Agricultural and Food Science 46 A G R I C U L T U R A L A N D F O O D S C I E N C E Vol. 1 (2007): 46–55 © Agricultural and Food Science Manuscript received December 2005 The effect of mineral fertilization on nutritive value and biological activity of chokeberry fruit Katarzyna Skupień Laboratory of Plant Raw Materials Processing and Storage, Agricultural University of Szczecin, ul. Słowackiego 17, 71-434 Szczecin, Poland, e-mail: kskupien@agro.ar.szczecin.pl Jan Oszmiański Department of Fruit, Vegetables and Cereal Technology, Agricultural University of Wrocław, Poland, e-mail: oszm@ozi.ar.wroc.pl The aim of the study was to assess whether an extra fertilization with manganese, commercial fertilizer Alkalin (N, K and Si), and combined treatment (manganese + Alkalin) affect the chemical composition of chokeberry fruits (Aronia melanocarpa (Michx) Elliot), especially sugar content and the quantity and profile of phenolics. Dry weight, soluble solids, titratable acidity, total sugar, reducing sugar, sucrose, vitamin C, total polyphenol (gallic acid equivalents); 2, 2-diphenyl-1-picrylhydrazyl radical scavenging activity; and phenolics profile were measured from the fruits harvested from different treatments. Chokeberries treated with manganese showed high content of non-identified phenolic acids [101.15 mg per 100 g fresh weight (FW), these compounds were not detected in fruit treated with Alkalin and manganese + Alkalin], and the highest content of cyanidin glycosides (813.75 mg per 100 g FW). The fruits treated with Alkalin displayed the highest content of quercetin derivatives (40.88 mg per 100 g FW) and eriodictyol 7-glucuronide (26.43 mg per 100g FW). Chokeberries in control treatments had the highest content of dry weight (30.76% FW), soluble solids (24.1% FW), total sugar (20.92% FW), vitamin C (8.4 mg 100 g–1 FW), total polyphenol (2377.1 mg gallic acid equivalents per 100 g FW), the highest 2, 2-diphenyl-1-picrylhydrazyl radical % inhibition (38.1%), highest content of chlorogenic acids (210.38 mg per 100 g FW), (-)epicatechin (32.18 mg per 100 g FW) and the highest degree of procyanidin polimerization (59). The results indicate that ap- plied fertilization exerted differential influence on chemical composition of aronia fruits. Key-words: chokeberry, fertilizers, fruit chemical composition, Aronia melanocarpa Introduction Black chokeberry (Aronia melanocarpa (Michx) Elliot) belongs to the Rosaceae family and is na- tive to eastern North America (Jeppsson 2000). In Poland aronia shrubs meant for fruit production were introduced in the 1970s. Chokeberries are rich in phenolic compounds and have been reported to have antioxidative effects in vitro and in vivo. Ogha- Vol. 16 (2007): 46–55 Vol. 16 (2007): 46–55 47 A G R I C U L T U R A L A N D F O O D S C I E N C E mi et al. (2005) noted an anti-inflamatory effect of aronia crude extract on endotoxin-induced uveitis in rats. Valcheva-Kuzmanova et al. (2004) studied the influence of the natural aronia juice on carbon tetrachloride (CCl4)-induced acute liver damage in rats. Chokeberry juice in a dose-dependent manner reduced necrotic changes in rat livers and inhib- ited the increase of plasma aspartate transaminase and alanine transaminase activities, induced by CCl4. In 2005, Valcheva-Kuzmanova et al. inves- tigated the effect of aronia juice pretreatment on indomethacin-induced gastric mucosal damage. The authors found that the administration of chokeberry juice diminished the number, area and severity of indomethacin-induced mucosal lesions. Similarly, Matsumoto et al. (2004) observed that aronia extract and its hydrolysate had a protective effect in suppressing the area of gastric mucosal damage caused by the subsequent application of ethanol to <30% in treated rats compared to the control group. Jankowski et al. (2000) noticed that administration of aronia pigments to rats before intraperitoneal injections of Platelet Activating Factor and ceruleine had a suppressive effect on the development of acute experimental pancre- atitis in animal study. Other phenolics of aronia (catechins, quercetin etc.) manifest anti-bacterial, anti-fungal, anti-viral and anti-mutagenic activity. Chokeberry anthocyanins exert protective effects towards UV radiation, thus they are of interest in cosmetic production. The phenolic content of plants depends, both quantitatively and qualitatively, on genetic informa- tion (species, variety per cultivar). The environment also plays an important role in determining the phenolic profile of fruits and vegetables. Extrinsic factors such as geographical conditions (Schaffer et al. 2005), climate, season, light, temperature, and degree of ripeness strongly influence phe- nolic synthesis in plants (Aherne and O’Brian 2002). There are opposite observations referring to cultivation techniques applied. Carbonaro et al. (2002) noticed an improvement in the antioxidant defence system of the plant (peach and pear) as a possible consequence of the agronomic cultiva- tion