外源物质浸种对迟播油菜越冬期抗寒性及产量的影响

doi:10.3724/SP.J.1006.2024.34134

作物学报 ›› 2024, Vol. 50 ›› Issue (5): 1271-1286.doi: 10.3724/SP.J.1006.2024.34134

外源物质浸种对迟播油菜越冬期抗寒性及产量的影响

王先领(), 姜岳, 雷贻忠, 肖胜男, 厍惠洁, 段圣省, 黄铭, 蒯婕, 汪波, 王晶, 赵杰, 徐正华^*(), 周广生

华中农业大学植物科学技术学院 / 农业农村部长江中游作物生理生态与耕作重点实验室, 湖北武汉 430070

收稿日期:2023-08-05 接受日期:2024-01-12 出版日期:2024-05-12 网络出版日期:2024-02-09
通讯作者: *徐正华, E-mail: xzh@mail.hzau.edu.cn
作者简介:E-mail: xlwang@webmail.hzau.edu.cn
基金资助:
湖北省重点研发计划项目(2023BBB028);财政部和农业农村部国家现代农业产业技术体系建设专项(CARS-12)

Effects of seed soaking with exogenous substances on late-seeded rapeseed cold resistance of during overwintering period and yield

WANG Xian-Ling(), JIANG Yue, LEI Yi-Zhong, XIAO Sheng-Nan, SHE Hui-Jie, DUAN Sheng-Xing, HUANG Ming, KUAI Jie, WANG Bo, WANG Jing, ZHAO Jie, XU Zheng-Hua^*(), ZHOU Guang-Sheng

College of Plant Science and Technology, Huazhong Agricultural University / Key Laboratory of Crop Ecophysiology and Farming System for the Middle Reaches of the Yangtze River, Ministry of Agriculture and Rural Affairs, Wuhan 430070, Hubei, China

Received:2023-08-05 Accepted:2024-01-12 Published:2024-05-12 Published online:2024-02-09
Contact: *E-mail: xzh@mail.hzau.edu.cn
Supported by:
Key Research and Development Plan of Hubei Province(2023BBB028);China Agriculture Research System of MOF and MARA(CARS-12)

摘要/Abstract

摘要：

确保迟播油菜产量是压减长江流域双季稻区冬闲田的关键, 提高越冬期抗寒性、促进冬前干物质积累是增加迟播油菜产量的有效途径。播前外源物质浸种是提高越冬期抗寒性, 促进冬前快速生长的有效措施。试验选用早熟品种华油杂137, 设置清水(CK), 0.01 mmol L^-1、0.05 mmol L^-1、0.10 mmol L^-1的甜菜碱(T1-1、T1-2、T1-3), 0.1 mmol L^-1、0.5 mmol L^-1、1.0 mmol L^-1的脯氨酸(T2-1、T2-2、T2-3), 0.03%、0.15%、0.30%的过氧化氢(T3-1、T3-2、T3-3), 0.001 mmol L^-1、0.01 mmol L^-1、0.05 mmol L^-1的苹果酸(T4-1、T4-2、T4-3), 25 mg L^-1、100 mg L^-1、300 mg L^-1的氧化纳米锌(T5-1、T5-2、T5-3), 0.5 mmol L^-1、1.0 mmol L^-1的多胺(T6-1、T6-2)浸种处理后, 于2021—2023年开展田间试验, 研究不同外源物质及浓度浸种对迟播油菜越冬期抗寒性及产量的影响。结果表明, 不同外源物质和不同浓度浸种处理影响迟播油菜出苗率, 部分处理如T3-3、T4-2、T5-3与CK相比显著提高, 提高幅度分别达到19.2%、15.3%、17.3%。部分外源物质浸种也显著提高了迟播油菜抗寒性, 其机制一方面是提高抗氧化系统中过氧化物酶、过氧化氢酶活性和谷胱甘肽含量, 减少活性氧、过氧化氢及丙二醛含量, 另一方面是增加可溶性糖、脯氨酸、苹果酸、多胺、甘露醇等渗透调节物质含量, 提高膜联冷应答蛋白激酶含量从而提高抗寒性。叶片抗寒性的增加有利于越冬期叶片生物量的积累, 有效分枝数增加, 单株角果数增加, 从而促进产量的提高。另外, 对筛选出的9个正向指标和3个负向抗寒性指标进行综合评价, 结果表明, 2年平均产量排序和抗寒性综合评价值排序结果基本一致, 产量较高、抗寒性较强的浸种处理为T5-3、T5-2、T2-3、T1-2。该研究可为长江流域迟播油菜冬前壮苗培育、提高越冬期抗寒性提供理论与技术支撑, 为迟播油菜抗逆稳产、促进冬闲田开发利用提供依据。

