菠萝花发育相关基因AcMADS1的克隆与组织表达特性分析

doi:10.3724/SP.J.1259.2014.00692

植物学报 ›› 2014, Vol. 49 ›› Issue (6): 692-703.DOI: 10.3724/SP.J.1259.2014.00692 cstr: 32102.14.SP.J.1259.2014.00692

菠萝花发育相关基因AcMADS1的克隆与组织表达特性分析

蔡元保¹, 杨祥燕^1*, 孙光明², 黄强¹, 刘业强³, 李绍鹏⁴, 张治礼⁵

¹广西壮族自治区亚热带作物研究所, 南宁 530001;
²中国热带农业科学院南亚热带作物研究所, 湛江 524091
³广西壮族自治区农业科学院园艺研究所, 南宁 530007;
⁴海南大学园艺园林学院, 海口 570228
⁵海南省农业科学院, 海口 571100

收稿日期:2013-05-07 修回日期:2013-11-03 出版日期:2014-11-01 发布日期:2014-11-21
通讯作者: 杨祥燕
基金资助:
公益性行业（农业）科研专项

Cloning of Flowering-related Gene AcMADS1 and Characterization of Expression in Tissues of Pineapple (Ananas comosus)

Yuanbao Cai¹, Xiangyan Yang^1*, Guangming Sun², Qiang Huang¹, Yeqiang Liu³, Shaopeng Li⁴, Zhili Zhang⁵

¹Guangxi Subtropical Crops Research Institute, Nanning 530001, China;

²South Subtropical Crop Research Institute, Chinese Academy of Tropical Agricultural Sciences, Zhanjiang 524091, China;

³Horticultural Research Institute, Guangxi Academy of Agricultural Sciences, Nanning 530007, China;

⁴College of Horticulture and Landscape Architecture, Hainan University, Haikou 570228, China;

⁵Hainan Academy of Agricultural Sciences, Haikou 571100, China

Received:2013-05-07 Revised:2013-11-03 Online:2014-11-01 Published:2014-11-21
Contact: Xiangyan Yang

摘要/Abstract

摘要： MADS-box转录因子在植物的发育过程特别是控制花器官的诱导与发育中起关键作用。利用同源克隆结合RACE技术, 从菠萝(Ananas comosus)花中分离出1个新的菠萝MADS-box基因, 命名为AcMADS1(GenBank登录号为KC257408)。AcMADS1基因的编码区为726 bp, 编码241个氨基酸, 蛋白质分子量为27.50 kDa, 等电点为9.26。序列比对和系统进化树分析表明, AcMADS1具有保守的MADS-box及半保守的K区, 属于AGL6亚家族MADS-box蛋白。生物信息学分析表明, AcMADS1是亲水碱性蛋白, 二级结构主要以α-螺旋、无规则卷曲和折叠延伸链为蛋白质骨架, 三级结构中蛋白核心结构符合转录因子与DNA结合的常见功能域MADS-box, 而且作为转录因子定位于细胞核中。组织特异性表达分析表明, AcMADS1基因在菠萝果肉以及花器官的雌蕊、花瓣和萼片中均有表达, 但在雄蕊以及营养器官的根、茎和叶中几乎不表达; 且在花器官早期发育过程中大量表达, 后期呈下降趋势。因此推测这个基因可能在菠萝花器官发育和开花诱导过程中起重要作用。

关键词: 菠萝, 花发育, MADS-box基因, 克隆, 基因表达

Abstract: MADS-box gene is a key transcription factor that plays crucial roles in plant development, especially controlling the formation and development of floral organs. We cloned the flower-specific gene from floral organs of Ananas comosus, named AcMADS1 (GeneBank accession no. KC257408), was cloned by homology-based cloning and RACE. The open reading frame of AcMADS1 was 726 bp, encoding 241 amino acids with molecular weight 27.5 kDa and isoelectric point 9.26. Sequence alignment and phylogenetic tree analysis indicated that the deduced protein AcMADS1 contained a conservative MADS-box and semi-conservative K domain and belonged to the AGL6 clade of the MADS-box family. Bioinformatics analysis demonstrated that AcMADS1 was an alkaline and hydrophilic protein; the secondary structure comprised an α-helix, a random coil and an extended strand; the protein core structure agreed with the transcription factors and the function of the common DNA combining domain MADS-box in its protein 3D model and was located in the nucleus as a transcription factor. Tissue-specific analysis showed that AcMADS1 was expressed in floral organs (pistils, petals and sepals) and flesh of pineapple, with nearly no transcription detected in vegetative organs (roots, stems and leaves) and stamens. Furthermore, the expession of AcMADS1 was higher at the early phase of floral development, then reduced at the late phase. AcMADS1 may have important roles in floral induction and floral development of pineapple.

