果树抗寒相关基因研究进展
摘要
温度是影响果树生长发育、果品产量及品质的重要的环境因子之一。低温会对果树的细胞结构造成伤害,引发树体物质代谢紊乱,甚至引起死亡。近年来,随着分子生物学技术的应用与发展,果树树体对低温胁迫相关基因的响应受到了国内外学者的广泛关注。果树低温胁迫诱导表达的基因,根据其调控的方式,主要分为以下2类,一类是通过调控抗寒基因的表达、寒冷信号传导等过程来提高植物的耐寒性的调控基因;另一类是与提高植物抗寒性直接相关的功能基因。该文介绍了果树抗寒相关基因的研究进展,以供参考。
引文
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[3]刘荣,刘清国,范建新,等.果树抗寒性生理生化及分子机理研究进展[J].分子植物育种,2017,15(5):2028-2034.
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[7]Nguyen H T,LeipnerJ,Stamp P,et al.Low temperature stress in maize(Zea mays L.)induces genes involved in photosynthesis and signal transduction as studied by suppression subtractive hybridization[J].Plant Physiol Biochem,2009,47(2):116-122.
[8]JanshaA,AprileA,Zamecnik,et al.Transcriptional responses of winter barley to cold indicate nucleosome remodelling as a specific feature of crown tissues[J].Funct Integr Genomics,2011,11(2):307-325.
[9]ZhangT,Zhao X,Wang W,et al.Comparative transcriptome profiling of chilling stress responsiveness in two contrasting rice genotypes[J].PLoS ONE,2012,7(8).
[10]米宝琴,毛娟,申鹏,等.山葡萄‘通化-3’抗寒相关基因SSH文库的构建及分析[J].果树学报,2015,32(4):546-554.
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[13]Xiao H,Siddiqua M,Braybrook Set,et al.Three grape CBF/DREB1genes respond to low temperature,drought and abscisic acid[J].Plant,Cell&Environment,2006,29(7):1410-1421.
[14]钟克亚.转录因子CBF在植物抗寒中的重要作用[J].遗传,2006,28(2):249-254.
[15]Champ K I,Febres V J,Moore G A.The role of CBFtranscriptional activators in two Citrus species(Poncirus and Citrus)with contrasting levels of freezing tolerance[J].Physiologia Plantarum,2007,129(3):529-541.
[16]金万梅.冷诱导转录因子CBF1转化草莓及其抗寒性鉴定[J].西北植物学报,2007,27(2):0223-0227.
[17]Siddiqua M,Nassuth A.Vitis CBF1 and Vitis CBF4 differ in their effect on Arabidopsis abiotic stress tolerance,development and gene expression[J].Plant,Cell&Environment,2011,34(8):1345-1359.
[18]Tillett R L,Wheatley M D,Tattersall E A R,et al.The Vitis vinifera C-repeat binding protein 4(VvCBF4)transcriptional factor enhances freezing tolerance in wine grape[J].Plant Biotechnology Journal,2012,10(1):105-124.
[19]Porat R,Pavoncello D,Lurie S,et al.Identification of a grapefruit cDNA belonging to a unique class of citrus dehydrins and characterization of its expression patterns under temperature stress conditions[J].Physiologia Plantatrum,2002,115:598-603.
[20]Hara M,Wakasugi Y,Ikoma Y.cDNA sequence and expression of a cold-responsive gene in Citrus unshiu[J].Bio-science,Biotechnology,and Biochenmistry,1999,63(2):433-437.
[21]Sahim-cevikm,Moore G A.Gold-induced dehydrins from Poncirus trifoliata localized in the nucleus[J].Journal of Plant Biochenistry and BIO technology,2012,21(1):134-139.
[22]江勇,贾士荣,费云标.抗冻蛋白及其在植物抗冻生理中的作用[J].植物学报,1999,7(41):687-692.
[23]Cheong Y H,ChangH S,Gupta R et al.Transcriptional profiling reveals novel interactions between wounding,pathogen,abiotic stress and hormonal responses in Arabidopsis[J].Plant Physiol,2002,129(2):661-677.
[24]Swindell W R,Huebner M,Weber A P.Transcriptional profiling of Arabidopsis heat shock proteins and transcription factors reveals extensive overlap between heat and non-heat stress response pathways[J].BMC Genomics,2007,8(1):125.
[25]RushtonPJ,Somssich I E,Ringler P et al.WRKY tran scriptionfactors. TrendsPlantSci,2010,15:247-258.
[26]Ishiham A N,Yoshioka H.Post-translationalregulationof WRKY transcriptionfactorsinplan timmunity. CurrOpinPlan tBiol,2012,15:1-7.
[27]罗昌国,渠慎春,张计育,等.湖北海棠MhWRKY40b在几种胁迫下的表达分析[J].园艺学报,2013,40(1):1-9.
[2]平晓燕,周莉.华南地区经济林果寒害研究进展[J].中国生态农业学报,2018,26(4):467-479.
