‘Fengtang’ plum fruits with uniform size, color, and ripeness as well as no physical damage were harvested in July from a well-managed orchard in Suining, Sichuan Province, China (altitude 450 m; latitude 31°10′ N; longitude 105°3′ E) and transported back to the laboratory within 4 h after harvesting. These fruits were randomly distributed into three groups (180 fruits per group). One group was dipped in distilled water for 2 min as the control group, and the other two groups were dipped in 100 μM and 200 μM melatonin solution for 2 min as melatonin-treatment groups, respectively. After dipping, all fruits were air-dried and then stored at 20-25°C with 85-90% relative humidity (simulated ambient temperature conditions). During the storage, 30 fruits in each group at 0, 3, 6, and 9 d after treatment (DAT) were randomly selected for further analysis. Fruit samples were immediately frozen in liquid nitrogen and stored at –80°C. For each treatment, there were three biological replicates, with each consisting of 10 plum fruits.

The firmness was determined according to the previously described method with certain adjustments (Lin et al., 2018). A texture analyzer (ENS-PRO, Beijing, China) was used to measure firmness. Three spots on the equatorial section of the fruit were chosen at random and compressed by 7 mm at a speed of 60 mm/min. During the test, the greatest force produced was noted and represented in Newtons (N).

For fruit water loss, 18 moderately sized and undamaged fruits were chosen and numbered from the melatonin and control groups, respectively. The weights of the corresponding numbered fruit during storage were recorded accurately, and the data of rotten fruits during storage were excluded. Water loss (%) = [(initial weight - weight after water loss)/initial weight] × 100%.

Total soluble solids (TSS) were determined by a digital hand-held refractometer (Atago Co. Ltd., Tokyo, Japan). Titratable acid (TA) content was determined by sodium hydroxide titration; the TSS/TA was the ratio of total soluble solids to titratable acid. Each experiment was performed in triplicate.

Antioxidant enzyme activity was measured using 0.5 g sample. Each experiment was performed in triplicate. Briefly, precooled phosphate buffer (pH=7.8) was added to the samples, centrifuged and the supernatant was extracted for determination. The activities of SOD and POD were determined according to the previously described method. One unit (U) of SOD activity was defined as the amount of enzyme required to inhibit 50% of the photoreduction reaction of nitro blue tetrazolium (NBT). One U of the POD activity unit was defined as the amount of enzyme that caused an absorbance change of 1 in OD₄₇₀ per minute. SOD and POD activities were expressed as U kg^-1 (Liao et al., 2015). CAT activity was determined by ultraviolet absorption. One U of CAT activity unit was defined as the amount of enzyme required to cause 0.1 of the absorbance in OD₂₄₀ per minute. CAT activities were expressed as U kg^-1 (Zhang et al., 2015).

The Folin-Ciocalteu colorimetric method was used to determine the total phenolic content, and the sodium nitrite-aluminum nitrate method was used to evaluate the total flavonoid content (Sarker et al., 2020). To determine APX activity was measured with a plant ascorbate peroxidase kit (G0203F, Suzhou Grace Biotechnology Co. Ltd., Suzhou, China), the contents of reduced glutathione (GSH) and oxidized glutathione (GSSG) were measured assay kits (G0207W and G0206W, Grace Biotechnology Co., Ltd, Suzhou, China), respectively, according to the manufacturer’s instructions. The ascorbic acid content was measured using a 2,6-dichloroindophenol titration (Sanchez-Mata et al., 2012). Each experiment was performed in triplicate.

MDA and free proline contents were measured using the methods in previous studies. MDA and free proline content were measured using 0.5 g sample (Bates et al., 1973; Bian et al., 2018). The H₂O₂ content was determined using an H₂O₂ contents test kit (No. G0112W) acquired from Suzhou Grace Biotechnology (Suzhou, China). Briefly, the samples were mixed with acetone, followed by centrifuged. The supernatant was separated for H₂O₂ contents assay. Each experiment was performed in triplicate.

