[1] Scutt C P, Vinauger-Douard M, Fourquin C, et al. (2003).The identification of candidate genes for a reverse genetic analysis of development and function in the Arabidopsis gynoecium.Plant Physiology,132:653-665. [2] Gomariz-Fernández A, Sánchez-Gerschon V, Fourquin C, et al. (2017). The role of shi/sty/srs genes in organ growth and carpel development is conserved in the distant eudicot species arabidopsis thaliana and nicotiana benthamiana. Frontiers in Plant Science, 8:814-830. [3] Theissen G, Melzer R. (2007).Molecular mechanisms underlying origin and diversification of the angiosperm flower. Annals of Botany, 100:603-619. [4] 邢佳毅.'香妃'葡萄2心皮和3心皮子房发育过程中VvYABBY5基因表达的研究[D].北京:中国农业大学,2016:1-10. XING Jia-yi. (2016).The study on VvYABBY5 gene expression during the process of bicarpellate and tricarpeiiate ovaries development in 'Xiangfei' grapevine (Vitis vinifera L.) [D]. Beijing: China agricultural University:1-10. (in chinese) [5] Cristina Ferrandiz, Chloe Fourquin, Nathanael Prunet, et al. (2010). Carpel Development:7-10. [6] Coen E S, Meyerowitz E M. (1991). The war of the whorls: genetic interactions controlling flower development. Nature, 353: 31-37. [7] Pelaz S, Ditta G S, Baumann E, et al. (2000). B and C floral organ identity functions require SEPALLATA MADS-box genes. Nature, 405:200-203. [8] Theissen G, Saedler H. (2001).Plant biology Floral quartets. Nature, 409:469-471. [9] Takhtajan A. (1970). Flowering Plants: Origin and Dispersal.Quarterly Review of Biology:58. [10] Melville R. (1963). Western Australian Wild Flowers. Kew Bulletin ,16(3):496. [11] 熊子仙.生殖叶学说与心皮学说[J].植物学通报,1998,15(3):74-77. XIONG Zi-xian. (1998).The theory of reproductive leaf and the theory of carpel[J]. Bulletin of Plant, 15(3):74-77. (in chinese) [12] Ndiz C F, Fourquin C, Prunet N, et al. (2010). Carpel Development. Advances in Botanical Research. 55:1-55. [13] Endress, P. K. (2015). Patterns of angiospermy development before carpel sealing across living angiosperms: diversity, and morphological and systematic aspects. Botanical Journal of the Linnean Society, 178(4):556-591. [14] 白惠磊,张素丽,梁庆沙,等.巨峰葡萄(Vitis labruscana Kyoho)闭花受精机理的研究[J].中国农业大学学报, 2007,12(2):27-33. BAI Hui-lei, ZHANG Su-li, LIANG Qing-sha, et al. (2007).Mechanism of cleistogamy in `Kyoho' grape (Vitis labruscana)[J]. Journal of China Agricultural University, 12(2):27-33. (in chinese) [15] 何余堂,龙卫华,胡进平,等.白菜型油菜角果多室性状的遗传及解剖学研究[J].中国油料作物学报, 2003,25(1):3-6,103. HE Yu-tang, LONG Wei-hua, HU Jin-ping, et al. (2003).Anatomic and genetic studies on multicapsular character in Brassica campestris L[J]. Chinese journal of oil crop sciences, 25(1):3-6,103. (in chinese) [16] 赵洪朝,杜德志,刘青元,等.芥菜型油菜多室性状的遗传研究[J].西北农林科技大学学报(自然科学版),2003, 31(6):90-92. ZHAO Hong-chao, DU De-zhi, LIU Qing-yuan, et al. (2003). Study on multilocular heredity of Bjuncea[J]. Jour of Northwest Sci-Tech University of Agricultural and Forestry (Nat. Sci. Ed. ), 31(6):90-92. (in chinese) [17] Choudhary B R,Solanki Z S. (2007).Inheritance of siliqua locule number and seed coat colour in Brssica juncea. Plant Breeding, 126:104-106. [18] 李悦,李天来,王丹.番茄花芽分化期茎尖内源激素水平与果实心室数目的相关性研究[J].中国农业科学,2008,41(9):2 727-2 733. LI Yue, LI Tian-lai, WANG Dan. (2008). Correlation Between Endogenous Hormone Content of Stem Apices and Fruit Locule Number in Tomato During Floral Bud Differentiation Stage[J].Scientia Agricultura Sinica,41(9):2,727-2,733. (in chinese) [19] 代秉勋,沈显生,欧明涛,等.