关键词: 油菜, 迟播, 抗寒性, 外源物质, 浸种

Abstract:

In double-cropping rice areas in the Yangtze River Basin (YRB), ensuring the yield of late-seeded rapeseed is essential to reduce the winter fallow fields. Additionally, promoting the accumulation of dry matter before winter and improving cold resistance during the overwintering period are effective ways to increase the yield of late-seeded rapeseed. Soaking seeds with exogenous substances is an effective measure to improve the cold resistance during the overwintering period and promote the rapid growth before winter. In this experiment, the early maturing rapeseed variety Huayouza 137 was selected, while soaking-seed treatments of water (CK); 0.01 mmol L^-1, 0.05 mmol L^-1, 0.10 mmol L^-1 betaine (T1-1, T1-2, T1-3); 0.1 mmol L^-1, 0.5 mmol L^-1, 1.0 mmol L^-1 proline (T2-1, T2-2, T2-3); 0.03%, 0.15%, 0.30% hydrogen peroxide (T3-1, T3-2, T3-3); 0.001 mmol L^-1, 0.01 mmol L^-1, 0.05 mmol L^-1 malic acid (T4-1, T4-2, T4-3); 25 mg L^-1, 100 mg L^-1, 300 mg L^-1 nano zinc oxide (T5-1, T5-2, T5-3); 0.5 mmol L^-1, 1.0 mmol L^-1 polyamines (T6-1, T6-2) were conducted between 2021 and 2023 rapeseed growing season. We studied the effects of soaking seeds with different exogenous substances and their levels on the cold resistance in winter and yield of late-seeded rapeseed. The results showed that the different exogenous substances and their levels of soaking seeds affected the germination rate of late-seeded rapeseed, and part of them, such as T3-3, T4-2, and T5-3, significantly increased by 19.2%, 15.3%, and 17.3% versus CK. Soaking seeds with some exogenous substances significantly improved the cold resistance of late-seeded rapeseed in winter. On the one hand, the activities of peroxidase, catalase, and the content of glutathione were improved, and the contents of hydrogen peroxide, active oxygen and MDA reduced; on the other hand, the contents of soluble sugar, proline, malic acid, polyamine, and mannitol were increased; at the same time, the content of membrane cold response protein kinase was increased. The increase of leaf cold resistance was beneficial to the accumulation of leaf biomass and the increase of effective branches and pod number per plant, thus promoting yield. In addition, 9 positive and 3 negative cold resistance indicators were comprehensively evaluated. The results showed that the two-year average yield ranking and the comprehensive evaluation value ranking of cold resistance were basically the same over the two years. While the soaking-seed treatments with the best yield and cold resistance were T5-3, T5-2, T2-3, and T1-2. These results of this study provide theoretical and technical support for the cultivation of late-seeded rapeseed seedlings before winter and the improvement of cold resistance in the YRB, and provide a basis for the stress resistance and stable production of late-seeded rapeseed and the development and utilization of winter fallow fields.

Key words: rapeseed, late-seeded, cold resistance, exogenous substance, soaking seeds

王先领, 姜岳, 雷贻忠, 肖胜男, 厍惠洁, 段圣省, 黄铭, 蒯婕, 汪波, 王晶, 赵杰, 徐正华, 周广生. 外源物质浸种对迟播油菜越冬期抗寒性及产量的影响[J]. 作物学报, 2024, 50(5): 1271-1286.

WANG Xian-Ling, JIANG Yue, LEI Yi-Zhong, XIAO Sheng-Nan, SHE Hui-Jie, DUAN Sheng-Xing, HUANG Ming, KUAI Jie, WANG Bo, WANG Jing, ZHAO Jie, XU Zheng-Hua, ZHOU Guang-Sheng. Effects of seed soaking with exogenous substances on late-seeded rapeseed cold resistance of during overwintering period and yield[J]. Acta Agronomica Sinica, 2024, 50(5): 1271-1286.