The cell wall material was extracted from fruits according to the previously reported method with minor modifications (Chen et al., 2017b). Each experiment was performed in triplicate. Added 30 mL of 80% ethanol (v/v) to 1 g of dried pulp and boiled the mixture for 25 min, repeating 3 times to remove the reducing sugars. Vacuum filter and incubate the filtrate with 30 mL of 90% (v/v) dimethyl sulfoxide for 15 h to remove starch. The filtrate was vacuum-filtered again with acetone and dried at 65°C to obtain cell wall material (CWM).

The cell wall polysaccharides were fractionated using the previously described method with some modifications (Chen et al., 2017a). Each experiment was performed in triplicate. Added 5 mL of sodium acetate buffer (50 mmol/L, pH 6.5) to CWM (50 mg) and oscillated for 6 h, then centrifuged for 10 min, the supernatant designated as water-soluble pectin (WSP). Next, the residual was transferred to 5 mL sodium acetate buffer (50 mmol/L, pH 6.5) which contained 50 mmol/L EDTA. To obtain ionic-soluble pectin (ISP), the mixture was centrifuged after shaking for 6 h. For covalent-soluble pectin (CSP), the residues were oscillated for 6 h with 50 mmol/L Na₂CO₃. The residue was oscillated for 6 hours with 5 mL of 4 mmol/L NaOH (containing 100 mmol/L NaBH₄) to collect hemicellulose. To obtain cellulose, 1.5 mL of 80% sulfuric acid was added to the residues, which were then left for 2 h. After that, 3 mL of distilled water was added, and the mixture was hydrolyzed for 5 h at 100°C. The carbazole colorimetric method was used to determine WSP, ISP, and CSP content, and the anthrone colorimetric method was used to determine the contents of cellulose and hemicellulose (Fan et al., 2019).

Polygalacturonase (PG) and cellulase (Cx) activity were measured using 0.2 g of plum pulp sample according to the PG activity assay kit (No. G0701W) and Cx activity assay kit (No. G0533W) purchased from Suzhou Grace Biotechnology Co. Ltd (Suzhou, China). Briefly, the pulp sample was added with 95% ethanol, centrifuged and the supernatant was discarded. The extraction buffer was then added after washing the residue with 80% ethanol. Finally, the sample solution was then centrifuged to separate the supernatant, which was then used to measure the enzyme activity.

The pectate lyases (PL) and β-galactanases (β-GAL) activities were measured according to the PL activity assay kit (No. G0702W) and β-GAL activity assay kit (No. G0524W). Briefly, 0.5 g pulp sample was added with extraction buffer, then, the sample solution was centrifuged and the supernatant was collected for enzyme activity determination. Each experiment was performed in triplicate.

AFM determination was performed according to the previous method (Wang et al., 2021). WSP, ISP and CSP solutions were diluted to approximately 10 mg/L, maintained at 60°C for 20 min, and then vortexed for 1 min. Then, 10 μL of the sample solution was dropped onto the surface of the newly cleaved mica sheet. The mica sheet was dried overnight at 25°C. AFM (Alpha300RA, WITEC corporation, German) was used to scan the nanostructures of the pectin fractions. More than three images were taken in each treatment.

Data were tested using SPSS statistics software. Significance analysis was analyzed by Duncan’s multiple comparison test and independent samples t-test (P <0.05). The experimental data were presented as mean ± standard error.

During storage at room temperature, the control fruits showed a waterlogging phenomenon at the periphery of the pulp ( Figure 1A ). As shown in Figure 1B , the firmness of three sets of ‘Fengtang’ plum fruits gradually declined throughout storage. The firmness of 200 μM melatonin-treated plum fruits was significantly higher than that of the control fruits after 3 and 6 days of harvest.

The water loss of ‘Fengtang’ plum fruits increased rapidly as the storage duration was extended. After 9 days of harvest, the control, 100 μM, and 200 μM melatonin-treated fruit experienced a maximum water loss of 21.6%, 19.4%, and 19.1%, respectively ( Figure 1C ). Additionally, melatonin treatment significantly decreased water loss in the fruit after 3 and 6 days of harvest. Consequently, the application of exogenous melatonin maintained fruit firmness and reduced water loss in ‘Fengtang’ plum fruits during short-term storage.

