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作物学报 ›› 2024, Vol. 50 ›› Issue (11): 2720-2730.doi: 10.3724/SP.J.1006.2024.44019

• 作物遗传育种·种质资源·分子遗传学 • 上一篇    下一篇

MeTCP3a转录因子在木薯叶片发育中的功能鉴定

王连南1(), 李远超3, 余乃通2, 麦伟涛1, 李亚军2,*(), 陈新2,*()   

  1. 1海南大学热带农林学院, 海南海口 570228
    2中国热带农业科学院热带生物技术研究所, 海南海口 571101
    3广西大学生命科学与技术与学院, 广西南宁 530004
  • 收稿日期:2024-01-31 接受日期:2024-06-20 出版日期:2024-11-12 网络出版日期:2024-07-11
  • 通讯作者: *李亚军, E-mail: liyajun@itbb.org.cn; 陈新, E-mail: chenxin@itbb.org.cn
  • 作者简介:E-mail: 1636794739@qq.com
  • 基金资助:
    中国热带农业科学院国家热带农业科学中心科技创新团队(CATASCXTD202301);财政部和农业农村部国家现代农业产业技术体系建设专项(木薯, CARS11-HNCX)

Functional identification of MeTCP3a transcription factor in cassava leaf development

WANG Lian-Nan1(), LI Yuan-Chao3, YU Nai-Tong2, MAI Wei-Tao1, LI Ya-Jun2,*(), CHEN Xin2,*()   

  1. 1College of Tropical Agriculture and Forestry, Hainan University, Haikou 570228, Hainan, China
    2Institute of Tropical Bioscience and Biotechnology, Chinese Academy of Tropical Agricultural Sciences, Haikou 571101, Hainan, China
    3College of Life Science and Technology, Guangxi University, Nanning 530004, Guangxi, China
  • Received:2024-01-31 Accepted:2024-06-20 Published:2024-11-12 Published online:2024-07-11
  • Contact: *E-mail: liyajun@itbb.org.cn; E-mail: chenxin@itbb.org.cn
  • Supported by:
    Chinese Academy of Tropical Agricultural Sciences for Science and Technology Innovation Team of National Tropical Agricultural Science Center(CATASCXTD202301);China Agriculture Research System of MOF and MARA (Cassava, CARS11-HNCX)

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摘要:

叶片是绿色植物进行光合作用的主要器官, 木薯叶片的发育间接影响其块根产量以及淀粉含量, 但木薯叶片发育的调控机制并不明晰, 本文探究了转录因子MeTCP3a在木薯叶片发育中的功能。氨基酸序列比对及进化树分析表明, MeTCP3a与橡胶(Hevea brasiliensis Muell. Arg) TCP4蛋白相似性最高。通过亚细胞定位和蛋白互作试验证实, MeTCP3a定位于细胞核, 且具有转录激活能力, 还能形成同源及异源二聚体, 表明其具备转录因子特性。此外, 不同组织部位表达分析发现, MeTCP3a在成熟叶片中表达活性最高, 而通过VIGS技术在木薯叶片中将其沉默后, 发现木薯心叶形态出现卷曲、皱缩。进一步实时荧光定量PCR分析发现, 与叶片形态发育相关的下游基因MeCUC1/2/3MeIAA的表达量也随之下调, 表明MeTCP3a可能通过调控下游基因的表达来影响叶片形态发育。本文为进一步探索TCP类转录因子在木薯叶片生长发育中的调控机制提供了理论依据。

关键词: 木薯, 叶片发育, MeTCP3a, 蛋白互作, VIGS

Abstract:

Leaves are the primary organs of photosynthesis in green plants, and their development indirectly affects the yield and starch content of cassava storage roots. However, the regulatory mechanisms governing cassava leaf development remain unclear. In this study, we explored the function of the MeTCP3a transcription factor in cassava leaf development. Amino acid sequence alignment and phylogenetic analysis showed that MeTCP3a was closely related to the TCP4 protein in rubber (Hevea brasiliensis Muell. Arg.). Subcellular localization and protein interaction assays demonstrated that MeTCP3a was localized in the nucleus, possessed transcriptional activation ability, and could form both homodimers and heterodimers in the nucleus, indicating its properties as a transcription factor. Expression analysis showed that the relative expression level of MeTCP3a was significantly higher in mature leaves compared to other tissues. When MeTCP3a expression was suppressed using VIGS (virus-induced gene silencing) technology, cassava heart leaves exhibited curled edges and a wrinkled appearance. Further real-time quantitative PCR analysis revealed that the expression levels of downstream genes related to leaf morphological development, such as MeCUC1/2/3 and MeIAA, were also down-regulated. This result suggested that MeTCP3a might influence leaf morphological development by regulating the expression of these downstream genes. This study provides a theoretical basis for further exploring the regulatory mechanisms of TCP-like transcription factors associated with leaf growth and development in cassava.