Key words: pineapple (Ananas comosus), flower development, MADS-box gene, cloning, gene expression

蔡元保, 杨祥燕, 孙光明, 黄强, 刘业强, 李绍鹏, 张治礼. 菠萝花发育相关基因AcMADS1的克隆与组织表达特性分析. 植物学报, 2014, 49(6): 692-703.

Yuanbao Cai, Xiangyan Yang, Guangming Sun, Qiang Huang, Yeqiang Liu, Shaopeng Li, Zhili Zhang. Cloning of Flowering-related Gene AcMADS1 and Characterization of Expression in Tissues of Pineapple (Ananas comosus). Chinese Bulletin of Botany, 2014, 49(6): 692-703.

导出引用管理器 EndNote|Ris|BibTeX

链接本文: https://www.chinbullbotany.com/CN/10.3724/SP.J.1259.2014.00692

https://www.chinbullbotany.com/CN/Y2014/V49/I6/692

参考文献

[1]樊金会,李文卿,董秀春,郭伟,束怀瑞.风信子AGL6同源基因在拟南芥中异位表达引起提早开花和器官同源转化[J].中国科学?Ｃ辑,2007,37:466-478
[2]王珍华,胡立霞,钟丹,韩雪,庞基良.AGAMOUS like 6亚家族基因研究进展[J].西北植物学报,2012,32:1480-1487
[3]杨祥燕,蔡元保,吴青松,孙光明.菠萝锌指蛋白基因AcRCHY1的克隆与表达分析[J].园艺学报,2009,36:1589-1596
[4]Angenent GC,Franken J,Busscher M,van Dijken A,van Went JL,Dons HJ,van Tunen AJ.A novel class of MADS box genes is involved in ovule development in petunia[J].Plant Cell,1995,7:1569-1582
[5]Becker A,Thei?en G.The major clades of MADS-box genes and their role in the development and evolution of flowering plants[J].Mol Phylogenet Evol,2003,29:464-489
[6]Boss PK,Sensi E,Hua C,Davies C,Thomas MR.Cloning and characterisation of grapevine (Vitis vinifera L[J].) MADS-box genes expressed during inflorescence and berry development. Plant Sci,2002,162:887-895
[7]Coen ES,Meyerowitz EM.The war of the whorls: genetic interactions controlling flower development[J].Nature,1991,353:31-37
[8]de Folter S,Immink RGH,Kieffer M,Parenicova L,Henz SR,Weigel D,Busscher M,Koolker M,Colombo L,Kater MM,Davies B,Angenent GC.Comprehensive interaction map of the Arabidopsis MADS-box transcription factors[J].Plant Cell,2005,17:1424-1433
[9]Ferrario S,Immink RG,Angenent GC.Conservation and diversity in flower land[J].Curr Opin Plant Biol,2004,7:84-91
[10]Gramzow L,Ritz MS,Thei?en G.On the origin of MADS-domain transcription factors[J].Trends Genet,2010,26:149-153
[11]Hsu HF,Huang CH,Chou LT,Yang CH.Ectopic expression of an orchid (Oncidium Gower Ramsey) AGL6-like gene promotes flowering by activating flowering time genes in Arabidopsis thaliana[J].Plant Cell Physiol,2003,44:783-794
[12]Immink RG,Gadella TWJ,Ferrario S,Busscher M,Angenent GC.Analysis of MADS box protein-protein interactions in living plant cells[J].P Natl Acad Sci USA,2002,99:2416-2421
[13]Irish VF (2003).The evolution of floral homeotic gene function. Bioessays,,25(7): 637–645
[14]Jack T.Molecular and genetic mechanisms of floral control[J].Plant Cell,2004,16:1-17
[15]Kaufmann K,Melzer R,Thei?en G.MIKC-type MADS-domain proteins: structural modularity,protein interactions and network evolution in land plants[J].Gene,2005,347:183-198
[16]Koo SC,Bracko O,Park MS,Schwab R,Chun HJ,Park KM,Seo JS,Grbic V,Balasubramanian S,Schmid M,Godard F,Yun DJ,Lee SY,Cho MJ,Weigel D,Kim MC.Control of lateral organ development and flowering time by the Arabidopsis thaliana MADS-box Gene AGAMOUS-LIKE6[J].Plant J,2010,62:807-816
[17]Li H,Liang W,Jia R,Yin C,Zong J,Kong H,Zhang D.The AGL6-like gene OsMADS6 regulates floral organ and meristem identities in rice[J].Cell Res,2010,20:299-313
[18]Lin EP,Peng HZ,Jin QY,Deng MJ,Li T,Xiao XC,Hua XQ,Wang KH,Bian HW,Han N,Zhu MY.Identification and characterization of two bamboo (Phyllostachys praecox) AP1/SQUA-like MADS-box genes during floral transition[J].Planta,2009,231:109-120
