XIAO Wang,TU Hongyan,LU Qiuchan,et al.Association of Physiological and Biochemical Properties and Cell Microstructures With Cut Flowers Senscence of Hedychium coronarium[J].Northern Horticulture,2023,(03):89-96.[doi:10.11937/bfyy.20221141]
白姜花生理生化和细胞结构变化与花衰老的相关分析
- Title:
- Association of Physiological and Biochemical Properties and Cell Microstructures With Cut Flowers Senscence of Hedychium coronarium
- Keywords:
- Hedychium coronarium; tetraploid; cut flower; senescence; physiology
- 文献标志码:
- A
- 摘要:
- 以白姜花二倍体和四倍体切花为试材,通过蒽酮比色法、酸性茚三酮法和透射电镜法比较切花发育过程中生理生化指标和显微特征,解析影响白姜花切花衰老的生理机制,以期进一步了解白姜花切花衰老机理。结果表明:随着瓶插时间延长,二倍体花瓣和旗叶的可溶性糖含量显著下降,四倍体保持相对稳定并高于二倍体;花瓣可溶性蛋白质含量变化不明显,四倍体含量高于二倍体;花瓣脯氨酸含量呈现升高趋势,二倍体花瓣脯氨酸含量高于四倍体。花瓣和花冠管丙二醛含量变化不明显,花瓣丙二醛含量高于花冠管;二倍体花瓣和花冠管丙二醛含量均高于四倍体。花冠管相对电导率显著升高发生早于花瓣,四倍体花瓣和花冠管相对电导率显著升高发生晚于二倍体。在萎蔫期花瓣细胞出现空腔化,各种细胞器结构消失,出现小泡或囊泡。综上,细胞自噬是花瓣和花冠管细胞膜透性增加的原因。较高的可溶性糖和可溶性蛋白质含量以及花瓣和花冠管细胞质膜破坏推迟等是小花弯颈和花瓣萎蔫延迟的因素之一,有利于切花寿命的延长。
- Abstract:
- Using anthrone reagent,acid ninhydrin,and transmission electron microscope,the physiological and biochemical properties and cell microstructures changes were tested and compared to interpret the senescence mechanism of cut flowers between the diploid and tetraploid Hedychium coronariums in order to further understand the aging mechanism of cut flower of Hedychium coronarium.The results showed that there were significant declines in the soluble sugar contents in flag leaves and petals of diploid,but not in the tetraploid.The soluble protein contents in petals of the diploid and tetraploid remained stable,while the content of tetraploid was more than that of the diploid.For the two ploidies,the contents of proline increased during the vase life,and the content of the diploid was more than that of the tetraploid.In the development,the contents of malonaldehyde in petals and corolla tubes did not change evidently.The contents of malonaldehyde in petals were more than those in corolla tubes in the two ploidies,and the contents of malonaldehyde in the two tissues of the diploid were more than those of the tetraploid.That the relative conductivities of corolla tubes increased significantly preceded that of petals.Compared to the diploid,the relative conductivity of tetraploid petal increased significantly in late development stage.In the wilting stage of the two ploidies,the cavities formed in petal cells,various organelle structures disappeared,and many vesicles were observed.Above all,the autophagy caused the increase of permeability of petal and corolla tube cell membranes which was one of the characteristics of programmed cell death.It was speculated that the delayed florets neck bending and petal wilting might be due to more soluble sugar and protein contents and the delay of the damage of cell membrane of petal and corolla which would be helpful for the longer vase life of Hedychium coronarium cut flowers.
