伽蓝菜属植物胎生苗发育过程中激素调控的研究进展
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摘要
景天科伽蓝菜属植物经体细胞胚形成和器官发育等过程在叶片上产生胎生苗。简述目前针对伽蓝菜属植物胎生苗发育各阶段中激素调控的研究情况,包括脱落酸、赤霉素、生长素、细胞分裂素、乙烯等激素和相关信号分子一氧化氮对胎生苗发育过程的影响,并探讨产生实验结果差异的原因,以期为相关研究和应用提供一定参考。
引文
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[2]李兆文.伽蓝菜属植物的栽培和园林应用[J].福建热作科技,2016,41(03):37-40.
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[8]Liu C, Zhu C, Zeng H M. Key KdSOC1 gene expression profiles during plantlet morphogenesis under hormone, photoperiod,and drought treatments[J].Genetics and Molecular Research,2016,15(1).
[9]屈东海,仇汉林,黄勇,阮颖,陈东红.锯缘落地生根的器官特征及多梳蛋白Ks RING1的组织表达分析[J].植物生理学报,2018,54(09):1441-1450.
[10]李珊珊.大叶落地生根KdSAHH基因功能鉴定[D].北京林业大学,2016.
[11]蒋文婷,曾会明.落地生根胎生苗发育及其相关基因研究进展[J].生物技术通报,2016,32(7):13-20.
[12]屈东海,赵静,谭环苗,等.伽蓝菜属植物遗传转化及其应用研究进展[J].分子植物育种,2018,16(18):5962-5969.
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[14]KulkaRG.CytokininsinhibitepiphyllousplantletdevelopmentonleavesofBryophyllum(Kalanchoe)marnierianum[J].Journal of experimental botany,2006,57(15):4089-4098.
[15]Palmer J P, Jasrai Y T. Precocious growth and effect of ABA:encapsulated buds of Kalanchoe tubiflora[J].Journal of Plant Biochemistry and Biotechnology,1996,5(2):103-104.
[16]Hedden P, Sponsel V. A century of gibberellin research[J].Journal of plant growth regulation,2015,34(4):740-760.
[17]Rademacher W.Chemicalregulatorsof gibberellinstatusandtheir applicationinplantproduction[J].Annualplantreviews,2018(3):359-403.
[18]Debeaujon I,Koornneef M. Gibberellin requirement for Arabidopsis seed germination is determined both by testa characteristics and embryonic abscisic acid[J].Plant physiology,2000,122(2):415-424.
[19]Su Y H, Zhao X Y, Liu Y B, et al. Auxin‐induced WUS expression is essential for embryonic stem cell renewal during somatic embryogenesis in Arabidopsis[J].The Plant Journal,2009,59(3):448-460.
[20] Moller B, Weijers D. Auxin Control of Embryo Patterning[J].Cold Spring Harbor Perspectives in Biology,2009,1(5):1-13.
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[23]KarpoffAJ.HormonesandearlyinvitrodevelopmentofepiphyllouspropagulesonBryophyllumcalycinum[J].American Journal of Botany,1982,69(3):348-355.
[24]钟天秀.大叶落地生根胎生苗差减cDNA文库的构建及相关基因的克隆[D].北京林业大学,2015.
[25]Kulka R G. Hormonal control of root development on epiphyllous plantlets of Bryophyllum(Kalanchoe)marnierianum:role of auxin and ethylene[J].Journal of experimental botany,2008,59(9):2361-2370.
[26]Schaller G E, Bishopp A, Kieber J J. The yin-yang of hormones:cytokinin and auxin interactions in plant development[J].The Plant Cell,2015:tpc.114.133595.
[27]Palavanunsal N, Arisan D. Nitric Oxide Signalling In Plants[J].Botanical Review,2009,75(2):203-229.
[28]AbatJK,DeswalR.Nitricoxidemodulatestheexpressionofproteinsandpromotesepiphyllousbuddifferentiationin Kalanchoe pinnata[J].Journal of plant growth regulation,2013,32(1):92-101.
[29]SawhneyS,MahajanA.Morphactin-inducedmalmorphogeneticeffectanditstransmissioninKalanchoe[J].Biologia plantarum,1995,37(3):443-447.
[30]Jaiswal S, Sawhney S. Thidiazuron-induced hypertrophic growth from foliar disks of Kalanchoe pinnata leads to visualization of a bioactive auxin gradient across the leaf plane[J].In Vitro Cellular&Developmental Biology-Plant,2008,44(1):65-68.
[2]李兆文.伽蓝菜属植物的栽培和园林应用[J].福建热作科技,2016,41(03):37-40.
[3]KlugeM,BrulfertJ.CrassulaceanacidmetabolisminthegenusKalanchoeecological,physiologicalandbiochemical aspects[M].Crassulacean acid metabolism. Springer, Berlin, Heidelberg,1996.324-335.
[4]GarcesHMP,ChampagneCEM,TownsleyBT,etal.Evolutionofasexualreproductioninleavesofthegenus Kalanchoe[J].Proceedings of the National Academy of Sciences,2007,104(39):15578-15583.
