Impact of salicylic acid,abscisic acid,and methyl jasmonate on postharvest quality and bioactive compounds of cultivated strawberry fruit

Abstract

BACKGROUND:

Strawberry is one of the most highly consumed fruits worldwide. However, it is highly a perishable fruit postharvest.

OBJECTIVE:

To assess the effect of dipping strawberry fruits after harvest in plant growth regulators to maintain postharvest quality.

METHODS:

Treatments tested were: 2 and 4 mM salicylic acid (SA), 0.25 and 0.50 mM abscisic acid (ABA) and methyl jasmonate at 0.25 and 0.50 mM (MeJA). Bioactive compounds and fungal growth were assessed over 12 days of storage at 4°C.

RESULTS:

Both concentrations of SA and MeJA significantly suppressed weight loss, decay and respiration rate and 0.50 mM ABA also reduced decay. Both concentrations of SA retarded color development, and total soluble solids content was enhanced by 0.50 mM ABA and MeJA treatments. The most effective treatments for preserving firmness were 0.25 mM MeJA and 4 mM SA. Reduction in loss of ascorbic acid and bioactive compounds during storage was achieved using the highest concentrations of SA, ABA, and MeJA. Fungal growth was suppressed by all treatments but the best treatment was MeJA at both concentrations.

CONCLUSIONS:

All three plant growth regulators reduce postharvest changes in strawberry but effects differ amongst the treatments.

Keywords

quality postharvest storage bioactive compounds

Highlights

Salicylic acid, abscisic acid, and methyl jasmonate could delay fruit deterioration.

Fruit respiration rate, weight loss and decay are reduced.

Ascorbic acid and antioxidant activity are retained.

Phenolic compounds and anthocyanin content are preserved.

Fungal growth was suppressed by postharvest treatments.

1 Introduction

Strawberry fruit is considered one of the most popular horticultural crops world-wide and is a rich source of important minerals, vitamins (vitamin C), and phytochemicals (anthocyanins carotenoids and polyphenols), that play a significant role in human health [1]. However, strawberry, a non-climacteric fruit, is highly perishable with limited shelf-life due to its high water content, respiration rate, susceptibility to mechanical injury, and to microbial attack (especially by Botrytis cinerea) during storage [2]. Strawberry fruit deteriorates rapidly after harvest with loss of economic and nutritional value, and it needs to be harvested at a precise stage of maturity in order to obtain maximum postharvest quality. Hence, there is a demand not only from the producers but also from the consumers to extend shelf-life and reduce decay of strawberry fruit.

Recently, many postharvest techniques have been applied for reducing decay of strawberry fruit such as edible coating with Aloe vera and ascorbic acid [3], dipping in essential oils [4], melatonin treatment [5], controlled atmosphere storage [6], γ-irradiation [7], hot air and hot water dipping [2, 8], Nano-ZnO treatment [9], pulsed light [10], and ethylene action inhibitor (1-MCP) treatment [11]. However, some of these treatments are not realistic due to low customer acceptance or high treatment price. Therefore, it is important to develop novel effective methods to reduce senescence and enhance quality of strawberry fruit. One of the postharvest treatments for reducing senescence of fruits is application of exogenous plant growth regulators. However, relatively few previous studies have compared the effects of different plant growth regulators on postharvest decay and quality of strawberry fruits.

Salicylic acid (SA) is a natural compound and is responsible for suppressing ethylene production and fungal growth such as that of B. cinerea. It was reported that SA concentrations of 1 and 2 mmol L^–1 were the most effective for reducing ethylene production, microbial load and retaining overall quality of strawberry fruits [12]. Moreover, postharvest treatment with SA enhanced total antioxidant content in strawberry fruit [13]. It also reduced weight loss, decay and redness, maintained firmness, and increased hue+ angle [14].

Abscisic acid (ABA) is one of the most important plant hormones, acting as an inhibitor of growth and metabolism. Previous studies indicated that ABA plays an important role in fruit ripening and senescence not only in climacteric fruits such as tomatoes [15] but also in non-climacteric fruits such as strawberry [16]. Previous reports indicated also that ABA might increase postharvest quality of some fruits such as tomato by enhancing suberin accumulation [17], and increasing soluble sugar concentrations [18]. In strawberry postharvest treatment with 1, 10 or 100 mM ABA resulted in increased accumulation anthocyanin and softening mediated by an increase in PAL activity [19 –21].

Methyl jasmonate (MeJA) is found naturally in higher plants and plays a key role in plant defense against pathogen infection. For example, application of exogenous MeJA reduced postharvest decay of peppers by enhancing tissue resistance to Botrytis cinerea [22] and reduced decay development in strawberry fruit [23 –25]. Previous studies indicated that crop quality traits were also improved following exogenous MeJA treatment. For example, treatment of Fragaria chiloensis with MeJA also maintained fruit firmness and anthocyanin levels [23]. Indeed MeJA treatment was also shown to enhance strawberry aroma while retaining nutritionally important compounds [26].

To our knowledge, no previous studies have been performed, however, to compare the effects of SA, ABA, and MeJA on storability, physico-chemical and sensory quality parameters of strawberry fruits. Thus, the aim of the current study was to evaluate comparatively the effects of postharvest treatment with SA, ABA, and MeJA on retarding senescence, reducing decay, and improving quality traits of strawberry fruit during storage at 4°C for 12 days.

2 Materials and methods

2.1 Plant materials and treatments

Strawberry (Fragaria×ananassa) cv. ‘Festival’ fruits were harvested at commercial ripeness stage (3/4 of fruit surface showing red colour) from the Faculty of Agriculture, Cairo University experimental station and transported to the postharvest laboratory within 2 h. The fruits were selected for uniformity of size and being free from any visual defects, and they were randomly divided into seven groups (about 100 fruits per group). The strawberry fruit groups were immersed in the following six solutions for 5 min at room temperature (20°C). The six solutions for treatments were prepared in distilled water as follows: SA-2 (2 mmolL^–1 salicylic acid), SA–4 (4 mmol L^–1 salicylic acid), MeJA-0.25 (0.25 mmolL^–1 methyl jasmonate), MeJA-0.50 (0.50 mmolL^–1 methyl jasmonate), ABA-0.25 (0.25 mmolL^–1 abscisic acid), and ABA-0.50 (0.50 mmolL^–1 abscisic acid). The concentrations used were selected based on preliminary experiment and previous work [SA (14), MeJA (23), and ABA (16)]. The seventh group was the control (CON) and was dipped in distilled water. After immersion, the fruit were picked using autoclaved forceps and allowed to dry in a laminar air flow hood at room temperature for 60 min. After drying, the fruit for each treatment were packed in clamshells (each containing about 200 g of fruit) and stored at 4°C and 90% RH for 12 d. Clamshells for each treatment were divided into two groups. The first group was stored continuously throughout the experimental storage period to determine weight loss and decay. The second group was used to determine fruit quality parameters (firmness, total soluble solids, respiration rate, and colour intensity), chemical parameters (pH, titratable acidity, vitamin C, anthocyanin, total phenolic content and antioxidants capacity), and fungal counts. All the measurements were performed at time intervals of 0, 4, 8 and 12 days after the treatments and each treatment was replicated three times. All physical and chemical analyses were performed on fresh fruits on the day of assay. The experiment was repeated twice.

