甜荞茎秆重心高度和抗折力的遗传分析

doi:10.16035/j.issn.1001-7283.2022.04.012

Abstract

Abstract:

Common buckwheat (Fagopyrum esculentum M.) is susceptible to lodging due to its slender and hollow stems. The culm gravity height and snapping resistance are recognized as important traits for lodging resistance. In this study, we developed the P_l, P₂, F_l, B_l, B₂ and F₂ populations from the reciprocal crosses between Youqiao 2 (lodging-resistance) and Ukraine daliqiao (lodging-susceptible) and analyzed the genetic effects of culm gravity height and culm snapping resistance. The heredity of culm gravity height optimally fitted to the genetic model for one major genes with additive-dominance effects plus polygenes with additive-dominance-epistatic effects and two major genes with additive-dominance-epistatic effects plus polygenes with additive-dominance effects. The genetic model was based on additive effects. The heritability of major genes was greater than the heritability of polygenes, and the environmental variation was greater than genetic variation, indicating that the environment had a great effect on the traits of the culm gravity height. Proper cultivation measures could be used to reduce the culm gravity height and enhance lodging resistance of buckwheat. The heredity of culm snapping resistance optimally fitted to the genetic model for two major genes with additive-dominance-epistatic effects plus polygenes with additive-dominance-epistatic effects and two major genes with additive-dominance-epistatic effects plus polygenes with additive-dominance effects. The genetic model was based on additive effects. There were obvious gene interaction effects between the two major genes. The heritability of major genes were greater than the heritability of polygenes. The heritability of polygenes were not detected in the F₂ generation. The heritability of the major genes was the highest in the F₂ generation, which was 88.94%. It can be selected in the early generations to improve breeding efficiency.

Key words: Common buckwheat, Culm gravity height, Culm snapping resistance, Quantitative trait, Genetic analysis

Hu Dan. Genetic Analysis of Culm Gravity Height and Snapping Resistance in Common Buckwheat[J].Crops, 2022, 38(4): 83-89.

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References 27

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组合 Combination	世代 Generation	株数 Number of plants	茎秆重心高度Culm gravity height (cm)		茎秆抗折力Culm snapping resistance (g)
组合 Combination	世代 Generation	株数 Number of plants	平均值Mean	变异系数CV (%)	平均值Mean	变异系数CV (%)
亲本Parent	P₁	25	50.92±4.09	11.09	1.31±0.61	2.15
	P₂	25	34.65±4.01	8.64	0.55±0.31	1.77
P₁×P₂	F₁	28	43.18±5.14	8.40	0.75±0.37	2.03
	B₁	153	45.81±4.68	9.79	0.83±0.47	1.77
	B₂	165	38.22±4.18	9.14	0.65±0.41	1.59
	F₂	274	47.12±5.60	8.41	1.61±0.83	1.94
P₂×P₁	F₁	28	40.59±3.63	11.18	0.57±0.32	1.78
	B₁	136	41.42±4.14	10.00	0.89±0.49	1.82
	B₂	133	43.82±4.23	10.36	0.97±0.53	1.83
	F₂	303	43.67±4.20	10.40	0.74±0.44	1.68

模型 Model	模型含义 Implication of model	极大对数似然函数值Maximum logarithmic likelihood value		AIC值AIC value
模型 Model	模型含义 Implication of model	P₁×P₂	P₂×P₁	P₁×P₂	P₂×P₁
A-1	1MG-AD	-2078.56	-1928.99	4165.12	3865.97
A-2	1MG-A	-2078.62	-1929.13	4163.24	3864.27
A-3	1MG-EAD	-2117.65	-1946.92	4241.31	3899.84
A-4	1MG-AEND	-2175.71	-1953.39	4357.42	3912.78
B-1	2MG-ADI	-2055.04	-1894.84	4130.08	3809.68
B-2	2MG-AD	-2088.13	-1928.38	4188.26	3868.76
B-3	2MG-A	-2083.57	-1945.53	4175.14	3899.06
B-4	2MG-EA	-2084.94	-1922.90	4175.88	3851.79
B-5	2MG-AED	-2123.43	-1934.96	4254.86	3877.93
B-6	2MG-EEAD	-2123.43	-1934.96	4252.86	3875.93
C-0	PG-ADI	-2095.99	-1886.69	4211.98	3793.37
C-1	PG-AD	-2121.85	-1918.88	4257.71	3851.75
D-0	MX1-AD-ADI	-2049.39	-1886.94	4122.78	3797.88
D-1	MX1-AD-AD	-2114.10	-1921.09	4246.21	3860.18
D-2	MX1-A-AD	-2082.39	-1919.56	4180.79	3855.12
D-3	MX1-EAD-AD	-2109.97	-1922.03	4235.94	3860.06
D-4	MX1-AEND-AD	-2109.91	-1919.80	4235.82	3855.60
E-0	MX2-ADI-ADI	-2037.94	-1886.94	4111.88	3809.88
E-1	MX2-ADI-AD	-2046.85	-1877.63	4123.70	3785.27
E-2	MX2-AD-AD	-2109.93	-1922.03	4241.86	3866.06
E-3	MX2-A-AD	-2098.35	-2342.76	4214.71	4703.52
E-4	MX2-EA-AD	-2109.98	-1922.03	4235.95	3860.06
E-5	MX2-AED-AD	-2109.98	-1922.03	4237.96	3862.06
E-6	MX2-EEAD-AD	-2109.98	-1922.03	4235.96	3860.06

