. (in Chinese)
[41] 张燕利, 高捍东, 吴锦华. 4种景天科植物耐热性测定. 西南林学院学报, 2010, 30(6): 52-54.
ZHANG Y L, GAO H D, WU J H. Study on the heat-tolerance of four species in family crassulaceae. Journal of Southwest Forestry University, 2010, 30(6): 52-54. (in Chinese)
[42] 龚萍, 王健. 利用电导率法测定六种芳香植物的耐热性. 湖北农业科学, 2011, 50(10): 2038-2040.
GONG P, WANG J. Measurement of thermal resistance of six aromatic plants with electrical conductivity method. Hubei Agricultural Sciences, 2011, 50(10): 2038-2040. (in Chinese)
[43] 刘德良, 赖万年. 夏季梅花品种耐热性生理生化指标研究. 北方园艺, 2012, 02: 57-61.
LIU D L, LAI W N. Research on physio-biochemistry indexes of heat resistant of prunus mume in summer. Northern Horticulture, 2012, 02: 57-61. (in Chinese)
[44] OGWENO J O, SONG X S, HU W H, SHI K, ZHOU Y H, YU J Q. Detached leaves of tomato differ in their photosynthetic physiological response to moderate high and low temperature stress. Scientia Horticulturae, 2009, 123(1): 17-22.
[45] 沈证言, 朱海山. 高温对菜豆生育影响及菜豆不同基因型的耐热性差异. 中国农业科学, 1993, 26(3): 50-55.
SHEN Z Y, ZHU H S. The effects of high temperature on growth and development and the differences of heat tolerance in common bean genotypes. Scientia Agricultura Sinica, 1993, 26(3): 50-55. (in Chinese)
[46] 欧祖兰, 曹福亮. 植物耐热性研究进展. 林业科技开发, 2008, 22(1): 1-5.
OU Z L, CAO F L. Research advance on heat stress tolerance in plant. China Forestry Science and Technology, 2008, 22(1): 1-5. (in Chinese)
[47] 耶兴元, 何晖, 张燕, 朱献辉. 脯氨酸对高温胁迫下猕猴桃苗抗热性相关生理指标的影响. 山东农业科学, 2010(5): 44-47.
YE X Y, HE H, ZHANG Y, ZHU X H. Effects of proline on physiological indexes related to heat resistance of kiwifruit seedlings under high temperature stress. Shandong Agricultural Sciences, 2010(5): 44-47. (in Chinese)
[48] 潘林娜. 不同温度下猕猴桃果实的呼吸作用和乙烯产生. 福建省农科院学报, 1995, 10(1): 54-57.
PAN L N. Respiration and ethylene production of kiwifruit at different remperature levels. Journal of Fujian Academy of Agricultural Sciences, 1995, 10(1): 54-57. (in Chinese)
[49] 李少昆, 张旺峰, 马富裕, 王克如, 李蒙春. 北疆高产棉田棉叶呼吸作用及其与光合作用关系的研究. 棉花学报, 1998, 10(5): 249-254.
LI S K, ZHANG W F, MA F Y, WANG K R, LI M C. Respiration of cotton leaves and its relate to phyotosynthesis in north xinjiang. Acta Gossypii Sinica, 1998, 10(5): 249-254. (in Chinese)
[50] 巩东辉, 乔辰. 温度对螺旋藻呼吸作用的影响. 内蒙古科技大学学报, 2010, 29(1): 73-75.
GONG D H, QIAO C. Effects of temperature on the respiratory of spirulina. Journal of inner Mongolia University of Science and Technology, 2010, 29(1): 73-75. (in Chinese)
[51] 潘瑞炽, 董愚得. 植物生理学. 北京: 高等教育出版社, 1995.
PAN R Z, DONG Y D. Plant physiology. Beijing: Higher Education Press, 1995. (in Chinese)
[52] 李合生. 植物生理生化实验原理与技术. 北京: 高等教育出版社, 2000.
LI H S. Principles and techniques of plant physiological and biochemical experiments. Beijing: Higher Education Press, 2000. (in Chinese)
[53] 杨华庚, 颜速亮, 陈慧娟, 杨重法, 杨福孙, 刘子凡. 高温胁迫下外源茉莉酸甲酯、钙和水杨酸对蝴蝶兰幼苗耐热性的影响. 中国农学通报, 2011, 27(28): 150-157.
YANG H G, YAN S L, CHEN H J, YANG C F, YANG F S, LIU Z F. Effect of exogenous methyl jasmonate, calcium and salicylic acid on the heat tolerance in phalaenopsis seedlings under high temperature stress. Chinese Agricultural Science Bulletin, 2011, 27(28): 150-157. (in Chinese)
[54] 陈少裕. 膜脂过氧化与植物逆境胁迫. 植物学通报, 1989, 6(4): 211-217.
