白桦四倍体与二倍体杂交的亲本配合力分析

doi:10.11707/j.1001-7488.LYKX20220704

摘要/Abstract

摘要： 目的基于白桦四倍体与二倍体杂交产生的子代（三倍体）测定分析结果，选出生长与材质性状兼优的杂交优势亲本及组合，为种子园的亲本选配提供理论依据。方法以白桦测交系交配设计获得的40个杂交组合10年生杂种试验林为研究对象，测定各杂交组合的生长、材性和保存率等性状，利用SPSS22. 0、WinNCⅡ等软件对各性状进行方差、配合力及效应值分析，采用隶属函数法并结合主成分分析综合评价各性状，选择杂交优势亲本及组合。结果 1）不同亲本杂交组合间的生长、材性和保存率等性状方差分析显示（除木材密度和保存率性状外），7个性状的组合间方差、配合力方差均达显著或极显著水平；7个性状的变异系数在6.34%～55.29%之间，广义遗传力和狭义遗传力分别在38.83%～73.72%和22.23%～68.48%之间，其中部分性状家系间变异较大、遗传能力较强。2）树高、胸径、材积、木质素含量和纤维长宽比5个性状的一般配合力（GCA）效应以及特殊配合力（SCA）效应差异均达显著或极显著水平。双亲的加性效应对胸径、材积等生长性状以及纤维素、半纤维素、纤维长宽比等材质性状具有明显影响，母本的加性效应远大于父本，且占主导地位，各性状中母本的方差分量在43.11%～94.15%之间，父本在0～4.86%之间。由特殊配合力效应分析发现，SCA仅对木质素含量和树高的控制较强，分别为52.03%和44.55%。3）根据亲本及杂交组合间各性状配合力效应值，采用隶属函数并结合主成分分析对各亲本及组合进行综合评价发现，父本F4、F7和F10为优异父本，Q19和Q103为生长或木材纤维性状的优异母本，其中Q103的材积遗传增益达8.60%。选择Q33×F1、Q103×F10、Q13×F12和Q19×F11为生长或纤维性状的优异杂交组合，其中Q33×F1和Q103×F10组合的材积遗传增益分别为16.33%和15.62%。结论白桦母本加性效应为本研究性状表现的主要贡献者；依据白桦三倍体家系生长、材性的各配合力效应值，最终选出优异父本3个（F4、F7和F10）、母本2个（Q19和Q103），优良杂交组合4个（Q33×F1、Q103×F10、Q13×F12和Q19×F11）。

关键词: 白桦, 三倍体, 测交系交配设计, 配合力分析

Abstract: Objective Based on the field trial on the triploid progeny produced from crossing between tetraploid and diploid birches, several superior parents and their combinations were selected with excellent growth and wood properties. This study aims to provide a scientific basis for parent selection in establishing birch seed orchards. Method This experiment was conducted in a field trial forest of 10-year-old progeny of 40 full-sib families derived from different parental combinations. Tree height (H), diameter at breast height (DBH), single tree volume, wood basic density, cellulose content, hemicellulose content, lignin content, fiber aspect ratio traits and retention rate of planted trees were measured respectively. SPSS 22.0 and WinNCII were used analyze variance, general combining ability (GCA) and specific combining ability (SCA) of each trait. Membership function and principal component analysis (PCA) were also used to identify the best overall performance of parental combinations. Result 1) Except the traits of wood basic density and tree retention rate, the variance of parental combination, GCA and SCA of remaining seven traits reached significant or extremely significant levels. The coefficient of variation of the seven traits ranged from 6.34% to 55.29%, and the broad-sense and narrow-sense heritability were between 38.83%–73.72% and 22.23%–68.48%, respectively. Some traits had significant variation and strong genetic ability among families, indicating that the selection opportunities were expected in this study. 2) Further analysis on the seven traits showed that the differences in the GCA and SCA effects of tree height, DBH, volume, lignin content and fiber length/width reached significant or extremely significant levels. The additive effect of parents was significant on traits of DBH, volume, cellulose hemicellulose content and fiber length/width ratio. By comparing the additive effect of maternal parent and paternal parent, it was found that the maternal parent had much greater effect on the observed traits than the paternal parent effect. The variance component of maternal parent was 43.11%–94.15%, while that of paternal parent was 0–4.86%. It was found that the lignin content and tree height traits were strong controlled by SCA effect only, which accounted for 52.03% and 44.55%, respectively. 3) Based on the combined analysis of membership function and PCA with GCA and SCA effect, F4, F7 and F10 were selected as superior male parents and Q19 with Q103 as superior female parents for growth or wood fiber traits, of which the volume genetic gain of Q103 reached 8.60%. Q33×F1, Q103×F10, Q13×F12 and Q19×F11 were selected as superior parental combinations, of which the volume genetic gain of Q33×F1 and Q103×F10 were 16.33% and 15.62% , respectively. Conclusion The main contributor to the performance of traits in this study is the additive effect of birch maternal parents. Based on growth and wood property measurements of birch triploid families and statistical analysis, three excellent male parents, two female and four superior parental combinations have finally been selected. This study provides a scientific basis for the establishing next generation birch seed orchard.