图/表 13

表1

图1

图2

表2

不同外源物质浸种对迟播油菜产量及产量构成的影响"

年份 Year	外源物质 Exogenous substance	浓度 Concentration	单株角果数 Pod number per plant	每角粒数 Seed number per pod	千粒重1000-seed weight (g)	单株产量 Yield per plant (g)	成株率Survival rate (%)	产量 Yield (kg hm^-2)
2021- 2022	对照CK	CK	128.7 ef	17.40 bc	3.55 ab	7.95 bc	45.27 d	2347.1 gh
	甜菜碱 Betaine (T1)	T1-1	125.1 ef	17.84 a	3.40 abc	7.61 bc	47.56 bcd	2112.9 i
		T1-2	145.8 cde	17.31 c	3.60 a	9.09 ab	46.95 bcd	2558.7 abc
		T1-3	146.3 cde	17.68 ab	3.44 abc	8.89 abc	47.33 bcd	2549.6 abc
	脯氨酸 Proline (T2)	T2-1	139.8 cdef	17.66 ab	3.51 abc	8.66 abc	47.18 bcd	2563.1 abc
		T2-2	178.7 a	17.48 abc	3.37 bc	10.53 a	49.68 abc	2571.5 abc
		T2-3	163.4 abc	17.42 bc	3.43 abc	9.75 ab	49.81 abc	2591.8 abc
	过氧化氢 Hydrogen peroxide (T3)	T3-1	114.5 f	17.34 bc	3.45 abc	6.87 c	49.82 abc	1771.8 j
		T3-2	126.7 ef	17.69 ab	3.52 abc	7.89 bc	47.17 bcd	2321.5 h
		T3-3	134.1 def	17.46 abc	3.34 c	7.83 bc	47.58 bcd	2430.2 efg
	苹果酸 Malic acid (T4)	T4-1	136.1 def	17.26 c	3.47 abc	8.13 bc	49.65 abc	2444.2 ef
		T4-2	141.5 cdef	17.38 bc	3.48 abc	8.57 abc	49.92 abc	2451.6 def
		T4-3	138.4 cdef	17.66 ab	3.51 abc	8.56 abc	44.65 d	2419.8 fg
	氧化纳米锌 Nano zinc oxide (T5)	T5-1	159.8 abcd	17.32 bc	3.48 abc	9.66 ab	45.74 cd	2536.1 bcd
		T5-2	163.8 abc	17.53 abc	3.34 c	9.60 ab	52.43 a	2603.6 ab
		T5-3	171.7 ab	17.45 abc	3.51 abc	10.52 a	50.00 ab	2635.1 a
	多胺 Polyamine (T6)	T6-1	148.8 bcde	17.39 bc	3.44 abc	8.90 abc	47.21 bcd	2451.3 def
