钝叶柃花器官性别分化的形态学研究

doi:10.11707/j.1001-7488.20200220

摘要/Abstract

摘要：

目的: 柃木属植物为热带和亚热带常绿阔叶林灌木层优势种，传统认为是严格的雌雄异株，但在重庆缙云山钝叶柃却存在性别变异现象，即除了典型的雌株、雄株还有两性变异株。通过对不同分化时期的花芽进行形态和结构观察，比较两性变异花芽与典型的雌花芽、雄花芽分化过程的异同，旨在掌握钝叶柃不同性别花芽分化的整体进程及各分化时期的形态特征，明确花芽性别分化的关键时期，进而为探讨性别分化的相关机理提供重要的形态学证据。方法: 以钝叶柃典型的雌株、雄株、两性变异株的花芽为试验材料，采用常规石蜡切片法对花芽分化过程中的外部形态变化和组织结构进行观察分析。结果: 1）钝叶柃1~4个花芽着生于当年生新枝及2年生枝叶腋处；2）花芽分化始于8月上旬，12月中下旬基本完成，历时120天左右，之后花芽处于休眠状态，次年2-3月进入始花期，两性变异花花芽分化时间晚于雄花芽、雌花芽；3）花芽分化大致可以划分为5个时期，即苞片分化期、萼片分化期、花瓣分化期、雌雄蕊分化期、雌雄蕊成熟期；4）在花芽发育过程中，两性变异花芽和雄花芽的雌雄蕊原基同时出现，雄花中雄蕊原基正常发育而雌蕊原基停止发育，两性变异花中雌雄蕊原基皆正常发育；雌花中只见雌蕊原基，未见雄蕊原基。5）在雌雄蕊分化期，两性变异花中，雌蕊原基发育速度略快于雄蕊原基，雌蕊发育与雌花一致，中央心皮原基基部愈合膨大，中部凹陷形成子房室，顶端愈合向上延伸形成花柱；雄蕊发育与雄花一致，雄蕊原基上端膨大形成花药，下端形成短的花丝。在雌雄蕊成熟期各花器官继续生长，发育日趋成熟。6）3种不同性别花芽长宽比在分化的整个过程中均呈先上升后下降的趋势，雄花芽在萼片分化期长宽比值达到峰值，而雌花芽、两性变异花芽均在雌雄蕊分化期达到峰值。花芽外部形态特征（形状、色泽）在5个分化时期的动态变化依次为圆锥形（绿色）→椭圆形或近圆形（绿色褪尽，深紫红色）→圆胖（深紫红色）→圆形，雄花芽顶端圆钝，雌花芽、两性变异花芽顶端渐尖（紫红色逐渐褪去，绿色加深）→椭圆形（紫红色完全褪尽，由嫩绿色逐渐变成黄绿色或棕绿色）。结论: 钝叶柃3种不同性别花芽在苞片分化期、萼片分化期、花瓣分化期花芽形态和内部组织结构保持一致，而在雌雄蕊分化期出现较大差异，两性变异花芽与雄花芽的分化较为相似，均出现雌蕊、雄蕊原基，明确性别分化的关键期为雌雄蕊分化期，随着分化时期不断推进，花芽外部形态也发生相应的变化。

关键词: 钝叶柃, 花芽分化, 性别变异, 形态

Abstract:

