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茉莉JsMYB108和JsMYB305转录因子对萜烯合成酶基因TPS启动子的调控研究

张月 胡莉 万超 胡双玲 尹秦婠 袁媛

张月,胡莉,万超,等. 茉莉JsMYB108和JsMYB305转录因子对萜烯合成酶基因TPS启动子的调控研究 [J]. 福建农业学报,2024,39(8):927−937 doi: 10.19303/j.issn.1008-0384.2024.08.006
引用本文: 张月,胡莉,万超,等. 茉莉JsMYB108和JsMYB305转录因子对萜烯合成酶基因TPS启动子的调控研究 [J]. 福建农业学报,2024,39(8):927−937 doi: 10.19303/j.issn.1008-0384.2024.08.006
ZHANG Y, HU L, WAN C, et al. Regulating JsTPS Promoters by JsMYB108 and JsMYB305 in Jasminum sambac [J]. Fujian Journal of Agricultural Sciences,2024,39(8):927−937 doi: 10.19303/j.issn.1008-0384.2024.08.006
Citation: ZHANG Y, HU L, WAN C, et al. Regulating JsTPS Promoters by JsMYB108 and JsMYB305 in Jasminum sambac [J]. Fujian Journal of Agricultural Sciences,2024,39(8):927−937 doi: 10.19303/j.issn.1008-0384.2024.08.006

茉莉JsMYB108和JsMYB305转录因子对萜烯合成酶基因TPS启动子的调控研究

doi: 10.19303/j.issn.1008-0384.2024.08.006
基金项目: 国家自然科学基金项目(31902050);福建省自然科学基金项目(2022J01588);福建农林大学科技创新专项基金(KFB23033)
详细信息
    作者简介:

    张月(1995 —),女,硕士,主要从事观赏园艺植物分子生物学研究,E-mail:1607906441@qq.com

    通讯作者:

    袁媛(1988 —),女,博士,讲师,主要从事观赏植物花色及香气代谢研究,E-mail: yuanyuan@fafu.edu.cn

  • 中图分类号: S685.16

Regulating JsTPS Promoters by JsMYB108 and JsMYB305 in Jasminum sambac

  • 摘要:   目的  探明茉莉香气合成相关转录因子JsMYB108和JsMYB305对3个萜烯合成酶基因JsTPS启动子的调控机制。  方法  以茉莉叶片DNA为模板,采用染色体步移法克隆3个JsTPS基因的启动子片段,预测启动子序列顺式作用元件,并在此基础上将3个JsTPS基因启动子片段分别构建到报告载体pGWB433,单独转化烟草叶片或与pK7FWG2.0-JsMYB108、pK7FWG2.0-JsMYB305效应载体共同转化烟草叶片以检测JsMYB108和JsMYB305对3个TPS基因启动子的激活作用;同时,通过酵母单杂交实验进一步检验JsMYB108和JsMYB305与3个TPS基因启动子的结合作用。  结果  克隆了3个JsTPS基因启动子片段,长度分别为 1 357、1 849、1 005 bp。这些序列中均含MYB识别位点,不同启动子序列包含不同顺式作用元件,如光反应元件、损伤响应元件、脱落酸诱导顺式作用元件等;叶片GUS染色和GUS活性检测结果显示3个JsTPS基因启动子片段均具有启动活性且JsMYB108和JsMYB305能不同程度地激活3个TPS基因启动子活性。JsMYB108使JsTPS1JsTPS3、JsTPS4启动子活性增强至对照的1.96倍、6.47倍和4.15倍;JsMYB305使JsTPS1JsTPS3、JsTPS4启动子活性增强至对照的1.57倍、15.18倍和3.12倍;酵母单杂交结果显示JsMYB108和JsMYB305能与JsTPS1、JsTPS3和JsTPS4启动子结合。  结论  JsMYB108和JsMYB305可以不同程度激活JsTPS基因启动子活性,推测这2个转录因子在茉莉花萜烯香气合成和代谢过程具有一定作用。
  • 图  1  JsMYB108和JsMYB305转录因子与3个JsTPS基因启动子共同转化烟草后的GUS组织化学染色结果

    A:阴性对照;B:阳性对照;C:单独注射proJsTPS1::GUS;D:proJsTPS1::GUS+35S::JsMYB108共同注射;E:proJsTPS1::GUS+35S::JsMYB305共同注射;F:单独注射proJsTPS3::GUS;G:proJsTPS3::GUS+35S::JsMYB108共同注射;H:proJsTPS3::GUS+35S::JsMYB305共同注射;I:单独注射proJsTPS4::GUS;J:proJsTPS4::GUS+35S::JsMYB108共同注射;K:proJsTPS4::GUS+35S::JsMYB305共同注射。图中标尺为1 mm。