	多胺 Polyamine (T6)	T6-2	135.1 def	17.67 ab	3.44 abc	8.20 bc	47.15 bcd	2510.4 cde
2022- 2023	对照CK	CK	126.0 de	17.19 b	3.54 ab	7.66 cde	47.09 ab	2280.0 e
	甜菜碱 Betaine (T1)	T1-1	122.0 de	17.44 ab	3.37 bc	7.20 de	50.45 a	2050.5 f
		T1-2	139.4 cd	17.73 a	3.58 a	8.85 abcd	48.46 ab	2508.4 a
		T1-3	141.9 bcd	17.67 a	3.33 bc	8.37 bcde	45.45 ab	2449.9 abcd
	脯氨酸 Proline (T2)	T2-1	133.0 d	17.16 b	3.47 abc	7.90 cde	50.05 ab	2482.5 abc
		T2-2	174.2 a	17.52 ab	3.45 abc	10.54 a	46.19 ab	2488.5 ab
		T2-3	160.7 abc	17.62 ab	3.31 c	9.38 abc	48.96 ab	2532.2 a
2022- 2023	过氧化氢 Hydrogen peroxide (T3)	T3-1	108.3 e	17.44 ab	3.50 ab	6.62 e	46.27 ab	1671.1 g
		T3-2	123.7 de	17.64 ab	3.50 ab	7.63 cde	46.81 ab	2261.2 e
		T3-3	129.4 de	17.74 a	3.30 c	7.56 cde	48.36 ab	2366.2 bcde
	苹果酸 Malic acid (T4)	T4-1	129.5 de	17.39 ab	3.53 ab	7.97 cde	47.89 ab	2355.1 de
		T4-2	134.1 d	17.56 ab	3.53 ab	8.33 bcde	47.61 ab	2359.4 cde
		T4-3	134.7 d	17.57 ab	3.48 abc	8.21 bcde	49.18 ab	2339.2 de
	氧化纳米锌 Nano zinc oxide (T5)	T5-1	157.2 abc	17.37 ab	3.45 abc	9.44 abc	50.37 ab	2453.1 abcd
		T5-2	159.2 abc	17.48 ab	3.48 abc	9.70 abc	47.66 ab	2525.9 a
		T5-3	164.1 ab	17.55 ab	3.52 ab	10.14 ab	47.83 ab	2575.0 a
	多胺 Polyamine (T6)	T6-1	146.8 bcd	17.44 ab	3.44 abc	8.81 abcd	48.40 ab	2358.4 cde
	多胺 Polyamine (T6)	T6-2	129.6 de	17.36 ab	3.51 abc	7.89 cde	45.10 b	2454.8 abcd
方差分析 ANOVA
年份 Year			*	ns	ns	ns	ns	**
处理 Treatment			**	ns	ns	**	ns	**
年份×处理 Year×Treatment			ns	ns	ns	ns	ns	ns