2.2 Chemicals

Salicylic acid, methyl jasmonate, abscisic acid, ethyl alcohol, ACS spectrophotometric grade, 95.0%, methyl alcohol, gallic acid and Folin & Ciocalteu’s phenol reagent were purchased from Sigma-Aldrich (USA). Potato dextrose Agar, sodium carbonate, potassium acetate and hydrochloric acid were purchased from Al Gomhoria CO, Cairo, Egypt.

2.3 Weight loss

Weight loss percentage was determined by weighing strawberry fruits using digital scale on each sampling day during storage and calculated using the following equation:

Weight loss (%) = (Initial weight–Final weight/Initial weight)×100.

2.4 Decay percentage

The decay percentage was determined at each sampling point and calculated according to the following equation:

Decay percentage (%) = (Number of decayed fruits/Total number of fruits)×100.

2.5 Firmness (N)

Ten random strawberry fruits from each treatment were used for determining firmness at two points. The two points tested were located in the central zone on opposite sides of fruits. Firmness was measured using a FT011 penetrometer (Wagner Instruments, Italy) and values are presented as Newtons (N).

2.6 Soluble solids content (SSC)

Five strawberry fruits were selected for measuring SSC from each treatment (with three replicates). The fruits were mixed in a blender for 2 mins and SSC was determined using a digital refractometer (model PR101, Co. Ltd., Japan) at room temperature (25°C). Readings were taken as % of soluble solids content in the fruit. The same juice was used for determining titratable acidity and pH.

2.7 Titratable acidity (TA) and pH

TA of strawberry juice was measured using a digital burette and determined by titrating 5 g (diluted with 50 mL distilled water) of strawberry juice sample with 0.1 N sodium hydroxide to an end point of pH 8.1 and expressed as percent of citric acid in the fruit juice. The pH of the juice was determined using a pH-meter (EuTech, Instruments, pH 510, Singapore).

2.8 Skin fruit colour

Skin colour of strawberry fruit was measured with a Minolta colorimeter (Model CR-400, KonicaMinolta, INC, Tokyo, Japan) on five fruit per replicate. L*, a*, b*, chroma (C*) and hue angle (h°) were determined. Each measurement was taken at three locations for each individual fruit. A standard white calibration plate was used to calibrate the colorimeter.

2.9 Respiration rate

Five separate single fruits were placed in separate gas-tight jars (200 ml) at 5°C for 2 h. After 2 h, 1 mL of air sample was removed from the headspace and was analyzed using an O₂/CO₂ gas analyzer (model 902D, MA, USA). Respiration rate was expressed as mmol CO₂ kg^–1FWh^–1.

2.10 Ascorbic acid and total anthocyanin content

Ascorbic acid (AA) content was determined using a titrimetric method with 2, 6-dichlorophenol indophenol [27]. The results of AA content are expressed as mg/100 g fresh weight.

Five strawberry fruits were selected randomly from each replicate and homogenized in a laboratory blender (Heidalph DGH Rundfunk-Fernsehen, Typ-DR 22054, Germany) at high speed to determine anthocyanin and total phenolic compounds. Anthocyanin content was determined using the pH-differential method described by Tonu et al. [28]. Briefly, 4 g of strawberry puree was extracted with 40 ml of solvent, ethanol: 0.1 M HCl (85:15%, V:V). The mixture was centrifuged at 6.000×g for 20 min and then the supernatant was filtered using Whatman No.1 filter paper; the supernatant was collected and used for anthocyanin determination. Extractions were done in triplicate. Extracts (3 ml) were diluted in 5 ml of two different buffers; pH = 1.0 and pH = 4.5. After 30 min of incubation at room temperature, absorption (A) was measured at 510 nm and at 700 nm. The absorbance values of the diluted samples (A) were calculated as follows:

A = (A₅₁₀– A₇₀₀) pH_1.0– (A₅₁₀– A₇₀₀) pH_4.5

Total anthocyanin content was calculated as follows:

TAC = A×MW×df×1000/(ɛ×λ×m)

Total anthocyanin content was calculated as mg cyanidin-3-glucoside equivalent per kg dry extract (mg C3GE/kg) by using (A) the difference of absorbance between pH 1 and pH 4.5 solutions, a dilution factor (df), conversion factor to kg (1000), a molar absorptivity (ɛ of 24,825 M^–1 cm^–1 (at 510 nm), a molecular weight (MW) of 484.82, cuvette optical path length (λ)(1 cm), and weight of the sample (m)(g).

2.11 Total phenolic content

The total phenolic content (TPC) was determined according to Aaby et al. [29] using Folin-Ciocalteau reagent with gallic acid as standard. Aliquots of strawberry puree were centrifuged at 8000×g for 20 min at room temperature. The resulting homogenate was filtered through filter paper to obtain a clear juice. One mL of collected clear juice was mixed with 5 mL of a 1/10 dilution of Folin-Ciocalteau reagent and 4 mL sodium bicarbonate (7.5% w/v), and the mixture was diluted to 100 mL with distilled water. The solution was kept in the dark at room temperature for 2 h; the absorbance was then measured at 765 nm with a spectrophotometer (model UV-2401 PC, Shimadzu, Milano, Italia). TPC was expressed as gallic acid equivalents in mg per 100 g fresh weight (mg GAE/100 g FW) using a gallic acid standard curve.

2.12 Antioxidant capacity

The effect of different treatments on strawberry fruit antioxidant capacity was determined according to the method of Yen and Chen [30]. Strawberry samples (10 g) were homogenized in 200 mL of distilled water, and then filtered using Whatman No.1 filter paper and 5 mL of filtrate was diluted into 25 mL of distilled water. Strawberry extract (1 mL) was added to 3 mL of methanol and 1 mL of 2,2-diphenyl-1-picrylhydrazyl (DPPH) (0.012 g DPPH in 100 mL^–1 of methanol). The mixture was shaken in the dark at room temperature for 10 min. The absorbance was measured at 517 nm. The antioxidant capacity was expressed as % of inhibition according to the formula:

Inhibition (%) = (A_control–A_sample/A_control)×100

where A control and A sample are the absorbance of the control and sample, respectively [31].

