大豆芽期耐高温评价方法构建及耐高温种质资源筛选

doi:10.3724/SP.J.1006.2023.34025

Abstract

Abstract:

The frequent occurrence of extreme high temperature (HT) events causes continuous heat damage to soybean production, which seriously damages the yield components and quality traits. The seeds are sensitive to the changes of the external environment at germination stage. The rising temperature and the accompanying drought will affect the emergence of soybean seeds. The establishment of a set of scientific evaluation methods for HT tolerance at bud stage can provide a theoretical basis for the early identification of soybean, the breeding of HT tolerance germplasm, and the study of tolerance mechanism. In this study, 385 germplasm resources varieties were selected as the experimental materials, which creating a HT environment by artificial climate incubator and subjected to HT-stress for 3 d (40℃, 16 h light /8 h darkness) at bud stage of soybean. Compared with the control (25℃, 16 h light /8 h darkness), the hypocotyl length of soybean bud stage was significantly decreased 10.9% under HT stress (P < 0.05). The indices of fresh root weight, dry root weight, and root-shoot ratio increased by 13.10%, 22.20%, and 16.90%, respectively (P<0.01). The results showed that HT-stress significantly affected the surface and underground biomass distribution of bud stage in soybean. Meanwhile, the principal component analysis for the coefficient of HT-tolerance for each trait converted 11 indexes into two principal component factors. The comprehensive evaluation value (H-value) of soybean response to HT-stress was obtained by the standardized analysis of membership function, and cluster analysis was conducted for the tested varieties based on H-value. Ultimately, 385 germplasm resources were divided into 5 grades for the HT-tolerance at bud stage in soybean [namely: Grade I (tolerance), Grade II (strong tolerance), Grade III (medium), Grade IV (strong sensitive), and Grade V (sensitive type)] and four HT-resistant varieties based on the specific performance (H245, H070, H268, and H216) were initially selected combined with the actual heat resistance performance. After the stepwise regression analysis of each index, a predictive model for the comprehensive evaluation of HT tolerance (H-value) at bud stage of soybean was established: H = 0.191 + 0.017X₁ - 0.007X₂ + 0.013X₇ + 0.027X₈ - 0.009X₁₀ (R²=0.9752). Five indexes main including hypocotyl length (X₁), main root length (X₂), hypocotyl dry weight (X₇), root fresh weight (X₈), and simplified vigor index (X₁₀) were screened out as the evaluation indexes for HT tolerance at bud stage in soybean.

Key words: soybean, germination stage, high temperature treatment, genetic resources, evaluation of high temperature resistance

LI Jia-Jia, LONG Qun, ZHU Shang-Shang, SHAN Ya-Jing, WU Mei-Yan, LU Yun, ZHI Xian-Guan, LIAO Wei, CHEN Hao-Ran, ZHAO Zhen-Bang, MIAO Long, GAO Hui-Hui, LI Ying-Hui, WANG Xiao-Bo, QIU Li-Juan. Construction of evaluation method for tolerance to high-temperature and screening of heat-tolerant germplasm resources of bud stage in soybean[J].Acta Agronomica Sinica, 2023, 49(11): 2863-2875.

Figures/Tables 8

Table S1

Soybean variety information"

