• 中国中文核心期刊
  • 中国科学引文数据库(CSCD)核心库来源期刊
  • 中国科技论文统计源期刊(CJCR)
  • 第二届国家期刊奖提名奖

留言板

尊敬的读者、作者、审稿人, 关于本刊的投稿、审稿、编辑和出版的任何问题, 您可以本页添加留言。我们将尽快给您答复。谢谢您的支持!

姓名
邮箱
手机号码
标题
留言内容
验证码

APETALA1基因启动子的克隆与功能分析

蒋瑶 戚晓利 赵树堂 卢孟柱

downloadPDF
文章导航 > 林业科学研究  > 2013 >  26(5): 578-587
引用本文:
shu
Citation:
shu

APETALA1基因启动子的克隆与功能分析

  • 基金项目:

    林业公益性行业科研专项重点项目"重要乡土树种核心种质评价及高效育种共性技术研究"(201004009)

  • 中图分类号: S718.46

Cloning and Functional Analysis of APETALA1 Promoter

  • 1.

    Research Institute of Forestry, State Key Laboratory of Tree Genetics and Breeding, Chinese Academy of Forestry, Beijing 100091, China

  • CLC number: S718.46

  • 摘要: 为了分析AP1的表达调控模式,本研究克隆了拟南芥花异常株系AFDL的AP1启动子,启动子元件预测结果表明:AP1启动子中含有3个结合MADS调控因子的CArG box(从5'依次编号为CArG1、CArG2、CArG3),通过删减AP1启动子长度以及改变CArG box数量构建了5个GUS表达载体并转化野生型拟南芥。测序结果显示:AFDL的AP1启动子在核苷酸序列上与野生型拟南芥完全一致,这表明AP1在AFDL中的表达显著降低并不是启动子序列突变引起的;转基因植株的GUS表达模式说明了CArG1在花发育早期及后期激活基因的表达,CArG2在整个后期都对基因的表达有抑制作用,而CArG3在花发育初期就能抑制基因的表达,并且在中后期仍然保持了对下游基因的抑制作用,CArG box1、2、3对AP1的表达有显著但非决定性的影响。此外,还推测在AP1启动子0-3 579 bp范围之外存在影响AP1在第4轮花器官表达的调控元件,-3 579 bp至-1 752 bp区域可促进AP1的表达,而AP1启动子-1 759 bp至-1 359 bp区域除CArG2外的其它元件对调节其表达无明显作用。
    Abstract: APETALA1 is an important MADS box gene involved in the regulatory pathway of flowering. The expression of the AP1 decreases dramatically in the Abnormal Flower Development Line (AFDL) of Arabidopsis. AFDL is absent of petals and with a stacked inflorescence meristems. In order to analysis the matically in the Abnormal Flower Development Line (AFDL) of Arabidopsis. AFDL is absent of petals and with a stacked inflorescence meristems. In order to analysis the regulation of the promoter of AP1, the -3 579 bp promoter region of AP1 was cloned from AFDL. The functional element predication indicated that three CArG boxes, the binding sites for the MADS regulator, were located in the promoter (the three boxes were identified by progressive number as CArG1, CArG2, CArG3 form). 5 vectors were constructed with the promoters of AP1 to drive GUS in wild-type, which with different length and number of the CArG boxes. The sequence of AP1 in AFDL was the same as that of wild-type, that indicated that the significant down-regulation of AP1 was not associated with the CArG boxes as well as its sequenced; And the GUS staining of the transformed plants showed that the CArG1 was the binding site for positively acting factor(s) during the early stage and the later stage of the flower development, and the deletion of the CArG2 and the mutations in CArG3 resulted in an increase in the level of reporter gene activity during the early or later floral stages, suggesting that CArG2 and CArG3 are the binding sites for negatively regulators. Therefore the three CArG boxes in the promoter of AP1 are functional on the regulation the AP1 expression rather than determinant expression of AP1. The ectopic GUS expression in the whorl 4 indicated that there were unidentified elements that played a role on the expression specificity outside the 0-3 579 bp upstream of the transcriptional start site. In addition, there may be some elements located in the region from -3 579 bp to -1 752 bp but the region from -1 752 bp to -1 359 bp was nonfunctional on the regulation of AP1 except the CArG2 box.
  • [1]

    Southerton S G, Strauss S H, Olive M R, et al. Eucalyptus has a functional equivalent of the Arabidopsis floral meristem identity gene LEAFY[J]. Plant molecular biology, 1998, 37(6): 897-910
    [2]

