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International trade in fresh products is dominated by products capable of long-term refrigerated storage, allowing marketing flexibility. For tropical products, postharvest chilling injury (PCI) is a barrier to long-term storage that limits trade by exacerbating the already-challenging requirements to minimise physical or biotic damage to products. In this review, the practical consequences of PCI in terms of international trade are described. Options for choosing to grow more resistant varieties or to predict the chilling injury risk of batches of fresh products can reduce overall losses by allowing better-informed sequencing of product marketing. Recent advances in technologies that reduce PCI risk or predict its severity, some of which can be used before harvest, are reviewed. At a more fundamental level, there is a growing number of excellent reviews on the potential for gene editing to alleviate postharvest chilling injury in tropical fruits and vegetables. Most are focused on research into ways to alleviate the consequences of chilling injury: i.e. oxidative stress arising from membrane dysfunction. A few recent reports show that reducing membrane dysfunction itself is possible, for example by increasing desaturation of membrane lipids, but this approach comes with a new and predictable problem: increased preharvest susceptibility to heat stress. Refined suggestions for strategies that could produce durable improvements in product quality hold the potential for significant increases in global trade with resulting economic benefits, particularly for developing countries.
International trade in fresh products is dominated by products capable of long-term refrigerated storage, allowing marketing flexibility. For tropical products, postharvest chilling injury (PCI) is a barrier to long-term storage that limits trade by exacerbating the already-challenging requirements to minimise physical or biotic damage to products. In this review, the practical consequences of PCI in terms of international trade are described. Options for choosing to grow more resistant varieties or to predict the chilling injury risk of batches of fresh products can reduce overall losses by allowing better-informed sequencing of product marketing. Recent advances in technologies that reduce PCI risk or predict its severity, some of which can be used before harvest, are reviewed. At a more fundamental level, there is a growing number of excellent reviews on the potential for gene editing to alleviate postharvest chilling injury in tropical fruits and vegetables. Most are focused on research into ways to alleviate the consequences of chilling injury: i.e. oxidative stress arising from membrane dysfunction. A few recent reports show that reducing membrane dysfunction itself is possible, for example by increasing desaturation of membrane lipids, but this approach comes with a new and predictable problem: increased preharvest susceptibility to heat stress. Refined suggestions for strategies that could produce durable improvements in product quality hold the potential for significant increases in global trade with resulting economic benefits, particularly for developing countries.
Yellow pitahaya is a tropical fruit that has gained popularity in recent years. Natural elicitors are compounds that can stimulate the resistance and quality of fruits. The objective of this study was to evaluate the effects of natural elicitors, methyl salicylate (MeSa), methyl jasmonate (JaMe), salicylic acid (SA) and oxalic acid (OA) at concentrations of 0.1 mM (MeSa and JaMe) and 5 mM (SA and OA), applied to the yellow pitahaya fruits under greenhouse conditions. After full blossom, four applications were made with a frequency of 15 days. At the time of harvest and after storage, the following variables were evaluated: firmness (whole fruit), total soluble solids (TSS), total acidity (TA), phenolics and carotenoids (in the pulp), while phenolics, carotenoids, macronutrients and micronutrients were determined in the peel. The results showed MeSa advanced the fruit maturation, according to higher TSS, lower TA and firmness than MeJa-treated fruits, for which a delayed ripening process was shown. All treatments induced a higher polyphenolic concentration during storage. Regarding the alternative use of the peel as a by-product, the application of natural elicitors significantly increased the content of polyphenols, carotenoids, macronutrients and micronutrients in the peel, especially MeSa, which can be used as a bioactive compound in the food industry. In conclusion, the results indicate that natural elicitors can be an alternative to improve the quality and shelf life of yellow pitahaya fruits.
Postharvest ripening of sand pear fruit leads to quality deterioration, including changes in texture, flavor, and fruit color. Salicylic acid (SA), an important defense-related hormone, delays fruit ripening and maintains fruit quality, but the underling mechanism remains unclear. Herein, we evaluated the efficacy of SA in delaying the ripening process of Pyrus pyrifolia cv. ’Hosui’ pear fruit, as evidenced by the reduction in fruit weight loss, inhibition of firmness loss, cell wall degradation and soluble sugars, and retention of total phenols. Based on comparative transcriptomic data, a total of 3837 and 1387 differentially expressed genes (DEGs) were identified during room-temperature storage of control fruit and between SA-treated and control fruit, respectively. Further KEGG analysis revealed that the DEGs were mainly implicated in plant hormone signal transduction, starch and sugar metabolism, and cell wall modification. Moreover, exogenous SA treatment also altered the expression of many transcription factor (TF) families, including those in the ethylene-responsive factor (ERF), NAM, ATAF, CUC (NAC), basic helix-loop-helix (bHLH), basic leucine zipper (bZIP), and v-myb avian myeloblastosis viral oncogene homolog (MYB) families. Together, the results offer important insights into the role of SA-responsive genes in controlling fruit ripening in sand pears.
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