棉花出苗期耐冷综合评价体系的构建及耐冷指标筛选

doi:10.3864/j.issn.0578-1752.2022.22.002

中国农业科学 ›› 2022, Vol. 55 ›› Issue (22): 4342-4355.doi: 10.3864/j.issn.0578-1752.2022.22.002

• 作物遗传育种·种质资源·分子遗传学 • 上一篇下一篇

棉花出苗期耐冷综合评价体系的构建及耐冷指标筛选

沈倩^1,²(),张思平¹,刘瑞华¹,刘绍东¹,陈静¹,葛常伟¹,马慧娟¹,赵新华¹,杨国正²,宋美珍¹(),庞朝友¹()

¹中国农业科学院棉花研究所/棉花生物学国家重点实验室，河南安阳 455000
²华中农业大学植物科学与技术学院，武汉 430070

收稿日期:2022-07-13 接受日期:2022-08-15 出版日期:2022-11-16 发布日期:2022-12-14
通讯作者: 宋美珍,庞朝友
作者简介:沈倩，E-mail：shenqian429@126.com。
基金资助:
2021年度第七师胡杨河市财政科技计划(2021C02);中国农业科学院科技创新工程(CAAS-ASTIP-2020-ICR)

Construction of A Comprehensive Evaluation System and Screening of Cold Tolerance Indicators for Cold Tolerance of Cotton at Seedling Emergence Stage

SHEN Qian^1,²(),ZHANG SiPing¹,LIU RuiHua¹,LIU ShaoDong¹,CHEN Jing¹,GE ChangWei¹,MA HuiJuan¹,ZHAO XinHua¹,YANG GuoZheng²,SONG MeiZhen¹(),PANG ChaoYou¹()

¹Institute of Cotton, Chinese Academy of Agricultural Sciences/State Key Laboratory of Cotton Biology, Anyang 455000, Henan
²College of Plant Science and Technology, Huazhong Agricultural University, Wuhan 430070

Received:2022-07-13 Accepted:2022-08-15 Online:2022-11-16 Published:2022-12-14
Contact: MeiZhen SONG,ChaoYou PANG

摘要/Abstract

摘要：

【目的】 综合评价棉花品种（系）出苗期耐冷性，建立可靠评价模型，筛选鉴定指标，为耐冷品种选育鉴定提供简便有效的评价方法。【方法】 以200份陆地棉品种（系）为试验材料，设恒定低温、昼夜变温和适宜温度3个处理，测定其出苗率、下胚轴长、根长、百粒重等指标，采用耐冷系数差异分析、频次分析、降幅分析、主成分分析、聚类分析和多元回归分析等方法，对群体进行耐冷型划分，并建立耐冷性评价模型和确定鉴定指标。【结果】 各指标在适宜温度下变异幅度较小，变异系数为3.12%—18.89%，各品种（系）出苗率在85.00%以上，具有较高的生活力，可用于后续耐冷性分析。在低温胁迫下群体内各指标变异幅度增大，为7.14%—108.33%，在恒定低温和昼夜变温下，变幅最大的指标依次为根长和萌发指数。主成分分析将14个低温相关指标和百粒重转换为6个相互独立的综合指标，代表了全部数据74.98%的信息量。利用隶属函数法计算综合耐冷评价值（D），并对其进行聚类分析，按照耐冷性强弱将200份陆地棉品种（系）划分为5类，第Ⅰ类群属于强耐冷型共2份，第Ⅱ类群属于耐冷型共42份，第Ⅲ类群属于中耐冷型共69份，第Ⅳ类群属于较敏感型共83份，第Ⅴ类群属于敏感型共4份，其中，新陆中16号为耐冷性最强的品种。采用多元回归分析方法，建立棉花出苗期耐冷性预测模型为Y=-4.10+0.58X4+0.40X14+0.32X1+0.22X5（R²=0.92），筛选出4个耐冷性鉴定指标，分别为恒定低温下的棉苗总长、出苗率、干物重和昼夜变温下的萌发率。田间早播试验中各品种（系）的出苗率，与室内试验结果基本一致。【结论】 采用恒定低温和昼夜变温处理结合多元统计分析方法对棉花出苗期耐冷性评价是可行的，恒定低温下的棉苗总长、出苗率、干物重和昼夜变温下的萌发率，可作为鉴定指标。