    Figure  1.  GUS histochemical staining on tobacco transformed with two JsMYB transcription factors and three JsTPS promoters

    A: negative control; B: positive control; C: single injection of proJsTPS1::GUS; D: co-injection of proJsTPS1::GUS+35S::JsMYB108; E: co-injection of proJsTPS1::GUS+35S::JsMYB305; F: single injection of proJsTPS3::GUS; G: co-injection of proJsTPS3::GUS+35S::JsMYB108; H: co-injection of proJsTPS3 ::GUS+35S::JsMYB305; I: single injection of proJsTPS4::GUS; J: co-injection of proJsTPS4::GUS+35S::JsMYB108; K: co-injection of proJsTPS4::GUS+35S::JsMYB305. Scale bar = 1 mm.

    图  2  瞬时转化烟草叶片中GUS活性检测

    图中“*”表示处理与对照相比有显著差异(P<0.05)。

    Figure  2.  GUS quantitative detection of gene expression

    * indicates significant differences with control at P<0.05.

    图  3  Y1H[proJsTPSs-pAbAi] 诱饵菌株最低AbA抑制浓度筛选

    Figure  3.  Screening for lowest AbA inhibitory concentration of Y1H [proJsTPSs-pAbAi] bait strain

    图  4  酵母单杂验证JsMYB108和JsMYB305与JsTPS启动子的互作

    Figure  4.  Yeast one-hybrid verification on interaction between JsMYBs and JsTPS promoters

    表  1  引物序列

    Table  1.   Sequences of primers applied

    引物名称
    Primer name
    引物序列(5′- 3′)
    Primer sequences (5′- 3′)
    用途
    Usage
    JsTPS1DNA-FATGGGCAGCCAAGTTTATGCATC扩增 DNA 序列
    DNA amplification
    JsTPS1DNA-RGAGATAGGGTTGTGGAACGCTA
    JsTPS1-GW-GSP1ATTGTGCGAAGGTCCTCGTTTTGCTTGTAA扩增启动子序列
    Promoter sequence amplification
    JsTPS1-GW-GSP2GTTACGGAGCGTCGAGCAACTTCAATGC
    JsTPS1-PRO-FTTTCATAGGGAAATTGGTGC验证启动子序列
    JsTPS1-PRO-RTTATATCTAATCAAATGCTTCTAGCConfirming promoter sequence
    JsTPS3-PRO-FATGACAAGGTATTAATGCTTGGCG
    JsTPS3-PRO-RTCTTGATATGTATTACTAGTAATTTAACAAC
    JsTPS4-PRO-FGTGATATTGATTCCAAATCTGGTC
    JsTPS4-PRO-RGATAACAAGTAAAACGGAAAATCAGG
    pAbAi-proJsTPS1-FAATTCGAGCTCGGTACCCGGGCACATTCAAGCTTGAAATACCGG扩增酵母单杂启动子片段
    pAbAi-proJsTPS1-RATACAGAGCACATGCCTCGAGCAAGCGCATGTAAACGCTAGACAmplification of promoter sequence
    for yeast one hybrid
    pAbAi-proJsTPS3-FAATTCGAGCTCGGTACCCGGGTGCATTTGGATGTAACATTAAAATCA
    pAbAi-proJsTPS3-RATACAGAGCACAATGCCTCGAGGTCACATCATGGTTGTGACGAACA
    pAbAi-proJsTPS4-FAATTCGAGCTCGGTACCCGGGGCCGCCATAAGAAAATTCGG
    pAbAi-proJsTPS4-RATACAGAGCACATGCCTCGAGGCTCGTGTACTACATATCGTTTATTAATTAC
    pAbAi-FGTTCCTTATATGTAGCTTTCGACA验证上游片段-pAbAi
    pAbAi-RCCATCTCGAAAAAGGGTTTGCCConfirming cloning sequence in –pABAi vector
    pGADT7-JsMYB108-FgtaccagattacgctcatatgATGGAGCATCATGTTAAAGGAGATG构建pGADT7-JsMYBs
    Construction of pGADT7-JsMYBs vectors
    pGADT7-JsMYB108-RcagctcgagctcgatggatccCTACTGTTGTAGGAAATTCCACATGTC
    pGADT7-JsMYB305-FgtaccagattacgctcatatgATGGACAAGAAAATATGCAATAGCTC
    pGADT7-JsMYB305-RcagctcgagctcgatggatccTTAATCCCCATTAAGTAACTGGATGG
    pGADT7-FTAATACGACTCACTATAGGG验证pGADT7-JsMYBs
    pGADT7-RAGATGGTGCACGATGCACAGConfirming the construction of
    pGADT7-JsMYBs vectors
    下载: 导出CSV