Objective: Plants of genus Eurya are dominant species in the tropical and subtropical evergreen broad-leaved forest, which is traditionally considered as a strictly dioecious plant. However, bisexual plants exist in Eurya obtusifolia trees at Jinyun mountain in Chongqing in addition to the typical female and male plants. The morphology and structure of flower buds at different stages of differentiation and the differences and similarities of the differentiation process between bisexual flower buds and typical female and male flower buds were investigated to understand the whole process of flower buds differentiation in different sexes and their morphological characteristics in each differentiation period, to identify the critical period of sex differentiation of flower buds, and further to provide important morphological evidences for exploring the relevant mechanism of sex differentiation. Method: Typical flower buds of female, male and bisexual trees of E. obtusifolia were used as experimental materials. The changes of external morphology and tissue structure during flower bud differentiation were observed and analyzed using conventional paraffin section. Result: 1) The E. obtusifolia has 1-4 flower buds, located in the axils of new or two-year-old branches. 2) The differentiation of flower buds began in early August and basically completed differentiation in the middle and late December, lasting about 120 days. After that, the flower buds were dormant, and entered the initial flowering period from February to March of the next year. The flower bud differentiation time of bisexual flower buds was later than that of male and female flower buds. 3) The process of flower bud differentiation can be divided into 5 stages:bract differentiation, sepal differentiation, petal differentiation, stamen and pistil differentiation, and stamen and pistil formation. 4) In the process of flower bud development, the primordia of both male and bisexual flower buds appeared at the same time. The primordia of stamens in male flowers developed normally while the primordia of pistil stopped developing, and both stamen and pistil primordia in the bisexual flower developed normally. Only pistil primordium was found in female flower bud, but not stamen primordium. 5) In the early stage of the development of bisexual flowers, the development speed of pistil primordium was slightly faster than that of the stamen primordium. The development of pistil was consistent with that of the female flower, the base of carpel primordium healed and enlarged, the middle depression formed ovary and the top healed and extended upward to form style. The development of stamens was consistent with that of the male flower. The upper end of stamen primordium expanded to form anthers and the lower end formed short filaments. At the mature stage of pistil and stamen, the floral organs continued to grow and develop gradually. 6) The length-width ratio of flower buds of the three types of sexes showed an increase first and followed by a decrease during the whole process of differentiation. The male flower buds reached the highest value in the differentiation stage of the bracts, while the female flower buds and the bisexual buds peaked in the stamen and pistil differentiation stages. The dynamic changes of the external morphological characteristics(shape, color) of flower buds in the five differentiation stages were conical (green)→elliptical or approximately circular shape (green faded, deep purple) →round and fat (royal purple)→round, the top of male flower bud was round and blunt, the top of female flower bud and bisexual flower bud was gradually sharp (purple red gradually faded and green deepened)→oval (purple red completely faded, from tender green to yellowish green or brownish green). Conclusion: The flower bud morphology and internal tissue structure of three sexual expression plants of E. obtusifolia are consistent during bract differentiation, sepal differentiation and petal differentiation, but there is a significant difference in the pistil and stamen differentiation stage. The differentiation of bisexual flower bud is similar to that of male flower bud, both with pistil and stamen primordium appearing. It is clear that the key stage of sex differentiation is pistil and stamen differentiation, and there is a corresponding relationship between the external morphology of flower buds and the differentiation stages.

Key words: Eurya obtusifolia, flower bud differentiation, sexual variation, morphology

中图分类号:

S718.47

顾梨,何平,邓洪平,倪东萍,王茜,程莅登,巴罗菊. 钝叶柃花器官性别分化的形态学研究[J]. 林业科学, 2020, 56(2): 174-183.

Li Gu,Ping He,Hongping Deng,Dongping Ni,Qian Wang,Lideng Cheng,Luoju Ba. A Morphology Study on Floral Organ Development Process of Eurya obtusifolia[J]. Scientia Silvae Sinicae, 2020, 56(2): 174-183.