[5]袁强,胡国富,胡宝忠.落地生根胎生苗发育解剖学研究[J].东北农业大学学报,2006,(03):321-324.
[6]Batygina T B, Bragina E A, Titova G E. Morphogenesis of propagules in viviparous species Bryophyllum daigremontianum and B. calycinum[J]. Acta Societatis Botanicorum Poloniae,1996,65(1-2):127-133.
[7]Garces H M P, Koenig D, Townsley B T, et al. Truncation of KdLEC1 protein is required for asexual reproduction in Kalanchoe daigremontiana[J].Plant physiology,2014,165(1):196-206.
[8]Liu C, Zhu C, Zeng H M. Key KdSOC1 gene expression profiles during plantlet morphogenesis under hormone, photoperiod,and drought treatments[J].Genetics and Molecular Research,2016,15(1).
[9]屈东海,仇汉林,黄勇,阮颖,陈东红.锯缘落地生根的器官特征及多梳蛋白Ks RING1的组织表达分析[J].植物生理学报,2018,54(09):1441-1450.
[10]李珊珊.大叶落地生根KdSAHH基因功能鉴定[D].北京林业大学,2016.
[11]蒋文婷,曾会明.落地生根胎生苗发育及其相关基因研究进展[J].生物技术通报,2016,32(7):13-20.
[12]屈东海,赵静,谭环苗,等.伽蓝菜属植物遗传转化及其应用研究进展[J].分子植物育种,2018,16(18):5962-5969.
[13]Handbook of plant science[M].John Wiley&Sons,2007.
[14]KulkaRG.CytokininsinhibitepiphyllousplantletdevelopmentonleavesofBryophyllum(Kalanchoe)marnierianum[J].Journal of experimental botany,2006,57(15):4089-4098.
[15]Palmer J P, Jasrai Y T. Precocious growth and effect of ABA:encapsulated buds of Kalanchoe tubiflora[J].Journal of Plant Biochemistry and Biotechnology,1996,5(2):103-104.
[16]Hedden P, Sponsel V. A century of gibberellin research[J].Journal of plant growth regulation,2015,34(4):740-760.
[17]Rademacher W.Chemicalregulatorsof gibberellinstatusandtheir applicationinplantproduction[J].Annualplantreviews,2018(3):359-403.
[18]Debeaujon I,Koornneef M. Gibberellin requirement for Arabidopsis seed germination is determined both by testa characteristics and embryonic abscisic acid[J].Plant physiology,2000,122(2):415-424.
[19]Su Y H, Zhao X Y, Liu Y B, et al. Auxin‐induced WUS expression is essential for embryonic stem cell renewal during somatic embryogenesis in Arabidopsis[J].The Plant Journal,2009,59(3):448-460.
[20] Moller B, Weijers D. Auxin Control of Embryo Patterning[J].Cold Spring Harbor Perspectives in Biology,2009,1(5):1-13.
[21]HeideOM.Effectsof6-benzylamino-purineand1-naphthaleneaceticacidontheepiphyllousbudformationin Bryophyllum[J].Planta,1965,67(3):281-296.
[22]YazganM,VardarY.Studiesontheeffectsofauxin-kinetinapplicationsontheepiphyllousbuddingofBryophyllum daigremontianum Berg[J].Zeitschrift für Pflanzenphysiologie,1977,84(3):203-211.
[23]KarpoffAJ.HormonesandearlyinvitrodevelopmentofepiphyllouspropagulesonBryophyllumcalycinum[J].American Journal of Botany,1982,69(3):348-355.
[24]钟天秀.大叶落地生根胎生苗差减cDNA文库的构建及相关基因的克隆[D].北京林业大学,2015.
[25]Kulka R G. Hormonal control of root development on epiphyllous plantlets of Bryophyllum(Kalanchoe)marnierianum:role of auxin and ethylene[J].Journal of experimental botany,2008,59(9):2361-2370.
[26]Schaller G E, Bishopp A, Kieber J J. The yin-yang of hormones:cytokinin and auxin interactions in plant development[J].The Plant Cell,2015:tpc.114.133595.
[27]Palavanunsal N, Arisan D. Nitric Oxide Signalling In Plants[J].Botanical Review,2009,75(2):203-229.
[28]AbatJK,DeswalR.Nitricoxidemodulatestheexpressionofproteinsandpromotesepiphyllousbuddifferentiationin Kalanchoe pinnata[J].Journal of plant growth regulation,2013,32(1):92-101.
[29]SawhneyS,MahajanA.Morphactin-inducedmalmorphogeneticeffectanditstransmissioninKalanchoe[J].Biologia plantarum,1995,37(3):443-447.
[30]Jaiswal S, Sawhney S. Thidiazuron-induced hypertrophic growth from foliar disks of Kalanchoe pinnata leads to visualization of a bioactive auxin gradient across the leaf plane[J].In Vitro Cellular&Developmental Biology-Plant,2008,44(1):65-68.