Influence of maturity and bagging on the relationship between anthocyanin accumulation and phenylalanine ammonia-lyase (PAL) activity in ‘Jonathan’ apples

Postharvest Biology and Technology 19 (2000) 123 – 128 www.elsevier.com/locate/postharvbio

Influence of maturity and bagging on the relationship between anthocyanin accumulation and phenylalanine ammonia-lyase (PAL) activity in ‘Jonathan’ apples Hongqing Wang * , Osamu Arakawa , Yoshie Motomura Faculty of Agriculture and Life Science, Hirosaki Uni6ersity, Bunkyo-machi 3, Hirosaki, Aomori 036 -8561, Japan Received 2 August 1999; accepted 19 February 2000

Abstract The influence of maturing and ripening on phenylalanine ammonia-lyase (PAL) activity and anthocyanin accumulation was examined using bagged, non-bagged and shaded ‘Jonathan’ (Malus domestica) apples. Bagged fruit were covered with paper bags from mid-June at an early stage of fruit growth. Shaded apples were insulated from sunlight by newspaper at the beginning of colouring (middle September). The apples were harvested at different maturity stages and were irradiated with UV+ white light for 96 h at 15°C after which anthocyanin content and PAL activity were measured. In non-bagged and shaded apples, anthocyanin accumulation and maximal PAL activity increased as the apples developed from the immature to the initial ripe stage, then decreased at full ripe stage. A positive linear relationship between the maximum PAL activity and the amount of anthocyanin accumulated suggested that the change in PAL activity is involved in the change of anthocyanin accumulation. In the bagged apples in the immature stage, anthocyanin accumulation and peak PAL activity after irradiation was higher than that in non-bagged apples. However, as the apples ripened, anthocyanin accumulation was less than for less mature fruit, even though PAL activity was relatively high. Therefore, PAL is not the only regulating factor for anthocyanin accumulation in bagged mature and ripe fruit. © 2000 Elsevier Science B.V. All rights reserved. Keywords: Maturity; Bagging; Anthocyanin; Phenylalanine ammonia-lyase (PAL)

1. Introduction The development of the red pigmentation with advancing maturity in apples still on the tree was thought to be dependent on an increase of their * Corresponding author: Tel.: +81-172-393809; fax: + 81172-393750. E-mail addresses: [email protected] (H. Wang), [email protected] (O. Arakawa)

ability to produce anthocyanin during the maturing period (Arakawa, 1988, 1990a,b). Faust (1965) suggested that at that time, glycolysis shifts toward the pentose phosphate pathway and secondary metabolism, resulting in an increase in anthocyanin synthesis. Moreover, it has been known that bagging promotes anthocyanin synthesis, and Arakawa, (1988, 1991) reported that bagged fruit which had been covered with paper

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bags for about one month after flowering produced much higher levels of anthocyanin at immature and mature stages than did shaded apples. However, this anthocyanin synthesis remarkably decreased during ripening. So, this result indicated that the change in anthocyanin synthesis in bagged fruit was largely different from that in shaded apples during ripening. Anthocyanin synthesis is a process that involves many steps from the primary precursor (phenylalanine) to the end products (glycosides of cyanidin) (Lancaster, 1992). Phenylalanine ammonia-lyase (PAL) is the first enzyme to catalyse the elimination of NH3 from L-phenylalanine to give trans-cinnamate (Hanson and Havir, 1981). PAL activity has been reported to positively correlate with anthocyanin synthesis in grapes (Kataoka et al., 1983), strawberries (Given et al., 1988) and apples (Faragher and Chalmers, 1977; Tan, 1979, 1980; Arakawa et al., 1986), but its role in regulating anthocyanin formation in apples remains controversial (Blankenship and Unrath, 1988; Ju et al., 1995). The purpose of this study is to examine the function of PAL in anthocyanin accumulation in bagged, non-bagged and shaded apples of varying levels of maturity.