表2

表3

不同外源物质浸种对迟播油菜成熟期关健农艺性状的影响"

年份 Year	外源物质 Exogenous substance	浓度 Concentration	株高 Plant height (cm)	有效分枝数Effective branch number	根颈粗 Root-crown diameter (mm)	地上部干重 Shoot biomass (g)	抗折力 Bending resistance (N)
2021-2022	对照CK	CK	164.1 ab	4.6 bcd	10.8 bcd	23.6 abc	79.2 g
	甜菜碱 Betaine (T1)	T1-1	171.5 ab	4.5 bcd	11.4 abcd	22.6 bc	64.2 h
		T1-2	170.8 ab	5.9 a	10.0 d	29.7 abc	96.4 cd
		T1-3	168.6 ab	5.6 abc	11.9 abcd	29.7 abc	95.4 cd
2021-2022	脯氨酸 Proline (T2)	T2-1	174.6 a	5.6 ab	12.1 abc	30.0 abc	96.4 cd
		T2-2	164.2 ab	5.1 abcd	11.1 abcd	30.7 ab	91.8 de
		T2-3	170.4 ab	5.4 abcd	12.7 ab	31.1 ab	115.6 a
	过氧化氢 Hydrogen peroxide (T3)	T3-1	166.8 ab	4.8 abcd	11.4 abcd	20.7 c	82.4 efg
		T3-2	172.3 ab	5.3 abcd	12.8 a	23.5 abc	91.6 de
		T3-3	157.8 b	5.2 abcd	11.1 abcd	24.7 abc	102.2 bc
	苹果酸 Malic acid (T4)	T4-1	173.1 a	5.5 abc	12.5 ab	24.8 abc	81.4 fg
		T4-2	166.9 ab	4.9 abcd	12.2 abc	26.3 abc	94.4 cd
		T4-3	169.6 ab	4.7 bcd	10.5 cd	24.7 abc	92.6 cd
	氧化纳米锌 Nano zinc oxide (T5)	T5-1	170.5 ab	4.4 cd	11.1 abcd	29.1 abc	81.4 fg
		T5-2	170.3 ab	4.2 d	10.5 cd	32.4 a	94.4 cd
		T5-3	166.3 ab	4.3 d	11.2 abcd	32.5 a	92.6 cd
	多胺 Polyamine (T6)	T6-1	173.7 a	5.5 abc	12.2 abc	27.2 abc	107.0 ab
	多胺 Polyamine (T6)	T6-2	170.8 ab	4.8 abcd	11.1 abcd	27.6 abc	89.4 def
2022-2023	对照CK	CK	166.3 ab	4.8 bcd	10.4 abc	22.6 abc	69.2 g
	甜菜碱 Betaine (T1)	T1-1	164.6 ab	4.4 d	10.3 bc	22.2 abc	54.2 h
		T1-2	172.0 ab	4.5 cd	11.0 abc	20.9 bc	86.4 bcd
		T1-3	171.4 ab	6.0 a	9.4 c	29.0 ab	85.4 cd
	脯氨酸 Proline (T2)	T2-1	169.1 ab	5.7 abc	11.2 abc	28.7 ab	86.4 bcd
		T2-2	175.0 a	5.7 ab	11.5 ab	28.6 ab	81.8 de
		T2-3	164.7 ab	5.2 abcd	10.6 abc	30.8 a	95.6 ab
	过氧化氢 Hydrogen peroxide (T3)	T3-1	171.0 ab	5.5 abcd	12.3 a	29.5 ab	72.4 efg
		T3-2	166.9 ab	4.9 abcd	10.5 abc	19.4 c	81.6 de
		T3-3	172.5 ab	5.4 abcd	12.1 ab	22.5 abc	92.2 abc
	苹果酸 Malic acid (T4)	T4-1	158.3 b	5.3 abcd	10.7 abc	23.9 abc	71.4 fg
		T4-2	173.7 ab	5.6 abc	11.8 ab	23.7 abc	84.4 cd
		T4-3	167.4 ab	4.9 abcd	11.6 ab	25.7 abc	82.6 cd
	氧化纳米锌 Nano zinc oxide (T5)	T5-1	170.2 ab	4.8 abcd	10.1 bc	23.7 abc	71.4 fg
		T5-2	170.9 ab	4.5 cd	10.3 bc	28.0 abc	84.4 cd
		T5-3	170.5 ab	4.3 d	10.2 bc	27.9 abc	82.6 cd
	多胺 Polyamine (T6)	T6-1	166.9 ab	4.3 d	10.6 abc	31.6 a	97.0 a
	多胺 Polyamine (T6)	T6-2	174.4 a	5.6 abc	11.7 ab	25.7 abc	79.4 def
方差分析 ANOVA
年份 Year			ns	ns	**	ns	**
处理 Treatment			ns	**	ns	**	**
年份×处理 Year×Treatment			**	ns	**	ns	ns

