Insights Into the Mechanisms of Tonoplast Dicarboxylate Transporter‐Induced Plant Tolerance Against Manganese Toxicity in Peach

毒性 金属毒性 生物 苹果酸 化学 生物化学 植物 柠檬酸 有机化学
作者
Kaijie Zhu,Xueke Wang,Jingxian Sun,Iqra Noor,Zhimin Du,Mirza Hasanuzzaman,Chuang Wang,Guohuai Li,Junwei Liu
出处
期刊:Plant Cell and Environment [Wiley]
卷期号:48 (6): 4703-4718 被引量:7
标识
DOI:10.1111/pce.15468
摘要

Manganese (Mn) toxicity poses a severe hazard to plant growth, with organic acids playing a crucial role in detoxifying toxic metals. However, the regulatory mechanisms governing the response of organic acids to Mn toxicity remain largely elusive, particularly in perennial fruit crops. Herein, we investigated the physio-biochemical and transcriptomic responses of peach seedlings to Mn toxicity. Organic acids, especially malate, significantly increased in Mn-treated peach seedlings. Subsequently, malate application markedly mitigated Mn toxicity in peach. Further, we identified a key vacuolar malate transporter, PpTDT, whose expression was dramatically induced by both Mn and malate treatments. PpTDT was localised to the vacuolar membrane. Heterologous expression of PpTDT in yeast restored growth arrest and enhanced Mn tolerance. Overexpression of PpTDT in tobacco, peach leaves and roots enhanced Mn toxicity tolerance, and increased malate and Mn content. Conversely, silencing of PpTDT in peach seedlings exacerbated Mn toxicity, resulting in decreased malate and Mn content. These findings unveil the role of PpTDT in facilitating intracellular chelation of Mn through malate transport, thereby imparting Mn toxicity tolerance in peach. Our study also highlights the potential of malate as an natural compound for improving Mn toxicity tolerance in peach and potentially other fruit crops.
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