关键词: 棉花, 出苗期, 耐冷性, 综合评价, 指标筛选

Abstract:

【Objective】 In this study, the purpose was to comprehensively evaluate the cold tolerance of cotton varieties (lines) at seedling emergence stage, establish a reliable evaluation model, screen and identify indicators, and provide a simple and effective evaluation method for the selection and identification of cold-tolerant varieties in cotton.【Method】200 upland cotton varieties (lines) were used to test hypocotyl length, root length and 100-grain weight, etc. under three treatments of constant chilling (CC), diurnal variation of chilling (DVC) and normal conditions. A combination of integrated cold tolerance coefficient difference analysis, frequency analysis, drop analysis, principal component analysis, cluster analysis, and multiple regression analysis were used to classify their cold tolerance types, establish cold tolerance prediction models, and screen evaluation parameters. 【Result】The variation of each parameters at normal conditions were minor fluctuations ranging from 3.12% to 18.89%. The seedling emergence rate was above 85.00%, which had high viability and could be used for subsequent cold tolerance analysis. The variability of each parameter within the accessions increased under chilling stress, ranging from 7.14%-108.33%, and the most variable parameter were root length under CC condition and germination index under DVC condition. Principal component analysis converted the 14 parameters under chilling stress and 100-grain weight measured into six mutually independent composite indicators, representing 74.98% of the total data information. The comprehensive cold tolerance evaluation value (D) was calculated by the affiliation function method and then clustering analysis was performed. 200 cotton varieties (lines) were divided into five categories according to their cold tolerance, with 2 of the group Ⅰ being strongly cold tolerant, 42 of the group Ⅱ being cold tolerant, 69 of the group Ⅲ being medium cold tolerant, 83 of the group Ⅳ being more sensitive, and 4 of the group Ⅴ being sensitive, of which Xinluzhong 16 was the most cold-tolerant material. A multiple regression analysis was applied to establish a prediction model for cold tolerance of cotton at seedling emergence as Y=-4.10+0.58X4+0.40X14+0.32X1+0.22X5 (R²=0.92), and four parameters for cold resistance evaluation were confirmed, namely total length of seedling, emergence rate, and dry weight under CC stress, germination rate under DVC stress. The cold-tolerant varieties (lines) had higher seedling emergence rates of early sowing experiment in the field, which were basically consistent with the results of the indoor results. 【Conclusion】 It is feasible to use CC and DVC stress combined with multivariate statistical analysis to evaluate the cold tolerance of cotton at seeding stage, and total length of seedling, emergence rate, and dry weight under CC stress, germination rate under DVC stress can be used as evaluation parameters.

Key words: Gossypium hirsutum L., seedling emergence stage, cold tolerance, comprehensive evaluation, parameters screening

沈倩,张思平,刘瑞华,刘绍东,陈静,葛常伟,马慧娟,赵新华,杨国正,宋美珍,庞朝友. 棉花出苗期耐冷综合评价体系的构建及耐冷指标筛选[J]. 中国农业科学, 2022, 55(22): 4342-4355.

SHEN Qian,ZHANG SiPing,LIU RuiHua,LIU ShaoDong,CHEN Jing,GE ChangWei,MA HuiJuan,ZHAO XinHua,YANG GuoZheng,SONG MeiZhen,PANG ChaoYou. Construction of A Comprehensive Evaluation System and Screening of Cold Tolerance Indicators for Cold Tolerance of Cotton at Seedling Emergence Stage[J]. Scientia Agricultura Sinica, 2022, 55(22): 4342-4355.