    Leseberg C H, Li A, Kang H, et al. MADS-box genes in dioecious aspen I: characterization of PTM1 and PTM2 floral MADS-box genes[J]. Physiology and Molecular Biology of Plants, 2003, 9: 187-196
    [3]

    Kotoda N, Wada M, Kusaba S, et al. Overexpression of MdMADS5, an APETALA1-like gene of apple, causes early flowering in transgenic Arabidopsis[J]. Plant Science, 2002, 162(5): 679-687
    [4]

    Pena L, Martín-Trillo M, Juárez J, et al. Constitutive expression of Arabidopsis LEAFY or APETALA1 genes in citrus reduces their generation time[J]. Nature biotechnology, 2001, 19: 263-267
    [5]

    Coen E S, Carpenter R. The Metamorphosis of Flowers [J]. The Plant Cell, 1993, 5(10):1175-1181
    [6]

    Ahn J H, Miller D, Winter V J, et al. A divergent external loop confers antagonistic activity on floral regulators FT and TFL1[J]. The EMBO Journal, 2006, 25: 605-614
    [7]

    Yu H, Ito T, Wellmer F, et al. Repression of AGAMOUS-LIKE 24 is a crucial step in promoting flower development [J]. Nature Genetics, 2004, 36: 157-161
    [8]

    Bradley D, Ratcliffe O, Vincent C, et al. Inflorescence commitment and architecture in Arabidopsis[J]. Science, 1997, 275(5296): 80-83
    [9]

    Kobayashi Y, Kaya H, Goto K, et al. A pair of related genes with antagonistic roles in mediating flowering signals[J]. Science, 1999, 286(5446): 1960
    [10]

    Mohamed R, Wang C T, Ma C, et al. Populus CEN/TFL1 regulates first onset of flowering, axillary meristem identity and dormancy release in Populus[J]. Plant Journal, 2010, 62(4): 674-688
    [11]

    Parcy F, Nilsson O, Busch M A, et al. A genetic framework for floral patterning[J]. Nature, 1998, 395: 561-566
    [12]

    Sitaraman J, Bui M, Liu Z. LEUNIG HOMOLOG and LEUNIG perform partially redundant functions during Arabidopsis embryo and floral development [J]. Plant Physiology, 2008, 147(2): 672-681
    [13]

    Grandi V, Gregis V, Kater M M. Uncovering genetic and molecular interactions among floral meristem identity genes in Arabidopsis thaliana[J]. The Plant Journal, 2012, 69(5): 881-893
    [14]

    Li D, Liu C, Shen L, et al. A Repressor Complex Governs the Integration of Flowering Signals in Arabidopsis[J]. Developmental Cell, 2008, 15(1): 110-120
    [15]

    Tilly J J, Allen D W, Jack T. The CArG boxes in the promoter of the Arabidopsis floral organ identity gene APETALA3 mediate diverse regulatory effects [J]. Development, 1998, 125: 1647-1657
    [16]

    Liu X, Kim Y J, Müller R, et al. AGAMOUS terminates floral stem cell maintenance in Arabidopsis by directly repressing WUSCHEL through recruitment of Polycomb Group proteins [J]. The Plant Cell, 2011, 23(10): 3654-3670
    [17]

    Qi X L, Jiang Y, Tang F, et al. An Arabidopsis thaliana (Ler) inbred line AFDL exhibiting abnormal flower development mainly caused by reduced AP1 expression[J]. Chinese Science Bulletin, 2011, 56(1): 39-47
    [18] 丁 峰,彭宏祥,罗 聪,等. 荔枝 APETALA1 (AP1) 同源基因 cDNA 全长克隆及其表达研究[J]. 园艺学报,2011,38(12):2373-2380
    [19] 邹冬梅,刘月学,,张志宏,等. 草莓 AP1 同源基因的克隆, 表达及启动子分析[J].中国农业科学,2012,45(10):1972-1981
    [20]

    Murray M G, Thompson W F. Rapid isolation of high molecular weight plant DNA [J]. Nucleic Acids Research, 1980, 8(19): 4321-4326
    [21]

    Higo K, Ugawa Y, Iwamoto M, et al. Plant cis-acting regulatory DNA elements (PLACE) database: 1999 [J]. Nucleic Acids Research, 1999, 27(1): 297-300
    [22]