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参考文献 0

	巴罗菊. 2017.细枝柃(Eurya loquaiana Dunn)花器官发生及激素动态变化研究.重庆:西南大学硕士学位论文.
	Ba L J. 2017. Study on floral organogenesis and dynamic changes of endogenous hormones of Eurya loquaiana Dunn. Chongqing: MS thesis of Southwest University.[in Chinese]
	陈之端, 路安民. 被子植物起源和早期演化研究的回顾与展望. 植物分类学报, 1997. 35 (4): 375- 384.
	Chen Z R , Lu A M . Origin and early evolution of angiosperms retrospect and prospects. Acta Phytotaxonomica Sinica, 1997. 35 (4): 375- 384.
	郜爱玲, 李建安, 刘儒, 等. 高等植物花芽分化机理研究进展. 经济林研究, 2010. 28 (2): 131- 136. doi: 10.3969/j.issn.1003-8981.2010.02.029
	Gao A L , Li J A , Liu R , et al. Advances in research on flower bud differentiation mechanism in higher plants. Nonwood Forest Research, 2010. 28 (2): 131- 136. doi: 10.3969/j.issn.1003-8981.2010.02.029
	冷琴, 杨洪. 被子植物起源:对老问题的新看法. 科学通报, 2001. 46 (5): 364- 370. doi: 10.3321/j.issn:0023-074X.2001.05.004
	Leng Q , Yang H . Origin of angiosperms:New views on old problems. Chinese Science Bulletin, 2001. 46 (5): 364- 370. doi: 10.3321/j.issn:0023-074X.2001.05.004
	李桂琴. 植物显微技术. 哈尔滨: 东北农业大学出版社. 2002.
	Li G Q . Plant microscopic technology. Harbin: Northeast Agricultural University Press. 2002.
	李运婷. 2016.钝叶柃(Eurya obtusifolia H.T.Chang)性别分化的生理生化研究.重庆:西南大学硕士学位论文.
	Li Y T. 2016. Study of physiological and biochemical on sexual differentiation of Eurya obtusifolia H. T. Chang. Chongqing: MS thesis of Southwest University.[in Chinese]
	李运婷, 宗秀虹, 张华雨, 等. 钝叶柃不同性别植株花期叶片内源激素含量的变化. 园艺学报, 2016. 43 (7): 1411- 1418.
	Li Y T , Zong X H , Zhang H Y , et al. Variation of endogenous hormones in the leaves of male, female and hermaphrodite plants of Eurya obtusifolia during flowering stages. Acta Horticulturae Sinic, 2016. 43 (7): 1411- 1418.
	刘亭亭. 2007.白菜花发育过程的形态学、细胞学及超微结构观察.杭州:浙江大学硕士学位论文.
	Liu T T. 2007. Morphological, cytological and ultrastructural observations on the development of Chinese cabbage flowers. Hangzhou: MS thesis of Zhejiang University.[in Chinese]
	吕柳新, 陶萌春, 潘仰星. 毛花猕猴桃(Actinidia eriantha Benth)的染色体与花粉母细胞减数分裂的观察. 福建农林大学学报:自然科学版, 1984. 13 (1): 25- 30.
	Lü L X , Tao M C , Pan Y X . Observation on the chromosome and meioses of pollen mother cells in Maohua gooseberry(Actinidia eriantha Benth). Journal of Fujian Agriculture and Forestry University:Natural Science Edition, 1984. 13 (1): 25- 30.
	马德风, 梁诗魁. 中国蜜粉源植物及其利用. 北京: 农业出版社. 1993.
	Ma D F , Liang S K . The nectar and pollen resource plants in China and their utilization. Beijing: Agriculture Press. 1993.
	施雁飞, 游新才, 张逸, 等. 茶树花芽分化解剖与形态学研究. 陕西师范大学学报:自然科学版, 2015. 43 (2): 70- 73.
	Shi Y F , You X C , Zhang Y , et al. Anatomy and morphological observation on flower bud differentiation of Camellia sinensis. Journal of Shaanxi Normal University:Natural Science Edition, 2015. 43 (2): 70- 73.
	孙建云, 王庆亚, 黄清渊. 李花芽形态分化的研究. 江西农业大学学报, 2005. 27 (3): 413- 416. doi: 10.3969/j.issn.1000-2286.2005.03.021
	Sun J Y , Wang Q Y , Huang Q Y . A study on morphological differentiation of flower bud of Prunus salicina Lindl. Acta Agriculturae Universitatis Jiangxiensis, 2005. 27 (3): 413- 416. doi: 10.3969/j.issn.1000-2286.2005.03.021
	王彩云, 高莉萍, 鲁涤非, 等. '厚瓣金桂'桂花花芽形态分化的研究. 园艺学报, 2002. 29 (1): 52- 56. doi: 10.3321/j.issn:0513-353X.2002.01.012
