Effects of NaCl stress on antioxidant enzyme content and malondialdehyde content in grape cultivars leaves

doi:10.6048/j.issn.1001-4330.2023.04.012

Xinjiang Agricultural Sciences ›› 2023, Vol. 60 ›› Issue (4): 880-888.DOI: 10.6048/j.issn.1001-4330.2023.04.012

• Horticultural Special Local Products·Forestry·Facility Agriculture • Previous Articles Next Articles

Effects of NaCl stress on antioxidant enzyme content and malondialdehyde content in grape cultivars leaves

CHEN Liliang(), LU Qianjun, MA Yuanyuan, LIU Ying, ZHAO Baolong, SUN Junli()

Key Laboratory of Characteristic Fruits and Vegetables Cultivation Physiology and Germplasm Resources Utilization of Xinjiang Production and Construction Corps/College of Agronomy,Shihezi University,Shihezi Xinjiang 832003,China

Received:2022-08-20 Online:2023-04-20 Published:2023-05-06
Correspondence author: SUN Junli (1976-), female, Jiaozuo, Henan, professor, research direction for the phys-iological regulation of horticultural plants, (E-mail)1530322722@qq.com
Supported by:
National Natural Science Foundation of China "Screening of salt-resistant rootstock of grape and the mechanism of salt-tolerant adaptive reaction"(32060647);National Natural Science Foundation of China "Mechanism of Grape resistant rootstock increasing resveratrol content of Cabernet Sauvignon"(32060648);Breeding Project of Shihezi University(XZZX202104)

不同葡萄品种的耐盐性比较分析

陈丽靓(), 鲁倩君, 马媛媛, 刘迎, 赵宝龙, 孙军利()

石河子大学农学院/特色果蔬栽培生理与种质资源利用兵团重点实验室,新疆石河子 832000

通讯作者: 孙军利(1976-),女,河南焦作人,教授,研究方向为园艺植物生理调节,(E-mail)1530322722@qq.com
作者简介:陈丽靓(1997-),女,新疆人,硕士研究生,研究方向为果树生理,(E-mail)1339004564@qq.com
基金资助:
国家自然科学基金项目“葡萄抗盐砧木筛选及其耐盐适应性反应机制研究”(32060647);国家自然科学基金项目“葡萄抗性砧木提高赤霞珠植株白藜芦醇含量的机理研究”(32060648);石河子大学育种项目(XZZX202104)

Abstract

Abstract:

【Objective】To compare grape cultivars salt tolerance in the hope of providing theoretical support for the selection of salt-tolerant grape varieties by using ten grape varieties.【Methods】The experimental materials were cultured by pot irrigation with salt by adopting potted salt irrigation method cultivate to study the effects of 100 mmol/L NaCl stress on the salt damage index, photosynthesis, antioxidant enzyme content and malondialdehyde content of different grape varieties. Meanwhile, salt tolerance was compared through principal component analysis.【Results】Under 100 mmol/L NaCl stress, the activities of SOD, CAT, POD, net photosynthetic rate (Pn), stomatal conductance (Gs) and transpiration of Kashhar,Munage,Hetian Red,Summer Black the rate (Tr) had the largest increase compared to the control. The content of intercellular carbon dioxide (Ci) and malondialdehyde decreased the least.The SOD, CAT, POD activities, net photosynthetic rate (Pn), stomatal conductance (Gs) and transpiration rate (Tr) of 101-14,Beda,Kangzhen 3 increased significantly compared with the control. The content of intercellular carbon dioxide (Ci) and malondialdehyde decreased slightly. The SOD, CAT, POD activities, net photosynthetic rate (Pn), stomatal conductance (Gs) and transpiration rate (Tr) of 5BB, SO4,3309M had the smallest increase compared with the control, and the increase of intercellular carbon dioxide (Ci) and The content of malondialdehyde decreased the least.【Conclusion】Kashhar,Munage,Hetian Red and Summer Black are salt-tolerant varieties, 101-14,Beda and Kangzhen 3 are moderately salt-tolerant varieties, and 5BB,SO4 and 3309M are salt intolerant varieties.

Key words: grape; NaCl stress; salt tolerance; photosynthesis; antioxidant enzymes; malonaldehyde