2.13 Microbiological evaluation

Fruit samples (10 g) were crushed and diluted (1:10 w/v) in 0.1% buffered peptone water, homogenized by hand massaging for 5 min and serially diluted with buffered peptone water. The homogenate (0.1 ml) was plated on potato dextrose agar in duplicate. Fungal counts (log CFU/g) were determined after incubation at 25–28°C for 5 days [32].

2.14 Statistical analysis

The whole experiment was repeated twice and the data were pooled. Data were subjected to analysis of variance (ANOVA) with SPSS software. Sources of variation were storage period (days) and treatments. A Duncan test at p < 0.05 was used to compare means among treatments.

3 Results

3.1 Weight loss, respiration rate, and decay were reduced by postharvest treatments

The effect of dipping strawberry cv. ‘Festival’ fruit in different concentrations of SA, ABA, and MeJA on weight loss, respiration rate, and decay percentage during 12 days of storage at 4°C is shown in Fig. 1. Weight loss increased during the storage period following all treatments (Fig. 1A) After 8 days of storage, all treatments significantly (p < 0.05) reduced weight loss compared to the control except the two concentrations of ABA. However, at the end of the storage period (12 days), only treatment with 0.25 mM MeJA significantly reduced weight loss compared to the control.

Fig. 1

Effect of salicylic acid (SA) (2 and 4 mM), abscisic acid (ABA) (0.25 and 0.50 mM), and methyl jasmonate (MeJA) (0.25 and 0.50 mM) on (A) weight loss (%), (B) respiration rate (mmol CO₂ kg^-1FWh^–1), and (C) decay % of strawberry fruits stored for 12 d at 4C. Respiration rate at start of the storage was 24.75±0.32 mmol CO₂ kg^–1FWh^–1. No decay was observed at 4 d from start of the storage, thus, panel (C) shows just 8 and 12 d. Data are means of three replicates. Different letters for every storage point indicate significant differences (Duncan test, p < 0.05).

The 2 and 4 mM SA treated fruits showed significant (p < 0.05) reduction of respiration rate at all storage period time points compared to the control fruits (Fig. 1B). After 4 and 8 days of storage, there were no differences in respiration rate between fruit treated with 0.25 and 0.50 mM ABA and the control. However, after 12 days of storage, treatment of strawberry fruit with 0.50 mM ABA resulted in greater respiration rate than the control or the other treatments. MeJA at 0.50 mM significantly reduced respiration rate at all storage period time points.

No decay was observed on the surface of strawberry fruit after 4 days of storage after any of the treatments, however, strawberry fruit treated with 2 and 4 mM SA showed greater resistance against decay when compared with the control and the other treatments after both 8 and 12 days of storage (Fig. 1C). Treatment with the higher concentration of SA resulted in less surface decay than the lower concentration after 8 days of storage, however, the difference between two concentrations of SA was not significant after 12 days of storage. Treatment with ABA showed the same trend of results as SA but after 12 days, treatment with 0.25 mM ABA was not effective at reducing decay compared to the control. Treatments with MeJA (0.25 and 0.50 mM) significantly delayed the development of decay compared to control fruits throughout the storage periods. However, no significant difference was observed in decay between 0.25 and 0.50 mM MeJA treated fruit.

3.2 Changes in colour

The effect of dipping strawberry cv. ‘Festival’ fruit in different concentrations of SA, ABA, and MeJA on L*, a*, and ascorbic acid content during 12 days of storage at 4°C is shown in (Fig. 2). The L* value is an indicator for brightness of the fruit surface: high values indicate less pigment accumulation and less ripening while the lower values indicate more intense colour and more ripening. Results shown in Supplementary Table 1 indicate that L* values of fruit surfaces generally decreased during storage. After 4 days of storage, the L* values of fruit subjected to all treatments were significantly higher (lighter colour) than those of the control except for the 0.25 mM MeJA treatment. After 8 days only the SA treated fruit and after 12 days the SA treated and the 0.25 mM JA treated fruit, had higher L* values than the control. (p < 0.05).

Fig. 2

Effect of salicylic acid (2 and 4 mM), abscisic acid (0.25 and 0.50 mM), and methyl jasmonate (0.25 and 0.50 mM) on (A) L* value, (B) a* vlaue, and (C) ascorbic acid (mg/100g FW) of strawberry fruits stored for 12 d at 4C. L* value, a* value, and ascorbic acid value at start of the storage were 34.52±0.23, 33.60±0.20, and 54.66±1.33 (mg/100g FW), respectively. Data are means of 3 replicates. Different letters for every storage point indicate significant differences (Duncan test, P < 0.05%).

A positive (+) a* value is an indicator for redness while, negative (–) values are a sign of greenness. Thus a positive a* value is correlated with anthocyanin concentration in strawberry fruits [17]. Here, a* values increased with storage duration from 4 to 8 days following all treatments (Supplementary Table 1). Both SA treatments resulted in significantly lower a* values than the control at all time points (Fig. 2B). There were no differences in a* values between the two concentrations of ABA or the lower concentration of MeJA treatment and the control after 8 days of storage. However, no differences were recorded between control and either ABA or MeJA concentrations after 12 days of storage.

3.3 Strawberry fruit quality is affected by treatments

Firmness, SSC, pH, and titratable acidity (TA) were determined as indicators of strawberry fruit ripening and quality as well as their metabolic activity (Table 1). SSC was significantly (p < 0.05) influenced by treatments. SSC at harvest was 10.87±0.13 Brix, and decreased significantly after 4 d of storage in both control and most treated fruits (Supplementary Table 1). Treatment with both ABA concentrations reduced SSC loss compared to the control while the other treatments had no effect after 4 days of storage. After 8 and 12 d of storage, both treatments with ABA (0.25 and 0.50 mM) and MeJA (0.25 and 0.50 mM) showed significantly higher SSC values compared to the control.