Key words: cassava, leaf development, MeTCP3a, protein interaction, VIGS

表1

本研究所用引物"

基因名称
Gene name		 上游引物
Forward primer (5'-3')		 下游引物
Reverse primer (5'-3')
MeTCP3a-pG1300-GFP GTTGATACATATGCCCGTCGACATGAAAGGAGCTGGAGGAG GTGGTGGAGCTCGGATCCGGTACCAGGAGTGGAGGAGGATGG
MeTCP3a-pGADT7 ATGATCGATGAATTCGTCGACATGAAAGGAGCTGGAGGAG CATCTGCAGCTCGATGGATCCAGGAGTGGAGGAGGATGG
MeTCP3a-pGBKT7 AGGACCTGCATATGATCGATATGAAAGGAGCTGGAGGAG TAGTTATGCGGCCGCTGCATAGGAGTGGAGGAGGATGG
MeTCP3a-BiFC AGTGGTCTCTGTCCAGTCCTATGAAAGGAGCTGGAGGAG GGTCTCAGCAGACCACAAGTAGGAGTGGAGGAGGATGG
MeTCP3a-nLUC GGACGAGCTCGGTACCCGGGATCCATGAAAGGAGCTGGAGGAG CCACGCGTACGAGATCTGGTCGACAGGAGTGGAGGAGGATGG
MeTCP3a-cLUC CCCGGGGCGGTACCCGGGATCCATGAAAGGAGCTGGAGGAG AACGAAAGCTCTGCAGGTCGACAGGAGTGGAGGAGGATGG
MeTCP3a-pCsCMV AGTGGTCTCTGTCCAGTCCTGTATAGTTTTCAGCTCCACAG GGTCTCAGCAGACCACAAGTATTGAAGCTGAGCCTGCAAA
qMeActin TCTTCTCAACTGAGGAGCTGCT CCTTCGTCTGGACCTTGCTG
qCP TTGTAGCTGCCGTCCTAACTTGG ACCAAATTGGAGGCTGGCTTCA
qMeTCP3a TGCCACAGCCACAATCAATG CCTCTGTTGCAAACCTGCTG
qMeCUC1 CTGCTGAGTTCCCTAGTCTTCC GCAATCTTGATGCGAGACGG
qMeCUC2 TCTCAACCTCATGTACTGTCTGG TCTGTCTTGCACTGTTTGGGA
qMeCUC3 TACCTCCTGGCTTTAGGTTTCAC GGCTCTATTAGTTCTCAGCCCA
qMeIAA CAAGACTGCTGTGCTGGAGA TTGTTGGGTTAGGTCGAAGGAA

图1

MeTCP3a蛋白与其他植物中同源蛋白的序列比对(A)及进化树分析(B) 图A中用红色、蓝色、黄色和绿色方框标示的为bHLH结构域。图B中的标尺代表遗传相似性。"

图2

MeTCP3a蛋白的亚细胞定位和转录激活能力检测 A: MeTCP3a蛋白在烟草中的亚细胞定位, 标尺为30 μm; B: 酵母中MeTCP3a的转录激活能力检测。"

图3

酵母双杂交、LCI和BiFC三种技术验证蛋白互作 A: 酵母双杂交试验中MeTCP3a自身能形成同源二聚体; B: LCI试验中MeTCP3a能形成同源二聚体; C: BiFC分析显示MeTCP3a能够在细胞核中形成同源和异源二聚体。标尺为30 μm。"

图4

MeTCP3a在木薯SC8的根、茎、叶、腋芽等不同组织部位表达分析 R: 块根; Tl: 嫩叶; Ts: 嫩茎; Tsc: 嫩茎皮层; Ml: 成熟叶; P: 叶柄; Lb: 腋芽; S: 茎; Sc: 茎皮层; Sx: 茎中柱。不同小写字母表示差异显著(P < 0.05)。"

图5

基因沉默植株中病毒积累量和MeTCP3a基因表达量检测及表型鉴定 A: MeTCP3a沉默木薯植株(MeTCP3a-VIGS)和对照植株(CsCMV-NC)叶片中的病毒积累量; B: MeTCP3a沉默木薯植株(MeTCP3a- VIGS)叶片中MeTCP3a表达量较对照(CsCMV-NC)降低; C: 接种36 d后, MeTCP3a基因沉默木薯植株和对照植株(CsCMV-NC)新叶的表型。Mock为未接种植株, MeChlI-VIGS为阳性对照。*表示显著相关(P < 0.05), **表示极显著相关(P < 0.01)。"

图6

候选靶基因在CsCMV-NC和MeTCP3a-VIGS植株中的相对表达量 A: 接种7 d后候选靶基因在MeTCP3a沉默木薯植株(MeTCP3a-VIGS)中的表达量; B: 接种36 d后候选靶基因在MeTCP3a沉默木薯植株(MeTCP3a-VIGS)中的表达量。*表示显著相关(P < 0.05), **表示极显著相关(P < 0.01)。"

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