Search Results (157)

Veraison represents a pivotal transition point in grape berry ripening, driven by a cascade of temporally coordinated physiological and molecular events. Studies have shown that the onset of veraison is initially triggered by a decline in cell turgor, regulated by osmotic potential and water status, which subsequently leads to fruit softening. This softening process is accompanied by extensive cell wall remodeling, establishing a structural basis for enhanced sugar influx. A rapid accumulation of sugars follows, acting not only as metabolic substrates but also as signaling molecules that synergize with abscisic acid (ABA) to activate transcriptional programs, including the induction of anthocyanin biosynthesis that drives skin color change. ABA accumulates at the early stages of veraison and functions as a key hormonal regulator initiating the ripening process. In contrast, auxin (IAA) and gibberellin (GA) levels decline prior to veraison, thereby releasing their inhibitory effects on ripening. Environmental factors such as water availability, light, and temperature significantly influence the timing and intensity of veraison by modulating hormonal signaling pathways. The initiation of grape berry ripening exemplifies a multilayered regulatory network that progresses through turgor signaling, hormonal regulation, metabolic reprogramming, and transcriptional activation, thereby providing a mechanistic framework for understanding non-climacteric fruit ripening. offering a mechanistic framework for understanding non-climacteric fruit ripening. This review provides an integrated perspective on the initiation mechanism of veraison, offering theoretical insights and practical implications for improving grape quality and vineyard management. Full article

Protein phosphatase 2Cs (PP2Cs) are members of the serine/threonine phosphatase family that play pivotal roles in regulating plant development and responses to environmental stresses. However, comprehensive genome-wide studies of the PP2C gene family in grape (Vitis vinifera L.) have not yet been conducted. In the present study, 78 VvPP2C genes were identified and classified into 12 clades based on their phylogenetic relationships. Analysis of physicochemical properties and gene/protein architectures revealed that the members within each clade shared conserved structural features. Synteny analysis demonstrated that both tandem and segmental duplications substantially contributed to the expansion of the VvPP2C gene family. Tissue-specific transcriptional profiles and cis-element analyses indicated the potential involvement of these genes in grape development and stress responses. Moreover, expression analysis identified VvPP2C26 and VvPP2C41 as the most abscisic acid (ABA)-responsive genes, with expression patterns highly correlated with grape berry development. Functional validation in transgenic tomato lines demonstrated that the overexpression of either gene markedly delayed fruit ripening. Collectively, this study provides new insights into the evolutionary diversification and regulatory functions of the PP2C gene family in grape and identifies VvPP2C26 and VvPP2C41 as key candidates for elucidating ABA-mediated ripening mechanisms in non-climacteric fruits. Full article

Banana (Musa spp.) is a typical climacteric fruit. Xyloglucan endotransglucosylase/hydrolase (XTH) is a key factor regulating plant cell wall dynamic remodeling and participates in fruit ripening. To clarify the core physiological traits of banana ripening, four ripening stages of banana cultivar (Musa AAA ‘Minai No. 1’) fruits in the fully green stage (S1), green-yellow stage (S2), fully yellow stage (S3), and yellow with brown spots stage (S4) were used in this study’s experimental materials, to examine dynamic changes in key physiological–biochemical properties. The results showed that fruit firmness decreased continuously, starch content first increased then decreased, and soluble protein and total soluble solids (TSS) accumulated gradually during the ripening stages of banana fruits. Transcriptome analysis of the four stages found that there were 14,315 differentially expressed genes (DEGs) in S1 versus S4, the GO enrichment pathway is enriched in “protein dephosphorylation”, and the KEGG enrichment pathway is enriched in the “Protein processing in endoplasmic reticulum” and “Ubiquitin mediated proteolysis” pathways. The fruit ripening process involves the processing of numerous proteins. The heatmap revealed that MaXTH32.5 was significantly up-regulated during banana ripening and the result of RT-qPCR is consistent with the transcriptome data. A total of 989 XTH members across 16 Musa varieties of the XTH gene family were further identified. Among them, MaXTH32.5 localized at the chloroplast, and transient overexpression of MaXTH32.5 significantly reduced banana fruit firmness and may be involved in regulating ripening in banana fruits. This study indicated that the differential expression of XTH gene family members may regulate ripening-related processes in banana and MaXTH32.5 as a key candidate, providing insights into banana ripening mechanisms and a foundation for subsequent Musa XTH research. Full article

