Harnessing the metabolic modulatory and antioxidant power of 1-(3-Phenyl-Propyl) cyclopropane and melatonin in maintaining mango fruit quality and prolongation storage life.
Study Goal
The researchers aimed to compare the effects of PPCP and melatonin (MT) as anti-ethylene agents on postharvest senescence, quality, chilling tolerance, and antioxidant metabolism in "Keitt" mangoes.
Results Summary
Both PPCP (20 μL L-1) and MT (200 μM) treatments effectively reduced chilling injury, preserved fruit quality, and maintained bioactive compounds, energy metabolism, and antioxidant activity compared to untreated fruit. PPCP specifically reduced metabolic activity (respiration rate and ethylene production), while MT improved membrane stability and reduced malondialdehyde content and electrolyte leakage.
Population
"Keitt" mango fruit stored at 5 ± 1 °C.
Effective Dosage
20 μL L-1 PPCP or 200 μM MT.
Duration
28 days.
Interactions
None mentioned.
| Intervention | Direction | Endpoint | Population | Dosage | Impact | Claim # |
|---|---|---|---|---|---|---|
1-(3-phenyl-propyl) cyclopropene (PPCP) | decrease | chilling injury | mango fruit cv. 'Keitt' | - | effective in reducing | #1 |
1-(3-phenyl-propyl) cyclopropene (PPCP) | no change | fruit quality | mango fruit cv. 'Keitt' | - | effective in preserving | #2 |
1-(3-phenyl-propyl) cyclopropene (PPCP) | decrease | metabolic activity | mango fruit cv. 'Keitt' | - | decrease in | #3 |
1-(3-phenyl-propyl) cyclopropene (PPCP) | decrease | respiration rate | mango fruit cv. 'Keitt' | - | decrease in | #4 |
1-(3-phenyl-propyl) cyclopropene (PPCP) | decrease | production of ethylene | mango fruit cv. 'Keitt' | - | decrease in | #5 |
1-(3-phenyl-propyl) cyclopropene (PPCP) | no change | fruit firmness | mango fruit cv. 'Keitt' | - | maintenance of | #6 |
1-(3-phenyl-propyl) cyclopropene (PPCP) | no change | bioactive compounds | mango fruit cv. 'Keitt' | - | maintenance of | #7 |
1-(3-phenyl-propyl) cyclopropene (PPCP) | no change | energy metabolism | mango fruit cv. 'Keitt' | - | maintenance of | #8 |
1-(3-phenyl-propyl) cyclopropene (PPCP) | no change | antioxidant activity | mango fruit cv. 'Keitt' | - | maintenance of | #9 |
melatonin (MT) | decrease | chilling injury | mango fruit cv. 'Keitt' | - | effective in reducing | #10 |
melatonin (MT) | decrease | weight loss | mango fruit cv. 'Keitt' | - | effective in reducing | #11 |
melatonin (MT) | increase | membrane stability | mango fruit cv. 'Keitt' | - | improving | #12 |
melatonin (MT) | decrease | malondialdehyde content | mango fruit cv. 'Keitt' | - | decrease in | #13 |
melatonin (MT) | decrease | electrolyte leakage | mango fruit cv. 'Keitt' | - | decrease in | #14 |
melatonin (MT) | no change | fruit quality | mango fruit cv. 'Keitt' | - | maintenance of | #15 |
melatonin (MT) | no change | fruit firmness | mango fruit cv. 'Keitt' | - | maintenance of | #16 |
melatonin (MT) | no change | peel and pulp colour values | mango fruit cv. 'Keitt' | - | maintenance of | #17 |
melatonin (MT) | no change | mango peel and pulp total carotenoid content | mango fruit cv. 'Keitt' | - | maintenance of | #18 |
melatonin (MT) | no change | phenylalanine ammonia lyase activity | mango fruit cv. 'Keitt' | - | maintenance of | #19 |
melatonin (MT) | no change | tyrosine ammonia lyase activity | mango fruit cv. 'Keitt' | - | maintenance of | #20 |
BACKGROUND: The aim of this study was to compare and investigate the effects of 1-(3-phenyl-propyl) cyclopropene (PPCP) and melatonin (MT) as anti-ethylene agents on postharvest senescence, quality, chilling tolerance, and antioxidant metabolism in the mango fruit cv. "Keitt". The study involved exposing the fruit to 20 μL L- 1 PPCP or 200 μM MT, in addition to a control group of untreated fruit, before storing them at 5 ± 1 °C for 28 d. The findings revealed that the treatments with PPCP and MT were effective in reducing chilling injury and preserving fruit quality when compared to the control group. RESULTS: The use of 20 μL L- 1 PPCP was an effective treatment in terms of mitigating chilling injury and preserving fruit quality for 28 d. This was attributed to the decrease in metabolic activity, specifically the respiration rate and the production of ethylene, which led to the maintenance of fruit firmness and bioactive compounds, energy metabolism, and antioxidant activity, such as ascorbic acid, total flavonoids, trolox equivalent antioxidant capacity, dehydroascorbate reductase, glutathione reductase activity, ATP, and ATPase activity. The study also found that the MT treatment at 200 μM was effective in reducing chilling injury and weight loss and improving membrane stability. Additionally, it led to a decrease in malondialdehyde content and electrolyte leakage, and the maintenance of fruit quality in terms of firmness, peel and pulp colour values for mango peel and pulp total carotenoid content, as well as phenylalanine ammonia lyase and tyrosine ammonia lyase activity. These findings indicate that PPCP and MT have the potential to be efficient treatments in maintaining mango quality and minimizing post-harvest losses. CONCLUSION: The utilisation of treatments with 20 μL L- 1 of PPCP or 200 μM MT was found to effectively preserve the postharvest quality parameters, in terms of bioactive compounds, energy metabolism, and antioxidant activity, of mangoes cv. "Keitt" that were stored at 5 ± 1 °C for 28 d.