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‘迪瓦多纳’桃在干旱和热胁迫适应及恢复机制下对Rootpac 20和Rootpac 40的生理生化响应

Physiological and biochemical responses of 'Divadona' peach on Rootpac 20 and Rootpac 40 under drought and heat stress adaptation and its recovery mechanisms.

作者信息

Dogan Meral, Bolat Ibrahim, Turan Metin, Kaya Ozkan

机构信息

Department of Horticulture, Harran University, Graduate School of Natural and Applied Sciences, Sanliurfa, Turkey.

Department of Horticulture, Harran University, Faculty of Agriculture, Sanliurfa, Turkey.

出版信息

Physiol Plant. 2025 May-Jun;177(3):e70250. doi: 10.1111/ppl.70250.

DOI:10.1111/ppl.70250
PMID:40329914
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12056577/
Abstract

Climate change-induced drought and heat stress pose significant challenges to global peach production, threatening agricultural sustainability and food security. This study, therefore, investigated the morphological, physiological and biochemical responses of the 'Divadona'peach cultivar grafted onto two different rootstocks (Rootpac 20 and Rootpac 40) under drought stress, heat shock, and their combination. We aimed to identify superior rootstock performances and understand stress tolerance mechanisms for improved cultivation strategies. Our findings revealed that combined stress induced the most severe impacts, with Rootpac 40 demonstrating superior stress tolerance. Under combined stresses, relative shoot diameter decreased less in Rootpac 40/'Divadona' (19.75%) compared to Rootpac 20/'Divadona', while relative shoot length showed similar patterns. Antioxidant enzyme activities increased significantly, with POD showing the highest elevation in Rootpac 40/'Divadona' compared to Rootpac 20/'Divadona. Stress markers exhibited substantial accumulation, with MDA content rising more in Rootpac 20/'Divadona' than in Rootpac 40/'Divadona'. Nutrient analysis showed that Rootpac 40/'Divadona' maintained higher levels of essential nutrients under stress, with nitrogen content declining less compared to Rootpac 20/'Divadona'. The study demonstrated that Rootpac 40/'Divadona' possesses superior stress tolerance mechanisms through better maintenance of growth parameters, enhanced antioxidant defense systems, and improved nutrient retention capacity. These findings provide valuable insights for fruit growing, enabling informed rootstock selection for peach cultivation in drought-prone regions, ultimately contributing to more resilient and sustainable fruit production systems under changing climatic conditions.

摘要

气候变化引发的干旱和热胁迫给全球桃子生产带来了重大挑战,威胁着农业可持续性和粮食安全。因此,本研究调查了嫁接到两种不同砧木(Rootpac 20和Rootpac 40)上的‘Divadona’桃品种在干旱胁迫、热激及其组合条件下的形态、生理和生化反应。我们旨在确定优良的砧木性能,并了解胁迫耐受机制,以改进栽培策略。我们的研究结果表明,复合胁迫造成的影响最为严重,Rootpac 40表现出更强的胁迫耐受性。在复合胁迫下,Rootpac 40/‘Divadona’的相对茎直径下降幅度(19.75%)小于Rootpac 20/‘Divadona’,而相对茎长呈现出类似的模式。抗氧化酶活性显著增加,与Rootpac 20/‘Divadona’相比,Rootpac 40/‘Divadona’中的过氧化物酶(POD)活性升高幅度最大。胁迫标志物大量积累,Rootpac 20/‘Divadona’中的丙二醛(MDA)含量上升幅度大于Rootpac 40/‘Divadona’。养分分析表明,Rootpac 40/‘Divadona’在胁迫下维持了较高水平的必需养分,与Rootpac 20/‘Divadona’相比,氮含量下降幅度较小。该研究表明,Rootpac 40/‘Divadona’通过更好地维持生长参数、增强抗氧化防御系统和提高养分保留能力,拥有更强的胁迫耐受机制。这些发现为果树种植提供了有价值的见解,有助于在易干旱地区明智地选择桃子栽培的砧木,最终在气候变化条件下建立更具韧性和可持续性的水果生产系统。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/f0a5/12056577/c1f6dec89b3d/PPL-177-e70250-g008.jpg
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