Table 1
Effect of salicylic acid (2 and 4 mM), abscisic acid (0.25 and 0.50 mM), and methyl jasmonate (0.25 and 0.50 mM) on SSC, firmness, pH, and acidity of strawberry fruits stored for 12 d at 4°C. Data are means of three replicates±standard errors. Different letters indicate significant differences amongst treatments at each time point (Duncan test, p < 0.05%)

Time Treatment SSC Firmness pH TA

(day) (mM) Brix N % citric acid

0 10.87±0.63 4.71±0.03 3.54±0.06 0.98±0.06

4 2 SA 9.23±0.88bc 4.11±0.05a 3.62±0.03bc 0.92±0.01ab

4 4 SA 9.23±0.06bc 4.16±0.03a 3.57±0.01c 0.97±0.01a

4 0.25 ABA 9.76±0.16ab 4.03±0.37a 3.57±0.02c 0.91±0.00ab

4 0.50 ABA 10.43±0.23a 4.13±0.08a 3.66±0.00b 0.89±0.01b

4 0.25 MeJA 8.63±0.12c 4.20±0.05a 3.62±0.01bc 0.95±0.01ab

4 0.50 MeJA 9.46±0.08bc 4.16±0.12a 3.74±0.01a 0.93±0.01ab

4 Control 8.63±0.63c 4.13±0.14a 3.64±0.02b 0.89±0.03b

8 2 SA 9.46±0.09bc 3.66±0.03bc 3.69±0.00ab 0.92±0.01ab

8 4 SA 9.46±0.17bc 3.78±0.04ab 3.58±0.01c 0.96±0.01a

8 0.25 ABA 9.61±0.19b 3.50±0.06c 3.67±0.03ab 0.91±0.03bc

8 0.50 ABA 10.56±0.19a 3.60±0.06bc 3.69±0.00ab 0.87±0.01cd

8 0.25 MeJA 9.96±0.30ab 3.90±0.10a 3.65±0.03b 0.90±0.00bc

8 0.50 MeJA 10.03±0.49ab 3.70±0.06b 3.72±0.01a 0.88±0.01cd

8 Control 8.68±0.09c 3.28±0.04d 3.71±0.02a 0.84±0.01d

12 2 SA 9.80±0.06cd 3.50±0.16bc 3.57±0.01a 0.89±0.02a

12 4 SA 9.70±0.10cd 3.70±0.06a 3.50±0.01a 0.89±0.01a

12 0.25 ABA 10.11±0.07bc 3.34±0.03d 3.60±0.07a 0.86±0.01ab

12 0.50 ABA 11.23±0.35a 3.43±0.03cd 3.56±0.03a 0.87±0.00ab

12 0.25 MeJA 10.76±0.46ab 3.60±0.06ab 3.59±0.07a 0.89±0.03a

12 0.50 MeJA 10.18±0.09bc 3.48±0.04bcd 3.64±0.05a 0.88±0.01ab

12 Control 9.16±0.44d 3.13±0.03e 3.50±0.01a 0.84±0.00b

Time	Treatment	SSC	Firmness	pH	TA
0	10.87±0.63	4.71±0.03	3.54±0.06	0.98±0.06
4	2 SA	9.23±0.88bc	4.11±0.05a	3.62±0.03bc	0.92±0.01ab
4	4 SA	9.23±0.06bc	4.16±0.03a	3.57±0.01c	0.97±0.01a
4	0.25 ABA	9.76±0.16ab	4.03±0.37a	3.57±0.02c	0.91±0.00ab
4	0.50 ABA	10.43±0.23a	4.13±0.08a	3.66±0.00b	0.89±0.01b
4	0.25 MeJA	8.63±0.12c	4.20±0.05a	3.62±0.01bc	0.95±0.01ab
4	0.50 MeJA	9.46±0.08bc	4.16±0.12a	3.74±0.01a	0.93±0.01ab
4	Control	8.63±0.63c	4.13±0.14a	3.64±0.02b	0.89±0.03b
8	2 SA	9.46±0.09bc	3.66±0.03bc	3.69±0.00ab	0.92±0.01ab
8	4 SA	9.46±0.17bc	3.78±0.04ab	3.58±0.01c	0.96±0.01a
8	0.25 ABA	9.61±0.19b	3.50±0.06c	3.67±0.03ab	0.91±0.03bc
8	0.50 ABA	10.56±0.19a	3.60±0.06bc	3.69±0.00ab	0.87±0.01cd
8	0.25 MeJA	9.96±0.30ab	3.90±0.10a	3.65±0.03b	0.90±0.00bc
8	0.50 MeJA	10.03±0.49ab	3.70±0.06b	3.72±0.01a	0.88±0.01cd
8	Control	8.68±0.09c	3.28±0.04d	3.71±0.02a	0.84±0.01d
12	2 SA	9.80±0.06cd	3.50±0.16bc	3.57±0.01a	0.89±0.02a
12	4 SA	9.70±0.10cd	3.70±0.06a	3.50±0.01a	0.89±0.01a
12	0.25 ABA	10.11±0.07bc	3.34±0.03d	3.60±0.07a	0.86±0.01ab
12	0.50 ABA	11.23±0.35a	3.43±0.03cd	3.56±0.03a	0.87±0.00ab
12	0.25 MeJA	10.76±0.46ab	3.60±0.06ab	3.59±0.07a	0.89±0.03a
12	0.50 MeJA	10.18±0.09bc	3.48±0.04bcd	3.64±0.05a	0.88±0.01ab
12	Control	9.16±0.44d	3.13±0.03e	3.50±0.01a	0.84±0.00b

Fruit firmness was 4.71±0.03 N at harvest time and decreased during storage after all treatments (Supplementary Table 1). No significant difference was observed between treated fruit and the control after 4 days of storage (Table 1). After 8 and 12 days of storage, fruit firmness was found significantly (p < 0.05) higher in all treated fruits when compared with control. Among all treatments, MeJA at 0.25 mM and SA at 4 mM showed highest fruit firmness at both time points during the storage period.

In the controls, pH rose from day 0 to day 8 and then fell back, while TA contents rose from day 0 to day 8 and thereafter remained constant (Supplementary Table 1). However, postharvest treatments with SA, ABA, and MeJA had no clear effect on either character during storage.

3.4 Effect of treatments on bioactive compounds and antioxidant capacity

3.4.1 Changes in ascorbic acid

Ascorbic acid decreased with increasing storage time (Fig. 2C). No significant difference was observed in AA amongst all treated fruit and the control after 4 days of storage. However after 8 and 12 days of refrigerated storage, treatment of fruit with 4 mM SA, 0.50 mM ABA, and 0.25 mM MeJA significantly reduced (p < 0.05) the loss of AA compared to the control. Neither of the lower concentration of SA or ABA was able to reduce AA loss after 8 or 12 days of storage. Both concentrations of MeJA also reduced loss of AA after 12 days and when used at 0.25 mM a loss reduction was also seen after 8 days of storage.