[19]Liu C,Zhang J,Zhang N,Shan H,Su K,Zhang J,Meng Z,Kong H,Chen Z.Interactions among proteins of floral MADS-box genes in basal eudicots: implications for evolution of the regulatory network for flower development[J].Mol Biol Evol,2010,27:1598-1611
[20]Ma H,Yanofsky MF,Meyerowitz EM.AGL1-AGL6,an Arabidopsis gene family with similarity to floral homeotic and transcription factor genes[J].Gene Dev,1991,5:484-495
[21]Melzer R,Wang YQ,Thei?en G.The naked and the dead: The ABC's of gymnosperm reproduction and the origin of the angiosperm flower[J].Semin Cell Dev Biol,2009,21:118-128
[22]Ohmori S,Kimizu M,Sugita M,Miyao A,Hirochika H,Uchida E,Nagato Y,Yoshida H.MOSAIC FLORAL ORGANS1,an AGL6-Like MADS box gene,regulates floral organ identity and meristem fate in rice[J].Plant Cell,2009,21:3008-3025
[23]Parenicová L,de Folter S,Kieffer M,Horner DS,Favalli C,Busscher J,Cook HE,Ingram RM,Kater MM,Davies B,Angenent GC,Colombo L.Molecular and phylogenetic analyses of the complete MADS-box transcription factor family in Arabidopsis: new openings to the MADS world[J].Plant Cell,2003,15:1538-1551
[24]Pelaz S,Ditta GS,Baumann E,Wisman E,Yanofsky MF.B and C floral organ identity functions require SEPALLATA MADS-box genes[J].Nature,2000,405:200-203
[25]Reinheimer R,Kellogg EA.Evolution of AGL6-like MADS box genes in grasses (Poaceae): ovule expression is ancient and palea expression is new[J].Plant Cell,2009,21:2591-2605
[26]Rounsley SD,Ditta GS,Yanofsky MF.Diverse roles for MADS box genes in Arabidopsis development[J].Plant Cell,1995,7:1259-1269
[27]Schwarz-Sommer Z,Huijser P,Nacken W,Saedler H,Sommer H.Genetic control of flower development by homeotic genes in Antirrhinum majus[J].Science,1990,250:931-936
[28]Smaczniak C,Immink RG,Angenent GC,Kaufmann K.Developmental and evolutionary diversity of plant MADS-domain factors: insights from recent studies[J].Development,2012,139:3081-3098
[29]Tapia-López R,García-Ponce B,Dubrovsky JG,Garay-Arroyo A,Pérez-Ruíz RV,Kim SH,Acevedo F,Pelaz S,Alvarez-Buylla ER.An AGAMOUS-related MADS-box gene,XAL1 (AGL12),regulates root meristem cell proliferation and flowering transition in Arabidopsis[J].Plant Physiol,2008,146:1182-1192
[30]Theissen G,Becker A,Di Rosa A,Kanno A,Kim JT,Münster T,Winter KU,Saedler H.A short history of MADS-box genes in plants[J].Plant Mol Biol,2000,42:115-149
[31]Thei?en G,Saedler H.Plant biology: Floral quartets[J].Nature,2001,409:469-471
[32]Thompson BE,Bartling L,Whipple C,Hall DH,Sakai H,Schmidt R,Hake S.Bearded-ear encodes a MADS box transcription factor critical for maize floral development[J].Plant Cell,2009,21:2578-2590
[33]Tian B,Chen YY,Yan YX,Li DZ.Isolation and ectopic expression of a bamboo MADS-box gene[J].Chinese Sci Bull,2005,50:217-224
[34]Viaene T,Vekemans D,Becker A,Melzer S,Geuten K.Expression divergence of the AGL6 MADS domain transcription factor lineage after a core eudicot duplication suggests functional diversification.[J].BMC Plant Biol,2010,10:148-
[35]Weigel D,Meyerowitz EM.The ABCs of floral homeotic genes. [J].Cell,1994,78:203-209
[36]Yang Y,Fanning L,Jack T.The K domain mediates heterodimerization of the Arabidopsis floral organ identity proteins,APETALA3 and PISTILLATA[J].Plant J,2003,33:47-59

