12个欧美杨无性系生长初期基因型与环境的互作效应

doi:10.11707/j.1001-7488.20200808

摘要/Abstract

摘要：

目的: 研究12个欧美杨杂交无性系生长初期在不同环境下生长性状的观测值变异，从基因型与环境互作效应的角度入手，筛选可以推广的稳产、丰产的优良基因型；总结试验中适地适品种的规律；评价试验地点的区分力和代表性。为后续欧美杨的育种工作提供相关技术支撑。方法: 试验材料为3年生的12个不同基因型的欧美杨杂交无性系，设计了辽宁黑山、河北滦南、湖北石首和山东诸城、郓城、宁阳6个试验地点，测定树高、胸径，计算变异系数和均值进行初步比较，利用ASReml-R软件建立混合效应模型，利用预测性状值作GGE双标图，分析并总结其中规律用以评价试验地点和筛选优良基因型。结果: 整体上胸径的变异大于树高，黑山和石首的变异较大。均值统计的结果表明，不同基因型的生长性状在同一环境下的表现不同，同一基因型的生长性状在不同环境下的表现也不同；经混合线性模型检验，基因型、环境及基因型与环境的互作对于生长初期的欧美杨树高、胸径存在极显著（P < 0.01）的效应，由区组带来的效应也极显著。提取性状预测值作GGE双标图，拟合度均在80%以上，结果近乎与实际情况一致。GGE双标图的结果表明，对于树高的表现和胸径的表现，环境间的关系相似但不相同；树高、胸径的表现均存在交叉性互作现象；入选基因型有5号、7号、3号、4号和9号，其中4号、5号和7号为全同胞家系。父本的遗传物质和种源地对杂交无性系的表现有明显可见的影响，荷兰北方型的欧洲黑杨N146是优良的父本材料。结论: 1）生长初期欧美杨杂交无性系树高、胸径在东北地区和华中地区变异较大；欧美杨杂交无性系在生长初期的生长性状受基因型、环境及其交互作用的显著影响。2）由GGE双标图中的信息，综合筛选出丰产性较高稳产性最高的基因型7号、丰产基因型5号、高于平均产量且丰产稳产都较好的基因型4号。3）在黑山地区和诸城地区适合栽植基因型3号和4号；在宁阳地区和石首地区适合栽植5号基因型；滦南地区和郓城地区适合栽植7号基因型。

关键词: 欧美杨, 无性系, 混合效应模型, 基因型与环境互作, GGE双标图, 基因型筛选

Abstract:

Objective: Variation of growth traits in 12 hybrid clones of Populus×euramericana in different environments was investigated to study the genotype by environment interaction. We screened superior genotypes that can be promoted for stable and high yield, summarized patterns of the interaction how varieties adapting to site conditions in the trials, and evaluated the discrimination and representation of the test sites. It aims to provide technical support for the follow-up work of the Populus×euramericana. Method: The test materials were 12 different genotypes of 3-year-old Populus×euramericana hybrid clones. Six test sites in Heishan, Luannan, Zhucheng, Yuncheng, Ningyang and Shishou were used in the trials. The tree height and DBH were measured, and the coefficient of variation and the mean were calculated for preliminary comparison. A mixed effect model was established using the ASReml-R package, and the predicted trait values were used to generate GGE biplots. Patterns of variation were analyzed and used to evaluate the test site and to select superior genotypes. Result: Overall, the variation is greater in DBH than in tree height, and the variation in Heishan and Shishou is larger. The statistics show that the growth traits of different genotypes behave differently under the same environment, and that the growth traits of the same genotype behave differently under different environments. The test by the mixed linear model shows that genotype, environment, and genotype-environment interaction have very significant (P < 0.01) effects on the tree height and DBH of Populus×euramericana in the early growth, and the effect brought by the block is also very significant (P < 0.01). The predicted values of the traits are extracted as GGE biplots, the fitting degrees are all above 80%, and the results are almost consistent with the actual situation. The GGE biplots show that the relationship between the environment of tree height and DBH is similar but not the same; there is crossover interaction in the tree height and DBH; the selected genotypes are 5, 7, 3, 4 and 9. Among them, genotype 4, 5 and 7 belong to a full sib family. The genetic material and provenance of the male parent have a visible effect on the performance of hybrid clones, and N146 is an excellent genetic material. Conclusion: 1) The tree height and DBH of Populus×euramericana in the early growth stage are highly variable in Northeast China and Central China; the growth traits of Populus×euramericana in the early growth stage are significantly affected by genotype and environment and their interaction. 2) From the information in the GGE biplots, selected genotypes are the genotype 7 with high yield and the highest stability of yield, the genotype 5 with high yield, and the genotype 4 with a yield higher than the average and a high yield stability. 3) It is suitable to grow the genotype 3 and 4 in Heishan and Zhucheng areas; it is suitable to grow genotype 5 in Ningyang and Shishou areas; it is suitable to grow genotype 7 in Luannan and Yuncheng areas.