CHEN S Y. Membrane-lipid peroxidation and plant stress. Chinese Bulletin of Botany, 1989, 6(4): 211-217. (in Chinese)
[55] KOTI S, REDDY K R, REDDY V R, KAKANI V G, ZHAO D L. Interactive effects of carbon dioxide, temperature, and ultraviolet-B radiation on soybean (Glycine max L.) flower and pollen morphology, pollen production, germination, and tube lengths. Journal of Experimental Botany, 2005, 56(412): 725-736.
[56] PORCH T G, JAHN M. Effect of high temperature stress on microsporogenesis in heat- sensitive and heat- tolerant of Phaseolus vulgaris. Plant Cell and Environment, 2001, 24(7): 723-731.
[57] SRINIVASAN A, JOHANSEN C, SAXENA N P. Cold tolerance during early reproductive growth of chickpea (Cicer arietinum L); characterization of stress and genetic variation in pod set. Field Crop Research, 1998, 57(2): 181-193.
[58] DAVIES S L, TURNER N C, KHM S, LEPORT L, PLUMMER J A. Seed growth of desi and kabuli chickpea (Cicer arietinum L.) in a short-season mediterranean-type environment. Australian Journal of Experimental Agriculture, 1999, 39(2): 181-188.
[59] HALL A E. Breeding for adaptation to drought and heat in cowpea.European Journal of Agronomy, 2004, 21(4): 447-454.
[60] THOMS J M G, BOOTE K J, ALLEN L H Jr, GALLO-MEAGHER Jr M, DAVIS J M. Elevated temperature and carbon dioxide effects on soybean seed composition and transcript abundance. Crop Science, 2003, 43(4): 1548-1557.
[61] REN C, BILYEU K D, BEUSELINCK P R. Composition, vigor, and proteome fo mature soybean seeds developed under high temperature. Crop Science, 2009, 49(3): 1010-1022.
[62] 夏天舒, 卞景阳, 谭贺, 许显滨, 林阳生, 潘博. 垦丰11大豆品种高温胁迫响应研究. 黑龙江农业科学, 2010, 2010(12): 23-24.
XIA T S, BIAN J Y, TAN H, XU X B, LIN Y S, PAN B. Response of high temperature stress on kenfeng 11. Heilongjiang Agricultural Sciences, 2010, 2010(12): 23-24. (in Chinese)
[63] XU G L, SINGH S K, REDDY V R, BARNABY J Y, SICHER R C, LI T. Soybean grown under elevated CO2 benefits more under low temperature than high temperature stress: varying response of photosynthetic limitations, leaf metabolites, growth, and seed yield. Journal of Plant Physiology, 2016, 205: 20-32.
[64] GIBSON L R, MULLEN R E. Soybean seed quality reductions by high day and night temperature. Crop Science, 1996, 36(5): 1615-1619.
[65] 金之庆, 葛道阔, 陈华, 郑喜莲. 全球气候变化影响我国大豆生产的利弊分析. 大豆科学, 1994, 13(4): 302 -311.
JIN Z Q, GE D K, CHEN H, ZHENG X L. Positive and negative effects of global climate change on soybean production in China. Soybean Science, 1994, 13(4): 302-311. (in Chinese)
[66] 周瑞莲, 王仲礼, 侯月利, Mark W E. 温度对大豆种子发育过程中蛋白质、脂肪和淀粉积累过程的影响. 生态学报, 2008, 28(10): 4635-4644.
ZHOU R L, WANG Z L, HOU Y L, MARK W E. The effect of growth temperature on the accumulation pattern of protein, oil and starch of soybean seed in seed filling. Acta Ecologica Sinica, 2008, 28(10): 4635-4644. (in Chinese)
[67] WOLF R B, CAVINS J F, KLEIMAN R, BLACK L T. Effect of temperature on soybean seed constituents: oil, protein moisture, fatty acids, amino acids, and sugars. Journal of Oil & Fat Industries, 1982, 59(5): 230-232.
[68] DLJR D, MULLEN R E. Soybean seed protein and oil contents and fatty acid composition adjustments by drought and temperature. Journal of the American Oil Chemists’ Society, 1992, 69(3): 228-231.
[69] PIPOLO A E, SINCLAIR T R, CAMARA C M S. Effects of temperature on oil and protein concentration in soybean seeds cultured in vitro. Annals of Applied Biology, 2004, 144(1): 71-76.