编号 No.	统一编号 Unified No.	编号 No.	统一编号 Unified No.	编号 No.	统一编号 Unified No.	编号 No.	统一编号 Unified No.	编号 No.	统一编号 Unified No.
H001	ZDD00058	H078	ZDD20449	H155	ZDD06507	H232	ZDD24460	H309	WDD01021
H002	ZDD00106	H079	ZDD23526	H156	ZDD14504	H233	ZDD24463	H310	WDD00957
H003	ZDD00152	H080	ZDD15011	H157	ZDD14520	H234	ZDD24470	H311	WDD01275
H004	ZDD00170	H081	ZDD15407	H158	ZDD14681	H235	ZDD23841	H312	WDD02850
H005	ZDD00176	H082	ZDD06971	H159	ZDD24235	H236	ZDD24340	H313	WDD02713
H006	ZDD00244	H083	ZDD22659	H160	ZDD24166	H237	ZDD24339	H314	WDD01552
H007	ZDD00248	H084	ZDD22699	H161	ZDD24166	H238	ZDD23771	H315	WDD01887
H008	ZDD06987	H085	ZDD22909	H162	ZDD24259	H239	ZDD24511	H316	WDD00584
H009	ZDD17679	H086	ZDD02356	H163	ZDD24311	H240	ZDD24392	H317	WDD02004
H010	ZDD17687	H087	ZDD09254	H164	ZDD25231	H241	ZDD23698	H318	WDD00577
H011	ZDD00323	H088	ZDD22852	H165	ZDD12588	H242	ZDD24358	H319	WDD00579
H012	ZDD17848	H089	ZDD20617	H166	ZDD24993	H243	ZDD24341	H320	WDD01976
H013	ZDD17939	H090	ZDD11578	H167	ZDD24997	H244	ZDD24347	H321	WDD01987
H014	ZDD17889	H091	ZDD12949	H168	ZDD24998	H245	ZDD24355	H322	WDD02428
H015	ZDD00536	H092	ZDD13110	H169	ZDD15972	H246	ZDD24356	H323	WDD03015
H016	ZDD00351	H093	ZDD20830	H170	ZDD24910	H247	ZDD23662	H324	WDD00819
H017	ZDD06996	H094	ZDD20859	H171	ZDD24923	H248	ZDD23674	H325	WDD02247
H018	ZDD17843	H095	ZDD10590	H172	ZDD25150	H249	ZDD24349	H326	WDD02199
H019	ZDD00414	H096	ZDD08023	H173	ZDD25316	H250	ZDD24352	H327	WDD02025
H020	ZDD00777	H097	ZDD16651	H174	ZDD25317	H251	ZDD23671	H328	WDD02024
H021	ZDD07646	H098	ZDD14788	H175	ZDD25330	H252	ZDD23820	H329	WDD03079
H022	ZDD18116	H099	ZDD14853	H176	ZDD25331	H253	ZDD24562	H330	WDD02165
H023	ZDD00744	H100	ZDD20617	H177	ZDD25334	H254	ZDD24580	H331	WDD02306
H024	ZDD01151	H101	ZDD18916	H178	ZDD25339	H255	ZDD25275	H332	WDD03067
H025	ZDD07732	H102	ZDD03340	H179	ZDD25349	H256	ZDD24417	H333	WDD03102
H026	ZDD00749	H103	ZDD03375	H180	ZDD25010	H257	ZDD23640	H334	WDD02010
H027	ZDD06289	H104	ZDD04681	H181	ZDD25018	H258	ZDD23641	H335	WDD02180
H028	ZDD06439	H105	ZDD14969	H182	ZDD25037	H259	ZDD23642	H336	WDD00676
H029	ZDD06498	H106	ZDD15157	H183	ZDD25038	H260	ZDD24600	H337	WDD03104
H030	ZDD21379	H107	ZDD15248	H184	ZDD25039	H261	ZDD24605	H338	WDD03107
H031	ZDD21893	H108	ZDD13759	H185	ZDD25046	H262	ZDD24606	H339	WDD02584
H032	ZDD21922	H109	ZDD13774	H186	ZDD25070	H263	ZDD24609	H340	WDD02171
H033	ZDD14452	H110	ZDD13782	H187	ZDD25071	H264	ZDD23693	H341	WDD00701
H034	ZDD21867	H111	ZDD05932	H188	ZDD25074	H265	ZDD24370	H342	WDD02252
H035	ZDD08091	H112	ZDD05935	H189	ZDD25106	H266	ZDD24371	H343	WDD02253
H036	ZDD13172	H113	ZDD05936	H190	ZDD24905	H267	ZDD24372	H344	WDD03082
H037	ZDD00120	H114	ZDD12438	H191	ZDD25204	H268	ZDD24520	H345	WDD00663
H038	ZDD00359	H115	ZDD12894	H192	ZDD25295	H269	ZDD24568	H346	WDD00712