2. Materials and methods Apple fruit were harvested from ‘Jonathan’ (Malus domestica Borkh, cv. Jonathan) trees at the experimental orchard of the Faculty of Agriculture and Life Science, Hirosaki University. Some apples were covered by two-layer-paper bags (Kobayashi seitai, Japan; 13 ×16 cm; blue paper with the inner layer coated with wax) in the middle of June. Apples covered by bags are referred to as ‘bagged fruit’. The bagged apples had very low chlorophyll content when the experiments started. At the beginning of colour development (middle September), non-bagged apples were covered by bags made from newspaper to shade them from direct sunlight effectively inhibiting pigmentation (referred to as ‘shaded apples’). This bagging treatment had little effect on

chlorophyll content of the fruit. The bagged apples were harvested on 2nd August (very immature), 23rd August (immature), 12th September (mature non-ripe), and 29th September (partially ripe). Bags were removed before subsequent light treatment. The non-bagged apples were harvested on 2nd August, 23rd August and 12th September, and shaded apples were harvested on 29th September and 17th October (full ripe). Harvested apples were irradiated for 96 h at 15°C with mixed light from a white fluorescent lamp (FL20-S. W, Toshiba, Tokyo; 4 W m − 2) and an ultraviolet fluorescent lamp with a filter eliminating radiation below 290 nm in wavelength (FL20-S. E., Toshiba, Tokyo; 1.3 W m − 2). Skin disks, 18 mm in diameter and 1–2 mm in thickness including cortical tissue, were prepared every 24 h and stored at − 40°C. Anthocyanin was extracted from skin disks with methanol containing 1% HCI, and absorbency was measured at 530, 620, and 650 nm by spectrophotometer (U-2000S Spectrophotometer, Hitachi, Japan). The anthocyanin content was calculated as described previously (Arakawa, 1991). An enzyme was prepared as described by Faragher and Chalmers (1977) with some modification. To assay the PAL activity, the enzyme was made of 100 mM borate buffer (pH8.8) and an L-phenylalanine concentration of 60 mM. Samples ware incubated for 1 h at 60°C. The protein concentration in the reaction mixture was from 30 to 60 ng l − 1, and was quantified according to the Bradford method (Bradford, 1976). A unit of PAL activity was defined as the production of 1 mol of trans-cinnamic acid per min under the assay conditions. All data reported throughout this paper are the averages of three to six replicates.

3. Results and discussion

3.1. Immature stage The anthocyanin content in both bagged and non-bagged apples harvested on 2nd August (78

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days after full bloom, very immature fruit) increased linearly with light irradiation, and reached its highest level after 96 h (Fig. 1). The amount of

Fig. 1. Anthocyanin content and PAL activity in the skin of immature ‘Jonathan’ apples irradiated with white (2.6 W m − 2) +UV (1.0 W m − 2) light at 15°C. Bagged fruits were covered with two layers of paper bags during fruit development. Apples were harvested on 2nd August. Vertical bars indicate 9SE.

Fig. 2. Anthocyanin content and PAL activity in the skin of ‘Jonathan’ apples irradiated with white (2.6 W m − 2)+ UV (1.0 W m − 2) light at 15°C. Bagged fruits were covered with two layers of paper bags during fruit development. Apples were harvested on the 23rd August. Vertical bars indicate 9SE.

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anthocyanin accumulated in bagged apples after 96 h light irradiation was about twice that of non-bagged apples. The PAL activity in both bagged and non-bagged apples increased rapidly up to 48 h under light irradiation, then decreased rapidly after 72 h. The highest level PAL activity in bagged apples was more than three times as high as that of non-bagged apples. In the immature apples (23rd August, 99 days after full bloom), the anthocyanin accumulation in bagged apples was greater than that in nonbagged apples, and PAL activity in bagged apples was also higher than that of non-bagged apples (Fig. 2). As indicated by Figs. 1 and 2, maximal PAL activity coincided with anthocyanin accumulation, which suggests that in immature apples, PAL activity is related to the larger anthocyanin accumulation in bagged apples, as indicated by its absence in non-bagged apples.

3.2. Mature stage The difference in anthocyanin content between bagged and non-bagged mature non-ripe apples (12th September, 119 days after full bloom) became smaller compared with that of the immature fruit stage (2nd and 23rd August), though the anthocyanin accumulation in the bagged apples was still higher than that in non-bagged apples (Fig. 3). The PAL activity in the bagged apples was more than twice as high as that in nonbagged apples, and the maximal PAL activity was still higher than in the apples harvested in August. The PAL activity in bagged apples increased rapidly with light irradiation for 24 h, and reached a maximum after 48 h, then decreased rapidly, as shown in Figs. 1 and 2. On the other hand, the PAL activity in non-bagged apples increased rapidly and attained its maximum after 24 h, maintaining this level for 48 h. The value of the maximal PAL activity in the mature stage was higher than that in the very immature and immature apples (2nd and 23rd August). This suggests that the increased PAL activity took part in the promotion of anthocyanin accumulation in the non-bagged apples at this stage.