    Prestridge D S. SIGNAL SCAN: a computer program that scans DNA sequences for eukaryotic transcriptional elements [J]. Computer applications in the biosciences: CABIOS, 1991, 7(2): 203-206
    [23] Clough S J, Bent A F. Flor捡瑬攠牤楩穰愺琠楡漠湳?潭晰?瑩桦敩??爠慭扥楴摨潯灤猠楦獯?映汁潧牲慯汢?档潴浥敲潩瑵業挭?来敤湩敡??偤?呴????学?嵲??乴慩瑯畮爠敯??????????び??㈠??????na[J]. The Plant Journal, 1998, 16(6): 735-743
    [24]

    Cecchetti V, Pomponi M, Altamura M M, et al. Expression of rolB in tobacco flowers affects the coordinated processes of anther dehiscence and style elongation [J]. The Plant Journal, 2004, 38(3): 512-525
    [25]

    Winter K U, Weiser C, Kaufmann K, et al. Evolution of class B floral homeotic proteins: obligate heterodimerization originated from homodimerization[J]. Molecular Biology and Evolution, 2002, 19(5): 587-596
    [26]

    Benlloch R, Kim M C, Sayou C, et al. Integrating long-day flowering signals: a LEAFY binding site is essential for proper photoperiodic activation of APETALA1[J]. The Plant Journal, 2011, 67(6): 1094-1102
    [27]

    Riechmann J L, Krizek B A, Meyerowitz E M. Meyerowitz. Dimerization specificity of Arabidopsis MADS domain homeotic proteins APETALA1, APETALA3, PISTILLATA, and AGAMOUS [J]. Plant Biology, 1996, 93(10): 4793-4798
    [28]

    Pidal B, Yan L, Fu D, et al. The CArG-Box Located Upstream from the Transcriptional Start of Wheat Vernalization Gene VRN1 Is Not Necessary for the Vernalization Response [J]. Journal of Heredity, 2009, 100(3): 355-364
    [29]

    Irish V F. The flowering of Arabidopsis flower development [J]. The Plant Journal, 2010, 61(6): 1014-1028
    [30]

    Smyth D R, Bowman J L, Meyerowitz E M. Early Flower Development in Arabidopsis[J]. The Plant Cell, 1990, 2(8): 755-767
    [31]

    Bohlenius H, Huang T, Charbonnel-Campaa, et al. CO/FT regulatory module controls timing of flowering and seasonal growth cessation in trees [J]. Science, 2006, 312(5776): 1040
    [32]

    Hsu C Y, Liu Y, Luthe D S, et al. Poplar FT2 shortens the juvenile phase and promotes seasonal flowering [J]. The Plant Cell, 2006, 18(8): 1846-1861
    [33]

    Krizek B A, Riechmann J L, Meyerowitz E M. Use of the APETALA1 promoter to assay the in vivo function of chimeric MADS box genes [J]. Sex Plant Report, 1999, 12: 14-26
    [34]