3.4.2 Changes in antioxidant capacity

Antioxidant capacity was 78.32±2.27% at the beginning of the storage period and decreased with increasing storage periods at 4°C in all treated fruits (Supplementary Table 1). However, all treated strawberry fruit retained more antioxidant capacity compared to the control treatment at each time point (Fig. 3A). Furthermore, strawberries treated with the higher concentration of SA, ABA, and MeJA showed higher values of antioxidant capacity at each time point compared to the lower concentrations, although the difference was not significant for ABA at day 8 of storage.

3.4.3 Changes in TPC

A slight increase in TPC was observed after 4 days of storage at 4°C in strawberry fruits with most of the plant hormone treatments, which ranged from (211–224) mg GAE/100 g FW, compared to the untreated control (206 GAE/100 g FW) (Fig. 3B). After 4 days of storage, there was a decrease in TPC in all treated fruit and control (Supplementary Table 1). However, the fruit treated with the higher concentrations of all three growth regulators retained significantly higher TPC after both 8 and 12 days of storage compared to the control.

Fig. 3

Effect of salicylic acid (2 and 4 mM), abscisic acid (0.25 and 0.50 mM), and methyl jasmonate (0.25 and 0.50 mM) on (A) antioxidant activity %, (B) total phenolic compunds (mg GAE/100 g fw), and (C) total anthocyanin content (mg C3GE/Kg) of strawberry fruits stored for 12 d at 4C. Antioxidant activity, total phenolic compunds, and total anthocyanin content at start of the storage were 78.32±2.27 %, 210.33±2.72 (mg GAE/100 g fw), and 26.22±0.91 (mg C3GE/Kg), respectively. Data are means of three replicates. Different letters indicate significant differences within each time point (Duncan test, p < 0.05%).

3.4.3 Changes in total anthocyanin content

Total anthocyanin content was significantly affected by treatment with SA, ABA, and MeJA (Fig. 3C). Anthocyanin content increased slightly between 4 and 8 days of storage following treatment with the lower concentrations of SA, ABA, and MeJA, but by day 12, it had decreased (Supplementary Table 1). However, anthocyanin content of all treated fruits was significantly greater at 8 and 12 days of storage compared to the control. Strawberries treated with the lower concentration of ABA showed the highest anthocyanin content at the end of storage period followed by the strawberries treated with 2 mM SA and 4 mM SA.

3.5 Fungal count (log CFU/g) was affected by postharvest treatments

The effect of dipping strawberry cv. ‘Festival’ fruit in different concentrations of SA, ABA, and MeJA on fungal counts (log CFU/g) during storage for 12 days at 4°C is presented in Table 2. The principal decay fungi detected were Botrytis cinerea and Rhizopus stolonifer. No fungal growth was detected from fruit treated with SA (4 mM), ABA (0.50 mM), and MeJA (0.25 and 0.50 mM) at day 0. At all storage time points (4, 8 and 12 days) fungal growth in all treated fruits was either absent or significantly lower than in the control (p > 0.05). After 8 days of storage, fruit treated with the higher concentration of SA and both concentrations of MeJA recorded significantly lower fungal counts than the other treatments or control and ranged from 2.5–2.6 log CFU/g. At the end of the storage period, the control sample reached 4.2 log CFU/g followed by the SA and ABA treated fruit (3.9 log CFU/g). The most effective treatments for controlling fungal growth were the two concentrations of MeJA without any significant difference between them.

Table 2
Effect of salicylic acid (2 and 4 mM), abscisic acid (0.25 and 0.50 mM), and methyl jasmonate (0.25 and 0.50 mM) on mold and yeast (log CFU/g) of strawberry fruits stored for 12 d at 4°C. Data are mean of 3 replicates±standard errors. Different letters indicate significant differences (Duncan test, P < 0.05%)

Treatments Storage period (Days)

0 4 8 12

2 SA 2.60±0.05b 2.6±0.05c 3.70±0.06b 3.93±0.03b

4 SA ND^* ND 2.53±0.03d 3.86±0.03b

0.25 ABA 2.53±0.03b 2.7±0.03b 3.53±0.03c 3.86±0.03b

0.50 ABA ND 2.6±0.05c 3.53±0.03c 3.86±0.03b

0.25 MeJA ND ND 2.43±0.03d 3.63±0.03c

0.50 MeJA ND ND 2.53±0.03d 3.66±0.03c

Control 2.9±0.03a 3.1±0.05a 4.00 ±0.06a 4.23±0.03a

Treatments	Storage period (Days)
2 SA	2.60±0.05b	2.6±0.05c	3.70±0.06b	3.93±0.03b
4 SA	ND^*	ND	2.53±0.03d	3.86±0.03b
0.25 ABA	2.53±0.03b	2.7±0.03b	3.53±0.03c	3.86±0.03b
0.50 ABA	ND	2.6±0.05c	3.53±0.03c	3.86±0.03b
0.25 MeJA	ND	ND	2.43±0.03d	3.63±0.03c
0.50 MeJA	ND	ND	2.53±0.03d	3.66±0.03c
Control	2.9±0.03a	3.1±0.05a	4.00 ±0.06a	4.23±0.03a

^*ND: mean (not detected) there is no fungal growth found.

4 Discussion

4.1 Weight loss, respiration rate, and colour changes

Our results showed that the most effective treatments for reduction of weight loss were SA and MeJA. Application of SA has been found to reduce water loss during refrigerated storage of various crops including strawberry [14]. The positive effects of SA for reducing weight loss are related to its overall effects in maintaining fruit quality [13, 14]. This in turn is likely due to the effect of SA treatments in reducing respiration rate and ethylene production [12, 13]. In this study respiration rate was significantly reduced by the SA treatments.

The effect of MeJA in reducing weight loss is likely related to its effect in reducing loss of firmness (Table 1). This in turn may be due to effects on total antioxidants [33] that result in increasing lignin content as observed in previous work on Fragaria chiloensis fruit [23]. Treatment with 0.50 mM MeJA also significantly reduced the respiration rate during storage of the strawberry fruit, presumably related to the maintenance of firmness and fruit quality. This is in agreement with previous work [34] showing that whereas in unripe fruit MeJA increased respiration, at later stages of ripening MeJA treatment had the opposite effect. The increased respiration rate induced by 0.5 mM ABA could be due to enhanced ethylene production elicited by ABA treatment which was previously reported in strawberry cv. ‘Everest’ [20].