[70] 宋晓昆, 胡燕金, 闫龙, 冯燕, 荆慧贤, 赵青松, 杨春燕. 持续高温对大豆品种萌发及幼苗生长的影响. 河北农业科学, 2009, 13(4): 1-3.
SONG X K, HU Y J, YAN L, FENG Y, JING H X, ZHAO Q S, YANG C Y. Effects of continuous high temperature on germination and seedling growth of soybean. Journal of Hebei Agricultural Sciences, 2009, 13(4): 1-3. (in Chinese)
[71] 赵志刚, 江玲, 肖应辉, 张文伟, 翟虎渠, 万建民. 水稻孕穗期耐热性QTLs分析. 作物学报, 2006, 32(5): 640-644.
ZHAO Z G, JIANG L, XIAO Y H, ZHANG W W, ZHAI H Q, WAN J M. Identification of QTLs for heat tolerance at the booting stage in rice (Oryza sativa L.). Acta Agronomica Sinica, 2006, 32(5): 640-644. (in Chinese)
[72] 张涛, 杨莉, 蒋开锋, 黄敏, 孙群, 陈温福, 郑家奎. 水稻抽穗扬花期耐热性的QTL分析. 分子植物育种, 2008, 6(5): 867-873.
ZHANG T , YANG L, JIANG K F, HUANG M, SUN Q, CHEN W F, ZHENG J K. QTL mapping for heat tolerance of the tassel period of rice. Molecular Plant Breeding, 2008, 6(5): 867-873. (in Chinese)
[73] SAKUMA Y, MARUYAMA K, QIN F, OSAKABE Y, SHINOZAKI K, YAMAGUCHI-SHINOZAKI K. Dual function of an Arabidopsis transcription factor DREB2A in water-stress-responsive and heat-stress-responsive gene expression. Proceedings of the National Academy of Sciences, USA, 2006, 103(49): 18822.
[74] SCHRAMM F, LARKINDALE J, KIEHLMANN E, GANGULI A, ENGLICH G, VIERLING E, VON KOSKULLl-DÖRING P. A cascade of transcription factor DREB2A and heat stress transcription factor HsfA3 regulates the heat stress response of Arabidopsis. The Plant Journal, 2008, 53(2): 264-274.
[75] YOKOTANI N, ICHIKAWA T, KONDOU Y, MATSUI M, HIROCHIKA H, IWABUCHI M, ODA K. Expression of rice heat stress transcription factor OsHsfA2e enhances tolerance to environmental stresses in transgenic Arabidopsis. Planta, 2008, 227(5): 957-967.
[76] LI S J, ZHOU X, CHEN L G, HUANG W D, YU D Q. Functional characterization of Arabidopsis thaliana WRKY39 in heat stress. Molecules and Cells, 2010, 29(5): 475-483.
[77] SATO H, TODAKA D, KUDO M, MIZOI J, KIDOKORO S, ZHAO Y, SHINOZAKI K, YAMAGUCHI- SHINOZAKI K. The Arabidopsis transcriptional regulator DPB3-1 enhances heat stress tolerance without growth retardation in rice. Plant Biotechnology Journal, 2016, 14(8): 1756-1767.
[78] CHEN C, BEGCY K, LIU K, FOLSOM J J, WANG Z, ZHANG C, WALIA H. Heat stress yields a unique MADS box transcription factor in determining seed size and thermal sensitivity. Plant Physiology, 2016, 171(1): 606-622.
[79] LARKINDALE J, HALL J D, KNIGHT M R, VIERLING E. Heat stress phenotypes of Arabidopsis mutants implicate multiple signaling pathways in the acquisition of thermotolerance. Plant Physiology, 2005, 138(2): 882-897.
[80] TIMABUD T, YIN X J, PONGDONTRI P, KOMATSU S. Gel-free/label-free proteomic analysis of developing rice grains under heat stress. Journal of Proteomics, 2016, 133:1-19.
[81] 江海东. 高温对大豆花期生长及生理特性的影响. 第26届全国大豆科研生产会会议报告,南京, 2016.
JIANG H D. Effects of high temperature on growth and physiological characteristics during flowering stage in soybean. Report on the 26th National Soybean Research and Production Conference, Nanjing, 2016. (in Chinese)
[82] 王利军, 黄卫东, 于风义. 高温胁迫对14C-水杨酸在葡萄苗中运转分配的影响. 植物生理学报, 2001, 27(2): 129-134.