The TSS and TA of ‘Fengtang’ plums displayed a tendency of decline followed by an increase, peaking at 9 d. After 3 and 6 d following harvest, the TSS content was higher in the 100 μM melatonin-treated fruits than in the control fruits. After 3 days of harvest, the TSS content in the 200 μM melatonin-treated fruits was lower compared to the control fruit, but was higher after 6 days of harvest ( Figure 1D ). In addition, during short-term storage, 200 μM melatonin-treated fruits had a lower TA content compared to the control fruit ( Figure 1E ). As a result, the TSS/TA of 200 μM melatonin-treated fruits was 22.1% higher than that of the control fruits after 6 days of harvest ( Figure 1F ).

As illustrated in Figure 2A , the H₂O₂ content in the control fruits gradually increased, while melatonin treatment inhibited the increase and maintained a lower content of H₂O₂ than the control. At the end of storage, the H₂O₂ content was 16.8% and 26.8% lower in the 100 μM and 200 μM treatment groups, respectively, than that in the control group. The MDA content in control ‘Fengtang’ plums increased gradually throughout the whole storage period, and it reached its maximum after 9 days of harvest ( Figure 2B ). Compared with the control group, the MDA content in melatonin-treated fruits (especially 200 μM) increased slowly and reached 11.5 U/kg which was lower than in the other groups. The proline content in melatonin-treated fruits displayed a rising trend and was higher than that in the control fruits after 3 and 9 days of harvest ( Figure 2C ).

Fruits treated with 200 μM melatonin exhibited increased SOD activity compared to the control and 100 μM melatonin-treated fruits during storage. SOD activity decreased in three groups during the first 3 days after harvesting, but melatonin treatment prevented further decrease during the following storage period. After 9 days of harvest, the SOD activity in the 200 μM melatonin-treated fruits was 25.3% higher than that in the control fruits ( Figure 3A ). Additionally, the activity of POD in 200 μM melatonin-treated plum fruits continued to rise during storage, whereas in the control group, it decreased in the first 3 days with a subsequent upward trend. Despite that, the POD activity in 200 μM melatonin-treated fruits (4 to 5 U/kg) was still much higher than that in control fruits (less than 3.2 U/kg) throughout the storage time ( Figure 3B ). Similar to the changes in POD activity, CAT activity increased after melatonin treatment (especially 200 μM), but it remained at a stable low level in control fruits ( Figure 3C ). The APX activity of melatonin-treated fruits (especially 200 μM) was significantly higher than that of the control fruits throughout the storage period ( Figure 3D ). These findings suggested that melatonin-treatment could improve the antioxidant enzyme activity of ‘Fengtang’ plums during storage.

The total phenolic content of 200 μM melatonin-treated plum fruits increased along with storage duration and was higher than the control after 3 days of harvest ( Figure 4A ). Additionally, the trend of changes in total phenolic and flavonoid content during storage was similar ( Figure 4B ). The total flavonoid content in 200 μM melatonin-treated plum fruits was considerably higher than that in control fruits after 3 and 9 days after harvest. Moreover, ascorbic acid content dropped throughout storage, and melatonin treatment delayed this decline for up to 6 days after harvest ( Figure 4C ). Melatonin-treatment promoted GSH accumulation, which was 40.0% and 76.5% higher in 200 μM melatonin-treated fruits than in the control after 3 days and 6 days of harvest, respectively ( Figure 4D ). After 9 days of storage, the content of GSSH in 200 μM melatonin-treated fruits was obviously higher than that in the control fruits ( Figure 4E ). Besides, melatonin treatment increased GSH/GSSG levels, with the GSH/GSSG levels in 200 μM melatonin-treated fruits being 1.6 and 2.7 times higher than the control after 3 days of harvest, respectively ( Figure 4F ). Thus, the application of melatonin might result in the accumulation of non-enzymatic antioxidants.