Key words: birch, triploid, tester mating design, combining ability analysis

中图分类号:

S792.15

董琳琳, 张国成, 刘立辉, 计家宝, 白向东, 顾宸瑞, 姜静, 刘桂丰. 白桦四倍体与二倍体杂交的亲本配合力分析[J]. 林业科学, 2023, 59(9): 75-84.

Dong Linlin, Zhang Guocheng, Liu Lihui, Ji Jiabao, Bai Xiangdong, Gu Chenrui, Jiang Jing, Liu Guifeng. Parental Combining Ability for Growth and Wood Property of Hybrids between Tetraploid and Diploid Betula platyphylla[J]. Scientia Silvae Sinicae, 2023, 59(9): 75-84.

参考文献

曹士晗, 张桂芹, 赵兴江, 等. 2013. 水曲柳种子园半双列杂交配合力测定初报. 林业科技, 38(5): 22-24.
Cao S H, Zhang G Q, Zhao X J, et al. 2013. Preliminary report on the combining ability under half diallel mating design in ash breeding seed orchard. Forestry Science and Technology, 38(5): 22-24. [in Chinese]
董虹妤, 刘青华, 周志春, 等. 2016. 马尾松3代杂交子代幼林松脂化学组分的GCA/SCA分析. 林业科学研究, 29(5): 654-661.
Dong H Y, Liu Q H, Zhou Z C, et al. 2016. GCA/SCA analysis of the chemical composition of pine resin in the 3rd generation hybrid offspring of Pinus massoniana. Forest Research, 29(5): 654-661. [in Chinese]
董雷鸣, 张守攻, 孙小梅, 等. 2019. 日本落叶松全双列交配生长性状的遗传分析. 林业科学研究, 32(4): 11-18.
Dong L M, Zhang S G, Sun X M, et al. 2019. Genetic analysis of growth traits of Japanese Larch under full-diallel mating design. Forest Research, 32(4): 11-18. [in Chinese]
金冬雪. 2021. 转BpGLK1白桦生长、叶色变异分析及环境安全性初步评价. 哈尔滨: 东北林业大学.
Jin D X. 2021. Analysis of growth, leaf color variation of trans-BpGLK1 birch and preliminary evaluation of environmental safety. Harbin: Northeast Forestry University.［in Chinese］
金国庆, 秦国峰, 刘伟宏, 等. 2008. 马尾松测交系杂交子代生长性状遗传分析. 林业科学, 44(1): 70-76.
Jin G Q, Guo G F, Liu W H, et al. 2008. Genetic analysis of growth traits of hybrid offspring of Pinus massoniana under tester mating design. Scientia Silvae Sinicae, 44(1): 70-76. [in Chinese]
康向阳. 2003. 林木多倍体育种研究进展. 北京林业大学学报, 25(4): 70-74.
Kang X Y. 2003. Research progress of polyploid species of forest trees. Journal of Beijing Forestry University, 25(4): 70-74. [in Chinese]
李春旭, 刘桂丰, 刘宇, 等. 2017. 盆栽白桦优良无性系苗期的初步选择. 北京林业大学学报, 39(2): 16-23.
Li C X, Liu G F, Liu Y, et al. 2017. Preliminary selection of excellent clones of potted birch. Journal of Beijing Forestry University, 39(2): 16-23. [in Chinese]
李贵雨, 卫星, 汤园园, 等. 2016. 白桦不同轻基质容器苗生长及养分分析. 林业科学, 52(7): 30-37.
Li G Y, Wei X, Tang Y, et al. 2016. Growth and nutrient analysis of seedlings in different light substrate containers of birch. Scientia Silvae Sinicae, 52(7): 30-37. [in Chinese]
李周岐, 王章荣. 2001. 鹅掌楸属种间杂种苗期生长性状的亲本配合力分析. 西北林学院学报, 16(3): 7-10, 17.
Li Z Q, Wang Z R. 2001. Analysis of parental compatibility of interspecific hybrid growth traits at seedling stage of Catalpa spp. Journal of Northwest Forestry College, 16(3): 7-10, 17. [in Chinese]
林琳, 穆怀志, 刘桂丰, 等. 2012. 白桦不同杂交组合三倍体子代当年生苗木生长性状分析. 北京林业大学学报, 34(5): 1-5.
Lin L, Mu H Z, Liu G F, et al. 2012. Growth traits of different hybrid combinations of birch triploid offspring in the current year. Journal of Beijing Forestry University, 34(5): 1-5. [in Chinese]
刘超逸, 刘桂丰, 方功桂, 等. 2017. 四倍体白桦木材纤维性状比较及优良母树选择. 北京林业大学学报, 39(2): 9-15.
Liu C Y, Liu G F, Fang G G, et al. 2017. Comparison of fibrous traits of tetraploid birch wood and selection of excellent mother trees. Journal of Beijing Forestry University, 39(2): 9-15. [in Chinese]
