不同砧木对‘87-1’葡萄光合特性及荧光特性的影响

doi:10.3864/j.issn.0578-1752.2018.10.016

摘要/Abstract

摘要：

目的评价贝达、1103P、3309C、140Ru、5C、SO4、华葡1号、抗砧1等8种不同砧木对‘87-1’葡萄光合特性和叶绿素荧光特性的影响,为筛选适宜设施栽培的砧木提供理论基础。方法通过Li-6400光合仪测定光响应曲线（设定CO₂浓度为400 μmol·mol^-1,温度为25℃,气体流速为500 mmol·s^-1。设定光合有效辐射按照由强到弱的顺序分别为2 000、1 800、1 500、1 200、800、400、200、100、50、20、0 μmol·m^-2·s^-1）、CO₂响应曲线（设定光合有效辐射为1 200 μmol·m^-2·s^-1,温度和气体流速分别设为25℃和500 mmol·s^-1。CO₂浓度按照400、200、100、50、20、400、400、800、1 200、1 500、1 800、2 000 μmol·mol^-1的顺序进行测定）、温度响应曲线（设定光合有效辐射为1 200 μmol·m^-2·s^-1,CO₂浓度控制为400 μmol·mol^-1,气体流速为500 mmol·s^-1。温度按照由小到大的顺序设定为25、27、30、32、35和37℃）,通过3条曲线分别求光补偿点、表观量子效率、暗呼吸效率、羧化效率、CO₂补偿点、不同温度下净光合速率等参数,通过FMS-2型便携脉冲调制式荧光仪测定叶绿素荧光F₀、Fm、Fv、Fv/F₀、Fv/Fm等参数,比较不同砧木对‘87-1’各光合参数的影响,并通过Topsis综合评价法进行排名。结果 ‘87-1’/3309C、‘87-1’/1103P组合表观量子效率高,光补偿点低,暗呼吸速率较低,Topsis综合排名位于前2名,两者耐弱光能力较强。‘87-1’/3309C、‘87-1’/华葡1号羧化效率较高,CO₂补偿点低,Topsis综合排名位于前2名,两者耐低浓度CO₂能力较强。‘87-1’/SO4、‘87-1’/华葡1号不同温度下净光合变化值较小,高温下净光合速率较大,Topsis综合排名位于前2名,说明两者耐高温能力较强。通过方差分析发现‘87-1’/140Ru和‘87-1’/SO4组合F₀最高,‘87-1’/1103P组合Fv最高,‘87-1’/1103P和‘87-1’/3309C的Fv/F₀值最高,8个砧穗组合的Fm和Fv/Fm无显著性差异。结论 3309C、1103P两种砧木可以有效提高‘87-1’耐弱光能力及原初光能转化效率,3309C、华葡1号两种砧木可以提高‘87-1’的耐低浓度CO₂能力,SO4、华葡1号2种砧木可以提高‘87-1’的耐高温能力。

关键词: 砧穗组合, ‘87-1’葡萄;, 光合特性, 叶绿素荧光特性, Topsis方法

Abstract:

