光周期与温度对紫花苜蓿phyA和phyB mRNA表达的影响

doi:10.11733/j.issn.1007-0435.2011.06.015

›› 2011, Vol. 19 ›› Issue (6): 975-982.DOI: 10.11733/j.issn.1007-0435.2011.06.015

光周期与温度对紫花苜蓿phyA和phyB mRNA表达的影响

樊文娜, 严学兵, 史莹华, 王成章

河南农业大学牧医工程学院, 河南郑州450002

收稿日期:2011-07-07 修回日期:2011-08-23 出版日期:2011-12-15 发布日期:2012-07-09
通讯作者: 王成章,E-mail:wangchengzhang@263.net
作者简介:樊文娜(1981- ),女,河南许昌人,助研,硕士,主要从事牧草栽培生理研究,E-mail:chou0516@163.com
基金资助:
国家牧草产业技术体系建设项目(CARS-35)资助

Effects of Photoperiod and Temperature on phyA and phyB mRNA Expression of Alfalfa

FAN Wen-Na, YAN Xue-Bing, SHI Ying-Hua, WANG Cheng-Zhang

College of Animal Science and Veterinary Medicine, Henan Agricultural University, Zhengzhou, Henan Province 450002, China

Received:2011-07-07 Revised:2011-08-23 Online:2011-12-15 Published:2012-07-09

摘要/Abstract

摘要： 通过探讨不同温度和不同光周期对紫花苜蓿(Medicago sativa L.)phyA和phyB mRNA含量的影响,以期为揭示调控苜蓿秋眠性的分子机理提供科学依据。试验采用FQ-PCR SYBR-Green I方法,测定了每天8,12和16h光照处理条件下3种秋眠类型苜蓿WL-232(秋眠型,FD2)、ArcherⅡ(半秋眠型,FD5)、WL-525(非秋眠型,FD8)的phyA和phyB mRNA表达水平;采用半定量RT-PCR,测定了5℃,15℃,25℃和35℃条件下秋眠型苜蓿Vernal(FD2)的phyA和phyB mRNA表达水平。结果表明:苜蓿存在光周期效应,短日照条件下秋眠型苜蓿phyB mR-NA表达量最大,相同光照条件下不同秋眠型苜蓿的表达规律为秋眠型>半秋眠型>非秋眠型,且相对于phyA,在紫花苜蓿绿叶中phyB对光周期的变化反应更敏感。在不同温度条件下秋眠型苜蓿Vernal的phyA和phyB合成规律不一致,低温条件下,phyB表达量较高,phyA表达量较低;高温条件下,phyA表达量较高,phyB表达量较低。上述结果表明phyB在调控苜蓿秋眠中发挥了更重要的作用。

关键词: 光周期, 温度, 苜蓿, phyA, phyB, mRNA表达

Abstract: The effects of photoperiod and temperature on fall dormancy of alfalfa were investigated by measuring phyA and phyB mRNA contents.The mRNA contents of phyA and phyB were observed in three alfalfa varieties: fall-dormant variety WL-232(FD2);semi-dormant Archer Ⅱ(FD5);and non-fall-dormant WL-525(FD8) under three different day lengths,(8,12 and 16 h) by FQ-PCR using SYBR-Green I.The mRNA contents of phyA and phyB in Vernal variety(FD2) under four different temperatures(5,15,25 and 35℃) were measured by semi-quantitative RT-PCR,respectively.Results showed that WL-232 had the highest mRNA expression of phyA and phyB at 8 h day length.The mRNA content of WL-232 variety was significantly higher than that of Archer Ⅱ and WL-525.The synthesis of phyA and phyB varied for different temperatures.The phyB expression was higher than phyA under low temperature conditions while opposite under high temperature conditions indicating that phyB played a more important role than phyA in the regulation of alfalfa dormancy.

Key words: Photoperiod, Temperature, Alfalfa, phyA, phyB, mRNA expression

中图分类号:

樊文娜, 严学兵, 史莹华, 王成章. 光周期与温度对紫花苜蓿phyA和phyB mRNA表达的影响[J]. , 2011, 19(6): 975-982.

FAN Wen-Na, YAN Xue-Bing, SHI Ying-Hua, WANG Cheng-Zhang. Effects of Photoperiod and Temperature on phyA and phyB mRNA Expression of Alfalfa[J]. , 2011, 19(6): 975-982.

