1-Methylcyclopropene treatment followed with ethylene treatment alleviates postharvest chilling injury of ‘Xuxiang’ kiwifruit during low-temperature storage

Exogenous dopamine application ameliorates chilling injury and preserves quality of kiwifruit during cold storage

This study investigated the mechanisms employed by exogenous dopamine application in alleviating chilling injury in kiwifruits during storage at 1 °C for 120 days. Our results indicated that dopamine treatment at 150 µM alleviated chilling injury in kiwifruits during storage at 1 °C for 120 days. By 150 µM dopamine application, higher SUMO E3 ligase (SIZ1) and target of rapamycin (TOR) genes expression accompanied by lower poly(ADP-Ribose) polymerase 1 (PARP1) and sucrose non-fermenting 1-related kinase 1 (SnRK1) genes expression was associated with higher salicylic acid, ATP, NADPH and proline accumulation in kiwifruits during storage at 1 °C for 120 days. In addition, higher 2,2-diphenyl-1-picrylhydrazyl (DPPH) scavenging capacity arising from higher phenols and flavonoids accumulation in kiwifruits treated with 150 µM dopamine could be ascribed to higher phenylalanine ammonia-lyase (PAL) enzyme activity. Additionally, lower endogenous hydrogen peroxide (H2O2) accumulation along with higher ascorbic acid accumulation in kiwifruits treated with 150 µM dopamine could be attributed to lower superoxide dismutase (SOD) along with higher catalase (CAT) enzymes activity. Moreover, lower phospholipase D (PLD) and lipoxygenase (LOX) genes expression in kiwifruits treated with 150 µM dopamine was accompanied with membrane integrity preservation as evidenced by lower electrolyte leakage and malondialdehyde (MDA) accumulation. Therefore, exogenous dopamine could be employed as a potential technique for alleviating chilling injury in kiwifruits during cold storage.

An integrated quality, physiological and transcriptomic analysis reveals mechanisms of kiwifruit response to postharvest transport vibrational stress

The 'Xuxiang' kiwifruit, a leading cultivar in China known for its high quality and yield, experiences quality degradation due to vibration stress during postharvest transportation. This study simulated the postharvest transportation vibrations of 'Xuxiang' kiwifruits to investigate the effects on the fruit quality and physiology. Different vibration intensities (0.26, 0.79, and 1.5 m s-2) and durations (0, 24, 48, 72, and 96 h) were applied to analyze the quality, physiological and transcriptomic changes of fruits after vibration stress, as well as the association between quality deterioration, gene networks, and key genes. Results indicated that vibration stress significantly accelerated the deterioration of fruit quality and induced physiological changes. As vibration intensity and duration increased, there was a rapid decrease in fruit firmness and an increase in weight loss, soluble solid content, relative conductivity, ethylene production, respiratory rate, and malondialdehyde levels. The most severe deterioration in fruit quality occurred at a vibration intensity of 1.5 m s-2. Transcriptome sequencing analysis was conducted on samples from different durations of exposure to the 1.5 m s-2 vibration intensity. Kyoto Encyclopedia of Genes and Genomes (KEGG) and Gene Ontology (GO) enrichment analyses identified key genes associated with ethylene metabolism and softening. Weighted Gene Co-Expression Network Analysis (WGCNA) and correlation analysis further determined that 24 of these genes were regulated by vibrational stress, impacting ethylene metabolism and cell wall degradation. Vibration stress induced changes in genes related to ethylene metabolism and cell wall degradation, promoting lipid peroxidation and respiratory changes, which compromise cell membrane integrity and lead to quality deterioration. Compared with untreated fruits, vibration stress caused the quality deterioration, physiological changes and transcriptional regulation of kiwifruits, indicating that kiwifruits respond to vibration stress through multiple aspects. It proposes a fresh outlook on the understanding of the mechanism of transport vibration stress and further illustrates the importance of monitoring vibration intensity and duration as well as reducing vibration.