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指标 Parameter	均值 Mean	中位数 Median	变异系数 Coefficient variation	标准差 Standard deviation	最小值 Minimum	最大值 Maximum	偏度 Skewness	峰度 Kurtosis
百粒重HGW (g)	9.71	9.50	11.12	1.08	7.13	12.98	0.41	0.07
出苗率ER (%)	94.34	95.00	6.53	6.16	85.00	100.00	-0.84	-0.36
下胚轴长度HL (cm)	10.11	10.10	6.82	0.69	8.20	12.68	0.14	0.52
根长RL (cm)	12.14	12.20	10.63	1.29	8.27	15.81	-0.32	0.22
总长TL (cm)	22.24	22.30	7.46	1.66	16.60	26.85	-0.2	0.24
萌发率GR (%)	99.05	100.00	3.12	3.09	60.00	100.00	-6.43	61.68
萌发指数GI	14.72	14.50	18.89	2.78	7.00	20.00	0.11	-0.95
干物重DW (mg/plant)	70.32	69.00	14.60	10.27	46.00	103.90	0.45	-0.07
可溶性糖含量SS (mg·g^-1)	49.92	47.45	12.70	6.34	32.14	66.50	0.15	0.035
游离氨基酸含量SAA (mg·g^-1)	28.12	27.65	17.99	5.06	14.73	40.30	-0.31	-0.07

低温处理 Chilling stress	时间 Time (d)	最小值 Minimum (%)	最大值 Maximum (%)	平均值 Mean	变异系数 Coefficient variation (%)
恒定低温 Constant chilling	1	59.26	99.97	85.89	17.02
	3	36.19	98.25	69.81	37.29
	5	0.00	68.03	40.77	88.04
	7	0.00	15.56	2.84	202.56
	9	0.00	24.44	2.19	265.24
昼夜变温 Diurnal variation of chilling	10	13.73	100.00	66.22	47.52
	12	20.95	96.30	60.51	50.29
	13	0.00	90.04	43.38	107.41
	14	0.00	84.44	23.02	126.45
	16	0.00	59.26	23.23	123.32

指标 Parameter	均值 Mean	中位数 Median	变异系数 Coefficient variation (%)	标准差 Standard deviation	最小值 Minimum	最大值 Maximum	偏度 Skewness	峰度 Kurtosis
ER-CC	0.66	0.67	21.21	0.14	0.00	0.99	-0.32	-0.25
HL-CC	0.70	0.70	7.14	0.05	0.52	0.83	-0.16	0.43
RL-CC	0.46	0.44	21.74	0.10	0.31	0.94	1.76	4.71
TL-CC	0.58	0.57	10.34	0.06	0.42	0.77	0.57	0.56
WD-CC	0.74	0.74	10.81	0.08	0.56	0.93	0.21	-0.09
SAA-CC	0.85	0.89	23.53	0.20	0.30	1.36	-0.41	-0.35
SS-CC	1.24	1.23	11.29	0.14	0.79	1.95	0.88	3.84
ER-DVC	0.63	0.64	25.40	0.16	0.16	0.96	-0.34	-0.06
HL-DVC	0.78	0.79	7.69	0.06	0.65	0.89	-0.15	0.29
RL-DVC	0.66	0.65	19.70	0.13	0.41	1.12	0.57	1.80
TL-DVC	0.72	0.71	11.11	0.08	0.56	1.00	0.51	1.51
WD-DVC	0.73	0.73	12.33	0.09	0.51	0.92	0.05	-0.05
GI-DVC	0.35	0.32	62.86	0.22	0.00	0.63	2.11	4.38
GR-DVC	0.12	0.08	108.33	0.13	0.02	0.81	0.50	-0.41