    表  2  茉莉JsTPS1JsTPS3JsTPS4启动子序列中顺式作用元件预测

    Table  2.   Predicted cis-acting elements in JsTPS1, JsTPS3, and JsTPS4 promoters

    顺式元件
    Cis-element
    序列
    Sequence
    位置 Position
    JsTPS1 JsTPS3 JsTPS4
    G-Box
    参与光响应的顺式作用调节
    CACGTT +1157 1555 −846, −725
    AuxRR-core
    参与生长素的顺式作用调节元件
    GGTCCAT +345
    ACE
    参与光响应的顺式作用元件
    GACACGTATG −616 +503
    TGACG-motif
    茉莉酮酸甲酯反应性中涉及的顺式作用调节元件
    TGACG −261 −561,+1676,+863,
    1660,+1254
    MBSI
    MYB结合位点参与类黄酮生物合成基因的调控元件
    aaaAaaC(G/C)GTTA 1318
    I-box
    光响应元件的一部分
    cCATATCCAAT −173
    TGA-element
    生长素反应元件
    AACGAC −153 1148
    Box 4
    涉及光响应性的保守 DNA 模板的一部分
    ATTAAT +136,−1146,+449,
    +413,+488
    +11,−1246,−1083,+1711,
    +869,+885,−1038,−1707
    +188,+163
    GC-motif
    参与缺氧特异性诱导的调控
    CCCCCG +1797, −145 −854,+172,−63
    ARE
    厌氧诱导必不可少的顺式作用元件
    AAACCA +374, −768
    CCAAT-box
    MYBHv1结合位点
    CAACGG −402 +894
    CGTCA-motif
    茉莉酮酸甲酯反应性中涉及的顺式作用调节元件
    CGTCA +261 1676, +561, −863
    +1660, −1254
    GATA-motif
    光响应元件的一部分
    GATAGGA −582 −566
    TATA-box
    转录启动子周围−30个核心启动子元件
    TATA +40,−1555,
    +82,+1556
    +726,+847,−434
    ABRE
    脱落酸反应性涉及的顺式作用元件
    ACGTG/TACGTGTC +213, −1157 +619,
    +618,+1130
    A-box
    顺式作用调节元件
    CCGTCC −46,−984
    TATC-box
    参与赤霉素反应的顺式作用元件
    TATCCCA −618
    GT1-motif
    光响应元件
    GGTTAA +58,−149,+100
    TCA-element
    水杨酸反应性涉及的顺式作用元件
    CCATCTTTTT 1148
    Sp1
    光响应元件
    GGGCGG −350
    GARE-motif
    赤霉素反应元件
    TCTGTTG +1813
    TGA-box
    生长素反应元件的一部分
    TGACGTAA +1254
    3-AF1binding site
    光响应元件
    TAAGAGAGGAA +1092
    AT1-motif
    光响应模板的一部分
    AATTATTTTTTATT −252
    TCT-motif
    光响应元件的一部分
    TCTTAC −926
    AE-box
    光响应模块的一部分
    AGAAACTT −150
    AT-rich element
    富含AT的DNA结合蛋白的结合位点
    ATAGAAATCAA +282
    O2-site
    玉米醇溶蛋白代谢调控中涉及的顺式调控元件
    GATGA(C/T)(A/G)TG(A/G) −657
    ABRE3a
    参与脱落酸反应的顺式作用元件
    TACGTG +212,+618 +39
    G-box
    参与光响应的顺式作用调节
    TACGTG +212,+618,+1129,+1157 +39,−81,−1555
    MYB
    MYB结构域
    CAACCA +1295 −99,−1814,+1665 −447
    MYB recognition site
    MYB识别位点
    CCGTTG
    +402 −894
    MYC
    干旱诱导相关的顺式作用元件
    CATTTG −228,−1170,+663 −207, −482,
    +457,+1334
    +986
    WUN-motif
    损伤响应元件
    AAATTTCTT +1253
    as−1
    水杨酸诱导型调控元件
    TGACG
    −261 +1822,−561,
    +1676,+1254
    Myb-binding site
    MYB结合位点
    CAACAG +863,−1660
    W box
    诱导子、受伤及病原体应答,结合 WRKY类转录因子
    TTGACC −1814 +858,+130
    WRE3
    顺式作用元件
    CCACCT +379
    WUN-motif
    损伤响应元件
    CAATTACAT −192
    下载: 导出CSV
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出版历程
  • 收稿日期:  2024-05-08
  • 修回日期:  2024-08-01
  • 网络出版日期:  2024-11-13
  • 刊出日期:  2024-08-28

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