重瓣花油菜的培育及其在生物学中的意义[J].生物学杂志,2003, 20(4):28-30. DAI Bing-xun, SHEN Xian-sheng, OU Ming-tao, et al. (2003).The culture of multitepal Brassica campestris var. oleifera and its biological significance[J]. Journal of biology, 20(4):28-30. (in chinese) [20] 蒋励,张小兰.植物果实发育调控的分子机理研究进展[J].中国蔬菜, 2013,(6):9-16. JIANG Li, ZHANG Xiao-lan.(2013).Research Progress on Molecular Mechanism for Regulating Development of Plant Fruit[J]. China Vegetables, (6):9-16. (in chinese) [21] 闫守伟,张素丽,张国军,等.不同葡萄品种柱头、花柱发育与种子形成的关系[J].西北植物学报,2007,27(3):435-441. YAN Shou-wei, ZHANG Su-li, ZHANG Guo-jun, et al. (2007). Development of Stigma and Style and Formation of Seed with Four Grapevine Cultivars[J]. Acta Bot Boreal -Occident Sin, 27(3):435-441.(in Chinese) [22] Ran G U, Liu X, Zhao W, et al. (2018). Functional characterization of the promoter and second intron of cum1, during flower development in cucumber (cucumis sativus, l). Horticultural Plant Journal,4(3):103-110. [23] 刘晓柱.荠菜心皮发育过程中生长素分布研究[D].长沙:湖南农业大学,2011. LIU Xiao-zhu. (2011).The study on the Auxin's distribution during the development of carpel of Capsella bursa-pastoris[D]. Changsha: Hunan Agricultural University. (in chinese) [24] 朱占伟.荠菜PIN基因表达与其心皮形态建成的相关性[D].长沙:湖南农业大学,2013. ZHU Zhan-wei. (2013).The PIN genes expression and Its relationship to carpel morphogenesis of Capsella bursa-pastoris[D] Changsha: Hunan Agricultural University. (in chinese) [25] 胡清云.荠菜PIN3基因的克隆分析及其对心皮形态建成的影响[D].长沙:湖南农业大学,2014. HU Qing-yun. (2014). The analyses of PIN3 of Capsella bursa-pastoris and Its influence to carpel morphogenesis[D]. Changsha: Hunan Agricultural University. (in chinese) [26] 刘晓柱,李银凤,赵燕,等.生长素对荠菜心皮发育的影响[J].河南农业科学,2018,47(8):88-94. Liu Xiao-zhu,LI Yin-feng ,ZHAO Yan,et al. (2018).Effects of Auxin on the Carpel Development of Capsella bursa-pastoris[J]. Journal of Henan Agricultural Sciences, 47(8):88-94. (in chinese) [27] Chen D, Molitor A M, Xu L, et al. (2016). Arabidopsis prc1 core component atring1 regulates stem cell-determining carpel development mainly through repression of class iknox genes. Bmc Biology, 14(1):112-113. [28] Boualem A, Troadec C, Camps C, et al. (2015). A cucurbit androecy gene reveals how unisexual flowers develop and dioecy emerges. Science, 350(6261):688-691. [29] Li X G, Su Y H, Zhao X Y, et al. (2010). Cytokinin overproduction-caused alteration of flower development is partially mediated by CUC2 and CUC3 in Arabidopsis. Gene, 450(2):109-120. [30] Jiao Y, Meyerowitz E M. (2010). Cell-type specific analysis of translating RNAs in developing flowers reveals new levels of control. Molecular Systems Biology, 6(1):419-431. [31] Bartrina I, Otto E, Strnad M, et al. (2011).Cytokinin regulates the activity of reproductive meristems, flower organ size, ovule formation, and thus seed yield in Arabidopsis thaliana. Plant Cell,23: 69-80. [32] Cong B, Barrero L S, Tanksley S D. (2008). Regulatory change in YABBY-like transcription factor led to evolution of extreme fruit size during tomato domestication. Nature Genetics, 40(6):800-804. [33] Muños S , Ranc N , Botton E ,et al. (2011). Increase in tomato locule number is controlled by two single-nucleotide polymorphisms located near WUSCHEL. Plant Physiology, 156(4):2,244-2,254. [34] Bollier N, Sicard