|Table of Contents|

Relationship Between Bolting Speed and Physiological and Biochemical Characteristics at Bolting Stage in Leaf Mustard

《北方园艺》[ISSN:1001-0009/CN:23-1247/S]

Issue:
2020年21
Page:
27-33
Research Field:
Publishing date:

Info

Title:
Relationship Between Bolting Speed and Physiological and Biochemical Characteristics at Bolting Stage in Leaf Mustard
Author(s):
YAN Fengjun12LIU Duchen12DAI Yunlu3GONG Xuefeng12CHANG Wei12LI Yuejian12
(1.Institute of Horticulture,Sichuan Academy of Agricultural Sciences/Vegetable Germplasm Innovation and Variety Improvement Key Laboratory of Sichuan Province,Chengdu,Sichuan 610066;2.Key Laboratory of Biology and Genetic Improvement of Horticultural Crops(Southwest Region)Ministry of Agriculture,Chengdu,Sichuan 610066;3.People′s Government of Putou Town,Lixian County,Aba Autonomous Prefecture,Lixian,Sichuan 623100)
Keywords:
leaf mustardbolting dateSODPODCATbolting speed
PACS:
-
DOI:
10.11937/bfyy.20194390
Abstract:
Three mustard materials with different bolting tolerance,F7212,F7073 and F7170 were selected in this study,the physiological and biochemical characteristics of leaves in 0-4 days before bolting stage were identified,and the correlation between each index and the bolting speed of mustard were studied,in order to provide a theoretical basis for revealing the physiological and biochemical characteristics of mustard buds and their relationship with bolting tolerance.The results showed that the activities of soluble protein,POD,SOD and CAT in the leaves of various mustard were performed gradually increasing during the 0-4 days before bolting stage,while the soluble sugar decreased.Meanwhile,the soluble protein content and CAT activity in leaves increased with the decline in bolting speed.Compared with other materials,F7212 was the highest on the soluble protein content and CAT activity,which increased by 0.12%-0.91% and 14.54%-149.86% respectively.However,SOD activity decreased with the increase of bolting tolerance,F7212 decreased by 2.68%-116.00% respectively.In addition,the soluble protein content and SOD activity of the low bolting speed mustard material performed sharply increasing.While,the POD and CAT activities showed a steady increasing.Correlation study showed that there was a significant correlation between the bolting speed and POD and CAT activities,but no significant correlation with soluble protein,soluble sugar contents and SOD activity.Path analyses showed that soluble sugar content and SOD activity were the most direct effects on the bolting speed (-0.80-1.09),but soluble protein,POD and CAT indirectly effected on soluble sugar and SOD.It Indicated that with the SOD increasing,the soluble sugar in leaf quickly transfer to outside were main the important factors to accelerate the mustard bolting rate.

References:

[1]刘独臣,李跃建,房超,等.四川叶用芥菜主要营养成分分析[J].西南农业学报,2014,27(2):763-767.[2]邓英,宋明,吴康云,等.不同叶用芥菜品种营养成分分析[J].中国蔬菜,2010(2):42-45.[3]刘琳,李珊珊,袁仁文,等.芥菜主要化学成分及生物活性研究进展[J].北方园艺,2018(15):180-185.[4]KIM H W,KO H C,BAEK H J,et al.Identification and quantification of glucosinolates in Korean leaf mustard germplasm (Brassica juncea var.integrifolia) by liquid chromatography-electrospray ionization/tandem mass spectrometry[J].European Food Research & Technology,2016,242(9):1479-1484.[5]范永红,沈进娟,董代文.芥菜类蔬菜产业发展现状及研究前景思考[J].农学学报,2016,6(2):65-71.[6]杨婷婷,李廷荣,李贵.芥菜类蔬菜产业发展现状及思考[J].云南农业,2019(7):39-40.[7]刘忠松,游亮,杨柳,等.芥菜的起源与驯化探索[J].中国油料作物学报,2018,40(5):649-655.[8]汤青林,宋明,王小佳,等.温光诱导芥菜和甘蓝抽薹的生化变化研究[J].西南大学学报(自然科学版),2009,31(4):52-57.[9]王真真,朱玉英.芸薹属蔬菜抽薹性研究进展[J].上海农业学报,2011,27(4):125-128.[10]常缨,戴建军,马凤鸣.温光诱导甜菜当年抽薹过程中过氧化物酶的研究[J].中国甜菜糖业,2002(2):3-5.[11]TAKADA N,WAKITA E,YAMAZAKI E,et al.Methyl 3-iso-cucurbate a potential bolting inhibitor to Brassica rapa[J].Tetrahedron,2013,69(26):5426-5430.[12]YUKO Y,NOBORU T,YASUNORI K.Isolation and identification of an anti-bolting compound,hexadecatrienoic acid monoglyceride,responsible for inhibition of bolting and maintenance of the leaf rosette in radish plants[J].Plant & Cell Physiology,2010,51(8):1341-1349.[13]汪精磊,李锡香,邱杨,等.十字花科蔬菜抽薹开花性状的调控机理和分子育种研究进展[J].植物遗传资源学报,2015,16(6):1283-1289.[14]李合生.植物生理生化实验原理和技术[M].北京:高等教育出版社,2000.[15]杨小明,李成琼,宋洪元,等.春甘蓝花芽分化至抽薹过程中生理生化指标的变化[J].中国蔬菜,2009(24):19-23.[16]杜鲜云,程继鸿,杨瑞,等.春化处理对‘北农1号’萝卜碳水化合物含量及相关酶活性的影响[J].中国农业科学,2011,44(11):2303-2309.[17]HUYSTEE R B V,CAIRNS W L.Progress and prospects in the use of peroxidase to study cell development[J].Phytochemistry,1982,21(8):1843-1847.[18]田山君,严希,孟繁博,等.萝卜抽薹特性的鉴定及抽薹前后生理生化特性的变化[J].北方园艺,2017(12):1-5.[19]胡瑶.植物生长调节剂对芥菜的抽薹效应研究[D].重庆:西南大学,2008.[20]任慧女.不同抽薹性萝卜春化及抽薹前后生理生化指标的研究[D].咸阳:西北农林科技大学,2019.[21]CHEN C,HUANG W,HOU K,et al.Bolting,an important process in plant development,two types in plants[J].Journal of Plant Biology,2019,62(3):161-169.[22]张素君,邱杨,宋江萍,等.萝卜种质资源耐抽薹性鉴定评价[J].植物遗传资源学报,2014,15(2):262-269.[23]梁乃国.温光诱导下甜菜抽薹和开花相关分子机制研究[D].哈尔滨:哈尔滨工业大学,2018.[24]LIU X Y,LIU R,HUANG Q,et al.Effects of morphological characterization in different bolting period of lettuce[C].Zhuhai:International Conference on Biological Sciences & Technology,2018.[25]李梅,刘玉梅,方智远,等.结球甘蓝自交系抽薹与开花性状配合力及遗传力分析[J].华北农学报,2009,24(5):86-89.[26]杨勇.不同耐抽薹性大白菜春化及抽薹前后生理特性的变化[D].天津:天津大学,2007.[27]马关鹏,赵大芹,潘业勤,等.2个生理指标与大白菜耐抽薹性相关性初探[J].种子,2019,38(4):51-55.[28]王帅,王海波,王孝娣,等.施硒和6-BA对葡萄叶片衰老与活性氧代谢的影响[J].果树学报,2015,32(2):206-214.[29]王虹,姜玉萍,师恺,等.光质对黄瓜叶片衰老与抗氧化酶系统的影响[J].中国农业科学,2010,43(3):529-534.[30]杨小飞,郭房庆.高温逆境下植物叶片衰老机理研究进展[J].植物生理学报,2014,50(9):1285-1292.

Memo

Memo:
-
Last Update: 2021-01-14