	Wang C Y , Gao L P , Lu D F , et al. A study on morphological differentiation of flower bud of Osmanthus fragrans 'Houban Jingui'. Acta Horticulturae Sinica, 2002. 29 (1): 52- 56. doi: 10.3321/j.issn:0513-353X.2002.01.012
	王茜, 邓洪平, 丁博, 等. 钝叶柃不同性别花的花部形态与传粉特征比较. 生态学报, 2012. 32 (12): 3921- 3930.
	Wang Q , Deng H P , Ding B , et al. Comparison of floral morphology and pollination characteristics between the sexes in Eurya loquaiana. Acta Ecologica Sinica, 2012. 32 (12): 3921- 3930.
	王湘南, 蒋丽娟, 陈永忠, 等. 花芽分化的形态解剖学特征观测. 中南林业科技大学学报, 2011. 31 (8): 22- 27. doi: 10.3969/j.issn.1673-923X.2011.08.005
	Wang X N , Jiang L J , Chen Y Z , et al. Observation on morphological and anatomical characteristics of the flower bud differentiation on Camellia oleifera.. Journal of Central South University of Forestry & Technology, 2011. 31 (8): 22- 27. doi: 10.3969/j.issn.1673-923X.2011.08.005
	杨康民, 夏瑞妹, 戚五妹. 上海地区桂花品种开花性状的分析研究. 园艺学报, 1989. 16 (2): 146- 152. doi: 10.3321/j.issn:0513-353X.1989.02.008
	Yang K M , Xia R M , Qi W M . An investigation and analysis on the cultivars of sweet osmanthus and their blooming characteristics in Shanghai. Acta Horticulturae Sinica, 1989. 16 (2): 146- 152. doi: 10.3321/j.issn:0513-353X.1989.02.008
	张波, 秦垦, 何昕孺, 等. 木本植物花芽分化研究进展. 湖北农业科学, 2017. 56 (22): 4224- 4226.
	Zhang B , Qin K , He X R , et al. Research progress of flower bud differentiation mechanism of woody plants. Hubei Agricultural Sciences, 2017. 56 (22): 4224- 4226.
	张大勇. 植物生活史进化与繁殖生态学. 北京: 科学出版社. 2004.
	Zhang D Y . Plant life-history evolution and reproductive ecology. Beijing: Science Press. 2004.
	张逸. 茶树花芽分化及花器官发育的形态学研究. 西安: 陕西师范大学. 2012.
	Zhang Y . Morphological study on flower bud differentiation and flower organ development of tea. Xi'an: Shaanxi Normal University. 2012.
	张瑞菊. 2006.厚皮香科植物的花器官发生及其系统学意义.昆明:云南大学硕士学位论文.
	Zhang R J. 2006. Floral organogenesis and its systematic significance of Pseudostellaceae. Kunming: MS thesis of Yunnan University.[in Chinese]
	朱雯, 许逸林, 李文锋, 等. 广宁红花油茶花芽分化特征. 广东农业科学, 2016. 43 (3): 51- 54.
	Zhu W , Xu Y L , Li W F , et al. Study on flower bud differentiation characteristics of Camellia semiserrata Chi. Guangdong Agricultural Sciences, 2016. 43 (3): 51- 54.
	Anderson G J , Anderson M K J , Patel N . The ecology, evolution, and biogeography of dioecy in the genus Solanum: with paradigms from the strong dioecy in Solanum polygamum, to the unsuspected and cryptic dioecy in Solanum conocarpum. American Journal of Botany, 2015. 102 (3): 471- 486. doi: 10.3732/ajb.1400486
	Aryal R , Ming R . Sex determination in flowering plants:Papaya as a model system. Plant Science, 2014. 217/218 (1): 56- 62.
	Calderon-Urrea D A . Special review issue on plant reproduction sex determination in flowering plants. The Plant Cell, 1993. 5 (10): 1241- 1251.
	Martine C T , Anderson G J , Jordon-Thaden I , et al. Leakiness may be an insurance policy for functionally dioecious Solanum of oceanic and terrestrial islands. Botany, 2014. 2014, 26- 30.
	Mitchell C H , Diggle P K . The evolution of unisexual flowers:morphological and functional convergence results from diverse developmental transitions. American Journal of Botany, 2005. 92 (7): 1068- 1076. doi: 10.3732/ajb.92.7.1068
	Venkatasamy S , Khittoo G , Keeley S . Leaky dioecy in Diospyros (Ebenaceae) endemic to the island of Mauritius. Plant Ecology, 2007. 189 (1): 139- 146.

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