不同磷效率大豆农艺性状与磷/铁利用率对磷素的响应

doi:10.3724/SP.J.1006.2021.04212

Abstract

Abstract:

The phosphorus content in soil is closely related to the iron absorption in plant. In this study, 15 agronomic traits were analyzed by principal component analysis in sand culture and split blot design, with P-efficient and P-inefficient soybean varieties screened in the early stage as the experimental materials. To analyze the relationship between agronomic traits and P/Fe utilization efficiency, and to provide the theoretical basis for the rational application of P and Fe fertilizer in soybean, the effects of different P:Fe ratios on biological traits and genotypic differences were studied in response to P-efficient and P-inefficient genotypes under different P:Fe treatments by factor scores in soybean. The results were as follows: (1) At R5 stage, plant height, stem diameter, root dry weight, and shoot dry weight of P-efficient genotypes were increased relatively rapidly under each treatment, and all of them were higher than those of P-inefficient genotypes. When P:Fe ratio was 100:100, root dry weight per plant at R5 stage was lower, while 100-seed weight was higher. In addition, when P:Fe ratio was 100:100, P utilization efficiency of the two soybean genotypes were the lowest. (2) Canonical correlation analysis revealed that stem diameter at R5 stage of P-efficient genotypes was positively correlated with Fe utilization efficiency in leaves, while shoot dry weight of P-inefficient genotypes was negatively correlated with P utilization efficiency in leaves. (3) The increase of P utilization efficiency of leaves at R3 stage and shoot dry weight at R8 stage were beneficial to the increase of seed weight per plant of P-efficient genotypes, while the increase of P-efficient genotypes at R3 stage would lead to the decrease of seed weight per plant of P-efficient genotypes. The increase of plant height at R3 stage, shoot dry weight at R3 and R8 stages contributed to the increase of seed weight per plant of P-inefficient genotypes, while the increase of stem diameter at R3, R5, and R8 stages, and Fe utilization efficiency of leaves at R5 stage resulted in the decrease of seed weight per plant of P-inefficient genotypes. Furthermore, shoot dry weight at R8 stage had the largest direct positive contribution to both P-efficient and P-inefficient genotypes. (4) Comprehensive evaluation by factor score showed that when P:Fe ≤ 100:100, the comprehensive performance of P-efficient genotypes and P- inefficient genotypes were the best when P:Fe ratio was 100:100. When P:Fe ≥ 500:100, the comprehensive performance of P-efficient genotypes and P-inefficient genotypes were the best when P:Fe ratio was 1000:100. In conclusion, the early stage of seed filling can be an important stage for screening soybean genotypes with different P efficiency. P:Fe ratio at 1:1 was better for both P-efficient and P-inefficient genotypes under sufficient Fe supply, considering the accumulation of phosphate fertilizer in soil and effect of phytates in seed on P efficiency.

Key words: P-efficient, P-inefficient, agronomic traits, P utilization efficiency, Fe utilization efficiency

ZHAO Jing, MENG Fan-Gang, YU De-Bin, QIU Qiang, ZHANG Ming-Hao, RAO De-Min, CONG Bo-Tao, ZHANG Wei, YAN Xiao-Yan. Response of agronomic traits and P/Fe utilization efficiency to P application with different P efficiency in soybean[J].Acta Agronomica Sinica, 2021, 47(9): 1824-1833.

Figures/Tables 9

Table 1

Fig. 1

Fig. 2

Table 2

Table 3

Table 4

Table 5

Table 6

Table 7

Comprehensive evaluation of P-inefficient genotypes under different treatments"