【Objective】 The effects of different rootstock on ‘87-1’ grape photosynthetic characteristics and chlorophyll fluorescence characteristics were evaluated, and the results will provide theoretical basis for screening suitable cultivation rootstock.【Method】 Two- and three-year-old ‘87-1’ grape were grafted on eight kinds of rootstocks, including Beta, 1103P, 3309C, 140Ru, 5C, SO4, HuaPu NO.1 and KangZhen NO.1 in 2016 and 2017, and the eight kinds of rootstook-scion combinations were planted in grape center technology demonstration areas of Fruit Research Institute of Chinese Academy of Agricultural Sciences (Xingcheng, Liaoning province, east longitude 120.51° and northern latitude 40.45°). Their spacing in the rows and spacing between rows are 2.5 m×4.0 m. Double plant colonization, oblique dry horizontal dragon shape with horizontal curtain werer applied with the integration of water and fertilizer, and other management measures were routine. The Li-6400 Photosynthetic apparatus was used to measure eight rootstock-scions combinations’ light response curve, carbon dioxide response curve, temperature response curve in the cloudless morning. Before the measurement of three kinds of light curves, the optimal function leaf of different rootstock-scion combinations were selected by Li-6400 Photosynthetic apparatus. Li-6400 Photosynthesis apparatus was also used to choose the leaves with the largest net photosynthetic rate of different rootstock-scion combinations. First of all, the light response curve was measured as the carbon dioxide concentration was set at 400 μmol·mol^-1, temperature was set as 25℃, gas velocity was set at 500 mmol·s^-1, photosynthetically active radiation was set at 2 000, 1 800, 1 500, 1 200, 800, 400, 200, 100, 50, 20, 0 μmol·m^-2·s^-1 from strong to weak. Secondly, the carbon dioxide response curve was measured as the photosynthetically active radiation was set at 1 200 μmol·m^-2·s^-1, temperature was set at 25℃, gas velocity was set at 500 mmol?s^-1, carbon dioxide concentrations were set at 2 000, 1 800, 1 500, 1 200, 800, 400, 200, 150, 100, 50, 20 μmol·mol^-1 from high to low. Finally, the net photosynthetic rate curve was measured as the photosynthetically active radiation was set at 1 200 μmol·m^-2·s^-1, carbon dioxide concentration was set at 400 μmol·mol^-1, gas velocity was set at 500 mmol·s^-1, the temperatures were set at 25, 27, 30, 32, 35,27℃ from low to high. And then, the apparent quantum yield, light compensation point, carboxylation efficiency, carbon dioxide compensation point, dark respiration rate were obtained using right angle hyperbolic correction model. And the FMS-2 pulse-modulated fluorometer was used to obtain minimal fluorescence, maximal fluorescence, variable fluorescence, potential quantum yield of PSⅡ, maximal photochemical efficiency of PSⅡ in the dark. Then, variance analysis was used to compare the effects of different stock on photosynthetic parameters of ‘87-1’ grape, and Topsis comprehensive evaluation method was used to rank the eight rootstock-scion. 【Result】 The results of Topsis comprehensive evaluation showed that rootstock-scion combinations of ‘87-1’/3309C and ‘87-1’/1103P were ranked the first and second to tolerate weak light,and with the low light compensation point, high apparent quantum yield, low dark respiration rate. The rootstock-scion combinations of ‘87-1’/3309C and ‘87-1’/Huapu NO.1 were ranked the first and second to tolerate low carbon dioxide levels,and with low carbon dioxide compensation point, high apparent quantum yield. The rootstock-scion combinations of ‘87-1’/SO4, ‘87-1’/Huapu NO.1 were ranked the first and second to tolerate high temperature,and with little net photosynthetic changes at different temperatures and high net photosynthetic rate at high temperature. Furthermore, the results of variance analysis showed that the highest minimal fluorescence was found in ‘87-1’/140Ru and ‘87-1’/SO4 rootstock-scion combinations, the highest of variable fluorescence was found in ‘87-1’/1103P rootstock-scion combination, the highest of rate variable fluorescence and minimal fluorescence were found in ‘87-1’/1103P and ‘87-1’/3309C two kinds of rootstock-scion combinations. There was no significant difference of maximal fluorescence,the rate of variable fluorescence and maximal fluorescence among all 8 kinds of rootsock-scion combinations had no. 【Conclusion】 The rootstocks 3309C and 1103P can improve ‘87-1’ grape weak light tolerance ability efficiently, the rootstock 3309C and Huapu NO.1 can improve ‘87-1’ grape low carbon dioxide level tolerance ability efficiently, the rootstocks SO4 and Huapu NO.1 can improve ‘87-1’ grape high temperature tolerance ability efficiently, the rootstocks 1103P and 3309C can improve the beneficial to the enhancement of ‘87-1’ grape the primary light energy conversion efficiency.

Key words: rootstock-scion combination, ‘87-1’ grape;, photosynthetic characteristics, chlorophyll fluorescence characteristics, topsis method

韩晓, 王海波, 王孝娣, 冀晓昊, 史祥宾, 王宝亮, 郑晓翠, 王志强, 刘凤之. 不同砧木对‘87-1’葡萄光合特性及荧光特性的影响[J]. 中国农业科学, 2018, 51(10): 1972-1981.

Xiao HAN, HaiBo WANG, XiaoDi WANG, XiaoHao JI, XiangBin SHI, BaoLiang WANG, XiaoCui ZHENG, ZhiQiang WANG, FengZhi LIU. Effects of Different Rootstocks on ‘87-1’ Grape Photosynthetic and Chlorophyll Fluorescence Characteristics[J]. Scientia Agricultura Sinica, 2018, 51(10): 1972-1981.