    Mandel M A, Gustafson-Brown C, Savidge B, et al. Molecular chara
  • [1] . 杨树维管组织特异启动子的克隆与启动活性分析. 林业科学研究, 2010, 23(2): 177-183.
    [2] 陈东亮彭镇华高志民 . 毛竹PeAP2基因及其启动子的克隆与表达初步分析. 林业科学研究, 2013, 26(2): 200-206.
    [3] 周琳袁梦齐宇张梦杰王雁 . 牡丹花青素苷合成关键基因PsDFR启动子活性分析. 林业科学研究, 2024, 37(2): 16-26. doi: 10.12403/j.1001-1498.20230270
    [4] 章晶晶郭英华赵树堂卢孟柱 . 杨树PtRRI基因的组织特异性表达模式分析. 林业科学研究, 2018, 31(2): 34-40. doi: 10.13275/j.cnki.lykxyj.2018.02.005
    [5] 赵岩秋周厚君魏凯丽江成宋学勤卢孟柱 . 杨树中Ⅰ类KNOX基因结构、表达与功能分析. 林业科学研究, 2018, 31(4): 118-125. doi: 10.13275/j.cnki.lykxyj.2018.04.017
    [6] 赵学彩郑唐春臧丽娜曲冠证 . 杨树类锌指基因ZFL的功能分析. 林业科学研究, 2013, 26(5): 562-570.
    [7] 邢俊霞臧巧路叶查龙张陈谊程冬霞齐力旺杨玲李万峰 . 日本落叶松瞬时转化体系的优化及初步应用. 林业科学研究, 2024, 37(3): 1-7. doi: 10.12403/j.1001-1498.20230390
    [8] 冯霞孙振元刘建锋彭镇华杜小娟 . 多年生黑麦草核型分析与组织培养再生植株染色体变异研究. 林业科学研究, 2005, 18(3): 321-324.
    [9] 苏文会顾小平马灵飞吴晓丽岳晋军 . 大木竹纤维形态与组织比量的研究. 林业科学研究, 2005, 18(3): 250-254.
    [10] 邵文豪刁松锋董汝湘姜景民岳华峰 . 无患子种实形态及经济性状的地理变异. 林业科学研究, 2013, 26(5): 603-608.
    [11] 刘会超刘孟刚郭丽娟贾文庆 . 农杆菌介导的SeNHX1基因转化月季愈伤组织的研究. 林业科学研究, 2010, 23(4): 617-621.
    [12] 黄少甫王雅琴楼一平肖江华 . 竹子染色体计数初报. 林业科学研究, 1988, 1(1): 109-111.
    [13] 赵治芬王雅琴黄少甫 . 植物染色体计数(五). 林业科学研究, 1990, 3(5): 503-508.
    [14] 李湘阳周坚 . 杉木单染色体的显微分离及体外扩增. 林业科学研究, 2002, 15(6): 746-750.
    [15] 张欣冯颖马涛马艳丁伟峰 . 五种双翅目昆虫细胞系染色体分析. 林业科学研究, 2007, 20(4): 551-555.
    [16] 张欣冯颖丁伟峰马涛马艳 . 7种鳞翅目昆虫细胞系染色体分析. 林业科学研究, 2008, 21(4): 493-499.
    [17] 徐川梅郑华威王骢汤定钦 . 龟甲竹染色体C-分带、荧光原位杂交及其核型分析. 林业科学研究, 2009, 22(5): 691-695.
    [18] 郭红艳谭新建田丰钟秋平 . 油茶成花启动与春梢生长的关系. 林业科学研究, 2022, 35(3): 123-130. doi: 10.13275/j.cnki.lykxyj.2022.03.014
    [19] 张妍刘瀛孙丰宾戴超刘雪梅 . 白桦APETALA2(AP2)转录因子基因的分离及其表达. 林业科学研究, 2012, 25(2): 254-260.
    [20] 周朝鸿 . 三种百合属植物再生植株的染色体数量变异. 林业科学研究, 1997, 10(6): 663-667.
  • 加载中
WeChat 点击查看大图
计量
  • 文章访问数:  3795
  • HTML全文浏览量:  286
  • PDF下载量:  1239
  • 被引次数: 0
出版历程
  • 收稿日期:  2012-08-24

APETALA1基因启动子的克隆与功能分析

  • 收稿日期: 2012-08-24
基金项目:  林业公益性行业科研专项重点项目"重要乡土树种核心种质评价及高效育种共性技术研究"(201004009)

摘要: 为了分析AP1的表达调控模式,本研究克隆了拟南芥花异常株系AFDL的AP1启动子,启动子元件预测结果表明:AP1启动子中含有3个结合MADS调控因子的CArG box(从5'依次编号为CArG1、CArG2、CArG3),通过删减AP1启动子长度以及改变CArG box数量构建了5个GUS表达载体并转化野生型拟南芥。测序结果显示:AFDL的AP1启动子在核苷酸序列上与野生型拟南芥完全一致,这表明AP1在AFDL中的表达显著降低并不是启动子序列突变引起的;转基因植株的GUS表达模式说明了CArG1在花发育早期及后期激活基因的表达,CArG2在整个后期都对基因的表达有抑制作用,而CArG3在花发育初期就能抑制基因的表达,并且在中后期仍然保持了对下游基因的抑制作用,CArG box1、2、3对AP1的表达有显著但非决定性的影响。此外,还推测在AP1启动子0-3 579 bp范围之外存在影响AP1在第4轮花器官表达的调控元件,-3 579 bp至-1 752 bp区域可促进AP1的表达,而AP1启动子-1 759 bp至-1 359 bp区域除CArG2外的其它元件对调节其表达无明显作用。

English Abstract

    全文HTML

参考文献 (34)

目录

    /

    返回文章
    返回

    京ICP备09064894号-3

    版权所有:《林业科学研究》编辑部

    地址:北京万寿山后中国林科院电话:010-62889680;62889702Email:lykxyj@caf.ac.cn

    本系统由 北京仁和汇智信息技术有限公司 设计开发 技术支持: info@rhhz.net   百度统计