濒危植物格木天然种群的表型多样性及变异

doi:10.11707/j.1001-7488.20190408

摘要/Abstract

摘要： [目的]通过对濒危植物格木在我国中心分布区种群的果荚和种子表型性状测量分析，研究其表型多样性及变异规律，结合地理气候信息探讨影响表型变异的关键因子，为格木天然种群的遗传多样性保护恢复和引种栽培提供科学依据。[方法]对8个格木天然种群114个单株的13个果荚及种子表型性状进行测量，利用巢式方差分析、多重比较、相关性分析、主成分分析、聚类分析等分析方法，探讨格木天然种群的表型多样性水平、进化和适应性潜力、表型变异规律、表型分化水平、种群聚类特征及其与地理气候因子的相关性。[结果]格木表型多样性水平中等，13个性状的Shannon-Wiener指数在1.911 1（种形指数）~2.103 9（果荚周长）之间，平均2.027 8；8个种群的Shannon-Wiener指数在0.920 9（P6）~1.885 6（P8）之间，均值为1.474 7。格木表型性状离散程度较轻，13个性状的变异系数在7.544 6%（种子长）~18.868 5%（果荚面积）之间，均值为12.410 9%；8个种群的变异系数在8.852 9%（P1）~13.984 8%（P5）之间，均值为12.410 9%。13个表型性状的极大值为极小值的1.395 2（种形指数）~2.805 6（每荚种子数）倍，均值为1.791 7。巢式方差分析表明，格木13个表型性状在种群间和种群内均存在极显著差异（P<0.01），说明这些性状在种群间和种群内均存在丰富的变异；种群内的变异（40.387 1%）远大于种群间（11.948 9%）。种群平均表型分化系数为21.857 9%，各性状的分化系数变化幅度在7.476 5%（种形指数）~38.674 0%（果荚宽）之间。相关性分析表明，13个表型性状之间大多存在显著或极显著相关，果荚宽度、种子周长等性状和温度指标呈负相关，与纬度呈正相关，格木在气温高、降雨量大的地区往往具有小果荚、小种子的特征，随着温度指标降低和纬度增加，格木果荚及种子有变大的趋势。格木13个表型性状可提炼为4个主成分，累积贡献率为87.382%。8个天然群体基于欧氏距离可分为3类：第1类2个种群呈现果荚小、种子小的特征，该类表型主要出现在格木分布区的南端；第2类5个种群呈现果荚大、种子大的特征，该类表型主要出现在格木分布区的北部，仅1个种群位于分布区的南部；第3类1个种群呈现果荚小、种子少、种子大而薄的特征，该类表型出现在格木南北分布区的中间衔接部。[结论]格木的表型多样性处于中等水平，在个体上存在较为丰富的变异。在群体及物种水平上，格木表型性状离散程度较轻，各个性状分布相对集中，较为稳定，不易发生群体分化，拥有特殊表型的格木单株具有较高的保存价值。果荚及种子大小进化及适应性潜力相对较大，种形指数最不易产生变异。种群内的变异是格木表型变异的主要来源，格木的种质资源收集保存可减少种群数量，增加种群内个体数量，并优先收集有特殊表型的单株。广西省容县和龙圩区的格木种群是格木遗传多样性保护及种质资源收集保存的重点区域。年均温等温度因子是影响格木表型及分布的最主要因子。果荚及其中种子的大小是格木种群间聚类的主要依据。