Here, treatment with 4 mM SA resulted in a shinier/lighter skin colour (higher L* values) compared to the control throughout storage at 4°C. Effects of post-harvest treatments on strawberry colour appear to vary [14]. For example, 2 mM SA treatment of F. ananassa cv ‘Camarosa’ fruit did not affect lightness (L*) [14]. The difference to the results presented here may be due to the cultivar, or the different SA concentration used. In other fruit, lower moisture loss leads to higher brightness (higher L* values) [35]. This would fit here with the reduction in weight loss, but would need further verification. No difference was observed in L* with ABA treatment at later storage time points. In previous work exogenous application of 0.1 mM ABA to strawberry fruit, accelerated colour development by increasing anthocyanin content and phenylalanine ammonia-lyase (PAL) activity [21]. The difference with our results could be explained by the difference in the fruit maturity stage used, or the method of ABA application, which in the case of Chen et al. [21] was via the peduncle.

In this study, the lowest a* values were obtained by both SA treatments during all storage periods. This could be due to the reduction in weight loss (Fig. 1A) and respiration rate (Fig. 1B) leading to a delay in the accumulation of anthocyanin. Again this contrasts with results reported by Shafiee et al. [14], who did not find any changes in a* values when strawberry cv. ‘Camarosa’ fruit were dipped in SA. The different cultivar used in this study could again explain the differences with our results. Compared to the control, treatment with ABA had no significant effect on a* value. However, Li et al. [19] reported a significant increase in a* value of strawberry fruits using a 1 mM ABA treatment compared to controls. The difference with our results could be due to the use of a higher concentration of ABA (1 mM) compared to our study (0.50 mM).

4.2 SSC, firmness, pH, and TA

SA treatment did not significantly affect SSC content, in agreement with Shafiee et al. [14]. However, in our study, ABA treatments did significantly increase SSC content. This is in agreement with previous work [19] where ABA treatment also increased colour formation, and anthocyanin accumulation while decreasing firmness. This combined effect was ascribed to an overall acceleration of ripening. Here firmness was actually increased by ABA treatment. The difference to the previous study may relate to the stage of maturity used for the studies: in this study fruit were treated at commercial ripeness while in the previous study the fruit were at the large green stage of maturity.

Firmness is a key factor for strawberry fruit quality. In this study, compared with controls, strawberry fruit treated with 4 mM SA showed higher firmness (Table 1), in agreement with a previous report showing that strawberry cv. ‘Camarosa’ fruits treated with SA had higher firmness than controls [14]. This result might be related to the effects of SA in reducing the activity of the main cell wall degrading enzymes (pectin methylesterase, cellulase, polygalacturonase) and reducing the activity of enzymes such as lipoxygenase which leads to higher firmness of fruits [13]. Here MeJA also increased firmness, in agreement with a previous study that tested pre-harvest applications of MeJA on postharvest qualities of F. chiloensis. In contrast Concha et al. [36] found that application of MeJA decreased firmness, however in their study fruit were treated at a less mature stage which may account for the difference.

Our results show that SA treatment resulted in a higher TA than the control after 8 and 12 days of storage. This result does not agree with Shafiee et al. [14] or Ayub et al. [37] who found that postharvest treatment with SA did not significantly affect TA, however these studies differed in the treatment combinations used [14] and length of treatment [37] making a full comparison difficult. Our results do however support the hypothesis that SA conserves acidity in fruits via a reduction in respiration rate [13, 37].

4.3 Ascorbic acid, total phenolics, anthocyanin and antioxidant capacity

The positive effect of SA in reducing loss of AA is in agreement with previous studies [13, 33] and is likely due to its stimulation of the biosynthesis of ROS scavenging enzymes [13]. Treatment with 0.50 mM ABA also significantly increased AA retention. This result is in agreement with Li et al. [19] who found an increase in antioxidant capacity in the first few days post-harvest but not at later time points. On the other hand, Ayub et al. [37] did not find any changes in AA related to ABA treatment. This could be due to the method of ABA application, which was performed by injecting 100μL of 1 mM ABA diluted in 2% ethanol solution into the fruit receptacles. In our study, MeJA also reduced AA loss in strawberry fruits after longer term storage. This is in agreement with, Lolaei et al. [38] who reported a significant increase in AA by treating strawberry cvs. ‘Selva’ and ‘Queen Elisa’ fruits with 0.50 and 1 mM MeJA.

The antioxidant capacity of all treated fruits was already higher than the control after only 4 days of storage. Moreover effects were most pronounced with the highest concentration of each of the growth regulators. This contrasts with the ascorbic acid levels which were not affected by the treatments at day 4 and suggests that the antioxidant effects of the treatments were not mediated by changes in ascorbic acid. Phenolics are an important class of antioxidant compounds in berries [9, 29]. In accordance with Ayala-Zavala et al. [40] MeJA significantly increased retention of TPC at all time points.

The pattern of the effects of treatments on TPC do follow quite closely the pattern of antioxidant capacity changes, although at day 4 the effects of all the treatments on antioxidant capacity seemed to be more pronounced compared to the trend of TPC change, suggesting that other antioxidant pathways may also be stimulated by the treatments. The retention of TPC by treatments with high concentrations of SA and MeJA are consistent with previous studies indicating that both growth regulators enhance the efficiency of antioxidant systems in plants [13, 40].

Anthocyanin is one of the major compounds present in strawberries. In our study we observed few differences in total anthocyanin content after 4 days of storage with the treatments tested. However, at later time points all the treatments significantly improved anthocyanin retention. This result is in agreement with the study by Ayala-Zavala et al. [40], where strawberries treated with MeJA showed the highest values of anthocyanin after 12 days of storage at 7.5°C. Moreover, Yueming and Daryl [41] reported that treatment with ABA stimulated accumulation of anthocyanin and increased ethylene production, and suggested that this may be due to the effects of ABA in enhancing PAL activity.

The antioxidant capacity of anthocyanins may be one of their most significant biological properties [42], however in our study the pattern of effects of the treatments on anthocyanin content did not match antioxidant activity closely, indicating that other antioxidants are also affected by the treatments.

4.5 Decay and fungal count (log CFU/g)

Results presented here show that treatment of fruits with SA, ABA, or MeJA reduced decay development during storage at 4°C. Plants use several mechanisms to protect themselves from pathogenic attack; one of them is accumulation of SA [13, 43]. Botrytis cinerea and Rhizopus stolonifer were the main decay fungi detected in our study. Our results are in agreement with those previously reported [12] showing that postharvest treatment with SA reduced fungal decay of strawberry cv. ‘Selva’ fruits caused by Botrytis cinerea. The role of SA in controlling postharvest spoilage is likely due to its role in increasing hydrogen peroxide (H₂O₂) in plants which acts as a signal molecule to activate plant resistance systems against pathogen attack [13]. To our knowledge, no previous work has studied the effect of exogenous ABA postharvest treatment on the decay development of strawberry fruit. Our results indicate that 0.50 mM ABA retards decay during cold storage. This result could be due to induced activity of defence enzymes by the ABA such as phenylalanine ammonia-lyase (PAL) [20]. Our results also showed that MeJA at the two tested concentrations could delay the development of decay in strawberry fruits, in agreement with previous studies [24 , 44]. The action of MeJA here is likely due to its activation of defence pathways [45].

