Zhou Jiaqi, Zhou Sitian, Chen Bixuan, Sangsoy Kamonwan, Luengwilai Kietsuda, Albornoz Karin, Beckles Diane M
Department of Plant Sciences, University of California, Davis, One Shields Avenue, CA, USA.
Department of Biostatistics, School of Public Health, Columbia University, 722 West 168th Street, New York, NY 10032, USA.
Hortic Res. 2024 Mar 25;11(6):uhae095. doi: 10.1093/hr/uhae095. eCollection 2024 Jun.
Tomato fruit ripening is triggered by the demethylation of key genes, which alters their transcriptional levels thereby initiating and propagating a cascade of physiological events. What is unknown is how these processes are altered when fruit are ripened using postharvest practices to extend shelf-life, as these practices often reduce fruit quality. To address this, postharvest handling-induced changes in the fruit DNA methylome and transcriptome, and how they correlate with ripening speed, and ripening indicators such as ethylene, abscisic acid, and carotenoids, were assessed. This study comprehensively connected changes in physiological events with dynamic molecular changes. Ripening fruit that reached 'Turning' (T) after dark storage at 20°C, 12.5°C, or 5°C chilling (followed by 20°C rewarming) were compared to fresh-harvest fruit 'FHT'. Fruit stored at 12.5°C had the biggest epigenetic marks and alterations in gene expression, exceeding changes induced by postharvest chilling. Fruit physiological and chronological age were uncoupled at 12.5°C, as the time-to-ripening was the longest. Fruit ripening to Turning at 12.5°C was not climacteric; there was no respiratory or ethylene burst, rather, fruit were high in abscisic acid. Clear differentiation between postharvest-ripened and 'FHT' was evident in the methylome and transcriptome. Higher expression of photosynthetic genes and chlorophyll levels in 'FHT' fruit pointed to light as influencing the molecular changes in fruit ripening. Finally, correlative analyses of the -omics data putatively identified genes regulated by DNA methylation. Collectively, these data improve our interpretation of how tomato fruit ripening patterns are altered by postharvest practices, and long-term are expected to help improve fruit quality.
番茄果实成熟由关键基因的去甲基化触发,这会改变它们的转录水平,从而引发并推动一系列生理事件。尚不清楚的是,当使用采后处理方法延长货架期使果实成熟时,这些过程会如何改变,因为这些处理方法往往会降低果实品质。为了解决这个问题,研究评估了采后处理引起的果实DNA甲基化组和转录组变化,以及它们与成熟速度以及乙烯、脱落酸和类胡萝卜素等成熟指标之间的相关性。这项研究全面地将生理事件的变化与动态分子变化联系起来。将在20°C、12.5°C或5°C冷藏(随后在20°C复温)黑暗储存后达到“转色期”(T)的成熟果实与新鲜采收的果实“FHT”进行比较。在12.5°C储存的果实具有最大的表观遗传标记和基因表达变化,超过了采后冷藏引起的变化。在12.5°C时,果实的生理年龄和时间年龄出现解耦,因为达到成熟的时间最长。在12.5°C成熟至转色期的果实不是跃变型的;没有呼吸或乙烯爆发,相反,果实中脱落酸含量很高。采后成熟果实和“FHT”果实在甲基化组和转录组中存在明显差异。“FHT”果实中光合基因的较高表达和叶绿素水平表明光照会影响果实成熟过程中的分子变化。最后,对组学数据的相关分析推定鉴定出了受DNA甲基化调控的基因。总体而言,这些数据改进了我们对采后处理如何改变番茄果实成熟模式的理解,从长远来看有望有助于提高果实品质。