刘福妹, 穆怀志, 刘子嘉, 等. 2013. 用秋水仙素处理不同家系白桦种子诱导四倍体的研究. 北京林业大学学报, 35(3): 84-89.
Liu F M, Mu H, Liu Z J, et al. 2013. Study on the induction of tetraploidy by treating different lineages of birch seeds with colchicine. Journal of Beijing Forestry University, 35(3): 84-89. [in Chinese]
刘青华, 金国庆, 储德裕, 等. 2011. 基于马尾松测交系子代的生长、干形和木材密度的配合力分析. 南京林业大学学报(自然科学版), 35(2): 8-14.
Liu Q H, Jin G Q, Chu D Y, et al. 2011. Combining ability analysis based on growth, stem form and wood density of the offspring of Pinus massoniana under tester mating design. Journal of Nanjing Forestry University (Natural Science Edition), 35(2): 8-14. [in Chinese]
刘　宇. 2016. 白桦三倍体种子园优良亲本综合选择. 哈尔滨: 东北林业大学.
Liu Y. 2016. Comprehensive selection of excellent parents in birch triploid seed garden. Harbin: Northeast Forestry University.［in Chinese］
刘宇, 徐焕文, 姜静, 等. 2014. 基于种子活力及苗期生长性状的白桦四倍体半同胞家系初选. 北京林业大学学报, 36(2): 74-80.
Liu Y, Xu H W, Jiang J, et al. 2014. Preliminary selection of birch tetraploid half-sibling family based on seed viability and growth traits at seedling stage. Journal of Beijing Forestry University, 36(2): 74-80. [in Chinese]
刘宇, 徐焕文, 李志新, 等. 2015. 白桦杂交子代家系生长变异及稳定性分析. 植物研究, 35(6): 937-944.
Liu Y, Xu H W, Li Z X, et al. 2015. Growth variation and stability analysis of birch hybrid offspring lineage. Bulletin of Botanical Research, 35(6): 937-944. [in Chinese]
穆怀志, 刘桂丰, 姜静, 等. 2009. 白桦半同胞子代生长及木材纤维性状变异分析. 东北林业大学学报, 37(3): 1-8.
Mu H Z, Liu G F, Jiang J, et al. 2009. Growth and fibrous traits of wood analysis of Birch platyphylla half-sib offspring. Journal of Northeast Forestry University, 37(3): 1-8. [in Chinese]
南京林学院. 1984. 林木良种选育方法. 中国林业出版社.
Nanjing Forestry University. 1984. Breeding method of fine forest seeds. China Forestry Publishing House.［in Chinese］
宁坤, 刘笑平, 林永红, 等. 2015. 白桦子代遗传变异与纸浆材优良种质选择. 植物研究, 35(1): 39-46.
Ning K, Liu X P, Lin Y H, et al. 2015. Genetic variation of birch offspring and selection of excellent germplasm of pulp. Bulletin of Botanical Research, 35(1): 39-46. [in Chinese]
童春发, 杨立伟, 蒋安纳, 等. 2013. 不平衡巢式设计遗传模型分析. 林业科学, 49(3): 1-8.
Tong C F, Yang L W, Jiang A N, et al. 2013. Genetic model analysis of unbalanced nest design. Scientia Silvae Sinicae, 49(3): 1-8. [in Chinese]
童春发, 蒋安纳, 杨立伟, 等. 2014. WinNC2: 因子交配设计遗传分析软件. 林业科学, 50(1): 55-62.
Tong C F, Jiang A N, Yang L W, et al. 2014. WinNC2: genetic analysis software for factor mating design. Scientia Silvae Sinicae, 50(1): 55-62. [in Chinese]
王成, 滕文华, 姜静, 等. 2011. 白桦5×5双列杂交子代生长性状的遗传效应分析. 北京林业大学学报, 33(3): 14-20.
Wang C, Teng W H, Jiang J, et al. 2011. Analysis of genetic effects on growth traits in a 5×5 full diallel cross of Betula platyphylla. Journal of Beijing Forestry University, 33(3): 14-20. [in Chinese]
杨传平, 刘桂丰, 魏志刚, 等. 2004. 白桦强化促进提早开花结实技术的研究. 林业科学, 40(6): 75-78.
Yang C P, Liu G F, Wei Z G, et al. 2004. Birch strengthening to promote early flowering and fruiting techniques. Scientia Silvae Sinicae, 40(6): 75-78. [in Chinese]
叶培忠, 陈岳武, 刘大林, 等. 1981. 配合力分析在杉木数量遗传研究中的应用. 南京林业大学学报(自然科学版), 24(3): 1-21.