关键词: 格木, 濒危植物, 天然种群, 表型多样性, 表型性状, 种质资源

Abstract: [Objective] The phenotypic traits of pod and seed from an endangered plant Erythrophleum fordii were measured to investigate the phenotypic diversity and variation pattern of populations. And combing with geographical and climatic information, the factors affecting the phenotypic variation were discussed. This study provides a basis for genetic diversity conservation, restoration, and cultivation of E. fordii.[Method] The phenotypic characteristics of thirteen pods and seeds from 114 individuals of eight natural populations were measured. Nested analysis of variance, multi-comparison, correlation analysis, principal components analysis, and cluster analysis were used to study phenotypic diversity,evolution and adaptive potential, patterns of phenotypic variation, level of phenotypic differentiation, cluster of populations, and the correlation between phenotypic traits and climate factors, respectively.[Result] E. fordii showed a modest level of phenotypic diversity, the range of Shannon-Wiener index is from 1.911 1 (Shape index of seed) to 2.103 9 (Perimeter of pod)with an average of 2.027 8. The range of Shannon-Wiener index of eight populations is from 0.920 9(P6)to 1.885 6(P8) with an average of 1.474 7. The range of variation of variance among the 13 traits was from 7.544 6% (Length of seed)to 18.868 5%(Area of pod)with an average of 12.410 9%. The range of variation of variance among the eight populations was from 8.852 9%(P1) to 13.984 8%(P5) with an average of 12.410 9%. The range of times of maximum and minimum was from 1.395 2(Shape index of seed) to 2.805 6(Number of seeds in pod)with an average of 1.791 7. Analysis of nested variance showed that there was a significant differences (P<0.01) among and within populations, suggesting that abundant variation among and within populations. The within-population variation(40.387 1%) was much larger than the among-population variation(11.948 9%); and the average phenotypic population differentiation coefficient was 21.857 9% with a range from 7.476 5% (Shape index of seed)to 38.674 0% (Width of pod). Correlation analysis revealed that there were significant correlations among most phenotypic traits. The significantly negative correlation between the width of pod, length of seed and perimeter of seed was detected, whereas, there were significantly positive correlations between width of pod and latitude. The pod and seed were mostly found small in the areas with high temperature and rainfall in general, and the size of pod and seed became bigger and bigger along with the increase of the latitude and the decrease of the temperature. Principal component analysis showed that the four principal components added up to 87.382% of the variation. The eight natural populations were divided into three groups by UPGMA cluster analysis based on Euclidean distance calculated from phenotypic traits. The first group was comprised of populations with small pods and small seeds, which are located in the south of the natural distribution. The second group has characteristics of big pods and big seeds, which are located in the north of the natural distribution, and only one population is located in the south of the distribution. Populations with small pods, big and thin seeds are located in the middle of the distribution, belonging to the third group.[Conclusion] E. fordii has the modest level of phenotypic diversity, there were abundant variations among and within populations. The degree of phenotypic variation was slight and stable, and there was low level of population differentiation in E. fordii. Within-population variation was the main source of variation. For germplasm collection and preservation, the number of populations can be reduced while the number of individual trees within populations can be increased, especially the individuals with unique phenotypic characteristics. Rongxian and Longxu of Guangxi are the most important regions for genetic conservation and germplasm collection. Temperature was the most important factor affecting the phenotypic traits and distribution of E. fordii. Pod and seed sizes are the basis for populations clustering.

Key words: Erythrophleum fordii, endangered plant species, natural population, phenotypic diversity, phenotypic traits, germplasm resources

中图分类号:

S718.54

李洪果, 陈达镇, 许靖诗, 刘光金, 庞晓东, 叶金辉, 莫小文, 谌红辉. 濒危植物格木天然种群的表型多样性及变异[J]. 林业科学, 2019, 55(4): 69-83.

Li Honguo, Chen Dazhen, Xu Jingshi, Liu Guangjin, Pang Xiaodong, Ye Jinhui, Mo Xiaowen, Chen Honghui. Phenotypic Diversity and Variation in Natural Populations of Erythrophleum fordii, an Endangered Plant Species[J]. Scientia Silvae Sinicae, 2019, 55(4): 69-83.