摘要：

【目的】研究不同葡萄品种耐盐性,为耐盐葡萄品种的筛选提供理论支持。【方法】以葡萄品种5BB、101-14、SO4、3309M、贝达、抗砧3号、喀什哈尔、木纳格、和田红、夏黑10份盆栽葡萄品种幼苗为材料,采用盆栽灌盐培养的方式,研究100 mmol/L NaCl胁迫对不同葡萄品种叶片的盐害指数、光合作用、抗氧化酶含量和丙二醛含量等指标的影响,运用主成分分析比较其耐盐性。【结果】100 mmol/L NaCl胁迫下,和田红、木纳格、喀什哈尔、夏黑的SOD、CAT、POD活性、净光合速率(Pn)、气孔导度(Gs)和蒸腾速率(Tr)与对照相比增幅最大,胞间二氧化碳(Ci)和丙二醛含量降幅最小;101-14、抗砧3号、贝达的SOD、CAT、POD活性、净光合速率(Pn)、气孔导度(Gs)和蒸腾速率(Tr)与对照相比增幅较大,胞间二氧化碳(Ci)和丙二醛含量降幅较小;3309M、5BB、S04的SOD、CAT、POD活性,净光合速率(Pn)、气孔导度(Gs)和蒸腾速率(Tr)与对照相比增幅最小,胞间二氧化碳(Ci)和丙二醛含量降幅最小。【结论】和田红、木纳格、喀什哈尔、夏黑为耐盐品种,101-14、抗砧3号、贝达为中等耐盐品种,3309 M、5BB、S04为不耐盐品种。

关键词: 葡萄, NaCl胁迫, 耐盐性, 光合作用, 抗氧化酶, 丙二醛

CLC Number:

S663.1

CHEN Liliang, LU Qianjun, MA Yuanyuan, LIU Ying, ZHAO Baolong, SUN Junli. Effects of NaCl stress on antioxidant enzyme content and malondialdehyde content in grape cultivars leaves[J]. Xinjiang Agricultural Sciences, 2023, 60(4): 880-888.

陈丽靓, 鲁倩君, 马媛媛, 刘迎, 赵宝龙, 孙军利. 不同葡萄品种的耐盐性比较分析[J]. 新疆农业科学, 2023, 60(4): 880-888.

Figures/Tables 6

References 30

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品种 Varieties	盐害指数 Salt damage index (%)	耐盐性排序 Salt tolerance ordination	耐盐性分类 Salt tolerance classification
和田红 Hetianhong	23.0	1	强
木纳格 Munage	25.0	2	强
喀什哈尔 Kashihaer	26.0	3	强
夏黑 Xiahei	33.0	4	强
101-14	48.0	5	中
抗3 Kang 3	50.0	6	中
贝达 Beida	53.0	7	中
3309M	63.0	8	弱
5BB	65.0	9	弱
SO4	70.0	10	弱

品种 Varieties	盐害指数 Salt damage index (%)	耐盐性排序 Salt tolerance ordination	耐盐性分类 Salt tolerance classification
和田红 Hetianhong	23.0	1	强
木纳格 Munage	25.0	2	强
喀什哈尔 Kashihaer	26.0	3	强
夏黑 Xiahei	33.0	4	强
101-14	48.0	5	中
抗3 Kang 3	50.0	6	中
贝达 Beida	53.0	7	中
3309M	63.0	8	弱
5BB	65.0	9	弱
SO4	70.0	10	弱

品种 Cultivars	处理 Treat	净光合速率 Pn (μmol/(m²·s))	气孔导度 Gs (mol/(m²·s))	胞间CO₂浓度 Ci (μmol/mol)	蒸腾速率 Tr (mmol/(m²·s))
和田红 Hetianhong	CK	7.434±0.012^a	0.105±0.004^a	104.18±4.061^a	5.820±0.008^a
和田红 Hetianhong	T	5.067±0.003^b	0.083±0.001^b	113.67±5.398^a	4.570±0.005^b
木纳格 Munage	CK	6.388±0.410^a	0.077±0.012^a	139.28±0.075^a	3.007±0.001^a
木纳格 Munage	T	3.637±0.010^b	0.052±0.003^b	171.46±7.180^a	2.405±0.404^b
喀什哈尔 Kashihaer	CK	5.417±0.148^a	0.080±0.005^a	103.23±0.567^a	2.710±0.003^a
喀什哈尔 Kashihaer	T	3.279±0.005^b	0.050±0.021^b	126.34±1.127^a	1.770±0.014^b
夏黑 Xiahei	CK	6.526±0.003^a	0.080±0.002^ba	118.75±2.447^a	2.088±0.004^a
夏黑 Xiahei	T	3.405±0.042^b	0.056±0.023^b	123.16±3.483^a	1.386±0.003^b
101-14	CK	5.568±0.058^a	0.092±0.008^a	357.64±6.318^b	2.290±0.001^a
101-14	T	2.783±0.292^b	0.048±0.001^b	449.85±4.418^a	1.093±0.002^b
抗3 Kang 3	CK	6.123±0.027^a	0.074±0.004^a	228.48±4.727^b	2.462±0.002^a
抗3 Kang 3	T	2.430±0.001^b	0.037±0.004^b	317.11±5.607^a	1.086±0.015^b
贝达 Beida	CK	6.129±0.278^a	0.071±0.003^a	355.32±4.604^b	3.941±0.006^a
贝达 Beida	T	2.202±0.174^b	0.034±0.005^b	450.29±5.096^a	1.929±0.005^b
3309M	CK	4.790±0.224^a	0.078±0.001^b	342.41±4.561^b	3.660±0.005^a
3309M	T	1.525±0.042^b	0.025±0.008^b	490.11±1.554^a	1.179±0.189^b
5BB	CK	5.425±0.002^a	0.068±0.001^a	312.02±0.572^b	3.266±0.002^a
5BB	T	1.515±0.025^b	0.026±0.001^b	460.65±0.910^a	1.206±0.235^b
SO4	CK	7.431±0.063^a	0.087±0.006^a	304.21±1.129^b	2.976±0.011^a
SO4	T	2.069±0.011^b	0.030±0.002^b	470.12±0.093^a	0.814±0.004^b