H039	ZDD00372	H116	ZDD16055	H193	ZDD25313	H270	ZDD24574	H347	WDD00667
H040	ZDD00412	H117	ZDD16095	H194	ZDD25328	H271	ZDD23682	H348	WDD01649
H041	ZDD16736	H118	ZDD16166	H195	ZDD24975	H272	ZDD24398	H349	WDD00679
H042	ZDD22283	H119	ZDD16221	H196	ZDD24981	H273	ZDD24542	H350	WDD01652
H043	ZDD09349	H120	ZDD16321	H197	ZDD25030	H274	ZDD24548	H351	WDD03093
H044	ZDD18877	H121	ZDD16354	H198	ZDD25113	H275	ZDD23795	H352	WDD03125
H045	ZDD18959	H122	ZDD16358	H199	ZDD25016	H276	ZDD24438	H353	WDD00672
H046	ZDD18965	H123	ZDD20874	H200	ZDD25068	H277	ZDD24439	H354	WDD03001
H047	ZDD23122	H124	ZDD20896	H201	ZDD24382	H278	ZDD24440	H355	WDD02363
H048	ZDD23124	H125	ZDD20903	H202	ZDD23643	H279	ZDD24481	H356	WDD02314
H049	ZDD22033	H126	ZDD20910	H203	ZDD23612	H280	ZDD24447	H357	WDD02317
H050	ZDD23053	H127	ZDD14673	H204	ZDD24113	H281	ZDD24450	H358	WDD03055
H051	ZDD23064	H128	ZDD14725	H205	ZDD23618	H282	ZDD24678	H359	WDD00756
H052	ZDD23075	H129	ZDD14740	H206	ZDD24410	H283	ZDD24161	H360	WDD00707
H053	ZDD11434	H130	ZDD22587	H207	ZDD24413	H284	ZDD24037	H361	WDD00722
H054	ZDD00765	H131	ZDD12535	H208	ZDD24414	H285	ZDD24748	H362	WDD00669
H055	ZDD18199	H132	ZDD13033	H209	ZDD24415	H286	ZDD23955	H363	WDD00668
H056	ZDD18200	H133	ZDD03731	H210	ZDD25264	H287	ZDD24076	H364	WDD03021
H057	ZDD00400	H134	ZDD22057	H211	ZDD25266	H288	ZDD23978	H365	WDD00820
H058	ZDD18044	H135	ZDD22076	H212	ZDD23754	H289	ZDD24595	H366	WDD00833
H059	ZDD22747	H136	ZDD19741	H213	ZDD23757	H290	ZDD24576	H367	WDD00834
H060	ZDD22767	H137	ZDD19742	H214	ZDD23749	H291	ZDD24550	H368	WDD00835
H061	ZDD22770	H138	ZDD19750	H215	ZDD24486	H292	ZDD24639	H369	WDD00805
H062	ZDD22773	H139	ZDD16473	H216	ZDD23785	H293	WDD01336	H370	WDD00810
H063	ZDD22785	H140	ZDD21998	H217	ZDD23786	H294	WDD01169	H371	WDD00830
H064	ZDD22797	H141	ZDD15492	H218	ZDD24495	H295	WDD01340	H372	WDD00896
H065	ZDD22836	H142	ZDD16889	H219	ZDD24499	H296	WDD01056	H373	WDD00900
H066	ZDD02767	H143	ZDD21515	H220	ZDD23783	H297	WDD01152	H374	WDD00838
H067	DD19366	H144	ZDD14566	H221	ZDD24488	H298	WDD01321	H375	WDD00806
H068	ZDD19403	H145	ZDD24117	H222	ZDD24476	H299	WDD01099	H376	WDD00924
H069	ZDD17013	H146	ZDD15672	H223	ZDD24479	H300	WDD01055	H377	WDD00925
H070	ZDD17146	H147	ZDD15757	H224	ZDD23705	H301	WDD01038	H378	WDD00870
H071	ZDD04110	H148	ZDD15812	H225	ZDD23709	H302	WDD01067	H379	WDD00845
H072	ZDD11531	H149	ZDD15828	H226	ZDD23712	H303	WDD01406	H380	WDD02939
H073	ZDD12837	H150	ZDD15829	H227	ZDD23718	H304	WDD01073	H381	WDD00677
H074	ZDD14596	H151	ZDD15837	H228	ZDD23723	H305	WDD00987	H382	WDD00811
H075	ZDD11583	H152	ZDD15848	H229	ZDD23724	H306	WDD01240	H383	WDD00854
H076	ZDD11690	H153	ZDD15980	H230	ZDD23727	H307	WDD01278	H384	WDD00923
H077	ZDD11943	H154	ZDD16473	H231	ZDD24457	H308	WDD01005	H385	WDD00929