模型 Model	模型含义 Implication of model	极大对数似然函数值Maximum logarithmic likelihood value		AIC值AIC Value
模型 Model	模型含义 Implication of model	P₁×P₂	P₂×P₁	P₁×P₂	P₂×P₁
A-1	1MG-AD	-686.56	-448.03	1381.13	904.05
A-2	1MG-A	-741.63	-457.25	1489.26	920.50
A-3	1MG-EAD	-762.45	-448.43	1530.89	902.85
A-4	1MG-AEND	-688.40	-469.48	1382.80	944.95
B-1	2MG-ADI	-530.00	-387.31	1080.00	794.62
B-2	2MG-AD	-646.40	-445.28	1304.81	902.56
B-3	2MG-A	-691.52	-482.00	1391.04	972.00
B-4	2MG-EA	-754.66	-457.19	1515.33	920.39
B-5	2MG-AED	-764.07	-446.82	1536.13	901.64
B-6	2MG-EEAD	-764.07	-452.16	1534.13	910.33
C-0	PG-ADI	-635.01	-441.12	1290.02	902.24
C-1	PG-AD	-704.65	-449.42	1423.30	912.83
D-0	MX1-AD-ADI	-577.16	-430.13	1178.33	884.26
D-1	MX1-AD-AD	-647.28	-420.88	1312.56	859.75
D-2	MX1-A-AD	-628.45	-446.95	1272.89	909.90
D-3	MX1-EAD-AD	-676.05	-449.32	1368.09	914.64
D-4	MX1-AEND-AD	-639.31	-449.85	1294.62	915.70
E-0	MX2-ADI-ADI	-497.42	-383.94	1030.84	803.87
E-1	MX2-ADI-AD	-528.75	-343.74	1087.50	717.48
E-2	MX2-AD-AD	-675.83	-449.32	1373.66	920.63
E-3	MX2-A-AD	-671.03	-589.04	1360.06	1196.07
E-4	MX2-EA-AD	-676.05	-449.22	1368.09	914.45
E-5	MX2-AED-AD	-676.05	-421.19	1370.09	860.39
E-6	MX2-EEAD-AD	-676.05	-449.32	1368.09	914.63

组合 Combination	模型 Model	模型含义 Implication of model	适合性检验 Test of goodness-fit
组合 Combination	模型 Model	模型含义 Implication of model	U₁²	U₂²	U₃²	nW²	D_n
P₁×P₂	D-0	2MG-EA	0	0	0	0	0
	E-0	MX1-A-AD	0	0	1	0	0
	E-1	MX2-ADI-AD	2	1	1	2	0
P₂×P₁	C-0	PG-ADI	0	0	0	0	0
	D-0	MX1-AD-ADI	0	0	0	0	0
	E-1	MX2-ADI-AD	0	0	0	0	0

组合 Combination	模型 Model	模型含义 Implication of model	适合性检验 Test of goodness-fit
组合 Combination	模型 Model	模型含义 Implication of model	U₁²	U₂²	U₃²	nW²	D_n
P₁×P₂	B-1	2MG-EA	3	2	1	3	0
	E-0	MX1-A-AD	0	0	2	1	0
	E-1	MX2-ADI-AD	2	1	2	2	0
P₂×P₁	B-1	PG-ADI	0	1	0	1	0
	E-0	MX1-AD-ADI	0	0	0	2	0
	E-1	MX2-ADI-AD	0	0	1	0	0

Genetic Analysis of Culm Gravity Height and Snapping Resistance in Common Buckwheat

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一阶遗传参数 1st order genetic parameter	P₁×P₂		P₂×P₁
一阶遗传参数 1st order genetic parameter	茎秆重心高度 Culm gravity height	茎秆抗折力 Culm snapping resistance	茎秆重心高度 Culm gravity height	茎秆抗折力 Culm snapping resistance
m	43.35	0.87	44.99	0.54
d_a	0.22	0.59	-3.30	-0.40
d_b		0.59	-3.30	-0.40
h_a	-0.08	-0.17	0.08	0.32
h_b		0.14	-2.01	0.10
i		0.56	-2.75	0.43
j_ab		0.16	3.34	0.20
j_ba		-0.15	5.44	0.73
l		0.23	-1.79	-0.81
[d]			-1.76	0.34
[h]			-0.50	0.51
h_a/d_a		-0.29	-0.02	-0.81
h_b/d_b		0.23	0.61	-0.26

组合 Combination	二阶遗传参数 2nd order genetic parameter	茎秆重心高度Culm gravity height			茎秆抗折力Culm snapping resistance
组合 Combination	二阶遗传参数 2nd order genetic parameter	B₁	B₂	F₂	B₁	B₂	F₂
P₁×P₂	σ_p²	21.92	18.41	35.95	0.22	0.17	0.69
	σ_mg²	0.17	0.00	0.16	0.13	0.07	0.59
	σ_pg²	3.34	0.00	17.39	0.00	0.00	0.00
	σ_e²	18.41	18.41	18.41	0.10	0.10	0.10
	h_mg² (%)	10.00	0.00	0.00	57.26	43.22	86.13
	h_pg² (%)	15.25	0.00	48.00	0.00	0.00	0.00
P₂×P₁	σ_p²	23.40	17.89	20.37	0.24	0.29	0.23
	σ_mg²	13.73	7.12	10.71	0.17	0.20	0.18
	σ_pg²	0.00	1.11	0.00	0.02	0.04	0.00
	σ_e²	9.66	9.66	9.66	0.05	0.05	0.05
	h_mg² (%)	80.22	39.78	60.61	69.94	68.12	91.75
	h_pg² (%)	0.00	6.20	0.00	7.84	13.43	0.00

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