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草业学报 ›› 2019, Vol. 28 ›› Issue (10): 187-198.DOI: 10.11686/cyxb2018739

• 研究论文 • 上一篇    下一篇

紫花苜蓿MsMBF1c基因在拟南芥中表达提高转基因植株的耐热性

李小冬1,2, 尚以顺1,*, 武语迪3, 王学敏3, 熊先勤1, 陈光吉1,2, 孙方1, 张文1, 蔡一鸣1,*   

  1. 1.贵州省农业科学院草业研究所, 贵州 贵阳 550006;
    2.贵州鼎芯农牧科技有限责任公司,贵州 贵阳 550006;
    3.中国农业科学院北京畜牧兽医研究所,北京 100000
  • 收稿日期:2018-11-12 修回日期:2019-01-08 出版日期:2019-10-20 发布日期:2019-10-20
  • 通讯作者: E-mail: 2892486467@qq.com,caiyiming2000@tom.com
  • 作者简介:李小冬(1984-),男,湖南邵阳人,副研究员,博士。E-mail: lixiaodongzl@163.com
  • 基金资助:
    MsMBF1c基因在紫花苜蓿响应热胁迫中的分子机理(国家自然科学科学基金31960345),贵州省农科院专项基金[黔农科院院专项(2013)03],贵州省科学技术基金[黔科合J字(2015)2080号],贵州省科研机构服务企业项目[黔科合服企(2018)4001号]贵州省科技计划项目[黔科合平台人才(2017)5210-1号]和贵州省科技重大专项[黔科合重大专项字(2014)6017号]资助

Overexpression of Medicago sativa Multi protein Bridging Factor 1c (MsMBF1c) enhances thermotolerance of Arabidopsis

LI Xiao-dong1,2, SHANG Yi-shun1,*, WU Yu-di3, WANG Xue-min3, XIONG Xian-qin1, CHEN Guang-ji1,2, SUN Fang1, ZHANG Wen1, CAI Yi-ming1,*   

  1. 1.Guizhou Academy of Agriculture Science, Guizhou Institute of Prataculture, Guiyang 550006, China;
    2.Guizhou Ding-xin Agriculture and Animal Husbandry Technology co. LTD, Guiyang 550006, China;
    3.Chinese Academy of Agricultural Sciences, Beijing Academy of Animal Husbandry and Veterinary Sciences, Beijing 10000, China
  • Received:2018-11-12 Revised:2019-01-08 Online:2019-10-20 Published:2019-10-20
  • Contact: E-mail: 2892486467@qq.com,caiyiming2000@tom.com

摘要: 高温能危害植物的生长发育,是限制紫花苜蓿在南方地区推广的主要非生物胁迫因素之一。从“中苜1号”紫花苜蓿品种克隆获得紫花苜蓿多桥蛋白1c(Medicago sativa Multi protein Bridging Factors 1c, MsMBF1c)全长编码序列,发现紫花苜蓿MsMBF1c蛋白与拟南芥AtMBF1c蛋白同源相似性高达72%。分析MsMBF1c在根、茎、叶、花和果实等不同组织中,以及在高温、干旱以及高温和干旱组合胁迫条件下的表达模式,发现该基因在不同组织中的表达强度依次为花>根>叶>茎>果实;MsMBF1c显著受高温、干旱以及高温和干旱组合诱导,分别被上调4.21、2.15和4.59倍。构建pBI121-35S: MsMBF1c过量表达载体并转入模式植物拟南芥(wild type, WT),在T3代获得卡那抗性不分离的过量表达株系(over expression, OE);利用OE与Atmbf1c突变体(mutant, MUT)杂交的方法获得互补株系(complementary, COM),并通过PCR与qRT-PCR的方法进行分子和表达验证。平行比较OE、COM、MUT以及WT等不同拟南芥株系在高温胁迫后的种子发芽率和幼苗存活率,在正常情况下,OE、COM、MUT以及WT拟南芥株系种子的发芽率没有显著差异(97.6%~100.0%),高温胁迫后,WT发芽率下降到71.7%,MUT发芽率下降到66.0%,显著低于WT(P<0.05);而COM与3个独立的OE株系的发芽率达79.3%~87.0%,显著高于WT(P<0.05)。在幼苗耐热试验中,OE、COM、MUT以及WT株系的存活率在正常条件下差异不显著,高温胁迫后,WT幼苗存活率下降到16.7%,MUT下降到10.0%,显著低于WT(P<0.05);而COM与3个独立的OE株系存活率下降到40.0%~76.7%,显著高于WT(P<0.05)。利用real-time PCR方法,分析HSFA1aHSFA2、HSFA3、HSFB1、WRKY25、WRKY18、DREB2a等耐热调节关键基因在OE、MUT和WT拟南芥株系的相对表达情况,在正常条件下,HSFA2、WRKY18与DREB2a在MUT株系中的表达显著低于WT(0.33~0.47)。而在OE株系中,除HSFA1a外,HSFA2、HSFA3、HSFB1、WRKY25、WRKY18、DREB2a的表达相对WT株系都有不同程度上调,幅度为1.74~3.80。高温胁迫后,与WT相比,HSFA2、HSFA3、HSFB1、WRKY18与DREB2a在MUT株系中的表达中被显著下调,在OE株系中,只有WRKY18显著高于WT外,其余基因的表达在OE与WT株系中差异不显著。综合分析,MsMBF1c是一个功能比较保守的耐热调节基因,过量表达MsMBF1c能够互补拟南芥mbf1c突变体耐热缺失表型,并能够增强拟南芥在种子萌发与幼苗生长阶段的耐热性。MsMBF1c可能与AtMBF1c一样,与其他耐热调节关键基因互作调节植物耐热性。

