Abstract

Citrus fruit ripening is coupled with the synthesis and deposition of epicuticular waxes, which reduces water loss during fruit postharvest storage. Although abscisic acid (ABA) is a major regulator of citrus fruit ripening, whether ABA mediates epicuticular wax formation during this process remains poorly understood. We investigated the implication of ABA in cuticle properties and epicuticular wax metabolism, composition, and morphology by comparing the Navelate orange [Citrus sinensis (L.) Osbeck] and its ABA biosynthesis-impaired mutant Pinalate in four ripening stages. ABA deficiency had minor effects on cuticle thickness and epicuticular wax load, but correlated with cuticle permeability. ABA content aligned with mostly fatty acids accumulation in both cultivars, and also with specific alkane, terpenoid, and aldehyde constituents in the parental fruit. In turn, cuticle permeability correlated with the fatty acid profile during fruit ripening in the Navelate and Pinalate, and with primary alcohols, terpenoids, and aldehydes, but only in the mutant fruit. Low ABA levels increased the susceptibility of waxes to crack and were lost from the epicuticular layer. The RNA-seq analysis highlighted the differential regulation of a list of 87 cuticle-related genes between genotypes and ripening stages. Changes in the gene expression of the selected genes in both cultivars were consistent with the content of the aliphatics and terpenoid fractions during ripening. The results suggest a role for ABA in the regulation of fatty acid content and primary alcohol composition, and point out the importance of alkane and triterpenoid for controlling water permeance through fruit cuticles.

Highlights

  • Citrus fruits are one of the most important crops in terms of production, exportation, and fresh consumption worldwide

  • Cuticle permeability was higher in the mutant from stage mature green (MG) to FC

  • Fruit weight loss showed a low correlation as referred to the abscisic acid (ABA) content in any cultivar, while it clearly correlated (R2 = 0.702) with cuticle permeability (Supplementary Table S4)

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Summary

Introduction

Citrus fruits are one of the most important crops in terms of production, exportation, and fresh consumption worldwide. Its major functions include protecting the plant against water loss and from pathogen invasion, it serves to regulate gas diffusion and dust accumulation, to control temperature fluctuations, to provide mechanical support, and as a signal transduction (Schreiber, 2010; Yeats and Rose, 2013; Aragón et al, 2017). It is composed of a cutin matrix covered and infiltrated with a mixture of cuticular waxes (Kunst and Samuels, 2009; Fich et al, 2016). The role of the cuticle in fruit quality and physiology has been largely underestimated, but recent reports have revealed its involvement in postharvest fruit quality (Lara et al, 2014, 2019; Martin and Rose, 2014; Lara, 2018; Tafolla-Arellano et al, 2018)

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