品种 Cultivars	处理 Treat	净光合速率 Pn (μmol/(m²·s))	气孔导度 Gs (mol/(m²·s))	胞间CO₂浓度 Ci (μmol/mol)	蒸腾速率 Tr (mmol/(m²·s))
和田红 Hetianhong	CK	7.434±0.012^a	0.105±0.004^a	104.18±4.061^a	5.820±0.008^a
和田红 Hetianhong	T	5.067±0.003^b	0.083±0.001^b	113.67±5.398^a	4.570±0.005^b
木纳格 Munage	CK	6.388±0.410^a	0.077±0.012^a	139.28±0.075^a	3.007±0.001^a
木纳格 Munage	T	3.637±0.010^b	0.052±0.003^b	171.46±7.180^a	2.405±0.404^b
喀什哈尔 Kashihaer	CK	5.417±0.148^a	0.080±0.005^a	103.23±0.567^a	2.710±0.003^a
喀什哈尔 Kashihaer	T	3.279±0.005^b	0.050±0.021^b	126.34±1.127^a	1.770±0.014^b
夏黑 Xiahei	CK	6.526±0.003^a	0.080±0.002^ba	118.75±2.447^a	2.088±0.004^a
夏黑 Xiahei	T	3.405±0.042^b	0.056±0.023^b	123.16±3.483^a	1.386±0.003^b
101-14	CK	5.568±0.058^a	0.092±0.008^a	357.64±6.318^b	2.290±0.001^a
101-14	T	2.783±0.292^b	0.048±0.001^b	449.85±4.418^a	1.093±0.002^b
抗3 Kang 3	CK	6.123±0.027^a	0.074±0.004^a	228.48±4.727^b	2.462±0.002^a
抗3 Kang 3	T	2.430±0.001^b	0.037±0.004^b	317.11±5.607^a	1.086±0.015^b
贝达 Beida	CK	6.129±0.278^a	0.071±0.003^a	355.32±4.604^b	3.941±0.006^a
贝达 Beida	T	2.202±0.174^b	0.034±0.005^b	450.29±5.096^a	1.929±0.005^b
3309M	CK	4.790±0.224^a	0.078±0.001^b	342.41±4.561^b	3.660±0.005^a
3309M	T	1.525±0.042^b	0.025±0.008^b	490.11±1.554^a	1.179±0.189^b
5BB	CK	5.425±0.002^a	0.068±0.001^a	312.02±0.572^b	3.266±0.002^a
5BB	T	1.515±0.025^b	0.026±0.001^b	460.65±0.910^a	1.206±0.235^b
SO4	CK	7.431±0.063^a	0.087±0.006^a	304.21±1.129^b	2.976±0.011^a
SO4	T	2.069±0.011^b	0.030±0.002^b	470.12±0.093^a	0.814±0.004^b

项目 Item	第一主成分 The first principal component	第二主成分 The second principal component
SOD	0.968	-0.192
MDA	-0.95	-0.047
CAT	0.948	0.112
GS	0.93	0.089
CI	-0.92	0.079
POD	0.904	-0.218
Tr	0.772	0.325
Pn	-0.03	0.966
特征值 Eigen values	5.866	1.152
方差贡献率 Proportion of variance (%)	73.324	14.398
累计贡献率 Cumulative variance (%)	73.324	87.722

Effects of NaCl stress on antioxidant enzyme content and malondialdehyde content in grape cultivars leaves

不同葡萄品种的耐盐性比较分析

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References 30

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Metrics

品种 Cultivars	Y₁	Y₂	综合主成分Y Comprehensive principal components	排名 Ranking
和田红 Hetianhong	4.963	2.285	5.643	1
木纳格 Munage	2.554	1.121	2.856	2
喀什哈尔 Kashihaer	2.493	0.749	2.484	3
夏黑 Xiahei	1.765	0.671	1.882	4
101-14	-0.300	-0.375	-0.549	5
抗砧3号 Kang 3	-0.503	-0.264	-0.601	6
贝达 Beida	-1.238	-0.572	-1.409	7
3309 M	-2.395	-1.083	-2.706	8
5BB	-3.250	-1.239	-3.470	9
SO4	-4.088	-1.292	-4.131	10

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