关键词: 高温, MBF1c, 紫花苜蓿, 耐热性, 耐热相关基因

Abstract: High temperature negatively affects plant growth and development, and is one of the major abiotic stress factors limiting the growth of alfalfa (Medicago sativa) in southern China. The full-length coding sequence of the gene encoding Multi protein Bridging Factor 1c (MsMBF1c) was isolated from the alfalfa variety “Zhongmu 1”. The MsMBF1c protein in alfalfa was found to be homologous to AtMBF1c in Arabidopsis thaliana, with 72% similarity at the amino acid sequence level. The transcript levels of AtMBF1c were measured in the root, stem, leaf, flowers, and fruit; and changes in transcript levels were monitored under high temperature, drought, and the combination of these stress conditions. The highest transcript level of MsMBF1c was detected in the flowers, followed by the root, leaf, stem, and fruit. MsMBF1c was induced by high temperature, drought, and their combination (up-regulated by 4.21, 2.15, and 4.59 fold, respectively). The pBI121-35S:MsMBF1c overexpression vector was constructed and transformed into wild-type (WT) Arabidopsis seedlings. Overexpression (OE) lines without the separation of kanamycin resistance were obtained in the T3 generation. The OE lines were then crossed with the mbf1c mutant (MUT) to generate complementary lines (COM). The presence of the transgene in the plant materials was confirmed by PCR, and the transcript levels of AtMBF1c and MsMBF1c were determined by qRT-PCR. To evaluate the heat resistance conferred by MsMBF1c, the seed germination rates and seedling survival rates were determined for the OE, COM, MUT, and WT Arabidopsis lines. The seed germination rates differed slightly among the OE, COM, MUT, and WT lines (97.6%-100.0%) under normal conditions (P>0.05). After a heat stress treatment, the germination rate of WT decreased to 71.7%; that of the MUT line decreased to 66.0%, significantly lower than that of WT (P<0.05); and those of three individual OE lines and the COM line decreased to 79.3%-87.0%, significantly higher than that of WT (P<0.05). The seedling survival rate did not differ significantly among the OE, COM, MUT, and WT lines under normal conditions. However, after a heat stress treatment, the survival rate of WT decreased to 16.7%; that of MUT decreased to 10.0%, significantly lower than that of WT (P<0.05); and those of three individual OE lines and the COM line decreased to 40.0%-76.7%, which were significantly higher than that of WT (P<0.05). The expression levels of genes encoding key regulators, including HSFA1a, HSFA2, HSFA3, HSFB1, WRKY25, WRKY18 and DREB2a were analyzed in the OE, MUT, and WT lines by real-time PCR. Under normal conditions, the transcript levels of HSFA2, WRKY18, and DREB2a were low in the MUT line (0.33-0.47 of that in WT); while the transcript levels of HSFA2, HSFA3, HSFB1, WRKY25, WRKY18 and DREB2a in the OE lines were 1.74 to 3.80 fold their respective levels in WT. After heat stress, compared with WT, the MUT line showed significantly decreased transcript levels of HSFA2, HSFA3, HSFB1, WRKY18, and DREB2a, and the OE lines showed increased transcript levels of WRKY18 but none of the other tested genes. In conclusion, MsMBF1c is a functional conserved gene in the heat regulation pathway. Overexpression of MsMBF1c can complement the thermotolerance deficiency of the mbf1c mutant, and also enhance the thermotolerance of Arabidopsis at the seed germination and young seedling stages. The function of MsMBF1c may be similar to that of AtMBF1c, which regulates plant thermotolerance with other key heat resistance genes.

Key words: high temperature, MBF1c, alfalfa, thermotolerance, heat resistant gene