表3

表4

不同外源物质浸种对迟播油菜越冬期关键农艺性状及叶片生物量的影响"

年份 Year	外源物质 Exogenous substance	浓度 Concentration	株高 Plant Height (cm)	根长 Root length (cm)	根颈粗 Root-crown diameter (mm)	叶面积 Leaf area (cm²)	叶片生物量 Leaf biomass (g)
2021- 2022	对照CK	CK	22.4 b	12.2 abc	2.80 cde	436.6 de	1.24 gh
	甜菜碱 Betaine (T1)	T1-1	21.8 bc	11.9 bc	2.71 de	423.6 e	1.13 h
		T1-2	21.0 bc	13.4 abc	3.43 abcd	487.9 bcde	1.63 cd
		T1-3	21.0 bc	12.8 abc	3.37 abcde	481.1 bcde	1.55 de
	脯氨酸 Proline (T2)	T2-1	20.1 bc	14.1 a	3.57 abc	498.3 bcd	1.71 bc
		T2-2	20.8 bc	12.8 abc	3.58 abc	506.9 bc	1.73 bc
		T2-3	21.6 bc	12.9 abc	3.63 abc	507.1 bc	1.82 ab
	过氧化氢 Hydrogen peroxide (T3)	T3-1	21.4 bc	12.6 abc	2.57 e	326.0 f	0.77 i
		T3-2	21.7 bc	13.3 abc	2.80 cde	426.2 e	1.24 gh
		T3-3	22.0 bc	12.9 abc	2.99 bcde	448.7 cde	1.38 efg
	苹果酸 Malic acid (T4)	T4-1	23.9 a	12.6 abc	3.07 abcde	460.6 cde	1.41 ef
		T4-2	20.2 bc	13.1 abc	3.14 abcde	470.7 cde	1.46 e
		T4-3	21.4 bc	11.9 bc	2.91 bcde	446.2 cde	1.27 fgh
	氧化纳米锌 Nano zinc oxide (T5)	T5-1	19.6 c	12.7 abc	3.27 abcde	476.0 bcde	1.49 e
		T5-2	20.6 bc	13.6 abc	3.69 ab	537.0 ab	1.89 a
		T5-3	21.1 bc	14.0 ab	3.84 a	571.7 a	1.93 a
	多胺 Polyamine (T6)	T6-1	20.7 bc	12.0 abc	3.10 abcde	470.1 cde	1.43 e
	多胺 Polyamine (T6)	T6-2	20.8 bc	11.4 c	3.23 abcde	473.3 bcde	1.48 e
2022- 2023	对照CK	CK	22.3 ab	12.4 bc	2.95 abc	435.7 cd	1.16 de
	甜菜碱 Betaine (T1)	T1-1	21.3 abc	12.3 bc	2.84 bc	413.6 d	1.02 e
		T1-2	20.3 bcd	14.3 abc	3.49 abc	481.2 bcd	1.46 bc
		T1-3	20.8 bcd	13.2 abc	3.50 abc	473.0 bcd	1.49 bc
	脯氨酸 Proline (T2)	T2-1	19.5 cd	14.9 a	3.68 abc	488.9 bc	1.63 ab
		T2-2	20.1 bcd	13.5 abc	3.78 ab	501.6 bc	1.61 ab
		T2-3	21.2 abcd	13.2 abc	3.73 ab	493.5 bc	1.72 a
	过氧化氢 Hydrogen peroxide (T3)	T3-1	21.0 bcd	13.1 abc	2.73 c	318.5 e	0.69 f
		T3-2	21.4 abc	13.5 abc	2.89 bc	416.8 d	1.16 de
		T3-3	21.5 abc	13.3 abc	3.17 abc	439.9 cd	1.21 de
	苹果酸 Malic acid (T4)	T4-1	23.1 a	12.8 abc	3.16 abc	446.5 cd	1.29 cd
		T4-2	20.0 bcd	13.6 abc	3.22 abc	454.9 bcd	1.34 cd
		T4-3	20.9 bcd	12.5 bc	3.08 abc	438.0 cd	1.15 de
	氧化纳米锌 Nano zinc oxide (T5)	T5-1	18.9 d	13.2 abc	3.33 abc	471.3 bcd	1.38 cd
		T5-2	20.3 bcd	14.0 abc	3.79 ab	521.2 ab	1.75 a
		T5-3	20.9 bcd	14.4 ab	3.93 a	559.9 a	1.77 a
	多胺 Polyamine (T6)	T6-1	20.2 bcd	12.3 bc	3.23 abc	459.1 bcd	1.32 cd
	多胺 Polyamine (T6)	T6-2	20.4 bcd	12.0 c	3.41 abc	464.8 bcd	1.32 cd
方差分析 ANOVA
年份 Year			**	**	*	ns	**
处理 Treatment			**	**	**	**	**
年份×处理 Year×Treatment			ns	ns	ns	ns	ns

