The Physiological Basis of Magnesium Recovering Tobacco Plants from High Temperature and Strong Light Stress

doi:10.11924/j.issn.1000-6850.casb2022-0064

Abstract

Abstract:

In this study, flue-cured tobacco ‘Cuibi No.1’ was used as the material, and four concentrations of magnesium supply (0, 12.0, 48.0 and 120.0 mg/L) and two light intensities [600 and 1200 µmol/(m²·s)] at 33℃ were designed to study the effects of magnesium supply on the physiology of tobacco plants under high light intensity and high temperature stress. The results showed that: (1) the contents of sucrose and soluble sugar in the shoots and roots of tobacco plants were significantly affected by the supply of magnesium and the intensity of light, while the starch content of tobacco plants was also significantly affected by the light intensity; high light intensity could induce the accumulation of soluble sugar in the shoots and roots of tobacco plants, and the soluble sugar in the shoots reached its maximum value under high light intensity when the magnesium supply was 48.0 mg/L; (2) with the increase of magnesium supply, the activities of key enzymes in carbon and nitrogen metabolism, including sucrose synthase (SS), sucrose phosphate synthase (SPS), acid invertase (AI), glutamine synthase (GS) and nitrate reductase (NR), increased first and then decreased, and reached the maximum at 48.0 mg/L of magnesium supply; these enzyme activities in tobacco plants under high light intensity were higher than those under normal light intensity; magnesium supply, light intensity and magnesium supply × light intensity significantly affect NR and AI activities in the shoots of tobacco plants; (3) high temperature and high light intensity enhanced the absorption of K⁺ and Ca²⁺ in tobacco plants, but the absorption was inhibited with the increase of magnesium supply; magnesium supply, light intensity and magnesium supply × light intensity significantly changed the contents of K⁺ and Ca²⁺ in the roots of tobacco plants. Appropriate magnesium supply (48.0 mg/L) could enhance the activities of key enzymes of carbon and nitrogen, promote the metabolism of carbon and nitrogen, increase the accumulation of soluble sugar, and then alleviate the damage of high temperature and high light intensity to tobacco plants.

Key words: tobacco, magnesium, high temperature and strong high stress, carbon and nitrogen metabolism, carbohydrate, K⁺ and Ca²⁺

CLC Number:

Q945.78
S572

FENG Changqing, WEI Xiaoling, HUANG Yunxia, XU Shichang, QIU Fuxiang, WU Ti, ZHENG Yingjie, LI Wenqing, HE Huaqin. The Physiological Basis of Magnesium Recovering Tobacco Plants from High Temperature and Strong Light Stress[J]. Chinese Agricultural Science Bulletin, 2022, 38(20): 53-60.

Figures/Tables 8

References 30

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处理名称	蔗糖含量		淀粉含量		可溶性糖含量
处理名称	地上部	地下部	地上部	地下部	地上部	地下部
L600Mg0	3.33±0.04a	4.15±0.07d	13.38±0.92bc	2.93±0.08f	8.72±0.24c	7.33±0.08d
L1200Mg0	1.99±0.16cd	8.49±0.33a	17.00±0.74a	2.70±0.04g	9.08±0.07c	10.00±0.27a
L600Mg12	2.33±0.06b	4.36±0.09cd	10.70±0.91c	4.11±0.09b	6.60±0.18d	7.44±0.30c
L1200Mg12	1.70±0.04ef	7.98±0.19b	13.87±0.92b	3.14±0.02e	10.18±0.29b	8.95±0.12b
L600Mg48	1.55±0.02fg	1.67±0.17e	6.62±0.60d	3.62±0.06d	6.86±0.29d	3.30±0.08e
L1200Mg48	1.46±0.02g	4.69±0.11c	6.48±0.58d	3.84±0.09c	11.71±0.07a	5.81±0.14d
L600Mg120	2.08±0.04c	4.01±0.07d	7.61±0.04d	4.28±0.03b	6.46±0.09d	6.71±0.07c
L1200Mg120	1.80±0.01de	7.76±0.12b	10.58±0.39c	5.22±0.09a	8.53±0.21c	8.63±0.20b

处理名称	蔗糖含量		淀粉含量		可溶性糖含量
处理名称	地上部	地下部	地上部	地下部	地上部	地下部
L600Mg0	3.33±0.04a	4.15±0.07d	13.38±0.92bc	2.93±0.08f	8.72±0.24c	7.33±0.08d
L1200Mg0	1.99±0.16cd	8.49±0.33a	17.00±0.74a	2.70±0.04g	9.08±0.07c	10.00±0.27a
L600Mg12	2.33±0.06b	4.36±0.09cd	10.70±0.91c	4.11±0.09b	6.60±0.18d	7.44±0.30c
L1200Mg12	1.70±0.04ef	7.98±0.19b	13.87±0.92b	3.14±0.02e	10.18±0.29b	8.95±0.12b
L600Mg48	1.55±0.02fg	1.67±0.17e	6.62±0.60d	3.62±0.06d	6.86±0.29d	3.30±0.08e
L1200Mg48	1.46±0.02g	4.69±0.11c	6.48±0.58d	3.84±0.09c	11.71±0.07a	5.81±0.14d
L600Mg120	2.08±0.04c	4.01±0.07d	7.61±0.04d	4.28±0.03b	6.46±0.09d	6.71±0.07c
L1200Mg120	1.80±0.01de	7.76±0.12b	10.58±0.39c	5.22±0.09a	8.53±0.21c	8.63±0.20b

方差来源	蔗糖含量		淀粉含量		可溶性糖含量
方差来源	地上部	地下部	地上部	地下部	地上部	地下部
镁浓度	^***	^***	^***	NS	^***	^***
光强	^***	^***	^***	^***	^***	^***
镁浓度×光强	^***	^**	NS	^***	^***	NS

方差来源	蔗糖含量		淀粉含量		可溶性糖含量
方差来源	地上部	地下部	地上部	地下部	地上部	地下部
镁浓度	^***	^***	^***	NS	^***	^***
光强	^***	^***	^***	^***	^***	^***
镁浓度×光强	^***	^**	NS	^***	^***	NS

方差来源	蔗糖磷酸合成酶活性	蔗糖合成酶活性	酸性转化酶活性
镁浓度	^*	^*	^***
光强	^*	^***	^***
镁浓度×光强	NS	NS	^***