Effect of Melatonin on Fruit Quality via Decay Inhibition and Enhancement of Antioxidative Enzyme Activities and Genes Expression of Two Mango Cultivars during Cold Storage.
Study Goal
The researchers aimed to evaluate the effects of exogenous melatonin treatment on delaying postharvest deterioration and enhancing physiological and metabolic processes in two mango cultivars during cold storage.
Results Summary
Melatonin treatment significantly delayed weight loss, firmness, respiration rate, and decay incidence in both mango cultivars. It also inhibited the decrease in total phenol, flavonoid, and AsA content while enhancing antioxidant enzyme activities and gene expression, though effects were cultivar-dependent.
Population
Two mango cultivars (specific types not named in the abstract)
Effective Dosage
1000 μmol L-1 melatonin
Duration
Duration of cold storage (specific length not mentioned)
Interactions
None mentioned
| Intervention | Direction | Endpoint | Population | Dosage | Impact | Claim # |
|---|---|---|---|---|---|---|
exogenous melatonin (MT, 1000 μmol L-1) treatment | decrease | weight loss | two mango cultivars | - | significantly delayed | #1 |
exogenous melatonin (MT, 1000 μmol L-1) treatment | decrease | firmness | two mango cultivars | - | significantly delayed | #2 |
exogenous melatonin (MT, 1000 μmol L-1) treatment | decrease | respiration rate | two mango cultivars | - | significantly delayed | #3 |
exogenous melatonin (MT, 1000 μmol L-1) treatment | decrease | decay incidence | two mango cultivars | - | significantly delayed | #4 |
exogenous melatonin (MT, 1000 μmol L-1) treatment | no change | TSS | two mango cultivars | - | did not influence | #5 |
exogenous melatonin (MT, 1000 μmol L-1) treatment | no change | TA | two mango cultivars | - | did not influence | #6 |
exogenous melatonin (MT, 1000 μmol L-1) treatment | no change | TSS:TA ratio | two mango cultivars | - | did not influence | #7 |
exogenous melatonin (MT, 1000 μmol L-1) treatment | decrease | total phenol content | two mango cultivars | - | inhibited the decrease in | #8 |
exogenous melatonin (MT, 1000 μmol L-1) treatment | decrease | flavonoid content | two mango cultivars | - | inhibited the decrease in | #9 |
exogenous melatonin (MT, 1000 μmol L-1) treatment | decrease | AsA content | two mango cultivars | - | inhibited the decrease in | #10 |
exogenous melatonin (MT, 1000 μmol L-1) treatment | increase | MDA content | two mango cultivars | - | delaying the increase in | #11 |
exogenous melatonin (MT, 1000 μmol L-1) treatment | decrease | enzyme activity of PPO | two mango cultivars | - | dramatically inhibited | #12 |
exogenous melatonin (MT, 1000 μmol L-1) treatment | increase | antioxidant enzymes (SOD and APX) | two mango cultivars | - | increase in the activities of | #13 |
exogenous melatonin (MT, 1000 μmol L-1) treatment | increase | PAL | two mango cultivars | - | increase in the activities of | #14 |
exogenous melatonin (MT, 1000 μmol L-1) treatment | increase | their genes' relative expression | two mango cultivars | - | increase in | #15 |
The postharvest deterioration of mango fruits is a critical issue limiting mango storage and preservation due to its climacteric nature. This study evaluated the storage behavior of two mango cultivars and their response to exogenous melatonin (MT, 1000 μmol L-1) treatment in attenuating fruit decay and enhancing fruits' physiological and metabolic processes and gene relative expression subjected to cold storage. MT treatment in both mango cultivars significantly delayed weight loss, firmness, respiration rate, and decay incidence. However, MT did not influence the TSS, TA, and TSS:TA ratio regardless of the cultivar. Moreover, MT inhibited the decrease in total phenol and flavonoid content and AsA content while delaying the increase in the MDA content of mango during storage in both cultivars. In addition, MT dramatically inhibited the enzyme activity of PPO. In contrast, an increase in the activities of antioxidant enzymes (SOD and APX) and PAL and their genes' relative expression was noticed in MT-treated fruits versus control in both cultivars. However, MT treatment was cultivar dependent in most parameters under study. These results demonstrated that MT treatment could be an essential postharvest treatment in minimizing decay, maintaining fruit quality, and extending mango fruits' postharvest shelf life by enhancing the physiological and metabolic processes during cold storage.