Anthracnose, caused by the Colletotrichum sp. gloeosporioides complex, severely affects guava quality, highlighting the need for sustainable alternatives to synthetic postharvest fungicides. This study is the first to evaluate modulated UV-C radiation as an innovative approach to controlling postharvest diseases and extending guava shelf-life. The modulation frequency significantly influenced mycelial growth and conidial germination, following a quadratic model (R² = 0.98), with maximum efficacy at ~30 Hz, reducing germination to 5.3 × 10⁴ CFU per plate. In vivo, the combinations of 0.99 kJ m⁻²/30 Hz and 0.66 kJ m⁻²/45 Hz inhibited anthracnose incidence and severity. Most physicochemical parameters remained unaffected after seven days of storage. However, treated fruits showed a higher hue angle (h) and lower a*, indicating the maintenance of shades closer to green due to slower chlorophyll degradation, and firmness was preserved, suggesting delayed ripening. Modulated UV-C also significantly reduced the respiration rate, lowering the climacteric peak. These findings demonstrate that anthracnose control depends on the modulation frequency, with 0.99 kJ m⁻²/30 Hz being particularly effective. Modulated UV-C radiation represents a promising, sustainable, and effective strategy for improving guava postharvest quality and shelf-life. Full article

Soursop fruit of Annona muricata L. is a delicious tropical fruit with several medicinal properties. Previous research focused mainly on postharvest fruit development. This study aims to study the changes during preharvest development and ripening of soursop fruit. Flowers were tagged, and fruit samples were collected at different developmental stages based on days after take-off (DAT). The weight changes, flesh firmness, ethylene production, respiration rate, pH, total acidity (TA), total soluble solids (TSS), and cuticle thickness were measured. An increase in respiration rate from 7 to 41 mL CO₂ kg⁻¹ h⁻¹, a weight increase from 20 to 600 g, a pH decrease from 6.5 to 3.8, a firmness reduction from 20 to 0.8 N, and a cuticle thickness change from 6 to 4 μm were recorded. During preharvest, two different growth periods were recorded: a continuous increase in respiration rate and TSS, a slow decrease in TA, and a constant pH. Further, an increase in firmness was observed until 75 DAT and a decrease after 90 DAT. Cuticle thickness did not show significant changes. During postharvest, soursop fruit showed a sharp increase in TSS, TA, and a notable decrease in pH and firmness. A climacteric peak was recorded six days after harvest with a short postharvest shelf life. It was concluded that the fruit showed the typical behavior of a climacteric fruit. Also, future investigations should focus on the period between 105 and 120 DAT to identify the optimal harvest periods due to the relatively short postharvest shelf life. Full article

Peach trees (Prunus persica L. Batsch) produce climacteric fruits that are prone to senescence and softening after harvesting, and they are susceptible to external pathogens that cause rot and deterioration. This study investigated the effects of 1-methylcyclopropene (1-MCP) treatment combined with laser microporous film (LMF) packaging on the preservation of firm-fleshed honey peaches (‘Xiahui No. 8’ variety) during refrigerated storage at 5 ± 1 °C. The combined 1-MCP + LMF treatment significantly reduced respiration and rot rates and preserved the levels of reducing sugar and titratable acid after 35 days more effectively compared to the control and LMF groups. The 1-MCP + LMF packaging suppressed cell-wall-degrading enzymes (polygalacturonase, β-glucosidase, and cellulase) and maintained high contents of original pectin, cellulose, and hemicellulose. The treatment also reduced the accumulation of superoxide anions and malondialdehyde, maintained cell-wall structural integrity and fruit hardness, and delayed fruit browning by inhibiting polyphenol oxidase and peroxidase activity. Together, our results demonstrate that the combination of 1-MCP treatment and LMF packaging effectively preserved the hardness and quality of firm-fleshed honey peaches during refrigerated storage, extending their shelf life to 28 days while maintaining good sensory and nutritional qualities. Full article