WANG L J, HUANG W D, YU F Y. Effects of elevated temperature on transportaqtion and distribution of 14C-salicylic acid in grape seedlings. Acta Phytophysiologica Sinica, 2001, 27(2): 129-134. (in Chinese)
[83] 汤日圣, 张大栋, 童红玉. 高温胁迫对稻苗某些生理指标的影响及ABA和6-BA对其的调节. 江苏农业学报, 2005, 21(3): 145-149.
TANG R S, ZHAGN D D, TONG H Y. Effects of high temperature on some physiological indexes in rice seedling leaves and regulations by ABA and 6-BA. Jiangsu Journal of Agricultural Sciences, 2005, 21(3): 145-149. (in Chinese)
[84] 毛胜利, 杜永臣, 王孝宣, 朱德蔚, 高建昌, 戴善书. 高温胁迫下番茄体内ABA水平的变化及其对花粉萌发的影响. 园艺学报, 2005, 32(2): 234-238.
MAO S L, DU Y C, WANG X X, ZHU D W, GAO J C, DAI S S. Changes of endogenous abscisic acid and the effect of exogenous ABA on pollen germination under heat stress tomato. Acta Horticulturae Sinica, 2005, 32(2): 234-238. (in Chinese)
[85] NAHAR K, HASANUZZAMAN M, ALAM Md M, FUJITA M. Exogenous glutathione confers high temperature stress tolerance in mung bean (Vigna radiata L.) by modulating antioxidant defense and methylglyoxal detoxification system. Environmental and Experimental Botany, 2015, 112(112): 44-54.
[86] 顾和平, 袁星星, 陈新, 陈华涛, 崔晓艳, 张红梅. 大豆耐热机制的自然积累. 大豆科技, 2013(1): 5-11.
GU H P, YUAN X X, CHEN X, CHEN H T, CUI X Y, ZHANG H M. Natural acclimatization of heat-tolerance mechanism in soybean. Soybean Science and Technology, 2013(1): 5-11. (in Chinese)
[87] SRIKANTHBABU V, GANESHKUMAR, KRISHNAPRASAD B T, GOPALAKRISHNA R, SAVITHA M, UDAYAKUMAR M. Identification of pea genotypes with enhanced thermotolerance using temperature induction response technique (TIR). Journal of Plant Physiology, 2002, 159: 535-545.
[88] 郭丽红, 陈善娜, 王德斌, 龚明. 热激和热胁迫过程中玉米幼苗谷胱甘肽还原酶活性和同工酶的变化.云南大学学报(自然科学版), 2006, 28(3): 262-266.
GUO L H, CHEN S N, WANG D B, GONG M. Changes in activity of glutathione reductase and it's isozyme of maize seedlings during heat shock and heat stress. Journal of Yunnan Agricultural University (Natural Science Edition), 2006, 28(3): 262-266. (in Chinese)
[89] KOTI S, REDDY K R, KAKANI V G, ZHAO D, GAO W. Effects of carbon dioxide, temperature and ultraviolet-B radiation and their interactions on soybean (Glycine max L.) growth and development. Environmental & Experimental Botany, 2007, 60(1): 1-10.
[90] 靳路真, 王洋, 张伟, 邱红梅, 陈健, 候云龙, 马晓萍, 王跃强, 谢甫绨. 大豆品种(系)耐热性鉴定及分级评鉴. 中国油料作物学报, 2016, 38(1): 77-87. JIN L Z, WANG Y, ZHANG W, QIU H M, CHEN J, HOU Y L, MA X P, WANG Y Q, XIE F T. Grading evaluation on heat-tolerance in soybean and identifcation of heat-tolerant cultivars. Chinese Journal of Oil Crop Sciences, 2016, 38(1): 77-87. (in Chinese)
[91] 陈芳, 郑炜君, 李盼松, 于太飞, 刘生祥, 陈明, 李连城, 徐兆师, 马有志. 小麦耐热性鉴定方法及热胁迫应答机理研究进展. 植物遗传资源学报, 2013, 14(6): 1213-1220.
CHEN F, ZHEGN W J, LI P S, YU T F, LIU S X, CHEN M, LI L C, XU Z S, MA Y Z. Progress of evaluating techniques and potential mechanism on heat tolerance in wheat. Journal of Plant Genetic Resources, 2013, 14(6): 1213-1220. (in Chinese)
[92] 李植良, 孙保娟, 罗少波, 黎振兴. 高温胁迫下华南茄子的耐热性表现及其鉴定指标的筛选. 植物遗传资源学报, 2009, 10(2): 244-248.