practices; whereas, Häkkinen and Törrönen (2000) found similar contents of phenolics in three strawberry cultivars grown by conventional and organic farming. Among all common fruits in the diet, berries (es- pecially those with dark blue or red colors) have the highest antioxidant capacities (Wu et al. 2004a). In recent years, the potential of aronia fruits has been recognized as a source of food colorants and valu- able phytonutrients (Slimestad et al. 2005). Choke- berries have specific astringent taste, and thus are not favoured as table fruits. Mineral fertilization, among other agronomic practices, may influence the nutritive value and the content of biologically active compounds of the fruits. Cultivation methods can be used to enhance the content of phenolics and pigmentation of fruits, although the information on this topic is very scarce and often contradictory (Tomás-Barberán and Espin 2001). Severe Mn deficiency affects the stability of the chloroplast lamellar systems thus reducing photo- synthesis and carbohydrate production in leaves (Pearson and Rengel 1997). Manganese is available to the plant in acidic and waterlogged soils (Shi et al. 2005); deficiency of Mn occurs in neutral and alkaline reaction soils. The most rapid and efficient way to prevent and/or correct Mn deficiency is fo- liar application of solutions containing inorganic or organic Mn (Papadakis et al. 2005). Silicon (Si) is involved in enhancing disease resistance of plants. Moreover Si was found to alleviate Mn toxicity in cucumber plants treated with an excess of Mn (Shi et al. 2005). Potassium (K) fertilization has been widely used in agronomic practice to increase sucrose content in sugar beets and starch content in potatoes and grains. Chapagain and Wiesman (2004) noticed higher glucose content in tomato fruits treated with monopotassium phosphate compared to control. Astringent, bitter, and sour tastes of chokeberries result from high content of chlorogenic acids and procyanidins. Awad and de Jager (2002) found negative correlation between N (nitrogen), K and chlorogenic acid concentration in the skin of ‘Elshof’ apples. In recent literature, data referring to influence of mineral fertilization on chemical composition of aronia fruits, especially phenolics, is scarce (Jeppsson 2000). In this study, we estimated whether manganese (Mn), Alkalin (N, K and Si), and combined fertiliza- A G R I C U L T U R A L A N D F O O D S C I E N C E Skupień, K. & Oszmiański, J. Mineral fertilization of chokeberry fruit 48 A G R I C U L T U R A L A N D F O O D S C I E N C E Vol. 1 (2007): 46–55 tion (Mn + Alkalin) influence the content of basic nutritive compounds and improve sensory attributes (increase sugar content), and thereby the nutritive value of chokeberries. Moreover, we investigated whether applied fertilization may affect the synthe- sis of phenolic compounds (imparting astringency) and influence antioxidant activity of aronia fruit. Material and methods Experimental Chokeberry fruits were obtained from the Experi- mental Station at Rajkowo near Szczecin, north- west Poland. The plantation was established on grey brown podsolic soil originated from medium boulder clay. Rooted cuttings of aronia were planted in 1995. In October 2003, shrub amelioration was performed by rejuvenate cutting and only 5 shoots were left per plant. The experiment was carried out in 2005. Two doses of nitrogen, 40kg N ha–1 each, were used for basic fertilization. Phosphorus and potassium fertilizations were not applied because the soil was abundant in these elements (7.3 mg per 100 g and 48.0 mg per 100 g, respectively) and followed the recommendations for fruit orchards on clay soils. Soil reaction was neutral (pH = 7.1). Additionally, three different fertilizers were applied by foliar spray: chelate manganese [(Mn ethylene-diamine-tetraacetic acid (EDTA), dieth- ylene-triamine-pentaacetate (DTPA)] in a dose of 1 g l–1, Alkalin fertilizer (N, K and Si) in a dose of 5 ml l–1, and Mn + Alkalin (combined dose). Man- ganese fertilizer contained 14 g of manganese per 100 g, Alkalin contained 40 g N-NH2, 360 g K2O and 15 g SiO2 l–1. Adjuvat Superam 10 AL (10% salt of alkylbenzensulfonic acid and etoxyalkyl- phenols) was added by spraying, using a dose of 50 ml per 100 l. The fertilizers were purchased from Intermag, Poland. The sprays were performed six times on 18, 24 and 31 May and 7, 16 and 30 June 2005. Every treatment comprised of five bushes in three replicates. Control plants were sprayed with Superam 10 AL diluted in distilled water; whereas, the basic nitrogen fertilization was applied in the same dose and term as for fertilizer treatments. From florescence to harvest, drip irrigation in a cycle of 3 hs per day was used when the length of drought lasted for more than seven days. Total water consumption was 1000 l per plantation. Weed control was performed chemically between rows [Kerb (Dow AgroSciences Poland) + Azotop before vegetative season] and using Roundup within