Curcumin leads to responses of grapes to aluminum stress by inducing whole genome hypo-methylation

IF 2.4 3区 农林科学 Q1 Agricultural and Biological Sciences
Xiaoqin Li, Yongfu Zhang, Zhen Ren, Kai Wang, Zhao Liu, Shiqin Xu, Zuqin Qiao
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Abstract

Aluminum (Al) is the most abundant element in the earth crust. Due to the abuse of phosphate fertilizer, acid rain has been frequently observed in recent years, resulting in the conversion of non-toxic aluminosilicates in the soil into Al ions, thereby causing stress to plants. As a DNA methylation inhibitor, curcumin can effectively counteract the Al stress on plants, while the epigenetic mechanism remains unclear. This study discusses the epigenetic mechanism of curcumin counteracting Al stress on grape. The results demonstrated that curcumin could significantly relieve the Al stress symptoms of grapes and reduce its whole genome methylation level. Al stress and curcumin treatment did not cause variations in the methylation level in each chromosome. While Al stress led to a slight increase in the average methylation level of each chromosome, and treatment by curcumin led to a significant decrease in the average methylation level of each chromosome. Specifically, the sites of CG and CHG were decreased significantly, and the site of CHH was increased or decreased significantly. Analysis of differentially-methylated regions (DMRs) revealed that treatment by curcumin led to an increase in hypo-DMRs in the whole genome of grape, and analysis of differentially-methylated genes (DMGs) also identified differentially related genes of hypo-DMRs in the whole genome of grapes, suggesting that curcumin triggers responses to Al stress by regulating hypo-methylation mode of the whole genome of grape. Additionally, Kyoto Encyclopedia of Genes and Genomes (KEGG) enrichment analysis demonstrated that DMGs of grapes generate responses to Al stress by participating in galactose metabolism, ascorbate, and aldarate metabolism, and amino sugar and nucleotide sugar metabolism pathways of carbohydrate metabolism in the KEGG subclass.

Abstract Image

姜黄素通过诱导全基因组低甲基化使葡萄对铝胁迫做出反应
铝(Al)是地壳中含量最高的元素。由于滥用磷肥,近年来酸雨频发,导致土壤中无毒的铝硅酸盐转化为铝离子,从而对植物造成胁迫。姜黄素作为一种 DNA 甲基化抑制剂,能有效抵御铝对植物的胁迫,但其表观遗传机制尚不清楚。本研究探讨了姜黄素对抗葡萄铝胁迫的表观遗传学机制。结果表明,姜黄素能显著缓解葡萄的铝胁迫症状,并降低其全基因组甲基化水平。铝胁迫和姜黄素处理并未引起各染色体甲基化水平的变化。铝胁迫导致每条染色体的平均甲基化水平略有上升,而姜黄素处理则导致每条染色体的平均甲基化水平显著下降。具体来说,CG 和 CHG 的位点明显减少,CHH 的位点明显增加或减少。差异甲基化区域(DMRs)分析表明,姜黄素处理导致葡萄全基因组中低甲基化区域增加,差异甲基化基因(DMGs)分析也发现了葡萄全基因组中低甲基化区域的差异相关基因,表明姜黄素通过调节葡萄全基因组的低甲基化模式触发对铝胁迫的响应。此外,京都基因组百科全书(KEGG)富集分析表明,葡萄的DMGs通过参与KEGG亚类中的半乳糖代谢、抗坏血酸和醛酸代谢,以及碳水化合物代谢中的氨基糖和核苷酸糖代谢途径,对铝胁迫产生响应。
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来源期刊
Horticulture Environment and Biotechnology
Horticulture Environment and Biotechnology Agricultural and Biological Sciences-Horticulture
CiteScore
4.30
自引率
4.20%
发文量
0
审稿时长
6 months
期刊介绍: Horticulture, Environment, and Biotechnology (HEB) is the official journal of the Korean Society for Horticultural Science, was launched in 1965 as the "Journal of Korean Society for Horticultural Science". HEB is an international journal, published in English, bimonthly on the last day of even number months, and indexed in Biosys Preview, SCIE, and CABI. The journal is devoted for the publication of original research papers and review articles related to vegetables, fruits, ornamental and herbal plants, and covers all aspects of physiology, molecular biology, biotechnology, protected cultivation, postharvest technology, and research in plants related to environment.
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