参考文献

陈丽君, 邓小梅, 丁美美,等. 2014. 苦楝种源果核及种子性状地理变异的研究. 北京林业大学学报, 36(1):15-20.
(Chen L J, Deng X M, Ding M M, et al. 2014. Geographic variation in traits of fruit stones and seeds of Melia azedarach. Journal of Beijing Forestry University, 36(1):15-20.[in Chinese])
邓绍勇, 曹泉, 余林,等. 2015. 栀子野生居群叶片和果实性状的表型多样性. 林业科学研究, 28(2):289-296.
(Deng S Y, Cao Q, Yu L, et al. 2015. Phenotypic diversity of leaf and fruit traits of natural Gardenia jasminoides population. Forest Research, 28(2):289-296.[in Chinese])
董昕, 王磊, 鲁仪增,等. 2017. 山东稀有植物小果白刺天然群体表型变异研究. 林业科学研究, 30(2):293-299.
(Dong X, Wang L, Lu Y Z, et al. 2017. Phenotypic variation of Nitraria sibirica natural population in Shandong. Forest Research, 30(2):293-299.[in Chinese])
葛颂, 王明庥, 陈岳武. 1988. 用同工酶研究马尾松群体的遗传结构. 林业科学, 24(4):399-409.
(Ge S, Wang M X, Chen Y W. 1988. An analysis of population genetic structure of Masson pine by isozyme technique. Scientia Silvae Sinicae, 24(4):399-409.[in Chinese])
胡启鹏, 郭志华, 李春燕,等. 2008. 植物表型可塑性对非生物环境因子的响应研究进展. 林业科学, 44(5):135-142.
(Hu Q P, Guo Z H, Li C Y, et al. 2008. Advance at phenotypic plasticity in plant responses to abiotic factors. Scientia Silvae Sinicae, 44(5):135-142.[in Chinese])
黄忠良, 郭贵仲, 张祝平. 1997. 渐危植物格木的濒危机制及其繁殖特性的研究. 生态学报, 17(6):671-676.
(Huang Z L, Guo G Z, Zhang Z P. 1997. A study about endangered mechanism of Erythrophleum fordii. Acta Ecologica Sinica, 17(6):671-676.[in Chinese])
李斌, 顾万春, 卢宝明. 2002. 白皮松天然群体种实性状表型多样性研究. 生物多样性, 10(2):181-188.
(Li B, Gu W C, Lu B M. 2002. A study on phenotypic diversity of seeds and cones characteristics in Pinus bungeana. Biodiversity Science, 10(2):181-188.[in Chinese])
李洪果, 杜庆鑫, 王淋,等. 2017. 利用表型数据构建杜仲雌株核心种质. 分子植物育种, 15(12):5197-5209.
(Li H G, Du Q X, Wang L, et al. 2017. Establishment of female core collection of Eucommia ulmoides Oliv. based on phenotypic characters. Molecular Plant Breeding,15(12):5197-5209.[in Chinese])
李洪果, 杜红岩, 贾宏炎,等. 2018. 利用表型性状构建杜仲雄性资源核心种质. 分子植物育种, 16(2):591-601.
(Li H G, Du H Y, Jia H Y, et al. 2018. Establishment of male core collection of Eucommia ulmoides based on phenotypic traits. Molecular Plant Breeding, 16(2):591-601.[in Chinese])
李珊, 甘小洪, 憨宏艳,等. 2016. 濒危植物水青树叶的表型性状变异. 林业科学研究, 29(5):687-697.
(Li S, Gan X H, Han H Y, et al. 2016. Leaf phenotypic traits of Tetracentron sinense, an endangered plant species. Forest Research, 29(5):687-697.[in Chinese])
李秀兰, 贾继文, 王军辉, 等. 2013. 灰楸形态多样性分析及核心种质初步构建. 植物遗传资源学报, 14(2):243-248.
(Li X L, Jia J W, Wang J H, et al. 2013. Morphological diversity analysis and preliminary construction of core collection of Catalpa fargesii Bur. Journal of Plant Genetic Resources, 14(2):243-248.[in Chinese])
林玲, 王军辉, 罗建,等. 2014. 砂生槐天然群体种实性状的表型多样性. 林业科学, 50(4):137-143.
(Lin L, Wang J H, Luo J, et al. 2014. Phenotypic diversity of seed and fruit traits in natural populations of Sophora moorcroftiana. Scientia Silvae Sinicae, 50(4):137-143.[in Chinese])
刘娟, 廖康, 刘欢,等. 2015. 新疆野杏种质资源表型性状多样性研究.西北植物学报, 35(5):1021-1030.
(Liu J, Liao K, Liu H, et al. 2015. Phenotypic diversity of wild Apricot germplasm resources in Xinjiang. Acta Botanica Boreali-Occidentalia Sinica, 35(5):1021-1030.[in Chinese])
柳江群, 尹明宇, 左丝雨, 等. 2017. 长柄扁桃天然种群表型变异. 植物生态学报, 41(10):1091-1102.