参考文献/References:
[1]CHEN H,YUE Y,YU R,et al.A Hedychium coronarium short chain alcohol dehydrogenase is a player in allo-ocimene biosynthesis[J].Plant Molecular Biology,2019,101(3):297-313.[2]李瑞红,范燕萍.白姜花不同开花时期的香味组分及其变化[J].植物生理学通讯,2007,43(1):176-180.[3]刘晓洲,范燕萍,余让才,等.乙烯和1-MCP对白姜花萜类香气及相关基因表达的影响[J].华南农业大学学报,2018,39(4):68-72.[4]WANG C,ABBAS F,ZHOU Y,et al.Genome-wide identification and expression pattern of SnRK gene family under several hormone treatments and its role in floral scent emission in Hedychium coronarium[J].PeerJ,2021(9):e10883.[5]ABBAS F,ZHOU Y,HE J,et al.Metabolite and transcriptome profiling analysis revealed that melatonin positively regulates floral scent production in Hedychium coronarium[J].Front Plant Sci,2021(12):808899.[6]KE Y,ABBAS F,ZHOU Y,et al.Auxin-responsive R2R3-MYB transcription factors HcMYB1 and HcMYB2 activate volatile biosynthesis in Hedychium coronarium flowers[J].Front Plant Sci,2021(12):710826.[7]ABBAS F,KE Y,ZHOU Y,et al.Genome-wide analysis reveals the potential role of MYB transcription factors in floral scent formation in Hedychium coronarium[J].Front Plant Sci,2021(12):623742.[8]ABBAS F,KE Y,ZHOU Y,et al.Functional characterization of Hedychium coronarium J.Koenig MYB132 confers the potential role in floral aroma synthesis[J].Plants (Basel),2021,10(10):2014.[9]YUE Y C,Y R C,FAN Y P.Transcriptome profiling provides new insights into the formation of floral scent in Hedychium coronarium[J].BMC Genomics,2015(16):470.[10]YUE Y C,WANG L,YU R C,et al.Coordinated and high-level expression of biosynthetic pathway genes is responsible for the production of a major floral scent compound methyl benzoate in Hedychium coronarium[J].Frontiers in Plant Science,2021(12):650582.[11]肖望,涂红艳,张爱玲,等.通过薄片培养技术建立白姜花高效植株再生体系[J].北方园艺,2016(3):96-99.[12]肖望,涂红艳,张爱玲.白姜花胚性愈伤组织的诱导与植株再生体系的建立[J].园艺学报,2016,43(8):1605-1612.[13]胡秀,吴永清,姬兵兵,等.姜花新品种‘渐变’[J].园艺学报,2018,45(3):607-608.[14]GANTAIT S,MANDAL N,BHATTACHARYYA S,et al.Induction and identification of tetraploids using in vitro colchicine treatment of Gerbera jamesonii Bolus cv.Sciella[J].Plant Cell,Tissue and Organ Culture (PCTOC),2011,106(3):485-493.[15]MCCARTHY E W,LANDIS J B,KURTI A,et al.Early consequences of allopolyploidy alter floral evolution in Nicotiana (Solanaceae)[J].BMC Plant Biol,2019,19(1):162.[16]MA G,SHI X,ZOU Q,et al.iTRAQ-based quantitative proteomic analysis reveals dynamic changes during daylily flower senescence[J].Planta,2018,248:859-873.[17]BIELESKI R L.Onset of phloem export from senescent petals of daylily[J].Plant Physiology,1995,109(2):557-565.[18]KLOTZ M G.The action of tentoxin on membrane processes in plants[J].Physiologia Plantarum,2010,74(3):575-582.[19]HONG-YAN T,AI-LING Z,WANG X,et al.Induction and identification of tetraploid Hedychium coronarium through thin cell layer culture[J].Plant Cell,Tissue and Organ Culture (PCTOC),2018,135:395-406.[20]陈钧辉,李俊.生物化学实验[M].5版.北京:科学出版社,2014.[21]李秀霞.生物学实践指导(上册)[M].沈阳:东北大学出版社,2014.[22]郭海林,刘建秀,朱雪花,等.结缕草属杂交后代抗寒性评价[J].草地学报,2006(1):24-28.[23]李和平.植物显微技术[M].2版.北京:科学出版社,2019.[24]HOEBERICHTS F A,van DOORN W G,VORST O,et al.Sucrose prevents up-regulation of senescence-associated genes in carnation petals[J].J Exp Bot,2007,58(11):2873-2885.[25]van DOORN W G,WOLTERING E J.Physiology and molecular biology of petal senescence[J].J Exp Bot,2008,59(3):453-480.[26]van DOORN W G.Is petal senescence due to sugar starvation?[J].Plant Physiol,2004,134(1):35-42.[27]EASON J R.Molecular and genetic aspects of flower senescence[J].Stewart Postharvest Review,2006,2(2):1-7.[28]DAR R A,TAHIR I,AHMAD S S.Sugars and sugar alcohols have their say in the regulation of flower senescence in Dianthus chinensis L[J].Scientia Horticulturae,2014,174:24-28.[29]PUN U K,ICHIMURA K.Role of sugars in senescence and biosynthesis of ethylene in cut flowers[J].Japan Agricultural Research Quarterly,2003,37(4):219-224.[30]AVILA-OSPINA L,MOISON M,YOSHIMOTO K,et al.Autophagy,plant senescence,and nutrient recycling[J].J Exp Bot,2014,65(14):3799-3811.[31]LI F,VIERSTRA R D.Autophagy:A multifaceted intracellular system for bulk and selective recycling[J].Trends Plant Sci,2012,17(9):526-537.[32]KWON S I,CHO H J,JUNG J H,et al.The Rab GTPase RabG3b functions in autophagy and contributes to tracheary element differentiation in Arabidopsis[J].Plant J,2010,64(1):151-164.[33]TRIVELLINI A,COCETTA G,HUNTER D A,et al.Spatial and temporal transcriptome changes occurring during flower opening and senescence of the ephemeral hibiscus flower,Hibiscus rosa-sinensis[J].J Exp Bot,2016,67(20):5919-5931.[34]KAMDEE,KIRASAK,KETSA,et al.Vesicles between plasma membrane and cell wall prior to visible senescence of Iris and Dendrobium flowers[J].J Plant Physiol,2015,188:37-43.