5 Conclusions

In summary, a comparison of our results with the literature clearly indicates the need for comparative studies using fruit of the same maturity and equivalent application methods. Our results confirm and expand on previous studies showing that application of SA, ABA and MeJA are potentially useful postharvest treatments to enhance strawberry shelf life. However, the direct comparison of their effects provided in this study, indicates subtly different responses that are worthy of further investigation to understand underlying mechanisms and potential synergies.

Funding

The authors report no funding.

Conflict of interest

The authors have declared no conflict of interest.

Footnotes

The supplementary material is available in the electronic version of this article:

Acknowledgments

The authors have no acknowledgments.

References

Dragišić Maksimović

, Poledica

, Mutavdžić

, Mojovic

, Radivojevic

, Milivojevic

. Variation in nutritional quality and chemical composition of fresh strawberry fruit: Combined effect of cultivar and storage. Plant Foods for Human Nutrition. 2015;70:77–84. DOI: 10.1007/s11130-014-0464-3

Wei

, Wei

, Xu

, Shao

. The combined effects of tea tree oil and hot air treatment on the quality and sensory characteristics and decay of strawberry. Postharvest Biology and Technology. 2018;136:139–44. DOI: 10.1016/j.postharvbio.2017.11.008

Sogvar

, Saba

, Emamifar

. Aloe vera and ascorbic acid coatings maintain postharvest quality and reduce microbial load of strawberry fruit. Postharvest Biology and Technology. 2016(a);114:29–35. DOI: 10.1016/j.postharvbio.2015.11.019

El-Mogy

, Alsanius

. Cassiaoil for controlling plant and human pathogens on fresh strawberries. Food Control. 2012;28:157–62. DOI: 10.1016/j.foodcont.2012.04.036

EL-Mogy

, Ludlow

, Roberts

, Müller

, Rogers

. Postharvest exogenous melatonin treatment of strawberry reduces postharvest spoilage but affects components of the aroma profile. Journal of Berry Research. 2019; DOI: 10.3233/JBR-180361.

Alamar

, Collings

, Cools

, Terry

. Impact of controlled atmosphere scheduling on strawberry and imported avocado fruit. Postharvest Biology and Technology. 2017;134:76–86. DOI: 10.1016/j.postharvbio.2017.08.003

Maraei

, Elsawy

. Chemical quality and nutrient composition of strawberry fruits treated by γ-irradiation. Journal of Radiation Research and Applied Sciences. 2017;10(1):80–7. DOI: 10.1016/j.jrras.2016.12.004

Caleb

, Wegner

, Rolleczek

, Herppich

, Geyer

, Mahajan

. Hot water dipping: Impact on postharvest quality, individual sugars, and bioactive compounds during storage of 'Sonata' strawberry. Scientia Horticulturae. 2016;210(10):150–7. DOI: 10.1016/j.scienta.2016.07.021

Sogvar

, Saba

, Emamifar

, Hallaj

. Influence of nano-ZnO on microbial growth, bioactive content and postharvest quality of strawberries during storage. Innovative Food Science & Emerging Technologies. 2016(b);35:168–76. DOI: 10.1016/j.ifset.2016.05.005

10.

Duarte-Molina

, Gomez

, Castro

, Alzamora

. Storage quality of strawberry fruit treated by pulsed light: Fungal decay, water loss and mechanical properties. Innovative Food Science & Emerging Technologies. 2016;34:267–74. DOI: 10.1016/j.ifset.2016.01.019

11.

, Lichter

, Chalupowicz

, Gamrasni

, Goldberg

, Nerya

, Ben-Arie

, et al. Effects of the ethylene-action inhibitor 1-methylcyclopropene on postharvest quality of non-climacteric fruit crops. Postharvest Biology and Technology. 2016; 111:322–9. DOI: 10.1016/j.postharvbio.2015.09.031

12.

Babalar

, Asghari

, Talaei

, Khosroshahi

. Effect of pre-and postharvest salicylic acid treatment on ethylene production, fungal decay and overall quality of Selva strawberry fruit. Food Chemistry. 2007;105:449–53. DOI: 10.1016/j.foodchem.2007.03.021

13.

Asghari

, Aghdam

. Impact of salicylic acid on post-harvest physiology of horticultural crops. Trends in Food Science and Technology. 2010;21:502–9. DOI: 10.1016/j.tifs.2010.07.009

14.

Shafiee

, Taghavi

, Babalar

. Addition of salicylic acid to nutrient solution combined with postharvest treatments (hot water, salicylic acid, and calcium dipping) improved postharvest fruit quality of strawberry. Scientia Horticulturae. 2010;124:40–5. DOI: 10.1016/j.scienta.2009.12.004

15.

Zhang

, Yuan

, Leng

. The role of ABA in triggering ethylene biosynthesis and ripening of tomato fruit. Journal of Experimental Botany. 2009;60:1579–88. DOI: 10.1093/jxb/erp026

16.

Chen

, Mao

, Lu

, Ying

, Luo

. Transcriptome profiling of postharvest strawberry fruit in response to exogenous auxin and abscisic acid. Planta. 2016(a);243:183–97. DOI: 10.1007/s00425-015-2402-5

17.

Tao

, Mao

, Li

, Chen

, Lu

, Huang, S. Abscisic acid mediates wound-healing in harvested tomato fruit. Postharvest Biology and Technology. 2016;118:128–33. DOI: 10.1016/j.postharvbio.2016.04.002.

18.

Barickman

, Kopsell

, Sams

. Abscisic acid improves tomato fruit quality by increasing soluble sugar concentrations. Journal of Plant Nutrition. 2017;40(7):964–73. DOI.10.1080/01904167.2016.1231812

19.

, Zisheng

, Mou

, Wang

, Ying

, Mao

. ABA and UV-C effects on quality, antioxidant capacity and antho-cyanin contents of strawberry fruit (Fragaria ananassa Duch.). Postharvest Biology and Technology. 2014;90:56–62. DOI: 10.1016/j.postharvbio.2013.12.006

20.

Jiang

, Joyce

. ABA effects on ethylene production, PAL activity, anthocyanin and phenolic contents of strawberry fruit. Plant Growth Regulation. 2003;39:171–4. DOI: 10.1023/A:1022539901044

21.