Table S1

Fig. 1

Table 1

Table 2

Fig. 2

Table 3

Table 4

Comprehensive evaluation (H) value of high temperature response of tested varieties"

编号 No.	H值 H-value	编号 No.	H值 H-value	编号 No.	H值 H-value	编号 No.	H值 H-value	编号 No.	H值 H-value
H001	0.21	H078	0.37	H155	0.23	H232	0.19	H309	0.63
H002	0.24	H079	0.23	H156	0.16	H233	0.26	H310	0.15
H003	0.25	H080	0.38	H157	0.24	H234	0.37	H311	0.19
H004	0.20	H081	0.13	H158	0.21	H235	0.26	H312	0.21
H005	0.22	H082	0.21	H159	0.23	H236	0.37	H313	0.27
H006	0.17	H083	0.24	H160	0.10	H237	0.20	H314	0.23
H007	0.22	H084	0.21	H161	0.24	H238	0.39	H315	0.17
H008	0.36	H085	0.15	H162	0.23	H239	0.22	H316	0.21
H009	0.28	H086	0.24	H163	0.45	H240	0.19	H317	0.27
H010	0.12	H087	0.20	H164	0.15	H241	0.30	H318	0.30
H011	0.21	H088	0.20	H165	0.19	H242	0.18	H319	0.30
H012	0.21	H089	0.13	H166	0.15	H243	0.40	H320	0.24
H013	0.20	H090	0.17	H167	0.16	H244	0.20	H321	0.33
H014	0.29	H091	0.17	H168	0.22	H245	0.72	H322	0.31
H015	0.17	H092	0.39	H169	0.14	H246	0.21	H323	0.18
H016	0.24	H093	0.15	H170	0.28	H247	0.19	H324	0.26
H017	0.18	H094	0.19	H171	0.21	H248	0.23	H325	0.17
H018	0.23	H095	0.20	H172	0.30	H249	0.21	H326	0.25
H019	0.24	H096	0.21	H173	0.21	H250	0.42	H327	0.27
H020	0.20	H097	0.24	H174	0.21	H251	0.21	H328	0.26
H021	0.44	H098	0.20	H175	0.37	H252	0.18	H329	0.18
H022	0.26	H099	0.18	H176	0.34	H253	0.32	H330	0.34
H023	0.24	H100	0.26	H177	0.20	H254	0.16	H331	0.35
H024	0.25	H101	0.23	H178	0.24	H255	0.18	H332	0.19
H025	0.31	H102	0.14	H179	0.27	H256	0.24	H333	0.29
H026	0.24	H103	0.17	H180	0.18	H257	0.24	H334	0.25
H027	0.36	H104	0.33	H181	0.28	H258	0.31	H335	0.15
H028	0.26	H105	0.22	H182	0.19	H259	0.24	H336	0.25
H029	0.20	H106	0.20	H183	0.17	H260	0.22	H337	0.31
H030	0.28	H107	0.26	H184	0.22	H261	0.27	H338	0.11
H031	0.23	H108	0.26	H185	0.23	H262	0.46	H339	0.17
H032	0.18	H109	0.22	H186	0.21	H263	0.37	H340	0.14
H033	0.26	H110	0.31	H187	0.21	H264	0.20	H341	0.28
H034	0.27	H111	0.29	H188	0.18	H265	0.24	H342	0.14
H035	0.27	H112	0.21	H189	0.17	H266	0.34	H343	0.19
H036	0.58	H113	0.37	H190	0.19	H267	0.22	H344	0.31