(Liu J Q, Yin M Y, Zuo S Y, et al.2017. Phenotypic variations in natural populations of Amygdalus pedunculata. Chinese Journal of Plant Ecology, 41(10):1091-1102.[in chinese])
尚帅斌, 郭俊杰, 王春胜,等. 2015. 海南岛青梅天然居群表型变异. 林业科学, 51(2):154-162.
(Shang S B, Guo J J, Wang C S, et al. 2015. Phenotypic variations in natural populations of Vatica mangachapoi in Hainan, China. Scientia Silvae Sinicae, 51(2):154-162.[in Chinese])
唐继新, 贾宏炎, 麻静,等. 2015.南亚热带珍稀濒危树种格木生长规律研究. 中南林业科技大学学报, 35(7):37-44.
(Tang J X, Jia H Y, Ma J, et al. 2015. Study on the growth law of a rare and endangered tree species of Erythrophleum fordii in south subtropical area of China. Journal of Central South University of Forestry & Technology, 35(7):37-44.[in Chinese])
T L 怀特, W T 亚当斯, D B 尼尔. 2013. 森林遗传学. 崔建国,李火根,译. 北京:科学出版社, 230-250.
(White T L, Adams W T, Neale D B. 2013. Forest Genetics. Translated by Cui J G and Li H G. Beijing:Science Press, 230-250.[in Chinese])
王娅丽, 李毅, 陈晓阳. 2008. 祁连山青海云杉天然群体表型性状遗传多样性分析. 林业科学, 44(2):70-77.
(Wang Y L, Li Y, Chen X Y. 2008. Phenotypic diversity of natural population in Picea crassifolia in Qilian mountains. Scientia Silvae Sinicae, 44(2):70-77.[in Chinese])
尹明宇, 高福玲, 乌云塔娜. 2017. 内蒙古西伯利亚杏种质资源表型多样性研究. 植物遗传资源学报, 18(2):242-252.
(Yin M Y, Gao F L, Wuyun Tana. 2017. High-level genetic diversity of Siberian Apricot(Armeniaca sibirica) in Inner Mongolia revealed by phenotyping. Journal of Plant Genetic Resources, 18(2):242-252.[in Chinese])
赵志刚. 2011. 珍稀濒危树种格木保护生物学研究. 北京:中国林业科学研究院博士学位论文.
(Zhao Z G. 2011. Conservation biology of Erythrophleum fordii Oliv., a rare and endangered tree species in south China. Beijing:PhD thesis of Chinese Academy of Forestry.[in Chinese])
赵志刚, 郭俊杰, 沙二,等. 2009. 我国格木的地理分布与种实表型变异. 植物学报, 44(3):338-344.
(Zhao Z G, Guo J J, Sha E, et al. 2009. Geographic distribution and phenotypic variation of fruit and seed of Erythrophleum fordii in China. Bulletin of Botany, 44(3):338-344.[in Chinese])
郑万钧. 1985. 中国树木志. 北京:中国林业出版社,1207-1209.
(Zheng W J. 1985. Records of Chinese trees. Beijing:China Forestry Publishing House, 1207-1209.[in Chinese])
中国科学院植物研究所. 1989. 中国珍稀濒危植物. 上海:上海教育出版社, 188-190.
(Institute of Botany, The Chinese academy of Science.1989. Rare and endangered plants in China. Shanghai:Shanghai Education Publishing House, 188-190.[in Chinese])
朱积余, 廖培来. 2006. 广西名优经济树种. 北京:中国林业出版社, 61-64.
(Zhu J Y, Liao P L. 2006. Famous and high-quality economic tree species in Guangxi. Beijing:China Forestry Publishing House, 61-64.[in Chinese])
Buss G R. 1995. Microsatellite and amplified sequence length polymorphisms in cultivated and wild soybean. Genome, 38(4):715-723.
Forcada J, Hoffman J I. 2014. Climate change selects for heterozygosity in a declining fur seal population. Nature, 511(7510):462-475.
Hake S, Ross-Ibarra J. 2015. Genetic, evolutionary and plant breeding insights from the domestication of maize. Elife, 4(4):61-71.
Pinsky M L, Palumbi S R. 2014. Meta-analysis reveals lower genetic diversity in overfished populations. Molecular Ecology, 23(1):29-39.
Soares M P, Weiss G. 2015. The Iron age of host-microbe interactions. EMBO Reports, 16(11):1482-1500.
Spielman D, Brook B W, Frankham R. 2004. Most species are not driven to extinction before genetic factors impact them. Proceedings of the National Academy of Sciences of the United States of America, 101(42):15261-15264.