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参考文献

[1] 张亚军,严学兵,朱见明,等.紫花苜蓿光敏色素A基因片段的克隆及其RNA干扰载体的构建[J].草地学报,2010,18(6):897-901
[2] Hih S C,Jung G A,Shelton D C.Effects of temperature and photoperiod on metabolic changes in alfalfa in relation to cold hardiness[J].Crop Science,1967,7:385-389
[3] Barnes D K,Smith D M,Stucker R E,et al.Fall dormancy in alfalfa:A valuable predictive tool[C]//Barnes D K,ed.Report of the 26th Alfalfa Improvement Conference.Brookings S D:South Dakota State University,1979:34
[4] Butler W L,Norris K H,Siegelman H W,et al.Detection assay and preliminary purification of the pigment controlling photorespensive development of plants[J].Proceedings of the National Academy of Science,1959,58:1703-1708
[5] Meng Chen.Phytochrome nuclear body:an emerging model to study interphase nuclear dynamics and signaling[J].Current Opinion in Plant Biology,2008,11(5):503-508
[6] Franklin K A,Davis S J,Stoddart W M,et al.Mutant analyses define multiple roles for phytochrome C in Arabidopsis photo morphogenesis[J].Plant Cell,2003,15:1981-1989
[7] Monte E,Alonso J M,Ecker J R,et al.Isolation and characterization of phyC mutants in Arabidopsis reveals complex crosstalk between phytochrome signaling pathways[J].Plant Cell,2003,15:1962-1980
[8] Horvath D.Common mechanisms regulate flowering and dormancy[J].Plant Science,2009,177:523-531
[9] 王成章,韩锦峰,胡喜峰,等.不同光周期条件下phyB和ABA对不同苜蓿品种的秋眠性调控[J].草业学报,2006,15(6):56-63
[10] Franklin K A,Whitela G C.Light-quality regulation of freezing tolerance in Arabidopsis thaliana[J].Nature Genetics,2007,39:1410-1413
[11] Halliday K J,Salter M G,Thingnaes E,et al.Phytochrome control of flowering is temperature sensitive and correlates with expression of the floral integrator FT[J].Plant Journal,2003,33(5):875-885
[12] Benedict C,Geisler M,Trygg J,et al.Consensus by democracy.using meta-analyses of microarray and genomic data to model the cold accli mation signaling pathway in Arabidopsis[J].Plant Physiology,2006,141:1219-1232
[13] 樊文娜,王成章,严学兵,等.紫花苜蓿肌动蛋白基因的提取[J].草原与草坪,2009(1):58-60
[14] 杨玲玲.RACE法克隆紫花苜蓿光敏色素A基因[D].郑州:河南农业大学,2008:28-42
[15] 李平.6种蒺藜状苜蓿光受体基因的预测和紫花苜蓿phyB、CRY1、CRY2、phyA基因的克隆与分析[D].郑州:河南农业大学,2009:65-67
[16] Livak K J,Schmittgen T D.Analysis was of relative gene expression data using real time quantitative PCR and the 2(-Delta Delta C(T))Method[J].Methods,2001,25(4):402-408
[17] 夏成,王哲,徐闯,等.应用半定量RT-PCR方法测定围产期奶牛肝PEPCK-C mRNA的丰度[J].中国兽医学报,2006,26(5):533-537
[18] Horvath D P,Anderson J V,Chao W S,et al.Knowing when to grow:signals regulating bud dormancy[J].Trends in Plant Science,2003,8(11):534-540
[19] Rohde A,Bhalerao R P.Plant dormancy in the perennial context[J].Trends in Plant Science,2007,12(5):217-223
[20] Chao W S,Foley M E,Horvath D P,et al.Signals regulating dormancy in vegetative buds[J].International Journal of Plant Developmental Biology,2007,1(1):49-56
[21] Horvath D.Common mechanisms regulate flowering and dormancyl[J].Plant Science,2009,177:523-531
[22] Kuhn N,Ormeno-Nunez J,Jaque-Zamora G,et al.Photope riod modifies the diurnal expression profile of VvPHYA and VvPHYB transcripts in field-grown grapevine leaves[J].Journal of Plant Physiology,2009,166(15):1172-180
[23] Ramos A,Perezsolis E,Ibanez C,et al.Winter disruption of the circadian clock in chestnut[J].Proceedings of the National Academy of Sciences of the United States of America,2005,102(19):7037-7042
[24] Cristian I,Alberto R,Paloma A,et al.Overall alteration of circadian clock gene expression in the chestnut cold response[J].Public Library of Science One,2008,10(3):e3567.doi:10.1371/journal.pone.0003567
[25] Horvath D P,Chao W S,Suttle J C,et al.Transcriptome analysis identifies novel responses and potential regulatory genes involved in seasonal dormancy transitions of leafy spurge (Euphorbia esula)[J].BMC Genomics,2008,9:536
[26] Mazzella M A,Arana M V,Staneloni R J.Phytochrome control of the Arabidopsis transcriptome anticipates seedling exposure to light[J].Plant Cell,2005,17:2507-2516
[27] Seo M,Hanada A,Kuwahara A,et al.Regulation of hormone metabolism in arabidopsis seeds:phytochrome regulation of abscisic acid metabolism and abscisic acid regulation of gibberellin metabolism[J].Plant Journal,2006,48(3):354-366
[28] Franklin K A.Light and temperature signal crosstalk in plant development[J] ,Science Direct,2009,12 (1):63-68
[29] Svendsen E,Wilen R,Stevenson R,et al.A molecular mark associated with low-temperature induction of dormancy in red osier dogwood (Cornus sericea)[J].Tree Physiology,2007,27:385-397
[30] Olsen J E,Junttila O,Nilsen J,et al.Ectopic expression of oat phytochrome A in hybrid aspen changes critical day length for growth and prevents cold acclimatization[J].Plant Journal,1997,12(6):1339-1350
[31] Wake C M F,Fennell A.Morphological,physiological and endo-dormancy responses of three Vitis genotypes to short photoperiod[J].Physiologia Plantarum,2000,109:203-210
[32] Eriksson M.Low levels of phytochrome A expression alters circadian rhythmand change levels of FLOWERING LOCUS T leading to early bud set in hybrid aspen[J].Comparative Biochemistry and Physiology A Molecular & Integrative Physiology,2007,146:231
[33] Quail P H.Phytochrome-regulated gene expression[J].Integra Plant Biology,2007,49:11-20
[34] Heschel M S,Selby J,Butler C,et al.A new role for phytochromes in temperature dependent germination[J].New Phytologist,2007,174:735-741

光周期与温度对紫花苜蓿phyA和phyB mRNA表达的影响

Effects of Photoperiod and Temperature on phyA and phyB mRNA Expression of Alfalfa

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