H037	0.32	H114	0.18	H191	0.19	H268	0.71	H345	0.26
H038	0.31	H115	0.60	H192	0.20	H269	0.44	H346	0.35
H039	0.48	H116	0.38	H193	0.22	H270	0.14	H347	0.18
H040	0.27	H117	0.19	H194	0.18	H271	0.20	H348	0.18
H041	0.25	H118	0.13	H195	0.26	H272	0.66	H349	0.23
H042	0.20	H119	0.27	H196	0.39	H273	0.29	H350	0.24
H043	0.44	H120	0.28	H197	0.31	H274	0.19	H351	0.19
H044	0.14	H121	0.16	H198	0.27	H275	0.31	H352	0.29
H045	0.27	H122	0.25	H199	0.13	H276	0.19	H353	0.23
H046	0.21	H123	0.31	H200	0.29	H277	0.28	H354	0.25
H047	0.25	H124	0.28	H201	0.47	H278	0.23	H355	0.21
H048	0.27	H125	0.31	H202	0.36	H279	0.37	H356	0.22
H049	0.31	H126	0.17	H203	0.15	H280	0.18	H357	0.22
H050	0.21	H127	0.36	H204	0.17	H281	0.28	H358	0.20
H051	0.23	H128	0.29	H205	0.22	H282	0.23	H359	0.21
H052	0.26	H129	0.19	H206	0.19	H283	0.18	H360	0.18
H053	0.25	H130	0.22	H207	0.19	H284	0.26	H361	0.18
H054	0.32	H131	0.18	H208	0.20	H285	0.25	H362	0.25
H055	0.38	H132	0.26	H209	0.32	H286	0.19	H363	0.48
H056	0.35	H133	0.33	H210	0.18	H287	0.20	H364	0.26
H057	0.26	H134	0.22	H211	0.25	H288	0.29	H365	0.23
H058	0.21	H135	0.16	H212	0.24	H289	0.15	H366	0.16
H059	0.26	H136	0.24	H213	0.34	H290	0.31	H367	0.25
H060	0.23	H137	0.23	H214	0.26	H291	0.23	H368	0.19
H061	0.44	H138	0.13	H215	0.28	H292	0.25	H369	0.16
H062	0.28	H139	0.23	H216	0.69	H293	0.26	H370	0.19
H063	0.27	H140	0.20	H217	0.26	H294	0.28	H371	0.15
H064	0.52	H141	0.27	H218	0.32	H295	0.15	H372	0.20
H065	0.26	H142	0.30	H219	0.27	H296	0.22	H373	0.16
H066	0.32	H143	0.23	H220	0.26	H297	0.19	H374	0.23
H067	0.28	H144	0.25	H221	0.44	H298	0.26	H375	0.26
H068	0.21	H145	0.24	H222	0.18	H299	0.18	H376	0.23
H069	0.26	H146	0.32	H223	0.29	H300	0.25	H377	0.32
H070	0.72	H147	0.20	H224	0.17	H301	0.23	H378	0.20
H071	0.25	H148	0.33	H225	0.20	H302	0.19	H379	0.31
H072	0.23	H149	0.18	H226	0.21	H303	0.14	H380	0.19
H073	0.32	H150	0.16	H227	0.24	H304	0.23	H381	0.20
H074	0.21	H151	0.22	H228	0.18	H305	0.13	H382	0.20
H075	0.28	H152	0.13	H229	0.23	H306	0.24	H383	0.23
H076	0.28	H153	0.38	H230	0.23	H307	0.23	H384	0.17
H077	0.16	H154	0.21	H231	0.26	H308	0.28	H385	0.19