LI Z L, SUN B J, LUO S B, LI Z X. Morphological response to heat stress and screening of assessment indexes for heat tolerance in eggplant (Solanum melogena L.) in south China. Journal of Plant Genetic Resources, 2009, 10(2): 244-248. (in Chinese)
[93] KUMAGAI E, SAMESHIMA R. Genotypic differences in soybean yield responses to increasing temperature in a cool climate are related to maturity group. Agricultural and forest meteorology, 2014, 198: 265-272. |
[1] | 董永鑫,卫其巍,洪浩,黄莹,赵延晓,冯明峰,窦道龙,徐毅,陶小荣. 在中国大豆品种上创建ALSV诱导的基因沉默体系[J]. 中国农业科学, 2022, 55(9): 1710-1722. |
[2] | 李易玲,彭西红,陈平,杜青,任俊波,杨雪丽,雷鹿,雍太文,杨文钰. 减量施氮对套作玉米大豆叶片持绿、光合特性和系统产量的影响[J]. 中国农业科学, 2022, 55(9): 1749-1762. |
[3] | 郭世博,张方亮,张镇涛,周丽涛,赵锦,杨晓光. 全球气候变暖对中国种植制度的可能影响XIV.东北大豆高产稳产区及农业气象灾害分析[J]. 中国农业科学, 2022, 55(9): 1763-1780. |
[4] | 隋心意,赵小刚,陈鹏宇,李亚灵,温祥珍. 生菜LsPHYB可变剪接体的克隆与高温诱导表达模式[J]. 中国农业科学, 2022, 55(9): 1822-1830. |
[5] | 马小艳,杨瑜,黄冬琳,王朝辉,高亚军,李永刚,吕辉. 小麦化肥减施与不同轮作方式的周年养分平衡及经济效益分析[J]. 中国农业科学, 2022, 55(8): 1589-1603. |
[6] | 阿依木古丽·阿不都热依木,阿尔祖古丽·阿依丁,王家敏,石嘉琛,马芳芳,蔡勇,乔自林. 大豆异黄酮对牦牛卵巢颗粒细胞增殖和凋亡的影响[J]. 中国农业科学, 2022, 55(8): 1667-1675. |
[7] | 王绿阳,崔雷鸿,冯江银,洪秋霞,游美敬,保浩宇,杭苏琴. 钙敏感受体和胆囊收缩素-1受体介导大豆蛋白水解物对小鼠食欲的影响[J]. 中国农业科学, 2022, 55(4): 807-815. |
[8] | 姜芬芬, 孙磊, 刘方东, 王吴彬, 邢光南, 张焦平, 张逢凯, 李宁, 李艳, 贺建波, 盖钧镒. 世界大豆生育阶段光温综合反应的地理分化和演化[J]. 中国农业科学, 2022, 55(3): 451-466. |
[9] | 刘进,胡佳晓,马小定,陈武,勒思,Jo Sumin,崔迪,周慧颖,张立娜,Shin Dongjin,黎毛毛,韩龙植,余丽琴. 水稻RIL群体高密度遗传图谱的构建及苗期耐热性QTL定位[J]. 中国农业科学, 2022, 55(22): 4327-4341. |
[10] | 闫强,薛冬,胡亚群,周琰琰,韦雅雯,袁星星,陈新. 大豆根特异性GmPR1-9启动子的鉴定及其在根腐病抗性中的应用[J]. 中国农业科学, 2022, 55(20): 3885-3896. |
[11] | 张川,刘栋,王洪章,任昊,赵斌,张吉旺,任佰朝,刘存辉,刘鹏. 不同时期高温胁迫对夏玉米物质生产性能及籽粒产量的影响[J]. 中国农业科学, 2022, 55(19): 3710-3722. |
[12] | 王巧娟,何虹,李亮,张超,蔡焕杰. 基于AquaCrop模型的大豆灌溉制度优化研究[J]. 中国农业科学, 2022, 55(17): 3365-3379. |
[13] | 刘瑞瑶,黄国弘,李海艳,梁敏敏,逯明辉. 辣椒CaHsfA2上游转录因子的筛选及耐热功能分析[J]. 中国农业科学, 2022, 55(16): 3200-3209. |
[14] | 原程,张玉先,王孟雪,黄炳林,辛明强,尹小刚,胡国华,张明聪. 中耕时间和深度对大豆光合特性及产量形成的影响[J]. 中国农业科学, 2022, 55(15): 2911-2926. |
[15] | 赵玎玲,王梦璇,孙天杰,苏伟华,赵志华,肖付明,赵青松,闫龙,张洁,王冬梅. 大豆单锌指蛋白基因GmSZFP的克隆及其在SMV与寄主互作中的功能[J]. 中国农业科学, 2022, 55(14): 2685-2695. |
|