A, Leblond J, et al. (2018). At-mini zinc finger2 and sl-inhibitor of meristem activity, a conserved missing link in the regulation of floral meristem termination in arabidopsis and tomato. Plant Cell, 30(1):83-84. [35] Roth O, Alvarez J, Levy M, et al. (2018). The knoxi transcription factor shoot meristemless regulates floral fate in arabidopsis. Plant Cell, 30:1,309-1,321. [36] Bartlett M E, Williams S K, Taylor Z, et al. (2015). The maize pi/glo ortholog zmm16/sterile tassel silky ear1 interacts with the zygomorphy and sex determination pathways in flower development. Plant Cell, 27(11),3,081-3,098. [37] Yanofsky M F, Ma H, Bowman J L, et al. (1990). The protein encoded by the Arabidopsis homeotic gene AGAMOUS resembles transcription factors. Nature, 346:35-39. [38] Melzer R, Wang Q, Theissen G. (2010). The naked and the dead:The ABCs of gymnosperm reproduction and the origin of the angiosperm flower. Seminars in Cell&Developmental Biology, 21:118-128. [39] Honma T and Goto K. (2011). Complexes of MADS-box proteins are sufficient to convert leaves into floral organs. Nature, 409:525-529. [40] Wellmer F, Graciet E, Riechmann J L. (2014).Specification of floral organs in Arabidopsis. Journal of Experimental Botany,65(1):1-9. [41] 孟雨婷,黄晓晨,侯元同,等.花的形态与花发育的ABCDE模型[J].生物学杂志, 2017,34(6):105-107,115. MENG Yu-ting, HUANG Xiao-chen, HOU Yuan-tong, et al. (2017). The floral morphology and the ABCDE model of floral organ development[J]. Journal of biology, 34(6):105-107,115. (in chinese) [42] Cucinotta, M, L. Colombo, and I. Roig-Villanova. (2014). Ovule development, a new model for lateral organ formation. Frontiers in Plant Science, 5:117-118. [43] Zhang X. (2014).Plant science. delayed gratification--waiting to terminate stem cell identity. Science, 343(6170):498-499. [44] Prunet N, Yang W, Das P, et al. (2017). Superman prevents class b gene expression and promotes stem cell termination in the fourth whorl of arabidopsis thaliana flowers. Proceedings of the National Academy of Sciences of the United States of America, 114(27):7,166-7,171. [45] Diarmuid S. ',Maoiléidigh. (2018). A conserved mechanism to terminate floral meristems. Plant Cell, 30:260. [46] Guo Y, Zhu Q, Zheng S, et al. (2007). Cloning of a MADS Box Gene (GhMADS3) from Cotton and Analysis of Its Homeotic Role in Transgenic Tobacco. Journal of Genetics and Genomics, 34(6):527-535. [47] 江苏城,宋美珍,庞朝友,等.陆地棉MADS-box基因GhMADS13的功能分析[J].棉花学报, 2013,25(5):377-381. JIANG Su-cheng, SONG Mei-zhen, PANG Chao-you, et al. (2013). Analysis of Transgenic Arabidopsis thaliana with the Gossypium hirsutum L.MADS-box GeneGhMADS13[J],Cotton Science, 25(5):377-381. (in chinese) [48] Arora R , Agarwal P, Ray S ,et al. (2007). MADS-box gene family in rice: genome-wide identification, organization and expression profiling during reproductive development and stress. Bmc Genomics, 8(1):242-244. [49] Morel P, Heijmans K, Rozier F, et al. (2017). Divergence of the floral a-function between an asterid and a rosid species. Plant Cell, 29(7):1,605-1,621. [50] Irish V F. (2003). The evolution of floral homeotic gene function. Bioessays, 25(7):637-646. [51] Liu B, Liu X, Yang S, et al. (2015). Silencing of the gibberellins receptor homolog, CsGID1a, affects locule formation in cucumber (Cucumis sativus) fruit. New Phytologist, 210(2):551-563. |