Mango (Mangifera indica L.) is a popular tropical fruit enjoyed worldwide, with Europe being a significant importer of this fruit. Its climacteric nature and short shelf-life pose challenges for maintaining quality, while emissions from transportation threaten the sustainability of the supply chain. This highlights the importance of low-impact logistics in maintaining fruit quality. This study aimed to evaluate the quality of fresh mangoes in Italy by comparing the different shipping systems (air, sea, and road) for seven cultivars sourced from seven countries. Quality assessment included pomological analysis, PTR-ToF-MS for volatile profiling (n = 11 cultivars × 2 years × 3 replicates), and consumer sensory analysis (n = 65 for untrained panellists in 1 year, n = 8 for trained panellists over 2 years). Results indicated that air and truck transport better preserved fruit quality compared to sea freight, primarily due to shorter transit times, which allowed for harvesting at more advanced ripeness stages. The combination of PTR-ToF-MS and PLS-DA effectively differentiated samples based on the method of transport, showcasing its potential as a quick quality monitoring tool. Mangoes transported by air showed significantly higher levels of volatile organic compounds (VOCs), a 29% greater total soluble solids (TSSs) content, and a 44% lower acidity (TA). Sensorial tests indicated that consumers preferred these mangoes. However, air transport resulted in 30 times higher CO₂ emissions per kg of fruit compared to sea freight (~642,117 CO₂e (kg) vs. ~19,132 CO₂e (kg)), highlighting a critical dilemma between sustainability and quality. These findings provide a framework for developing hybrid logistics strategies that strike a balance between preserving quality and environmental responsibility. Additionally, they support the development of European mango cultivation, which can optimise harvest timing, reduce emissions, and enhance fruit quality. Full article

Food waste is a global challenge, with nearly 40% of food discarded annually, leading to economic losses, food insecurity, and environmental harm. Major factors driving spoilage include microbial contamination, enzymatic activity, oxidation, and excessive ethylene production. Active packaging offers a promising solution by extending shelf life through the selective absorption or release of specific substances. In this study, polyvinyl alcohol (PVA) films incorporating metal-organic frameworks (MOFs) were prepared via solvent casting to enhance their mechanical and barrier properties. Five MOFs (HKUST-1, MIL-88A, BASF-A520, UiO-66, and MOF-801) were embedded in the PVA matrix and analyzed for their physical, mechanical, and optical characteristics. The incorporation of TEMPO-oxidized cellulose nanofibers (CNF) improved MOF dispersion, significantly strengthening film performance. Among the formulations, PVA-CNF-MOF-801 exhibited the best performance, with a 130% increase in tensile strength, a 50% reduction in water vapor permeability, and a 168% improvement in UV protection compared with neat PVA films. Ethylene adsorption tests with climacteric fruits confirmed that CNF-containing films retained ethylene more effectively than those without CNFs, although the differences among the MOFs were minimal. These results highlight the potential of PVA-CNF-MOF composite films as sustainable active packaging materials, providing an effective strategy to reduce food waste and its environmental impact. Full article

Plantain (Musa paradisiaca) is a climacteric fruit with high endogenous ethylene production, which accelerates ripening and limits shelf life, especially during transport and exportation, leading to significant losses for producers and distributors. This study evaluated the effect of gibberellic acid (GA₃) and zeatin (Zea) on delaying the ripening of Hartón plantains grown in Colombia. The goal was to assess whether these plant regulators could delay physicochemical changes under simulated cold chain conditions. A completely randomized design was used with nine treatments, plus a control, each with five replicates. Fruits were stored at 11 ± 2 °C and 75% relative humidity for 25 days. Pulp firmness, soluble solids, titratable acidity, pH, starch, chlorophyll, carotenoids, total polyphenols, and polyphenol oxidase activity were assessed. The combination of GA₃ + Zea was effective in preserving firmness, maintaining starch and chlorophyll content, and limiting increases in soluble solids and polyphenol oxidase activity associated with senescence. This delayed ripening did not affect structural integrity or caused oxidative stress. Combined application of GA₃ and Zea is a low-cost and effective strategy to extend the shelf life of plantains for export, benefiting the tropical agri-food chain. This approach offers a practical alternative for maintaining fruit quality without the need for costly preservation technologies. Full article