表4

图3

表5

表6

表7

图4

图5

表8

参考文献 39

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外源物质 Exogenous substance	浓度 Concentration	MDA (nmol g^-1)	H₂O₂ (μmol g^-1)	O₂∙^- (μg g^-1)	·OH (ng g^-1)	SOD (U)	POD (U)	CAT (U)	APX (U)
对照CK	CK	184.3 a	0.983 b	5.56 b	7.37 a	1730.1 g	2.64 def	589.3 d	0.86 e
甜菜碱 Betaine (T1)	T1-1	190.2 a	1.014 b	6.29 a	7.85 a	1727.4 g	2.48 f	569.8 d	1.17 cd
	T1-2	121.7 cde	0.682 cd	5.48 bc	5.08 cd	2463.3 cd	3.52 bc	968.2 b	1.10 d
	T1-3	128.6 cd	0.741 c	4.95 bcde	5.24 c	2319.4 cde	3.41 c	937.1 b	0.94 e
脯氨酸 Proline (T2)	T2-1	116.6 cde	0.614 d	4.74 cde	4.69 cde	2485.1 cd	3.72 abc	969.1 b	0.91 e
	T2-2	115.8 cde	0.589 d	5.33 bc	4.69 cde	2585.5 c	3.80 ab	982.7 b	1.35 ab
	T2-3	115.3 cde	0.589 d	4.49 def	4.67 cde	2938.6 b	3.83 ab	1002.2 b	1.43 a
过氧化氢 Hydrogen peroxide (T3)	T3-1	192.8 a	1.123 a	4.43 ef	7.96 a	1091.9 h	1.59 g	561.1 d	0.85 e
	T3-2	185.4 a	1.002 b	3.94 f	7.40 a	1730.1 g	2.56 ef	589.3 d	0.98 e
	T3-3	177.9 a	0.968 b	5.18 bcd	7.16 a	1855.0 fg	2.84 def	681.6 cd	0.97 e
苹果酸 Malic acid (T4)	T4-1	157.3 b	0.937 b	3.97 f	6.37 b	1998.9 efg	2.93 de	740.8 c	1.26 bc
	T4-2	155.3 b	0.918 b	6.17 a	6.29 b	2069.6 defg	2.95 de	772.9 c	1.12 cd
	T4-3	183.3 a	0.969 b	4.60 def	7.25 a	1768.1 fg	2.69 def	613.5 d	0.95 e
氧化纳米锌 Nano zinc oxide (T5)	T5-1	134.2 c	0.773 c	5.50 bc	5.27 c	2210.8 cdef	3.08 d	917.6 b	0.98 e
	T5-2	108.1 de	0.570 d	6.45 a	4.30 de	3047.2 ab	4.00 a	1013.8 b	1.15 cd
	T5-3	105.4 e	0.561 d	6.23 a	4.14 e	3313.4 a	4.11 a	1122.6 a	0.90 e
多胺 Polyamine (T6)	T6-1	138.5 c	0.891 b	5.33 bc	6.19 b	2199.9 cdef	3.00 de	780.6 c	1.21 cd
多胺 Polyamine (T6)	T6-2	135.2 c	0.781 c	4.77 cde	5.44 c	2191.8 cdef	3.00 de	891.4 b	1.15 cd

外源物质 Exogenous substance	浓度 Concentration	抗坏血酸 ASA (μmol g^-1)	类胡萝卜素 Carnosine (pmol g^-1)	谷胱甘肽 GSH (mg g^-1)
对照CK	CK	6.91 b	1.22 def	4.06 d
甜菜碱 Betaine (T1)	T1-1	5.76 c	1.19 ef	3.46 e
	T1-2	9.13 a	1.03 gh	4.88 bc
	T1-3	7.14 b	0.96 h	4.84 bc
脯氨酸 Proline (T2)	T2-1	7.66 b	1.17 f	5.07 ab
	T2-2	5.57 c	1.53 ab	5.14 ab
	T2-3	9.42 a	1.29 cde	5.23 ab
过氧化氢 Hydrogen peroxide (T3)	T3-1	8.88 a	1.10 fg	3.28 e
	T3-2	8.73 a	1.12 fg	3.47 e
	T3-3	6.86 b	1.33 cd	4.34 cd
苹果酸 Malic acid (T4)	T4-1	5.90 c	1.37 c	4.37 cd
	T4-2	5.51 c	1.29 cde	4.44 cd
	T4-3	7.22 b	1.51 ab	4.11 d
氧化纳米锌 Nano zinc oxide (T5)	T5-1	7.31 b	1.35 cd	4.83 bc
	T5-2	8.65 a	1.42 bc	5.48 a
	T5-3	5.84 c	1.30 cde	5.56 a
多胺 Polyamine (T6)	T6-1	6.86 b	1.38 c	4.79 bc
多胺 Polyamine (T6)	T6-2	9.77 a	1.56 a	4.81 bc