指标 Parameter	0<CTC≤0.2		0.2<CTC≤0.4		0.4<CTC≤0.6		0.6<CTC≤0.8		0.8<CTC≤1.2		1.2<CTC≤1.8
指标 Parameter	次数 Times	频次 Freq. (%)	次数 Times	频次 Freq. (%)	次数 Times	频次 Freq. (%)	次数 Times	频次 Freq. (%)	次数 Times	频次 Freq. (%)	次数 Times	频次 Freq. (%)
ER-CC	38	19.00	40	20.00	52	26.00	41	20.50	29	14.50	0	0.00
HL-CC	0	0.00	0	0.00	7	3.50	188	94.00	5	2.50	0	0.00
RL-CC	0	0.00	54	27.00	132	66.00	12	6.00	2	1.00	0	0.00
TL-CC	0	0.00	137	68.50	63	31.50	0	0.00	0	0.00	0	0.00
DW-CC	0	0.00	0	0.00	6	3.00	148	74.00	46	23.00	0	0.00
SS-CC	0	0.00	0	0.00	0	0.00	1	0.50	74	37.00	125	62.50
SAA-CC	0	0.00	3	1.50	20	10.00	46	23.00	125	62.50	6	3.00
ER-DVC	2	1.00	13	6.50	68	34.00	90	45.00	27	13.50	0	0.00
HL-DVC	0	0.00	0	0.00	0	0.00	135	67.50	65	32.50	0	0.00
RL-DVC	0	0.00	0	0.00	55	27.50	130	65.00	15	7.50	0	0.00
TL-DVC	0	0.00	0	0.00	6	3.00	177	88.50	17	8.50	0	0.00
DW-DVC	0	0.00	0	0.00	10	5.00	154	77.00	36	18.00	0	0.00
GI-DVC	170	85.00	17	8.50	11	5.50	2	1.00	0	0.00	0	0.00
GR-DVC	46	23.00	87	43.50	43	21.50	23	11.50	1	0.50	0	0.00
CTC：耐冷系数。下同 CTC: Cold tolerance coefficient. The same as below

性状 Trait	特征向量Power vector
性状 Trait	PV1	PV2	PV3	PV4	PV5	PV6
ER-CC	0.52	0.00	0.11	0.42	0.35	0.05
HL-CC	0.87	0.17	-0.02	-0.04	-0.24	0.09
RL-CC	0.81	0.20	0.01	-0.25	0.045	-0.09
TL-CC	0.94	0.23	-0.02	-0.14	-0.11	0.00
DW-CC	0.69	0.15	0.17	-0.19	-0.08	0.06
SS-CC	0.31	0.10	-0.09	0.56	0.13	-0.07
SAA-CC	-0.30	0.07	0.39	-0.27	-0.33	-0.37
ER-DVC	-0.10	0.46	-0.25	0.58	-0.24	0.13
HL-DVC	-0.10	0.65	-0.25	0.08	-0.15	0.05
RL-DVC	-0.23	0.77	-0.36	-0.22	0.07	-0.03
TL-DVC	-0.23	0.85	-0.36	-0.21	0.03	-0.01
DW-DVC	-0.11	0.28	0.09	-0.17	0.82	-0.13
GI-DVC	-0.12	0.50	0.80	0.07	-0.02	0.12
GR-DVC	-0.18	0.55	0.73	0.17	-0.02	0.05
HGW	-0.15	-0.09	0.04	-0.25	0.06	0.89
特征值 Characteristic value	3.40	2.74	1.76	1.24	1.10	1.01
方差贡献率 Contribution rate (%)	22.65	18.25	11.74	8.26	7.35	6.72
累积贡献率 Cumulative contribution rate (%)	22.65	40.90	52.64	60.90	68.25	74.98

棉花出苗期耐冷综合评价体系的构建及耐冷指标筛选

Construction of A Comprehensive Evaluation System and Screening of Cold Tolerance Indicators for Cold Tolerance of Cotton at Seedling Emergence Stage

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多元回归方程 Multiple regression equation	相关系数 r	判定系数 R²	F值 F value	P值 P value
Y=-3.28+0.80X4	0.80	0.64	342.76	≤0.001
Y=-3.94+0.82X4+0.42X14	0.90	0.81	409.48	≤0.001
Y=-3.84+0.71X4+0.41X14+0.31X1	0.94	0.87	506.66	≤0.001
Y=-4.10+0.58X4+0.40X14+0.32X1+0.22X5	0.96	0.92	537.36	≤0.001
Y=-5.02+0.54X4+0.39X14+0.29X1+0.23X5+0.17X6	0.97	0.94	654.30	≤0.001

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