Extending the postharvest life of apricots (Prunus armeniaca L.) while maintaining their quality is a significant challenge due to their perishability, climacteric ripening, and susceptibility to mechanical injury. This study evaluated the effects of preharvest calcium (Ca) application and postharvest treatments, including modified-atmosphere packaging (MAP) and 1-methylcyclopropene (1-MCP), on apricot quality during storage, carried out in two production years (2016 and 2017) under contrasting climatic conditions. Apricot fruits, cv. ‘Buda’, were treated with Ca before harvest and subjected to MAP or 1-MCP postharvest treatment. Quality parameters, including firmness, color, total soluble solids (TSS), titratable acidity (TA), carotenoids, phenols, respiration rate, and sensory attributes, were analyzed over 15 days of cold storage followed by 3 days of shelf life (15 + 3). The growing season significantly influenced all measured parameters. Fruits harvested in 2017 had double the initial firmness compared to those from 2016 (50.03 N vs. 24.3 N), with higher sweetness and acidity scores. Ca treatment effectively reduced firmness loss by 30% in 2016, particularly beneficial under that year’s wetter conditions, but showed limited impact in the drier 2017 season. MAP successfully delayed ripening and maintained higher acidity levels across both years compared to controls. While 1-MCP treatment preserved fruit firmness effectively, it reduced sweetness perception by 37–59% and limited aroma development, with effects most pronounced in 2017. Sensory evaluation revealed no negative impacts of the applied treatments on overall taste acceptance, with Ca-treated fruits scoring significantly higher for sweetness than controls. The combination of preharvest Ca and postharvest treatments showed potential for extending apricots’ shelf life, but their efficacy was highly dependent on yearly climatic variability. These findings demonstrate that treatment effectiveness varies substantially between years, with Ca applications providing greater benefits in wet years, while 1-MCP and MAP showed more a consistent performance across varying climatic conditions. Therefore, customized and specifically tailored pre- and postharvest protocols are greatly needed to maintain the fruit quality and achieve targeted storage outcomes. Full article

Plums are climacteric fruits with a short postharvest shelf-life, which makes them highly susceptible to spoilage by moulds and pathogens. Biological control using antagonistic yeasts offers a promising approach to extend shelf-life by inhibiting fungal growth. This study evaluated the effects of two yeast strains, Hanseniaspora uvarum L793 and Metschnikowia pulcherrima L672, on the quality of ‘Larry Ann’ Japanese plums during cold storage. Plums were divided into three batches: two treated by immersion in yeast suspensions (10⁸ cells mL⁻¹) and one untreated control. Quality parameters assessed over 12 weeks at 1 °C included weight loss, decay index, microbial counts, yeast colonisation, skin and flesh colour, texture, pH, titratable acidity, total soluble solids, and ripening index, with evaluations every week. M. pulcherrima L672 showed strong colonisation and persistence on the plum surface, significantly reducing skin damage and mould incidence. In contrast, H. uvarum L793 initially colonised well but declined over time, being replaced by native yeasts such as Aureobasidium spp. Both treatments maintained the physicochemical and organoleptic quality of the plums throughout storage. However, M. pulcherrima L672 was more effective in suppressing fungal growth and preserving fruit integrity. These findings suggest that M. pulcherrima L672 is a promising biocontrol agent for prolonging the shelf-life of Japanese plums during cold storage, maintaining their commercial quality for up to three months. Full article

Flavor formation in citrus fruit is governed by complex and dynamic changes in primary and secondary metabolism during development and ripening. Here, we integrated metabolomic, hormonal, and transcriptomic analyses to elucidate the regulatory landscape underlying soluble sugar and organic acid metabolism in ‘Kiyomi’ citrus fruit. A total of 1679 metabolites were identified, revealing stage-specific reprogramming of metabolic pathways, including a sharp decline in citric acid after 90 days after flowering (DAF) and peak accumulation of sucrose at 180 DAF. Hormonal profiling showed that abscisic acid (ABA) progressively accumulated from 120 to 210 DAF, while 1-aminocyclopropane-1-carboxylic acid (ACC) peaked at 120 DAF and declined thereafter, suggesting distinct and temporally coordinated roles in ripening regulation. Transcriptomic profiling uncovered widespread temporal shifts in gene expression, with the most pronounced changes occurring between 180 and 210 DAF. Co-expression network analysis identified gene modules associated with sugar and acid accumulation, and highlighted transcription factors from the ERF, MYB, NAC, and HSF families as candidate regulators of ripening-related metabolic transitions. These findings provide a comprehensive framework for understanding the coordinated molecular and metabolic programs underlying flavor development in non-climacteric citrus fruit and offer candidate genes for the genetic improvement of fruit quality. Full article