Table 4

Fig. 3

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性状 Tait	对照 Control (mean ± SD)	高温处理后 After HT stress (mean ± SD)	变幅 Range (%)	F值 F-value
下胚轴长Hypocotyl length (cm)	4.626±1.980	4.118±1.661	-10.90	14.816^*
主根长Main root length (cm)	5.868±2.397	6.140±2.265	4.60	2.618
总鲜重Total fresh weight (g)	0.754±0.255	0.746±0.270	-1.06	0.199
总干重Total dry weight (g)	0.163±0.046	0.160±0.050	-1.80	0.611
相对水分含量Relative moisture content (%)	0.768±0.083	0.766±0.093	-0.26	0.065
下胚轴鲜重Hypocotyl fresh weight (g)	0.135±0.060	0.129±0.050	-4.40	0.212
下胚轴干重Hypocotyl dry weight (g)	0.011±0.013	0.012±0.010	9.10	0.284
根鲜重Root fresh weight (g)	0.107±0.076	0.121±0.084	13.10	5.700^**
根干重Root dry weight (g)	0.009±0.008	0.011±0.009	22.20	6.867^**
简化活力指数Simplified vitality index (g)	0.248±0.228	0.283±0.276	14.10	3.625
根冠比R/S (%)	0.159±0.087	0.186±0.104	16.90	14.865^**

性状 Trait	极小值 Min.	极大值 Max.	单项系数 Single coefficient (mean ± SD)	变异系数 CV (%)
下胚轴长Hypocotyl length (cm)	0.090	7.125	1.057±0.373	35
主根长Main root length (cm)	0.058	2.250	1.441±0.561	39
总鲜重Total fresh weight (g)	0.263	3.246	1.060±0.434	41
总干重Total dry weight (g)	0.176	2.170	1.049±0.860	82
相对水分含量Relative moisture content (%)	0.167	2.554	1.009±0.161	16
下胚轴鲜重Hypocotyl fresh weight (g)	0.058	6.333	1.132±0.260	23
下胚轴干重Hypocotyl dry weight (g)	0.036	9.310	1.324±0.317	24
根鲜重Root fresh weight (g)	0.026	6.535	1.676±1.491	89
根干重Root dry weight (g)	0.041	9.000	1.738±0.712	41
简化活力指数Simplified vitality index (g)	0.013	9.667	2.132±1.236	58
根冠比R/S (%)	0.043	8.009	1.494±1.135	76

指标 Item	成分矩阵 Component matrix
指标 Item	1	2	3
下胚轴长Hypocotyl length (cm)	0.682	-0.053	0.385
主根长Main root length (cm)	0.530	-0.058	0.108
鲜重Raw weight (g)	0.804	0.027	-0.061
干重Dry weight (g)	-0.026	0.884	-0.130
相对水分含量 Relative moisture content (%)	0.642	-0.354	-0.010
下胚轴鲜重Fresh weight of hypocotyl (g)	0.505	-0.052	0.506
下胚轴干重Hypocotyl dry weight (g)	0.377	0.318	0.501
根鲜重Root fresh weight (g)	0.929	0.021	-0.283
根干重Root dry weight (g)	0.611	0.261	0.122
简化活力指数Simplified vitality index (g)	0.720	0.048	-0.459
根冠比 R/S (%)	0.835	-0.014	-0.231
特征值 Eigenvectors	4.654	1.089	1.047
贡献率 Contribution ratio (%)	42.31	9.90	9.51
累计贡献率 Cumulative contribution ratio (%)	42.31	52.21	61.72

Construction of evaluation method for tolerance to high-temperature and screening of heat-tolerant germplasm resources of bud stage in soybean

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