Ethanol vapor treatment maintains postharvest storage quality and inhibits internal ethylene biosynthesis during storage of oriental sweet melons

In order to evaluate the effect of ethanol vapor treatments (0.5 mL/kg and 3 mL/kg) on postharvest storage at 23 °C, quality of oriental sweet melons, and to clarify the mechanism of the inhibition of senescence, we investigated physiological and quality changes induced by ethanol vapor, decay incidence, internal ethylene concentration (IEC) and ethylene-related enzymes activities as well as gene expression. Both ethanol vapor treatments, irrespective of concentration, significantly (P < 0.5) delayed skin color changes, retarded softening and suppressed fruit decay in ethanol vapor-treated fruit. Between the two treatments, 0.5 mL/kg of ethanol vapor maintained better quality in storage than that of 3 mL/kg. Compared with the control, both ethanol vapor treatments resulted in different profiles and composition of aromatic volatile compounds of fruit during storage, and a significant increase of ethyl esters, including ethyl acetate, ethyl butanoate, ethyl hexanoate, ethyl 2-methylbutanoate, 3-(methylthio) propionate and 2-phenethyl acetate, and five new ethyl esters were also detected. Both treatments increased alcohol acyl-transferase (AAT) activity levels, which peaked earlier than in the control, but there were no significant differences in activities of alcohol dehydrogenase (ADH). Both treatments significantly (P < 0.5) suppressed internal ethylene concentrations (IEC) during storage at 23 °C, which was evident from reducing 1-aminocyclopropane-1-carboxylic acid (ACC) synthase (ACS) and ACC oxidase (ACO) activities, and inhibiting ACC biosynthesis, and the effect of the 0.5 mL/kg treatment was better than that of 3 mL/kg. Real-time quantitative PCR (Q-PCR) analysis showed that the expression patterns of CM-ACO1, CM-ACO2, CM-ACS1 and CM-ACS2 were consistent with ethylene production during storage. These results suggest that postharvest ethanol vapor treatments markedly delayed the senescence of harvested oriental sweet melons, maintained better quality in storage and improved levels of volatile aroma compounds, especially the ethyl esters, through suppressing the expression of particular members of ethylene-forming enzyme gene families as well as ethylene biosynthesis, and the effect is dose dependent.     

Epicuticular wax content and morphology as related to ethylene and storage performance of ‘Navelate’ orange fruit

The effect of ethylene (2 μL L⁻¹) on total and soft epicuticular wax content and wax morphology has been investigated in mature ‘Navelate’ (Citrus sinensis, L. Osbeck) oranges held under non-stressful environmental conditions (22 °C and constant high relative humidity (90–95% RH)). In addition, the objective of the study was to understand whether the ethylene-induced changes in epicuticular wax might participate in the beneficial effect of ethylene reducing non-chilling peel pitting, by modifying peel water, osmotic or turgor potential, or disease incidence caused by Penicillium digitatum (Pers.:Fr.) Sacc. Ethylene increased total and soft epicuticular wax content in ‘Navelate’ fruit and induced structural changes in surface wax that might be related to the formation of new waxes. Changes in epicuticular wax morphology, but not in its content, might be involved in the protective role of ethylene reducing non-chilling peel pitting, although the beneficial effect of the hormone is not related to water stress. Cell water and turgor potentials in freshly harvested fruit and fruit stored in air under non-stressful conditions suggest that water stress is not a limiting factor leading to the development of this physiological disorder. In addition, the results indicated that formation of new waxes in fruit treated with ethylene may partially cover stomata, cracks or areas lacking wax occurring in stored fruit and is likely to improve physical barriers to P. digitatum penetration.