[3]刘荣,刘清国,范建新,等.果树抗寒性生理生化及分子机理研究进展[J].分子植物育种,2017,15(5):2028-2034.
[4]王庆杰,王立.植物抗寒性基因研究综述[J].农村经济与科技,2018,29(08).
[5]Welling A,Palvae T.Molecular control of cold acclimation in trees[J].Physiol Plant,2006,127(2):167-181.
[6]Lee B-H,Henderson DA,Zhu J-K.The Arabidopsis coldresponsive transcriptome and its regulation by ICE1[J].Plant Cell Online,2005,17(11):3155-3175.
[7]Nguyen H T,LeipnerJ,Stamp P,et al.Low temperature stress in maize(Zea mays L.)induces genes involved in photosynthesis and signal transduction as studied by suppression subtractive hybridization[J].Plant Physiol Biochem,2009,47(2):116-122.
[8]JanshaA,AprileA,Zamecnik,et al.Transcriptional responses of winter barley to cold indicate nucleosome remodelling as a specific feature of crown tissues[J].Funct Integr Genomics,2011,11(2):307-325.
[9]ZhangT,Zhao X,Wang W,et al.Comparative transcriptome profiling of chilling stress responsiveness in two contrasting rice genotypes[J].PLoS ONE,2012,7(8).
[10]米宝琴,毛娟,申鹏,等.山葡萄‘通化-3’抗寒相关基因SSH文库的构建及分析[J].果树学报,2015,32(4):546-554.
[11]王海波,程来亮,常源升,等.苹果矮化砧‘71-3-150’对冷胁迫的生理与转录组响应[J].园艺学报,2016,43(8):1437-1451.
[12]张真真,邱立军,刘博文,等.柑橘抗寒相关基因及抗寒基因工程研究进展[J].浙江农业科学,2015,56(11).
[13]Xiao H,Siddiqua M,Braybrook Set,et al.Three grape CBF/DREB1genes respond to low temperature,drought and abscisic acid[J].Plant,Cell&Environment,2006,29(7):1410-1421.
[14]钟克亚.转录因子CBF在植物抗寒中的重要作用[J].遗传,2006,28(2):249-254.
[15]Champ K I,Febres V J,Moore G A.The role of CBFtranscriptional activators in two Citrus species(Poncirus and Citrus)with contrasting levels of freezing tolerance[J].Physiologia Plantarum,2007,129(3):529-541.
[16]金万梅.冷诱导转录因子CBF1转化草莓及其抗寒性鉴定[J].西北植物学报,2007,27(2):0223-0227.
[17]Siddiqua M,Nassuth A.Vitis CBF1 and Vitis CBF4 differ in their effect on Arabidopsis abiotic stress tolerance,development and gene expression[J].Plant,Cell&Environment,2011,34(8):1345-1359.
[18]Tillett R L,Wheatley M D,Tattersall E A R,et al.The Vitis vinifera C-repeat binding protein 4(VvCBF4)transcriptional factor enhances freezing tolerance in wine grape[J].Plant Biotechnology Journal,2012,10(1):105-124.
[19]Porat R,Pavoncello D,Lurie S,et al.Identification of a grapefruit cDNA belonging to a unique class of citrus dehydrins and characterization of its expression patterns under temperature stress conditions[J].Physiologia Plantatrum,2002,115:598-603.
[20]Hara M,Wakasugi Y,Ikoma Y.cDNA sequence and expression of a cold-responsive gene in Citrus unshiu[J].Bio-science,Biotechnology,and Biochenmistry,1999,63(2):433-437.
[21]Sahim-cevikm,Moore G A.Gold-induced dehydrins from Poncirus trifoliata localized in the nucleus[J].Journal of Plant Biochenistry and BIO technology,2012,21(1):134-139.
[22]江勇,贾士荣,费云标.抗冻蛋白及其在植物抗冻生理中的作用[J].植物学报,1999,7(41):687-692.
[23]Cheong Y H,ChangH S,Gupta R et al.Transcriptional profiling reveals novel interactions between wounding,pathogen,abiotic stress and hormonal responses in Arabidopsis[J].Plant Physiol,2002,129(2):661-677.
[24]Swindell W R,Huebner M,Weber A P.Transcriptional profiling of Arabidopsis heat shock proteins and transcription factors reveals extensive overlap between heat and non-heat stress response pathways[J].BMC Genomics,2007,8(1):125.
[25]RushtonPJ,Somssich I E,Ringler P et al.WRKY tran scriptionfactors. TrendsPlantSci,2010,15:247-258.
[26]Ishiham A N,Yoshioka H.Post-translationalregulationof WRKY transcriptionfactorsinplan timmunity. CurrOpinPlan tBiol,2012,15:1-7.
[27]罗昌国,渠慎春,张计育,等.湖北海棠MhWRKY40b在几种胁迫下的表达分析[J].园艺学报,2013,40(1):1-9.