Key words: Populus×euramericana, clones, mixed effect model, genotype by environment interaction, GGE biplot, genotype selection

中图分类号:

S722.3

刘宁,丁昌俊,李波,丁密,苏晓华,黄秦军. 12个欧美杨无性系生长初期基因型与环境的互作效应[J]. 林业科学, 2020, 56(8): 63-72.

Ning Liu,Changjun Ding,Bo Li,Mi Ding,Xiaohua Su,Qinjun Huang. Effects of Genotype by Environment Interaction of 12 Populus×euramericana Clones in Their Early Growth[J]. Scientia Silvae Sinicae, 2020, 56(8): 63-72.

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环境因子 Environmental factor	诸城 Zhucheng	郓城 Yuncheng	宁阳 Ningyang	滦南 Luannan	石首 Shishou	黑山 Heishan
土壤类型Soil type	壤质 Loam	沙质 Sandy	沙壤质 Sandy and loam mixed	沙质 Sandy	壤质 Loam	沙质 Sandy
气温年较差Annual temperature range /℃	27.2	27.9	28	30.6	23.9	34.2
年平均气温Average annual temperature /℃	13.1	13.9	13.7	11.4	16.9	9.0
年平均气温日较差Average annual daily temperature range /℃	9.6	10.2	11.2	10.2	7.4	10.2
年平均最低气温Average annual minimum temperature /℃	8.9	9.4	8.7	6.8	13.7	4.2
年日降水量≥10.0 mm日数 Daily precipitation in a year ≥10.0 mm days /d	20.9	16.7	18.2	15.9	36.1	16.8
年日最低气温≤2.0 ℃日数 Daily minimum temperature in a year ≤2.0 ℃ days /d	114.5	111.8	118	139.7	42.1	159.4
年日最高气温≥30.0 ℃日数 Daily maximum temperature in a year ≥30.0 ℃ days /d	52.7	73.4	75.7	46.4	79.9	22.9
年平均风速Average annual wind speed /(m·s ^-1)	3.1	1.9	1.8	2.2	2.2	3.4
平均月日照时长Average monthly sunshine duration /h	200.5	181.8	160.6	201.7	141.8	229.1
平均年日照时长Average annual sunshine duration /h	2 405.7	2 182.0	1 927.2	2 420.7	1 702.0	2 749.1

基因型编号 Genotypic number	无性系 Clones	亲本 Parents	父本来源 Origin of male parent
1	11-20-2	P. deltoides ‘Danhong’× P. nigra ‘N46’	俄罗斯北部Northern Russia
2	11-21-8	P. deltoides ‘Danhong’× P. nigra ‘N50’	俄罗斯北部Northern Russia
3	11-24-4	P. deltoides ‘Danhong’× P. nigra ‘N120’	德国北部Northern Germany
4	11-26-10	P. deltoides ‘Danhong’× P. nigra ‘N146’	荷兰北部Northern Netherlands
5	11-26-4	P. deltoides ‘Danhong’× P. nigra ‘N146’	荷兰北部Northern Netherlands
6	11-26-8	P. deltoides ‘Danhong’× P. nigra ‘N146’	荷兰北部Northern Netherlands
7	11-26-9	P. deltoides ‘Danhong’× P. nigra ‘N146’	荷兰北部Northern Netherlands
8	11-27-4	P. deltoides ‘Danhong’× P. nigra ‘N150’	荷兰北部Northern Netherlands
9	11-28-11	P. deltoides ‘Danhong’× P. nigra ‘N166’	荷兰北部Northern Netherlands
10	11-32-1	P. deltoides ‘Zhongshi8’× P. nigra ‘N23’	德国北部Northern Germany
11	11-36-26	P. deltoides ‘Zhongshi8’× P. nigra ‘N31’	意大利南部Southern Italy
12	11-40-2	P. deltoides ‘Zhongshi8’× P. nigra ‘N39’	意大利南部Southern Italy