处理 Treatment	基因型 Genotype	C₁	C₂	C₃	C₄	C₅	C₆	C₇	CE	ACE
CK	合丰25 Hefeng 25	0.040	-0.624	0.120	-0.105	-0.031	-0.045	0.017	-0.628	-0.096
	吉农18 Jinong 18	-0.062	-0.891	-0.019	0.052	0.108	-0.041	-0.060	-0.913
	欧科豆25 Oukedou 25	0.247	0.237	0.093	0.021	0.116	0.039	-0.002	0.752
	九农27 Jiunong 27	0.206	0.879	0.324	-0.021	0.073	-0.070	-0.011	1.379
	吉农21 Jinong 21	-0.490	0.384	0.005	-0.218	0.146	-0.073	-0.035	-0.281
	绥农22 Suinong 22	0.166	-0.737	-0.193	-0.335	0.166	0.077	-0.028	-0.884
P1	合丰25 Hefeng 25	-0.927	-0.445	0.229	0.224	0.006	0.022	-0.003	-0.895	0.106
	吉农18 Jinong 18	0.279	-0.237	0.006	0.159	0.160	0.056	0.028	0.451
	欧科豆25 Oukedou 25	-0.317	0.209	-0.116	0.050	0.035	0.006	-0.041	-0.174
	九农27 Jiunong 27	1.376	-0.051	0.280	0.102	0.043	-0.098	0.000	1.652
	吉农21 Jinong 21	0.428	-0.359	-0.041	0.095	0.061	-0.104	0.010	0.090
	绥农22 Suinong 22	-0.837	0.360	-0.177	0.199	0.073	-0.096	-0.009	-0.487
P2	合丰25 Hefeng 25	-0.395	-0.254	-0.006	0.175	-0.121	-0.005	-0.001	-0.607	-0.075
	吉农18 Jinong 18	-0.117	0.071	0.227	0.047	0.067	0.253	0.114	0.662
处理 Treatment	基因型 Genotype	C₁	C₂	C₃	C₄	C₅	C₆	C₇	CE	ACE
	欧科豆25 Oukedou 25	-0.304	0.333	0.034	0.018	-0.006	-0.063	0.031	0.043
	九农27 Jiunong 27	0.932	-0.035	0.054	-0.186	-0.100	-0.047	0.026	0.646
	吉农21 Jinong 21	-0.543	0.424	-0.067	-0.165	0.060	-0.021	-0.030	-0.342
	绥农22 Suinong 22	-0.551	0.031	-0.318	-0.048	-0.062	-0.081	0.179	-0.850
P3	合丰25 Hefeng 25	-0.502	-0.469	0.150	-0.073	-0.222	0.058	-0.031	-1.090	0.064
	吉农18 Jinong 18	1.439	0.200	-0.542	0.172	-0.037	0.075	-0.022	1.285
	欧科豆25 Oukedou 25	-0.272	0.333	-0.059	0.040	-0.109	0.095	-0.163	-0.137
	九农27 Jiunong 27	0.907	0.057	0.124	-0.055	-0.231	-0.046	0.004	0.761
	吉农21 Jinong 21	0.156	0.585	0.002	-0.091	-0.043	0.138	0.025	0.772
	绥农22 Suinong 22	-0.860	0.001	-0.110	-0.057	-0.155	-0.029	0.006	-1.204

Table 7

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基因型 Genotype	典型相关系数 Canonical correlation coefficient	P值P-value	典型向量 Canonical variables
磷高效基因型 P-efficient genotypes	0.92	0.0145	U_E = - 0.1774X₁ + 0.3527X₂ - 0.5376X₃ + 0.6918X₄ - 0.8259X₅ + 1.6345X₆ + 0.3873X₇ - 0.5418X₈ - 0.3599X₉ + 0.0221X₁₀ - 0.7607X₁₁ + 0.8133X₁₂ - 0.0339X₁₃
磷高效基因型 P-efficient genotypes	0.92	0.0145	V_E = 0.4051Y₁ + 0.6116Y₂ - 0.4141Y₃ + 0.2499Y₄ - 0.3933Y₅ + 0.3567Y₆
磷低效基因型 P-inefficient genotypes	0.98	0.0059	U_IE = 0.7518X₁ - 0.2609X₂ - 0.2263X₃ - 0.4150X₄ - 0.5712X₅ + 0.4853X₆ - 0.4017X₇ + 0.8477X₈ + 0.3437X₉ + 0.2264X₁₀ - 0.1210X₁₁ - 0.2134X₁₂ + 0.0590X₁₃
磷低效基因型 P-inefficient genotypes	0.98	0.0059	V_IE = 0.5590Y₁ - 0.6724Y₂ + 0.0917Y₃ - 0.6286Y₄ - 0.7682Y₅ + 0.6182Y₆

基因型 Genotype	回归方程 Regression equation	决定系数 R²	P值 P-value	剩余标准差 Residual standard deviation	杜宾-沃森检验 Durbin-Watson test
磷高效基因型 P-efficient genotypes	W_E= 1.34 - 0.60X₃ + 0.25X₁₂ + 1.02Y₄	0.89	1.00E-07	0.0118	2.20
磷低效基因型 P-inefficient genotypes	W_IE = 6.84 + 0.027X₁- 0.67X₂+ 0.22X₄ - 0.87X₆ - 0.74X₁₀ + 0.24X₁₂- 0.22Y₂	0.87	5.41E-06	0.0196	1.62