Anthocyanins are important phenolic compounds in grape skins, affecting the color, oxidation resistance, and aging ability of red wine. In recent years, global warming has had a negative effect on anthocyanin biosynthesis in grape berries. Ethylene serves as a crucial phytohormone regulating the development and ripening processes of fruit; however, the specific molecular mechanism and the regulatory network between ethylene signaling and the anthocyanin biosynthesis pathway remain incompletely understood. In this study, 400 mg/L ethephon (ETH) solution was sprayed onto the surface of grape berries at the lag phase (EL-34), and the changes in anthocyanin-related genes and metabolites were explored through transcriptomic and metabolomic analysis. The results showed that ETH treatment increased Brix and pH in mature berries. In total, 35 individual anthocyanins were detected, in which 21 individual anthocyanins were enhanced by ETH treatment. However, the anthocyanin profile was not affected by exogenous ethylene. Transcriptomics analysis showed that there were a total of 825 and 1399 differentially expressed genes (DEGs) 12 h and 24 h after treatment. Moreover, key structural genes in the anthocyanin synthesis pathway were strongly induced, including VvPAL, VvCHS, VvF3H, VvF3′5′H, VvDFR and VvUFGT. At the maturity stage (EL-38), the expression levels of these genes were still higher in EHT-treated berries than in the control. ETH treatment also influenced the expression of genes related to hormone biosynthesis and signal transduction. The ethylene biosynthesis gene (VvACO), ethylene receptor genes (VvETR2, VvERS1 and VvEIN4), ABA biosynthesis gene (VvNCED2), and ABA receptor gene (VvPYL4) were up-regulated by ETH treatment, while the auxin biosynthesis gene (VvTAA3) and seven genes of the auxin-responsive protein were inhibited by exogenous ethylene. Meanwhile, ETH treatment promoted the expression of the sugar transporter gene (VvEDL16) and two sucrose synthase genes (VvSUS2 and VvSUS6). In EHT-treated berries, 19 MYB and 23 ERF genes were expressed differently compared with the control (p < 0.05). This study provides the theoretical foundation and technical support for the regulation of anthocyanin synthesis in non-climacteric fruit. Full article

Banana (Musa paradisiaca) is a climacteric fruit with high postharvest perishability, limiting its export potential. This study evaluated the effectiveness of a natural protein–polysaccharide edible coating—comprising whey, agar, cassava starch, and glycerol—on maintaining the physicochemical quality of green bananas during 28 days of refrigerated storage (13 °C, 95% RH). Seven formulations were tested, including an uncoated control. Physicochemical parameters such as weight loss, firmness, fruit dimensions, peel color, titratable acidity, pH, and soluble solids (°Brix) were systematically monitored. Significant differences were observed among treatments (ANOVA, p < 0.001). The most effective coating (T5), composed of 16.7% whey, 16.7% agar, 33.3% cassava starch, and 33.3% glycerol (based on 30 g/L solids), reduced weight loss by 58.8%, improved firmness retention by 48.4%, and limited sugar accumulation by 17.0% compared to the control. It also stabilized pH and acidity, preserved peel thickness and color parameters (L*, a*, b*), and delayed ripening. These findings confirm the coating’s capacity to form a cohesive semipermeable barrier that modulates moisture loss and respiration, making it a functional and sustainable alternative for extending banana shelf life in tropical supply chains. Full article

During fruit ripening in Capsicum species, substantial amounts of carotenoids accumulate in the pericarp. While the carotenoid biosynthesis pathway in Capsicum species has been extensively investigated from various angles, the transcriptional regulation of genes encoding carotenoid biosynthetic enzymes remains less understood in this non-climacteric horticultural crop compared to tomato, a climacteric fruit. In the present study, we investigated the function of the NAM, ATAF1/2 or CUC2 81 (CaNAC81) transcription factor gene. This gene was selected through RNA-Seq co-expression analysis based on the correlation between expressed transcription factor gene profiles and those of carotenoid structural genes. To determine its role in regulating the expression of biosynthetic-related carotenogenic genes, we performed Virus-Induced Gene Silencing (VIGS) assays in the Serrano-type C. annuum ‘Tampiqueño 74’. Fruits from plants infected with a pTRV2:CaNAC81 construct (silenced fruits) exhibited altered carotenoid pigmentation accumulation, manifested as yellow-orange spots, in contrast to fruits from non-agroinfected controls (NTC) and fruits from plants infected with the empty TRV2 construct (red fruits). Quantitative real-time PCR (qPCR) assays confirmed decreased transcript levels of CaNAC81 in fruits displaying altered pigmentation, along with reduced transcription of the PSY gene, which encodes the carotenoid biosynthetic enzyme phytoene synthase (PSY). High-performance liquid chromatography (HPLC) analysis revealed a distinct carotenoid pigment accumulation pattern in fruits from plants showing silencing symptoms, characterized by low concentrations of capsanthin and zeaxanthin and trace amounts of capsorubin, compared to control plants (NTC). These findings suggest the involvement of CaNAC81 in the regulatory network of the carotenoid biosynthetic pathway in chili pepper fruits. Full article