K+-缺乏对番茄H2O2动态及蔗糖含量的影响

IF 1 Q3 HORTICULTURE

Horticultural Science Pub Date : 2021-05-21 DOI:10.17221/103/2020-HORTSCI

Xiaoming Zhao, Ning Zhang, Xin Liu, Jing Jiang

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引用次数: 1

摘要

钾(K+)缺乏抑制光合产物的运输，造成严重的作物产量损失。然而，人们对其潜在机制知之甚少。本研究以耐K+缺乏的2个番茄品系081018 (K+敏感)和081034 (K+耐缺)为材料，研究K+缺乏条件下番茄H2O2与蔗糖的关系。在低K+ (0.5 mM)条件下，081018处理8 h后H2O2积累量增加。与H2O2代谢相关的酶减少，丙二醛(MDA)产生增多。24 h后，叶片中蔗糖含量显著积累，而根系中蔗糖含量不足，蔗糖转运蛋白(SUT1)表达水平受到抑制。在081034中，在K+缺乏的情况下，抗氧化酶的活性增加，然后H2O2随后恢复到对照处理(4 mM)的水平，并没有产生更多的MDA。24 h后，蔗糖含量与对照处理无显著差异，SUT1的表达未受抑制。这些结果表明，H2O2动力学在两种不同菌株中起着不同的作用。在081018中，H2O2从叶(源)向根(库)的转运受到抑制，而在081034中，H2O2的优势活性氧动力学能力则不受限制。

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The effects of K+-deficiency on H2O2 dynamics and sucrose in tomato

Potassium (K+) deficiency inhibits the transport of photosynthetic products and causes severe crop yield losses. However, the underlying mechanisms are poorly understood. In this study, we used two tomato lines 081018 (K+-deficiency-sensitive) and 081034 (K+-deficiency-tolerant), showing tolerance to K+ deficiency to investigate the relationship between the H2O2 and sucrose in the tomato under K +-deficiency. The H2O2 accumulation was increased by the low K+ condition (0.5 mM) after 8 h in 081018. The enzymes related to the metabolism of H2O2 were decreased, and more malondialdehyde (MDA) was produced. After 24 h, the sucrose content had accumulated significantly in the leaves, however, it was deficient in the roots, and the expression level of the sucrose transporters (SUT1) was inhibited. In 081034, the activity of antioxidant enzymes was increased under K+-deficiency, and then the H2O2 subsequently returned to the control treatment (4 mM) levels and did not produce more MDA. The sucrose content was not significantly different from the control treatment after 24 h. The expression of SUT1 was not suppressed. These results suggested that the H2O2 dynamics played different roles in the two different strains. The transportation of sucrose was suppressed by the H2O2 from the leaf (source) to the root (sink) in 081018, and unrestricted by the advantageous reactive oxygen species dynamics capacity in 081034.

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来源期刊

Horticultural Science Horticulture-园艺

CiteScore

2.20

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： The journal publishes results of basic and applied research from all areas of horticulture, fruit-growing, vegetable-growing, wine-making and viticulture, floriculture, ornamental gardening, garden and landscape architecture, concerning plants that are grown under the conditions of European temperate zone, or field plants that are considered as horticultural cultures. Original scientific papers, short communications and review articles are published in the journal. Papers are published in English (British spelling).