[1]	徐永杰, 韩华柏, 王滑, 陈凌娜, 马庆国, 裴东. 大巴山区核桃实生居群的坚果表型和遗传多样性[J]. 林业科学, 2016, 52(5): 111-119.
[2]	尚帅斌, 郭俊杰, 王春胜, 赵志刚, 曾杰. 海南岛青梅天然居群表型变异[J]. 林业科学, 2015, 51(2): 154-162.
[3]	林玲, 王军辉, 罗建, 陈帅. 砂生槐天然群体种实性状的表型多样性[J]. 林业科学, 2014, 50(4): 137-143.
[4]	赵志刚, 郭俊杰, 曾杰, 徐建民. 广西大明山格木种群的空间分布格局与数量动态特征[J]. 林业科学, 2014, 50(10): 1-7.
[5]	王永康, 吴国良, 赵爱玲, 李登科. 枣种质资源的表型遗传多样性[J]. 林业科学, 2014, 50(10): 33-41.
[6]	黄红兰, 张露, 郭晓燕, 梁跃龙, 刘足根. 九连山毛红椿种群的结实特性及其生殖力[J]. 林业科学, 2013, 49(7): 170-174.
[7]	王亚飞;王强;阮晓;张莺莺. 红豆杉属植物资源的研究现状与开发利用对策[J]. 林业科学, 2012, 48(5): 116-125.
[8]	梁艳;徐刚标;张合平;吴雪琴;申响保;王爱云. 南岭山地伯乐树天然种群和人工种群遗传多样性比较[J]. 林业科学, 2012, 48(12): 45-52.
[9]	刘方炎;李昆;廖声熙;崔永忠. 濒危植物翠柏的个体生长动态及种群结构与种内竞争[J]. 林业科学, 2010, 46(10): 23-28.
[10]	郝朝运　张小平　张昱　李文良. 濒危植物永瓣藤的种群生命表与动态分析*[J]. 林业科学, 2009, 12(9): 79-84.
[11]	董东平郑敬刚叶永忠. 河南嵩山国家森林公园木本植物区系[J]. 林业科学, 2009, 12(3): 160-166.
[12]	魏志刚高玉池刘桂丰刘关君杨传平. 白桦核心种质初步构建*[J]. 林业科学, 2009, 12(10): 74-80.
[13]	王娅丽李毅. 陈晓阳. 祁连山青海云杉天然群体表型性状遗传多样性分析*[J]. 林业科学, 2008, 44(2): 70-77.
[14]	胡世俊何平王瑞波方兴. 濒危植物缙云卫矛不同种群的种子萌发研究[J]. 林业科学, 2007, 43(05): 42-47.
[15]	程诗明;顾万春. 苦楝表型性状梯度变异的研究[J]. 林业科学, 2006, 42(05): 29-35.