The WSP content in control fruits steadily increased throughout the storage, especially in 0-3 days and 6-9 days after harvest ( Figure 5A ). After 3 and 6 days after harvest, the WSP content in 200 μM melatonin-treated fruits was 19.9% and 16.0% lower than in control fruits, respectively. The ISP content exhibited a strong increase after melatonin treatment, while it changed slightly in the control group ( Figure 5B ). In contrast, the CSP content showed an overall downward trend during storage. After melatonin treatment, the CSP content increased in the first 3 days but then decreased ( Figure 5C ). During the entire storage period, melatonin-treated fruits had a higher content of CSP than control fruits, particularly on days 3 and 9 after harvest. By the end of storage, the CSP content of melatonin-treated fruits with concentrations of 100 μM and 200 μM reached 8.8 g/kg and 6.5g/kg, respectively, which was significantly higher than that of the control group (4.5 g/kg).

The content of cellulose reduced after harvest in both control and melatonin-treated groups, whereas melatonin treatment delayed its decline. Meanwhile, melatonin treatment (200 μM) maintained a higher cellulose content after 3 and 9 days of harvest ( Figure 5D ). Notably, the content of cellulose in melatonin-treated groups was more than 11 g/kg, which is much higher than that in the control group (9.4 g/kg). Similar to the changes in cellulose content, the hemicellulose content in different groups decreased throughout storage ( Figure 5E ). In comparison with melatonin-treated fruits, a more pronounced decrease in hemicellulose content was observed in control fruits. In summary, melatonin treatment reduced the disassembly of cell wall polysaccharides (CSP, cellulose, hemicellulose) and delayed the increase of WSP in the plum fruits.

To investigate the effect of melatonin treatment on cell wall enzymes and pectin structure in plum fruits, 200 μM melatonin-treated fruits were chosen for further analysis. The activities of PG, PL, and β-GAL significantly increased as storage progressed, and they exhibited a slower growth rate in melatonin-treated fruits compared to the control ( Figures 6A-C ). Melatonin-treated fruits showed lower PL activity than that in the control fruits. After 9 days of storage, the PL activity in the melatonin-treated group was 23% lower than that in the control group. PG and β-GAL activities were also detected in melatonin-treated fruit after 6 and 9 days postharvest. After 9 days of harvest, the PG and β-GAL activities in melatonin-treated fruit were about 20% lower than that in control fruit, respectively. Cx activity reduced in the first 3 days after harvest and subsequently increased, whereas melatonin treatment inhibited the increase in Cx activity after 6 days of harvest ( Figure 6D ).

The pectin structure determines the properties of the cell wall. We further analyzed the nanostructures of WSP, ISP and CSP after 9 days of storage. The WSP polymer on mica by AFM was found to have many small ellipses, and chains of ISP fraction were observed. In comparison to the control group, the nanostructure of IPS in the melatonin treatment group had more short chains and branches. However, the ISP aggregates in the control fruits were found to be more shortened and degraded ( Figures 7A–D ). CSP fraction formed a self-assembled network on mica that was different from the structures of WSP and ISP. The network structure of CSP in melatonin-treated fruit was interconnected and consisted of more single chains. However, the CSP fraction in the control fruit exhibited poor networking and high aggregation and had more shortened single chains and random degradation of polymers ( Figures 7E, F ).

Pearson correlation coefficient analysis was further constructed to analyze the correlation between fruit quality, reactive oxygen species and cell wall metabolism during storage of ‘Fengtang’ plum fruit. As shown in Figure 8 , the fruit firmness, as well as water loss, was significantly positively correlated with ascorbic acid, CSP, cellulose, and hemicellulose. Conversely, they were negatively correlated with water loss, MDA, total phenolic, proline, WSP, PG, PL, and β-GAL. Besides, the content of H₂O₂ was found to be significantly positively correlated with MDA, total phenolic, WSP, and the activity of three cell wall-degrading enzymes (PG, PL and β-GAL), but negatively correlated with CSP, cellulose, hemicellulose, ascorbic acid and GSH/GSSH.