Ye P Z, Chen Y W, Liu D L, et al. 1981. Application of synergy analysis in genetic study of fir number. Journal of Nanjing Forestry University (Natural Science Edition), 24(3): 1-21. [in Chinese]
叶志宏, 施季森, 翁玉榛, 等. 1991. 杉木十一亲本双列交配遗传分析. 中国林学会林木遗传育种分会学术会议论文集, 武汉：中国.
Ye Z H, Shi J S, Weng Y Z, et al. 1991. Genetic analysis of Chinese fir under full-diallel mating design with eleven parents. Proceeding of the Annals Meeting on Chinese fir Genetic Improvement, organized by the Society of Forest Genetics and Breeding, CSF. at Tongdao, Wuhan: China. ［in Chinese］
曾广植. 2006. 对用纸浆纤维筛分组分评价纸张综合强度影响关系的探讨. 纸和造纸, 25(5): 74-75.
Zeng G Z. 2006. The discussion of using pulp fiber fraction to estimate the paper comprehensive strength. Paper and Paper Making, 25(5): 74-75. [in Chinese]
张爱民. 1994. 植物育种亲本选配的理论和方法. 北京: 农业出版社.
Zhang A M. 1994. Theory and method of parent selection in plant breeding. Beijing: Agriculture Press.［in Chinese］
张建龙. 2019. 中国森林资源报告. 北京: 中国林业出版社.
Zhang J L. 2019. China forest resources report. Beijing: China Forestry Publishing House.［in Chinese］
Bai F Y, Kang N, Kang X Y, et al. 2019. Selection of female parents with high fertility and high combining abilities for cross-breeding Populus tomentosa. Journal of Forestry Research, 30(2): 445-450.
Brennan A N, McKenna J R, Hoban S M, et al. 2020. Hybrid breeding for restoration of threatened forest trees: evidence for incorporating disease tolerance in Juglans cinerea. Frontiers in Plant Science, 11: 580693.
Huang H J, Wang S, Jiang J, et al. 2014. Overexpression of BpAP1 induces early flowering and produces dwarfism in Betula platyphylla×Betula pendula. Physiologia Plantarum, 151(4): 495-506.
Li H Y, Wu D Y, Wang Z J, et al. 2016. BpMADS12 mediates endogenous hormone signaling: effect on plant development Betula platyphylla. Plant Cell, Tissue and Organ Culture, 124 (1): 169-180.
Mu H Z, Jiang J, Liu G F, et al. 2012a. Transcriptomic analysis of phenotypic changes in birch (Betula platyphylla) autotetraploids. International Journal of Molecular Sciences, 13(10): 13012-13029.
Mu H Z, Jiang J, Li H Y, et al. 2012b. Seed vigor, photosynthesis and early growth of saplings of different triploid Betula families. Dendrobiology, 68: 11-20.
Serapiglia M J, Gouker F E, Hart J F, et al. 2014. Ploidy level affects important biomass traits of novel shrub willow (Salix) hybrids. Bioenergy Research, 8(1): 259-269.
Xu H W, Liu Y, Jiang J, et al. 2016. Progeny test of tetraploid Betula platyphylla and preliminary selection of hybrid parents. Journal of Forestry Research, 27(3): 665-674.
Yang G, Chen S, Jiang J, et al. 2015. Transcriptome analysis reveals the role of BpGH 3.5 in root elongation of Betula platyphylla×B. pendula. Plant Cell, Tissue and Organ Culture, 121(3): 605-617.
Yang Y F, Hou L J, Wei Z C, et al. 2000. A phytosociological study on Betula platyphylla forests in Daxing’an Mountains of China. Journal of Forestry Research, 11(1): 23-28.
Zhang W B, Wei R, Chen S, et al. 2015. Functional characterization of CCR in birch (Betula platyphylla×Betula pendula) through overexpression and suppression analysis. Physiologia Plantarum, 154(2): 283-296.

