|国家科技期刊平台
首页|期刊导航|农业生物技术学报|大豆GmBAS1基因的鉴定以及对大豆株型结构的影响

大豆GmBAS1基因的鉴定以及对大豆株型结构的影响OACSTPCD

Identification of Soybean(Glycine max)GmBAS1 Gene and Its Effect on Soybean Plant Architecture Structure

中文摘要英文摘要

在改善株高、叶柄夹角、节间长度等大豆(Glycine max)株型结构的前提下,密植是提高大豆产量的主要途径.油菜素内酯(brassinolide,BR)作为第六大植物激素,对于控制水稻(Oryza sativa)的叶柄夹角和拟南芥(Arabidopsis thaliana)的株型结构具有重要作用,在大豆中,油菜素内酯基因研究多与花期有关,而对株型的研究未见报道.细胞色素P450 734A1(CYP734A1/BAS1)基因属于油菜素内酯代谢基因,能够控制水稻叶柄夹角的大小,改善水稻株型.为了探究CYP734A1/BAS1基因对大豆株型的影响,本研究在大豆中同源克隆了CYP734A1/BAS1的2个同源基因GmBAS1a(GenBank No.NC_038253.2)和GmBAS1b(GenBank No.NC_038241.2),进化树分析显示,GmBAS1a和GmBAS1b与拟南芥中同源序列亲缘关系最近,在单子叶植物和双子叶植物中进化方向不同.单倍型分析表明,GmBAS1基因外显子区域自然突变少,该基因在大豆中行使重要功能;启动子预测表明,GmBAS1基因启动子区具有参与光反应和逆境胁迫等多种顺式作用元件,能够参与大豆多个生长发育过程.进一步通过农杆菌(Agrobacterium)介导大豆子叶节转化过表达载体获得BR突变体.过表达GmBAS1a大豆株高降低70%,不同部位叶柄夹角减小10%~50%,节间长度减小55%~82%,而过表达GmBAS1b大豆植株表现出更严重的矮化表型,这2个表型与通常的BR缺陷体表型一致.以上结果表明,过表达GmBAS1a和GmBAS1b能够降低大豆株高和减小叶柄夹角,促使大豆株型紧凑,且GmBAS1b相较于GmBAS1a在BR代谢中发挥更主要的作用,对于株型的影响更大.本结果为BR调控大豆株型作用的研究提供了参考.

Close planting is the main way to increase soybean(Glycine max)yield.The premise is to improve the soybean plant structure such as plant height,petiole angle,and internode length.Brassinolide(BR),as the sixth plant hormone,plays an important role in controlling the petiole angle of rice(Oryza sativa)and the plant structure of Arabidopsis thaliana.In soybean,most of the studies on ester genes are related to the flowering period,but the studies on plant architecture have not been reported.The cytochrome P450 734A1(CYP734A1/BAS1)gene belongs to the brassinosteroid metabolism gene,which can control the size of the petiole angle of rice and improve the plant architecture of rice.In order to explore the influence of the CYP734A1/BAS1 gene on the soybean plant architecture.This study homologously cloned 2 homologous genes GmBAS1a and GmBAS1b of CYP734A1/BAS1 in soybean.Phylogenetic tree analysis showed that the homologous sequence of GmBAS1a(GenBank No.NC_038253.2)and GmBAS1b(GenBank No.NC_038241.2)were the closest related with that of Arabidopsis thaliana,and the evolution direction was different in monocots and dicots.Haplotype analysis showed that there were few natural mutations in the exon region of GmBAS1 gene,and the gene performed important functions in soybean;Promoter prediction showed that the promoter region of GmBAS1 gene had various cis-acting elements involved in light response and adversity stress,and could participate in multiple growth and development processes of soybean.Further,the BR mutants were obtained by Agrobacterium-mediated transformation of soybean cotyledon nodes into overexpression vectors.The plant height of soybean overexpressing GmBAS1a was reduced by 70%,the angle of petiole in different parts was reduced by 10%~50%,and the length of internode was reduced by 55%~82%,while soybean plants overexpressing GmBAS1b showed a more serious dwarf phenotype.These two phenotypes were consistent with the usual BR-deficient phenotypes.The results showed that overexpression of GmBAS1a and GmBAS1b could reduce soybean plant height and petiole angle,and promote soybean plant compactness,and GmBAS1b was more important in BR metabolism than GmBAS1a.GmBAS1b played a more important role and had a greater impact on plant architecture.The results provide a reference for exploring the role of BR in regulating soybean plant architecture.

陈晓睿;王影;邱丽娟;陈庆山

东北农业大学农学院,哈尔滨 150030||中国农业科学院作物科学研究所,北京 100081中国农业科学院作物科学研究所,北京 100081东北农业大学农学院,哈尔滨 150030

农业科学

油菜素内酯大豆株型遗传转化

BrassinolideSoybeanPlant architectureGenetic transformation

《农业生物技术学报》 2024 (001)

26-38 / 13

农业生物育种重大项目(2022ZD0400701)

10.3969/j.issn.1674-7968.2024.01.003

评论