DOI: 10.3390/antiox15070808 ISSN: 2076-3921

Salicylic Acid Mitigates Drought-Stress-Induced Oxidative Damage in Ilex rotunda Through Tissue-Specific Reprogramming of Antioxidant Phenolics and ROS Scavenging

Huwei Yuan, Qinyuan Shen, Ye Zheng, Mingzheng Duan, Junhan Guo, Yihui Li, Jiashuang Qiao, Liangye Huang, Maryam Tahira, Yanyan Yin, Jiaxin Hu, Jianfang Zuo, Daoliang Yan, Bingsong Zheng, Muhammad Junaid Rao

Drought stress imposes oxidative damage on plants, yet the tissue-specific roles of salicylic acid (SA) in modulating phenolic metabolism remain poorly understood in woody species. Using Ilex rotunda seedlings, we investigated whether exogenous SA (100 µM) mitigates drought-induced oxidative damage and reshapes phenolic profiles in different tissues. Drought alone increased leaf total phenolics by 32% but depleted root phenolics by 29%, whereas combined drought + SA (DSA) treatment partially restored root phenolic levels, coinciding with elevated malondialdehyde (MDA) (2.2-fold in leaves, 2.6-fold in roots) and H2O2. Leaf antioxidant capacity increased under drought (DPPH by 73%, •OH by 33%), whereas root DPPH declined by 27% despite a 26% rise in •OH scavenging. SA alone induced mild oxidative responses and selectively upregulated caffeoylquinic and galloyl derivatives, notably 1-Caffeoylquinic acid (log2FC = 6.38) in leaves. DSA treatment mitigated oxidative damage—reducing leaf MDA by 44% and root H2O2 by 38%. Metabolomics revealed tissue-specific reprogramming leaves accumulated dicaffeoylshikimic acid (log2FC = 10.66) and trilobatin D (log2FC = 11.18) under DSA, whereas roots showed contrasting patterns with up-accumulation of vanillate (log2FC = 5.77) and suppression of 3,5-dicaffeoylquinic acid (log2FC = −7.21) under drought, with stronger metabolic reprogramming in leaves than roots. Our findings indicate that SA-mediated drought tolerance is associated with tissue-specific phenolic reprogramming, identifying candidate indicators that advance the mechanistic understanding of woody plant resilience to drought. These results provide a framework for translating metabolomic signatures into practical strategies for stress mitigation in medicinal perennials facing climate change.

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