相似文献/References:
[1]陈春桦,高建明,刘巧莲,等.芦笋四倍体诱导、倍性鉴定及生物学特性的研究[J].北方园艺,2014,38(11):88.
CHEN Chun-hua,GAO Jian-ming,LIU Qiao-lian,et al.Study on Tetraploid Induction,Identification and Biological Characteristics of Asparagus[J].Northern Horticulture,2014,38(03):88.
[2]袁建民,党选民,詹园凤,等.二倍体及同源四倍体小果型西瓜核型分析[J].北方园艺,2013,37(23):40.
YUAN Jian-min,DANG Xuan-min,ZHAN Yuan-feng,et al.Karyotype Analysis of Diploid and Autotetraploid Mini-watermelon[J].Northern Horticulture,2013,37(03):40.
[3]陈荣,朱昌叁.预培养时间对观音莲染色体加倍的影响[J].北方园艺,2013,37(01):105.
CHEN Rong,ZHU Chang-san.Study on Effect of Precultivation Period on Chromosome Doubling of Alocasia indica[J].Northern Horticulture,2013,37(03):105.
[4]张娜,施先锋,任俭,等.利用胺磺灵诱变西瓜四倍体研究[J].北方园艺,2013,37(19):52.
ZHANG Na,SHI Xian-feng,REN Jian,et al.Study on Mutugenesis of Tetraploid Watermelon by Using Oryzalin[J].Northern Horticulture,2013,37(03):52.
[5]张勇,房勇霖,邓丽家,等.厚皮甜瓜四倍体的诱导及其特性变化[J].北方园艺,2012,36(04):104.
ZHANG Yong,FANG Yong-lin,DENG Li-jia,et al.Induction and Change of Its Characteristics of Tetraploid Muskmelon[J].Northern Horticulture,2012,36(03):104.
[6]郭玉,邵建柱,何建华,等.染色体加倍对“珠美”海棠形态特征的影响[J].北方园艺,2012,36(16):101.
GUO Yu,SHAO Jian-zhu,HE Jian-hua,et al.Effect of Chromosome Doubling on Morphological Characteristics of Malus zumi [J].Northern Horticulture,2012,36(03):101.
[7]李蕾,张伟超,郭婧,等.杜仲四倍体与二倍体光合特性比较[J].北方园艺,2012,36(06):35.
LI Lei,ZHANG Wei-chao,GUO Jing,et al.Photosynthetic Characteristics of Tetraploid and Diploid Eucommia ulmoides[J].Northern Horticulture,2012,36(03):35.
[8]祝海燕,杨洛滨.萝卜异倍体间的特征特性比较[J].北方园艺,2013,37(16):48.
ZHUHai-yan,YANGLuo-bing.ComparisonoftheCharactersofRadishHeteroploid[J].Northern Horticulture,2013,37(03):48.
[9]闻永慧,孟英,李慧敏,等.LED不同光质对白及组培苗生长及可溶性糖含量的影响[J].北方园艺,2014,38(15):58.
WEN Yong-hui,MENG Ying,LI Hui-min,et al.Effect of LED Different Light Qualities on Growth and the Content of Soluble Sugar of Bletiua striata Tissue Culture Seedlings[J].Northern Horticulture,2014,38(03):58.
[10]肖望,涂红艳,张爱玲,等.通过薄片培养技术建立白姜花高效植株再生体系[J].北方园艺,2016,40(03):96.[doi:10.11937/bfyy.201603026]
XIAO Wang,TU Hongyan,ZHANG Ailing,et al.Plant Regeneration From Hedychium coronarium via Thin Layer Culture[J].Northern Horticulture,2016,40(03):96.[doi:10.11937/bfyy.201603026]
备注/Memo
第一作者简介:肖望(1970-),女,博士,教授,现主要从事植物生理学教学与科研等工作。E-mail:xiaowang@gdei.edu.cn.基金项目:广东省创新强校工程基础研究重点项目及应用研究重点资助项目(2018KZDXM049);广州市科技计划资助项目(201804010413,202102080244);广东第二师范学院大学生创新创业训练计划资助项目(202114278106,202114278097);2022年广东省科技创新战略专项资金(“攀登”计划专项资金)资助项目(pdjh2022b0383)。收稿日期:2022-03-25