基因型 Genotype	树高Tree height							胸径DBH
基因型 Genotype	黑山 Heishan	滦南 Luannan	宁阳 Ningyang	石首 Shishou	郓城 Yuncheng	诸城 Zhucheng	总变异 Total variation	黑山 Heishan	滦南 Luannan	宁阳 Ningyang	石首 Shishou	郓城 Yuncheng	诸城 Zhucheng	总变异 Total variation
1	18.55	10.57	5.22	33.85	9.70	5.27	30.51	19.33	14.11	6.32	43.90	15.25	19.14	40.32
2	11.89	12.83	18.04	21.06	16.88	23.95	27.12	14.50	17.07	15.84	14.11	22.84	26.34	40.98
3	11.36	6.84	15.22	24.88	9.46	6.89	24.19	15.52	10.90	12.40	12.55	13.82	19.54	36.92
4	11.18	8.57	2.57	24.89	10.19	4.83	26.67	15.71	14.67	7.26	33.02	19.15	21.28	40.91
5	23.34	7.95	6.37	25.10	7.25	24.32	31.25	30.82	13.22	12.58	34.25	11.44	22.78	40.00
6	10.00	8.72	14.80	21.52	10.51	6.49	32.73	16.05	11.84	10.81	20.27	13.92	19.87	42.86
7	19.82	8.76	12.28	19.75	4.02	12.56	29.03	24.87	13.63	9.93	29.95	10.03	28.46	41.43
8	29.49	10.77	19.94	12.66	9.66	9.07	30.77	35.84	13.31	8.48	25.72	15.40	14.76	43.64
9	21.11	8.62	15.81	29.30	8.27	8.70	29.51	26.46	13.19	7.70	37.98	14.66	19.07	41.94
10	28.43	10.09	7.80	16.64	19.32	6.72	35.71	35.38	13.16	9.22	29.57	17.52	14.47	41.38
11	21.81	11.49	13.29	16.58	6.88	9.92	33.33	27.71	14.94	8.86	20.24	9.60	19.41	43.40
12	18.53	11.42	7.06	16.16	10.21	7.99	36.21	23.74	16.91	10.34	26.81	8.99	17.05	41.82
总变异 Total variation	20.93	10.77	12.90	26.98	13.04	13.33		27.91	15.94	13.33	35.29	20.00	23.64

变异类型 Type of variation	树高Tree height				胸径DBH
变异类型 Type of variation	自由度 Degree of freedom	平方和 Sum of square	F	P	自由度 Degree of freedom	平方和 Sum of square	F	P
基因型Genotype	11	109.81	153.56	< 0.01	11	331.2	301.3	< 0.01
地点Site	5	2 127.02	2 974.48	< 0.01	5	6 016.2	5 472.2	< 0.01
基因型×地点Genotype×site	55	108.45	151.66	< 0.01	55	199.2	181.2	< 0.01
残差Residual		0.72				1.1

生长指标Growth trait	变异类型Type of variation	方差分量Variance component	标准误Standard error	P
树高 Tree height	区组Block	0.103 8	0.091 4	< 0.01
树高 Tree height	误差Error	0.715 1	0.034 1
胸径 DBH	区组Block	0.119 0	0.107 7	< 0.01
胸径 DBH	误差Error	1.099 4	0.047 0