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砧穗组合 Rootstock-scion combination	年份 Years	表观量子效率 Apparent quantum yield	光补偿点 Light combination point (μmol·m^-2·s^-1)	暗呼吸速率 Dark respiration rate (μmol·m^-2·s^-1)	Topsis得分 Topsis score		Topsis排名 Topsis ranking
砧穗组合 Rootstock-scion combination	年份 Years	表观量子效率 Apparent quantum yield	光补偿点 Light combination point (μmol·m^-2·s^-1)	暗呼吸速率 Dark respiration rate (μmol·m^-2·s^-1)	得分 Score	总分 Total score	Topsis排名 Topsis ranking
‘87-1’/HPYH	2016	0.0758a	23.309bc	1.5222b	0.5862	1.0433	4
‘87-1’/HPYH	2017	0.0657b	23.4195c	0.7787d	0.4571	1.0433	4
‘87-1’/3309C	2016	0.0778a	17.5864d	1.2661c	0.3614	1.2148	1
‘87-1’/3309C	2017	0.0694b	19.3291de	1.9137a	0.8534	1.2148	1
‘87-1’/140Ru	2016	0.0625b	22.4564bc	1.3096c	0.2225	0.7233	7
‘87-1’/140Ru	2017	0.0563c	27.1271b	1.3909b	0.5008	0.7233	7
‘87-1’/1103P	2016	0.0624b	20.3795cd	1.1497c	0.5394	1.194	2
‘87-1’/1103P	2017	0.0439d	18.3896ef	0.7745d	0.6546	1.194	2
‘87-1’/SO4	2016	0.0713a	23.489abc	1.5487b	0.6334	0.0337	5
‘87-1’/SO4	2017	0.0987a	15.7004f	1.367b	0.4003	0.0337	5
‘87-1’/KZYH	2016	0.0573b	25.2786ab	1.3098c	0.2472	0.6468	8
‘87-1’/KZYH	2017	0.0698b	31.186a	1.9143a	0.3996	0.6468	8
‘87-1’/5C	2016	0.0799a	26.8487a	1.9114a	0.4063	0.7399	6
‘87-1’/5C	2017	0.0661b	22.7534dc	1.177c	0.3336	0.7399	6
‘87-1’/Beta	2016	0.0745a	18.9303d	1.3077c	0.3501	1.1017	3
‘87-1’/Beta	2017	0.0548c	22.8865c	1.1474c	0.7516	1.1017	3

砧穗组合 Rootstock-scion combination	年份 Year	羧化效率 Carboxylation efficiency	CO₂补偿点 CO₂ combination point (μmol?m^-2?s^-1)	Topsis得分 Topsis score		Topsis排名 Topsis ranking
砧穗组合 Rootstock-scion combination	年份 Year	羧化效率 Carboxylation efficiency	CO₂补偿点 CO₂ combination point (μmol?m^-2?s^-1)	得分 Score	总分 Total score	Topsis排名 Topsis ranking
‘87-1’/HPYH	2016	0.0391cd	74.6669d	0.5677	1.0955	2
‘87-1’/HPYH	2017	0.087ab	77.2568c	0.5278	1.0955	2
‘87-1’/3309C	2016	0.0615ab	72.2445d	0.5465	1.1132	1
‘87-1’/3309C	2017	0.0894a	77.2742c	0.5667	1.1132	1
‘87-1’/140Ru	2016	0.0331d	86.5089b	0.5308	0.9881	4
‘87-1’/140Ru	2017	0.1002a	80.0318c	0.4573	0.9881	4
‘87-1’/1103P	2016	0.0554ab	79.4095c	0.5203	1.0279	3
‘87-1’/1103P	2017	0.0913a	85.53c	0.5076	1.0279	3
‘87-1’/SO4	2016	0.0267d	95.7802a	0.4525	0.9059	7
‘87-1’/SO4	2017	0.0408d	96.2671b	0.4534	0.9059	7
‘87-1’/KZYH	2016	0.0532ab	86.0179b	0.4659	0.9238	6
‘87-1’/KZYH	2017	0.0291d	109.7934a	0.4579	0.9238	6
‘87-1’/5C	2016	0.0508bc	96.0808a	0.4331	0.8197	8
‘87-1’/5C	2017	0.0749b	97.0057b	0.3866	0.8197	8
‘87-1’/Beta	2016	0.0649a	79.12c	0.4389	0.9742	5
‘87-1’/Beta	2017	0.0565c	84.6062c	0.5353	0.9742	5