外源物质 Exogenous substance	浓度 Concentration	可溶性糖 Soluble sugar (mg g^-1)	脯氨酸 Proline (ng g^-1)	苹果酸 Malate (μg g^-1)	甜菜碱 Betaine (pg g^-1)	多胺 Polyamine (mg g^-1)	甘露醇 Mannitol (ng g^-1)
对照CK	CK	4.28 k	268.5 b	3.71 f	398.6 cd	5.69 ef	126.7 e
甜菜碱 Betaine (T1)	T1-1	4.11 l	211.7 c	3.40 f	475.9 ab	5.45 ef	125.0 e
	T1-2	5.15 ef	319.3 a	5.03 bcd	365.0 cde	9.24 ab	181.8 bcd
	T1-3	5.13 ef	308.8 a	4.82 cd	523.3 a	8.99 abc	177.6 bcd
脯氨酸 Proline (T2)	T2-1	5.27 d	318.0 a	5.06 bcd	319.2 e	9.31 ab	184.4 bcd
	T2-2	5.23 de	321.8 a	5.17 bc	338.5 de	9.71 a	186.4 bc
	T2-3	5.39 c	318.7 a	5.42 bc	383.0 cde	9.32 ab	187.9 bc
过氧化氢 Hydrogen peroxide (T3)	T3-1	4.05 l	256.6 b	2.89 g	488.2 ab	5.01 f	70.4 f
	T3-2	4.27 k	303.8 a	3.48 f	492.7 ab	5.52 ef	125.5 e
	T3-3	4.42 j	264.7 b	3.78 f	483.7 ab	5.97 ef	159.2 cd
苹果酸 Malic acid (T4)	T4-1	4.55 i	215.0 c	3.81 f	354.4 de	6.10 ef	161.4 cd
	T4-2	4.72 h	253.0 b	4.06 ef	473.0 ab	7.91 d	162.9 cd
	T4-3	4.41 j	267.7 b	3.67 f	325.8 e	5.79 ef	153.6 d
氧化纳米锌 Nano zinc oxide (T5)	T5-1	5.04 f	300.0 a	4.77 cd	388.4 cde	8.12 cd	177.1 bcd
	T5-2	5.60 b	330.9 a	5.59 ab	428.4 bc	10.02 a	201.8 ab
	T5-3	6.31 a	322.8 a	6.00 a	369.1 cde	10.04 a	215.5 a
多胺 Polyamine (T6)	T6-1	4.84 g	323.3 a	4.15 ef	513.9 a	6.61 e	165.8 cd
多胺 Polyamine (T6)	T6-2	5.04 f	264.7 b	4.45 de	512.7 a	8.45 bcd	168.7 cd

外源物质 Exogenous substance	评价对象 Evaluation object	正理想解距离D+ Positive ideal solution distance D+	负理想解距离D- Negative ideal solution distance D-	相对接近度C Relative proximity C	排序结果Sorting result	平均产量排序结果 Average yield Sorting result
对照CK	CK	2.618	1.350	0.340	15	15
甜菜碱 Betaine (T1)	T1-1	3.111	0.882	0.221	17	17
	T1-2	0.908	2.890	0.761	6	4
	T1-3	1.079	2.705	0.715	7	7
脯氨酸 Proline (T2)	T2-1	0.733	3.068	0.807	5	6
	T2-2	0.642	3.168	0.832	4	5
	T2-3	0.581	3.219	0.847	3	3
过氧化氢 Hydrogen peroxide (T3)	T3-1	3.659	0.377	0.093	18	18
	T3-2	2.765	1.349	0.328	16	16
	T3-3	2.340	1.624	0.410	13	13
苹果酸 Malic acid (T4)	T4-1	2.236	1.741	0.438	12	12
	T4-2	1.904	1.942	0.505	11	10
	T4-3	2.505	1.493	0.373	14	14
氧化纳米锌 Nano zinc oxide (T5)	T5-1	1.258	2.527	0.668	8	8
	T5-2	0.335	3.496	0.913	2	2
	T5-3	0.068	3.724	0.982	1	1
多胺 Polyamine (T6)	T6-1	1.737	2.192	0.558	10	11
多胺 Polyamine (T6)	T6-2	1.445	2.365	0.621	9	9

外源物质浸种对迟播油菜越冬期抗寒性及产量的影响

Effects of seed soaking with exogenous substances on late-seeded rapeseed cold resistance of during overwintering period and yield

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浓度 Concentration	对照 Contrast (CK)	甜菜碱 Betaine (T1)	脯氨酸 Proline (T2)	过氧化氢 Hydrogen peroxide (T3)	苹果酸 Malic acid (T4)	氧化纳米锌 Nano zinc oxide (T5)	多胺 Polyamine (T6)
浓度-1 Concentration-1	—	0.01 mmol L^-1	0.1 mmol L^-1	0.03%	0.001 mmol L^-1	25 mg L^-1	0.5 mmol L^-1
浓度-2 Concentration-2	—	0.05 mmol L^-1	0.5 mmol L^-1	0.15%	0.01 mmol L^-1	100 mg L^-1	1.0 mmol L^-1
浓度-3 Concentration-3	—	0.10 mmol L^-1	1.0 mmol L^-1	0.30%	0.05 mmol L^-1	300 mg L^-1	—

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