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Fig. 3. Anthocyanin content and PAL activity in the skin of ‘Jonathan’ apples irradiated with white (2.6 W m − 2)+ UV (1.0 W m − 2) light at 15°C. Bagged fruits were covered with two layers paper of bags during fruit development. Apples were harvested on the 12th September. Vertical bars indicate 9SE.

stage), the shaded apples had twice as much anthocyanin as the bagged apples; in fact, the bagged apples harvested on 29th September produced less anthocyanin than did the bagged apples harvested on 12th September (Fig. 4). The PAL activity in shaded apples increased linearly until 72 h and decreased slightly after 96 h. Maximal PAL activity in the bagged apples was higher than that in shaded apples. Therefore, the decrease in anthocyanin accumulation (when it is compared with that immature or mature stage) in bagged apples at this stage did not correspond to a change in PAL activity. In the apples harvested on 17th October (154 days after full bloom, ripening stage), the PAL activity in shaded apples increased linearly until 48 h and then remained relatively constant, and the anthocyanin accumulation was increased linearly until 96 h (Fig. 5). The maximal PAL activity and anthocyanin accumulation were lower than those of apples harvested on 29th September. Thus the decreased PAL activity in shaded apples was coincided with decreased anthocyanin accumulation.

Fig. 4. Anthocyanin content and PAL activity in the skin of ‘Jonathan’ apples irradiated with white (2.6 W m − 2)+ UV (1.0 W m − 2) light at 15°C.Bagged fruits were covered with 2 layers of paper bags during fruit development. Apples were harvested on 29th Sep. Vertical bars indicate 9SE.

3.3. Ripening stage In the apples harvested on 29th September (136 days after full bloom, initial ripening

Fig. 5. Anthocyanin content and PAL activity in the skin of ‘Jonathan’ apples irradiated with white (2.6 W m − 2) +UV (1.0 W m − 2) light at 15°C. Apples were harvested on the 17th October. Vertical bars indicate 9 SE.

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Fig. 6. Distribution plot showing a correlation between PAL activity and anthocyanin content in the skin of ‘Jonathan’ apples irradiated with white (2.6 W m − 2)+ UV (1.0 W m − 2) light at 15°C for 96 h.

3.4. Relationship between PAL acti6ity and anthocyanin accumulation The relationship between the maximal PAL activity and amount of anthocyanin accumulated in 96 h of light irradiation during fruit development was examined on each harvest day (Fig. 6). A significant positive linear relationship between maximal PAL activity and anthocyanin accumulation was found only in non-bagged and shaded apples (P =0.05). These results therefore suggest that the change in PAL activity was involved in the change in anthocyanin accumulation during the development of non-bagged and shaded apples. This is the first report that describes the change in anthocyanin accumulation and PAL activity during fruit maturation using harvested apples.

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According to Ju et al. (1995), changes in anthocyanin accumulation can occur independently of changes in PAL activity; the increase of anthocyanin during maturation involved additional enzymes between leucocyanidin and cyanidin glycosides. In our experiment, harvested apples were exposed to UV+ white light, a process that can reveal the ability of the fruit to produce anthocyanin. This method differs from those of Ju et al. (1995) and Lister and Lancaster (1996a,b) who investigated the relationship between anthocyanin accumulation and PAL activity using fruit on the tree. PAL activity in apples has been reported to be induced by light irradiation (Arakawa et al., 1985), while anthocyanin synthesis in apples also requires long light exposure. So it is unlikely that anthocyanin accumulation is initiated without PAL when the fruit is exposed to light. In bagged apples, the relationship between PAL activity and anthocyanin accumulation was not significant (Fig. 6). PAL activity in the bagged apples was always relatively high, but it was not always related to the induction of higher levels of anthocyanin accumulation. Ju et al. (1995) suggested that precursors of anthocyanin synthesis after the PAL stage in bagged apples were deficient, and that PAL was critical for pigment formation (with ‘Delicious’ apples 120 days after full bloom). Our experimental methods differed with those of Ju et al. (1995), and we found that the induction of higher levels of anthocyanin accumulation during the immature stage does coincide with an increase in PAL activity. But as the apples ripened, the anthocyanin accumulation decreased, even though PAL activity was relatively high. Therefore, maximal PAL activity is not the only regulating factor for anthocyanin accumulation in bagged mature and ripe apples.

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