Effects of Efficient Ethylene Remover on the Lignification of Fresh Faba Bean (Vicia faba L.) during Storage

Postharvest ethylene accumulation and lignification are significant issues affecting the storage quality of fresh faba beans, resulting in rapid quality decline. However, there is still a lack of effective preservation methods to preserve the quality of faba beans during storage. This study aimed to investigate the regulation of lignification in faba beans during storage using a high-efficiency ethylene remover (HEER), examining physiological responses, key enzyme activities, and transcriptomic changes. Results showed that the HEER treatment inhibited the lignification, reducing it by 45% and lowering the respiratory rate of fresh pods by 32.8% during storage. Additionally, the HEER treatment suppressed respiration rates and the activities of lignin synthesis-related enzymes, including phenylalanine ammonia-lyase (from 353.73 to 246.60 U/g), cinnamic acid-4-hydroxylase (from 635.86 to 125.00 U/g), 4-coumarate: coenzyme A ligase (from 1008.57 to 516.52 U/g), and cinnamyl-alcohol dehydrogenase (from 129.42 to 37.12 U/g), thus slowing lignin accumulation. During storage, the hardness of fresh faba bean increased by 9.79% from the initial period, being 1.44 times higher than that of HEER. On days 8 and 16 of storage, the respiratory rate of the treated beans decreased by 24.38% and 4.12%, respectively. Physiological and enzyme activity analyses indicated that HEER treatment-induced increase in hardness was associated with the phenylpropanoid metabolic pathway. Moreover, the HEER significantly down-regulated the expression of several key genes, namely FaPAL, FaC4H, and FaCAD. This study helps to deepen the understanding of the inhibition of lignification by HEER and provide new insights for the development of preservation technology of faba bean.

Recent advances in postharvest technologies for reducing chilling injury symptoms of fruits and vegetables: A review

Low temperature storage is widely used in the storage and transportation of postharvest fruits and vegetables. However, the negative effects of chilling injury (CI) on certain fruits and vegetables cannot be ignored. Therefore, efficient CI prevention technologies were used for reducing CI. This paper expounds the mechanisms of CI, common symptoms of CI and its impacts on the quality of fruits and vegetables, and summarizes the application of CI prevention technology. CI control methods are mainly classified into physical treatments (hot shock, near-freezing storage, high relative humidity storage, light-proof storage, and electromagnetic field), chemical treatments (melatonin, 1-methylcyclopropene, astragalus polysaccharides, γ-aminobutyric acid, 24-epibrassinolide, methyl jasmonate, trisodium phosphate, glycine betaine, and salicylic acid, etc.), coating treatments (sodium alginate, chitosan, carboxymethyl cellulose and aloe vera gel, etc.) and their combined treatments. These treatments have enhanced antioxidant activity, enzyme activity, membrane system integrity, and energy levels, thereby reducing the CI of fruits and vegetables.

The Simultaneous Use of 1-Methylcyclopropene and Methyl Jasmonate Vapor as an Innovative Strategy for Reducing Chilling Injury and Maintaining Pomegranate Fruit Quality at Suboptimal Temperatures

Spain is one of the main contributors to global pomegranate production. Pomegranate presents a challenge for preservation at suboptimal temperatures. Preserving this fruit for an extended period is challenging due to its susceptibility to chilling injury (CI). For this reason, we have examined different postharvest treatments to extend the pomegranate shelf life and their potential impact on reducing CI. For this reason, two postharvest treatments have been applied: 1-Methylcyclopropene (1000 nL L-1 1-MCP) and methyl jasmonate vapors (0.01 mM MeJA), a natural elicitor found in many plant organs that induces a wide range of physiological processes, including the activation of defense mechanisms against stress. Following the application of these treatments and subsequent fruit storage at 2 °C for 90 days, maintenance of firmness and membrane integrity was observed. Additionally, a positive synergic effect was observed in these quality traits when combining both substances (1-MCP + MeJA), especially with regard to delaying weight loss, the external color evolution, and total polyphenol accumulation. On the other hand, MeJA treatment alone or in combination with 1-MCP also increased the anthocyanin content in arils, thereby enhancing the fruit quality. In general, the best results were observed when these two different technologies were applied as a combined treatment, especially in terms of maintaining quality traits such as fruit firmness and total acidity and reducing weight loss and CI. This is the first time that these two substances have been tested together in any fruit species, and their simultaneous application in the same container represents an innovative approach that could be an interesting tool for commercial purposes.