菠萝花发育相关基因AcMADS1的克隆与组织表达特性分析

Cloning of Flowering-related Gene AcMADS1 and Characterization of Expression in Tissues of Pineapple (Ananas comosus)

PDF (PC)

可视化

被引次数

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	韩大勇, 李海燕, 张维, 杨允菲. 东北碱化草甸芦苇匍匐型分株超速生长过程及生理机制[J]. 植物生态学报, 2025, 49(2): 320-330.
[2]	李巧峡, 李有龙, 李纪纲, 陈晨龙, 孙坤. 光周期调控维西堇菜与裂叶堇菜开放花和闭锁花的发育[J]. 生物多样性, 2024, 32(6): 23484-.
[3]	吴锁伟, 安学丽, 万向元. 玉米雄性不育机理及其在工程核不育制种中的应用[J]. 植物学报, 2024, 59(6): 932-949.
[4]	王子阳, 刘升学, 杨志蕊, 秦峰. 玉米抗旱性的遗传解析[J]. 植物学报, 2024, 59(6): 883-902.
[5]	赵来鹏, 王柏柯, 杨涛, 李宁, 杨海涛, 王娟, 闫会转. SlHVA22l基因调节番茄耐旱性[J]. 植物学报, 2024, 59(4): 558-573.
[6]	何璐梅, 马伯军, 陈析丰. 植物执行者抗病基因研究进展[J]. 植物学报, 2024, 59(4): 671-680.
[7]	段政勇, 丁敏, 王宇卓, 丁艺冰, 陈凌, 王瑞云, 乔治军. 糜子SBP基因家族全基因组鉴定及表达分析[J]. 植物学报, 2024, 59(2): 231-244.
[8]	廖丹, 王艺彤, 雷晶晶, 王映霓, 张新娜, 王娟. 雌雄异株克隆植物髭脉槭对种间竞争的性别差异响应[J]. 植物生态学报, 2024, 48(12): 1623-1636.
[9]	孙福辉, 方慧仪, 温小蕙, 张亮生. 马银花MADS-box基因家族系统进化与表达分析[J]. 植物学报, 2023, 58(3): 404-416.
[10]	吴楠, 覃磊, 崔看, 李海鸥, 刘忠松, 夏石头. 甘蓝型油菜EXA1的克隆及其对植物抗病的调控作用[J]. 植物学报, 2023, 58(3): 385-393.
[11]	王菲菲, 周振祥, 洪益, 谷洋洋, 吕超, 郭宝健, 朱娟, 许如根. 大麦NF-YC基因鉴定及在盐胁迫下的表达分析[J]. 植物学报, 2023, 58(1): 140-149.
[12]	杨凯如, 贾绮玮, 金佳怡, 叶涵斐, 王盛, 陈芊羽, 管易安, 潘晨阳, 辛德东, 方媛, 王跃星, 饶玉春. 水稻黄绿叶调控基因YGL18的克隆与功能解析[J]. 植物学报, 2022, 57(3): 276-287.
[13]	杨丽婷, 谢燕燕, 左珂怡, 徐森, 谷瑞, 陈双林, 郭子武. 分株比例对异质光环境下美丽箬竹克隆系统光合生理的影响[J]. 植物生态学报, 2022, 46(1): 88-101.
[14]	王霞, 严维, 周志勤, 常振仪, 郑敏婷, 唐晓艳, 吴建新. 水稻雄性不育突变体ms102的鉴定和基因定位[J]. 植物学报, 2022, 57(1): 42-55.
[15]	尚江源, 淳雁, 李学勇. 水稻穗长基因PAL3的克隆及自然变异分析[J]. 植物学报, 2021, 56(5): 520-532.