变量 Variable	直接通径系数 Direct path coefficient	→X₃	→X₁₂	→Y₄
X₃	-0.2481		-0.0755	0.0791
X₁₂	0.9028	0.0208		-0.0083
Y₄	0.1610	-0.1220	-0.0465

变量 Variable	直接通径系数 Direct path coefficient	→X₁	→X₂	→X₄	→X₆	→X₁₀	→X₁₂	→Y₂
X₁	0.2277		0.1770	0.2169	-0.2246	-0.0942	0.1118	0.0425
X₂	-0.4223	0.0954		0.1693	-0.1133	0.0647	-0.1678	0.0080
X₄	0.3424	0.1442	-0.2088		-0.1718	-0.1147	0.1520	0.0236
X₆	-0.4367	0.1171	-0.1096	0.1347		0.0029	-0.0101	0.0182
X₁₀	-0.4472	0.0479	0.0610	0.0878	0.0029		0.4820	0.0480
X₁₂	0.7848	0.0324	0.0903	0.0663	0.0056	-0.2746		0.0470
Y₂	-0.1587	-0.0610	0.0214	-0.0509	0.0501	0.1354	-0.2326

处理Treatment	基因型 Genotype	C₁	C₂	C₃	C₄	C₅	C₆	CE	ACE
CK	长农15 Changnong 15	-0.543	0.283	0.114	-0.045	-0.022	0.042	-0.171	-0.265
	吉育69 Jiyu 69	-0.923	0.392	-0.073	-0.184	0.023	-0.154	-0.919
	九农36 Jiunong 36	1.191	-0.432	-0.188	-0.218	0.081	-0.122	0.312
	吉农23 Jinong 23	-1.036	-0.340	0.130	-0.112	-0.097	0.056	-1.399
	吉育95 Jiyu 95	-0.311	0.135	0.013	-0.058	-0.004	-0.046	-0.270
	抗线6号Kangxian 6	0.736	-0.013	0.410	-0.144	-0.069	-0.062	0.857
P1	长农15 Changnong 15	-0.197	0.275	0.399	0.241	0.057	-0.009	0.765	0.127
	吉育69 Jiyu 69	-1.117	0.379	0.077	0.071	0.088	-0.036	-0.538
	九农36 Jiunong 36	1.149	-0.463	0.318	0.108	0.035	0.065	1.212
	吉农23 Jinong 23	-0.742	-0.313	0.232	-0.106	0.034	0.057	-0.838
	吉育95 Jiyu 95	0.008	-0.258	0.315	0.032	-0.045	-0.006	0.048
	抗线6 Kangxian 6	-0.057	-0.191	0.307	-0.020	0.023	0.053	0.114
P2	长农15 Changnong 15	-0.190	0.517	0.001	0.012	0.025	0.055	0.421	0.019
	吉育69 Jiyu 69	-0.538	0.068	0.244	-0.041	-0.080	0.035	-0.312
	九农36 Jiunong 36	0.266	-0.396	-0.346	-0.091	0.175	0.003	-0.390
	吉农23 Jinong 23	-0.732	-0.199	-0.340	-0.187	0.076	0.128	-1.254
	吉育95 Jiyu 95	0.386	0.162	-0.306	0.112	-0.025	0.037	0.365
	抗线6 Kangxian 6	0.625	0.047	0.329	0.195	0.147	-0.058	1.285
P3	长农15 Changnong 15	-0.942	0.071	-0.446	0.237	0.024	-0.007	-1.064	0.119
	吉育69 Jiyu 69	-0.930	0.194	-0.095	-0.039	-0.167	-0.060	-1.098
	九农36 Jiunong 36	1.139	-0.671	-0.142	0.053	-0.143	-0.035	0.202
	吉农23 Jinong 23	-0.363	-0.156	-0.461	0.016	-0.023	0.015	-0.973
	吉育95 Jiyu 95	0.606	-0.086	-0.341	0.329	-0.082	-0.025	0.402
	抗线6号Kangxian 6	2.517	0.996	-0.151	-0.161	-0.032	0.074	3.243

Response of agronomic traits and P/Fe utilization efficiency to P application with different P efficiency in soybean

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