Chen

, Mao

, Mi

, Lu

, Ying

, Luo

. Involvement of abscisic acid in postharvest water-deficit stress associated with the accumulation of anthocyanins in strawberry fruit. Postharvest Biology and Technology. 2016(b);111:99–105. DOI:10.1016/j.postharvbio.2015.08.003

22.

Tzortzakisa

, Chrysargyrisa

, Sivakumarb

, Loulakakisc

. Vapour or dipping applications of methyl jasmonate, vinegar and sage oil for pepper fruit sanitation towards grey mould. Postharvest Biology and Technology. 2016;118:120–7. DOI: 10.1016/j.postharvbio.2016.04.004

23.

Saavedra

, Figueroa

, Poblete

, Cherian

, Figueroa

. Effects of preharvest applications of methyl jasmonate and chitosan on postharvest decay, quality and chemical attributes of Fragaria chiloensis fruit. Food Chemistry. 2016;190:448–53. DOI: 10.1016/j.foodchem.2015.05.107

24.

Saavedra

, Sanfuentes

, Figueroa

. Independent preharvest applications of methyl jasmonate and chitosan elicit differential upregulation of defense-related genes with reduced incidence of gray mold decay during postharvest storage of fragaria chiloensis fruit. International Journal of Molecular Sciences. 2017;18(7):1420. Doi: 10.3390/ijms18071420

25.

Zhang

, Wang

, Ma

, Cao

, Li

, Wang

, Zheng

. Effects of methyl jasmonate on postharvest decay in strawberry fruit and the possible mechanisms involved. Acta Horticulturae. 2006;712:693–8.

26.

Moreno Fde

, Blanch

, Flores

, del Castillo

. Impact of postharvest methyl jasmonate treatment on the volatile composition and flavonol content of strawberries. Journal of the Science of Food and Agriculture. 2010;90:989–94.

27.

Association of Official Analytical Chemistry. (AOAC). Official Methods of Analysis of AOAC international. 17th ed. Gaithersburg, MD, USA, 2000.

28.

Tonu

, Ulvi

, Lech

. Strawberry anthocyanin determination by pH differential spectroscopic method-how to get true results? Acta Scientiarum Polonorum, Hortorum Cultus. 2014;13(3):35–47.

29.

Aaby

, Skrede

, Wrolstad

. Phenolic composition and antioxidant activities in flesh and achenes of strawberries (Fragraria ananassa). Journal of Agricultural and Food Chemistry. 2005;3:4032–4040. DOI: 10.1021/jf048001o

30.

Yen

, Chen

. Antioxidant activity of various tea extracts in relation to their antimutagenicity. Journal of Agriculture and Food Chemistry. 1995;43:27–32. DOI: 10.1021/jf00049a007

31.

Rababah

, Al-Mahasneh

, Kilani

, Yang

, Alhamad

, Ereifej

, et al. Effect of jam processing and storage on total phenolics, antioxidant activity, and anthocyanins of different fruits. Journal of the Science of Food and Agriculture. 2010;91:1096–102. DOI: 10.1002/jsfa.4289

32.

Naresh

, Byungjin

, Eunice

. Microbial decontamination of fresh produce (Strawberry) using washing solutions. Journal of Food Research. 2015;4(3):128–37. DOI: 10.5539/jfr.v4n3p128

33.

Asghari

, Hasanlooe

. Interaction effects of salicylic acid and methyl jasmonate on total antioxidant content, cata-lase and peroxidase enzymes activity in "Sabrosa" strawberry fruit during storage. Scientia Horticulturae. 2015;197:490–5. doi.10.1016/j.scienta.2015.10.009

34.

Perez

, Sanz

, Olias

. Effect of methyl jasmonate on in Vitro strawberry ripening. Journal of Agricultural and Food Chemistry. 1997;45(10):3733–7. DOI: 10.1021/jf9703563

35.

Delwiche

, Baumgardner

. Ground color as a peach maturity index. Journal of the American Society for Horticultural Science. 1983;110:53–7.

36.

Concha

, Figueroa

, Poblete

, Onate

, Schwab

, Figueroa

. Methyl jasmonate treatment induces changes in fruit ripening by modifying the expression of several ripening genes in Fragaria chiloensis fruit. Plant Physiology and Biochemistry. 2013;70:433–44. doi: 10.1016/j.plaphy.2013.06.008

37.

Ayub

, Bosetto

, Galvao

, Etto

, Inaba

, Lopes

. Abscisic acid involvement on expression of related gene and phyto-chemicals during ripening in strawberry fruit Fragaria x ananassa cv. Camino Real. Scientia Horticulturae. 2016;203:178–84. DOI: 10.1016/j.scienta.2016.03.026

38.

Lolaei

, Zamani

, Ahmadian

, Mobasheri

. Effect of methyl jasmonate on the composition of yield and growth of strawberry (Selva and Queen Elisa). International Journal of Agriculture Crop Science. 2013;5:200–6.

39.

Kahkonen

, Hopia

, Vuorela

, Rauha

, Pihlaja

, Kujala

, Heinonen

. Antioxidant activity of plant extracts containing phenolic compounds. Journal of Agricultural and Food Chemistry 1999;47(10):3954–62.

40.

Ayala-Zavala

, Wang

, Gonzalez-Aguilar

. Methyl jasmonate in conjunction with ethanol treatment increases antioxidant capacity, volatile compounds and postharvest life of strawberry fruit. European Food Research and Technology. 2005;221(6):731–8. DOI: 10.1016/j.lwt.2004.03.002

41.

Yueming

, Daryl

. ABA effects on ethylene production, PAL activity, anthocyanin and phenolic contents of strawberry fruit. Plant Growth Regulation. 2003;39:171–4.

42.

Wang

, Cao

, Prior

. Total antioxidant capacity of fruits. Journal of Agricultural and Food Chemistry. 1996;44:701–5. DOI: 10.1021/jf950579y

43.

Barman

, Sharma

, Kumari

, Siddiqui

. Salicylic Acid. Postharvest Management Approaches for Maintaining Quality of Fresh Produce, Wyndmoor, PA, Springer Nature, 2016, pp. 51–68.

44.

Moline

, Buta

, Saftner

, Maas

. Comparison of three volatile natural products for the reduction of postharvest decay in strawberries. Advances in Strawberry Research. 1997;16:43–8.

45.

Dar

, Uddin

, Khan

MMA

, Hakeem

, Jaleel

. Jasmonates counter plant stress: A Review. Environmental and Experimental Botany. 2015;115:49–57.