砧穗组合 Rootstock-scion combination	年份 Year	25℃	27℃	30℃	32℃	35℃	37℃	ΔX	Topsis得分 Topsis score		Topsis排名 Topsis ranking
砧穗组合 Rootstock-scion combination	年份 Year	25℃	27℃	30℃	32℃	35℃	37℃	ΔX	得分 Score	总分 Total score	Topsis排名 Topsis ranking
‘87-1’/HPYH	2016	12.4	12.2	12.2	12.0	11.8	—	0.6	0.4052	1.717	2
‘87-1’/HPYH	2017	17	16.5	16	14.9	13.9	13.1	3.9	0.6066	1.717	2
‘87-1’/3309C	2016	14.50	14.8	14.5	14.3	14.0	—	0.8	0.3204	1.0118	6
‘87-1’/3309C	2017	17	15.7	14.6	12.7	11.9	11.3	5.7	0.3807	1.0118	6
‘87-1’/140Ru	2016	13.9	13.7	13.5	13.0	12.8	—	1.1	0.199	0.8932	7
‘87-1’/140Ru	2017	16	14.2	13	12.4	11.9	11.3	4.7	0.4297	0.8932	7
‘87-1’/1103P	2016	13.0	12.6	12.2	11.7	11.4	—	1.6	0.1033	0.892	5
‘87-1’/1103P	2017	18.9	18.3	17.4	16.3	15.8	14.6	4.3	0.6105	0.892	5
‘87-1’/SO4	2016	14.3	14.2	13.9	13.6	13.3	—	1	0.2353	0.7138	1
‘87-1’/SO4	2017	16.7	16.2	15.4	14.8	14.5	14	2.7	0.901	0.7138	1
‘87-1’/KZYH	2016	13.8	13.4	13.20	12.7	12.3	—	1.5	0.143	0.7011	8
‘87-1’/KZYH	2017	9.5	9.32	8.25	7.25	6.02	5.61	3.89	0.2439	0.7011	8
‘87-1’/5C	2016	10.99	11.09	10.90	10.87	10.64	—	0.56	0.4559	0.6287	4
‘87-1’/5C	2017	10.2	8.42	7.83	7.76	7.24	7.11	3.09	0.4361	0.6287	4
‘87-1’/Beta	2016	12.5	12.30	12.0	11.60	11.40	—	1.1	0.157	0.3869	3
‘87-1’/Beta	2017	16.2	15.1	13.8	13.8	13.3	13	3.2	0.7362	0.3869	3

砧穗组合 Rootstock-scion combination	F₀	Fv	Fm	Fv/Fm	Fv/F₀
‘87-1’/HPYH	233.0b	1003bc	1236a	0.811a	4.301ab
‘87-1’/3309C	232.7b	1055.7abc	1288a	0.817a	4.529a
‘87-1’/140Ru	257.7a	1099ab	1295a	0.771a	4.264ab
‘87-1’/1103P	248ab	1149.7a	1217a	0.811a	4.689a
‘87-1’/SO4	253.3a	1095.7ab	1349a	0.812a	4.345ab
‘87-1’/KZYH	237.7ab	944c	1181a	0.798a	3.970b
‘87-1’/5C	244.7ab	1021.3abc	1266a	0.807a	4.176ab
‘87-1’/Beta	230.7b	969.7bc	1200a	0.807a	4.201ab

	F₀	Fv	Fm	Fv/Fm	Fv / F₀	表观量子效率 AQY	光补偿点 LCP	暗呼吸速率 Rd	羧化效率 CE	CO₂ 补偿点 CCP	高温下净光合速率 NPR	ΔX
F₀	1
Fv	0.70637	1
Fm	0.57505	0.55952	1
Fv/Fm	-0.55284	-0.06732	-0.046	1
Fv / F₀	0.14838	0.80414	0.27875	0.38603	1
表观量子效率AQY	0.14665	-0.08636	0.63229	0.25166	-0.24755	1
光补偿点LCP	-0.13968	-0.61891	-0.55659	-0.63451	-0.75195*	-0.28537	1
暗呼吸Rd	-0.10423	-0.3034	0.12864	-0.12677	-0.34982	0.38938	0.32475	1
羧化效率CE	0.14869	0.53979	0.17599	-0.18706	0.60889	-0.56644	-0.17226	-0.38793	1
CO₂补偿点CCP	0.14281	-0.36561	-0.20268	-0.01505	-0.60409	0.37939	0.32798	0.36329	-0.82159*	1
高温下净光合速率 NPR	0.12225	0.59286	0.29319	0.25136	0.72352*	-0.07224	-0.71057*	-0.57168	0.3565	-0.65507	1
ΔX	-0.1395	0.24452	-0.01394	-0.12738	0.4371	-0.38358	0.1165	0.36265	0.61024	-0.53241	0.01598	1