[1]	张兹鹏,王君杰,刘索名,姜立春. 形率对白桦单木材积和生物量预测精度的影响[J]. 林业科学, 2022, 58(5): 31-39.
[2]	王律几,张晓晓,王君. 基于45S rDNA-FISH的异源三倍体'银中杨’小孢子母细胞减数分裂染色体行为追踪[J]. 林业科学, 2022, 58(3): 69-78.
[3]	胡建文,王庆成. 早春树干液流用于白桦营养诊断的可行性[J]. 林业科学, 2022, 58(11): 174-180.
[4]	段光爽,郑亚丽,洪亮,宋新宇,符利勇. 基于潜在生产力的华北落叶松纯林和白桦山杨混交林立地质量评价[J]. 林业科学, 2022, 58(10): 1-9.
[5]	张晓芳,郭旭展,洪亮,陈涛,符利勇,张会儒. 冬奥核心区华北落叶松和白桦单木冠幅预测模型——组级贝叶斯模型、加性模型和混合效应模型比较[J]. 林业科学, 2022, 58(10): 89-100.
[6]	黄宏超,谢栋博,段光爽,张状,张海江,符利勇. 华北落叶松和白桦半参数树高曲线模型[J]. 林业科学, 2022, 58(10): 101-110.
[7]	刘中原,刘峥,徐颖,刘珊珊,田志兰,解庆军,高彩球. 白桦HSFA4转录因子的克隆及耐盐功能分析[J]. 林业科学, 2020, 56(5): 69-79.
[8]	Shahzad Muhammad Khurram,Hussain Amna,何培,姜立春. 大兴安岭白桦削度方程[J]. 林业科学, 2020, 56(11): 87-96.
[9]	金明月, 姜峰, 金光泽, 刘志理. 不同年龄白桦比叶面积的生长阶段变异及冠层差异[J]. 林业科学, 2018, 54(9): 18-26.
[10]	田梦迪, 李燕杰, 张平冬, 王健, 郝静颐. 高温诱导银灰杨花粉染色体加倍创制杂种三倍体[J]. 林业科学, 2018, 54(3): 39-47.
[11]	席本野, 王烨, 贾黎明. 滴灌施肥下施氮量和施氮频率对毛白杨生物量及氮吸收的影响[J]. 林业科学, 2017, 53(5): 63-73.
[12]	刘宇, 徐焕文, 尚福强, 焦宏, 张利民, 罗建新, 滕文华, 刘桂丰. 16年生白桦种源变异及区划[J]. 林业科学, 2016, 52(9): 48-56.
[13]	李贵雨, 卫星, 汤园园, 吕琳, 杜欣竹. 白桦不同轻基质容器苗生长及养分分析[J]. 林业科学, 2016, 52(7): 30-37.
[14]	李永宁, 刘丽颖, 冯楷斌, 黄选瑞. 燕山北部白桦林剥皮木的空间分布特征及风折规律[J]. 林业科学, 2016, 52(1): 10-17.
[15]	王冬至, 张冬燕, 张志东, 黄选瑞. 基于非线性混合模型的针阔混交林树高与胸径关系[J]. 林业科学, 2016, 52(1): 30-36.