rows (before flowering). Because Aronia melanocarpa plants are resistant to pathogen diseases, no chemi- cal protection was needed. The fruits – one-kg bulk samples – were collected in full-ripeness stage on 7 September. Plant material Dry weight, soluble solids, titratable acidity, total sugar, reducing sugar, vitamin C, total polyphenol content, and measurements for 2, 2-diphenyl-1- picrylhydrazyl radical (DPPH˙) % inhibition were performed on fresh fruits packed in polyethylene bags and stored overnight at 5°C. Phenolic compo- sition was determined by high-performance liquid chromatography (HPLC) on fruits packed as above and stored for 5 days at 5°C. Chemicals All the chemicals used for analyses were of ana- lytical grade and purchased from POCh (Gliwice, Poland). High performance liquid chromatography chemicals were of HPLC purity and purchased from Sigma-Aldrich (USA). Analyses Dry weight of fruit was determined with a gravi- metric method (an aliquot ~5 g of fruit tissue was dried at 105°C to constant weight) according to Polish standard (PN-90/A-75101/03). Soluble solids content was determined with an Abbé refractometer (PN-90/A-75101/02). Titratable acidity was determined by titration of a water extract of chokeberry homogenate with Vol. 16 (2007): 46–55 49 A G R I C U L T U R A L A N D F O O D S C I E N C E 0.1 N NaOH to the end point of pH 8.1 (measured with an Orion 720 A pH meter; Orion Research Incorporated, Boston, MA, USA) according to PN-90/A-75101/04. Total sugar and reducing sugar content were determined according to the Loof-Schoorl method. Sucrose content was calculated according to the relationship: sucrose = (total sugar – reducing sugar) × 0.95. Vitamin C was determined as L-ascorbic acid using the Tillmans method (titration of an 10 ml aliquot of oxalic acid berry extract by means of 0.025% 2,6-dichlorophenol-indophenol according to PN-90/A-75101/1) prior to adsorption of pig- ments into C18 Sep-Pak cartridge (Waters Associ- ates, Milford, MA, USA) from an acid extract of chokeberry homogenate. Total polyphenol content in the methanol (70%) extracts was estimated according to Singleton and Rossi (1965) with the Folin-Ciocalteu reagent. The data is expressed as mg of gallic acid equivalents (GAE) per 100 g of fruit tissue. DPPH-radical percent inhibition The DPPH was obtained from Sigma-Aldrich Co. (USA). Scavenging effect of chokeberry fruit on DPPH-radical was determined according to the method of Yen and Chen (1995) with some modi- fication. The fruits were homogenised with a food processor (Predom Zelmer, Poland) and the juice was squeezed through cheese cloth. Further, the raw juice was centrifuged at 8,000 × g (centrifuge MPW-250, MPW Med. Instruments, Poland) and diluted 400 times in methanol (32.04 g mol–1). A 1 ml aliquot of diluted juice was added to 3 ml of methanol and 1 ml of DPPH solution (0.012 g DPPH per 100 ml). The mixture was shaken and left at room temperature for 10 min; the absorbance was measured spectrophotometrically at 517 nm. DPPH percent inhibition was calculated according to Rossi et al. (2003) from the formula: Percent inhibition = 100 – [(At/Ar) × 100], where At – ab- sorbance of test solution and Ar – absorbance of reference solution. HPLC analyses Cooled berries were homogenized with DIAX 900 (Heidolph, Germany) homogenizer. Aliquots of 1 g of fruit tissue were extracted with methanol acidi- fied with 0.1% HCl. The extraction was performed in an ultrasonic bath for 20 min. This has proved to be adequate for complete extraction. The slurry was centrifuged at 19000 × g for 10 min and the supernatant was used for HPLC analysis. The su- pernatant was recovered and filtered through a 0.45 mm cellulose syringe filter before analysis. The HPLC analyses of (-)epicatechin, hydroxy- cinnamates, anthocyanin glycosides and flavonol glycosides were carried out on a HPLC apparatus consisting of a Merck-Hitachi L-7455 diode ar- ray detector (DAD) and quaternary pump L-7100 equipped with D-7000 HSM Multisolvent Delivery System (Merck-Hitachi, Tokyo, Japan). The separa- tion was performed on a Synergi Fusion RP-80A 150 × 4.6 mm (4mm) Phenomenex (Torrance, CA USA) column. Column oven temperature was set at 30°C. The mobile phase was composed of solvent A (2.5% acetic acid, pH 2.9) and solvent B (aceto- nitrile). The program began with a linear gradient from 0% B to 25% B (0–36 min), followed by washing and reconditioning the column. The flow rate was 1 ml · min–1 and the runs were monitored at the following wavelengths: (-)epicatechin at 280 nm, chlorogenic and neochlorogenic acid at 320 nm, flavonol glycosides at 360 nm, and an- thocyanin glycosides at 520 nm. The Photo Diode Array spectra were measured over the wavelength range 240–600 nm in steps of 2 nm. Retention times and spectra were compared to those of pure stan- dards within 200–600 nm. Standards of cyanidin 3-galactoside and chlorogenic acid were obtained from Polyphenols Laboratories (Norway) while rutin from Sigma-Aldrich and chlorogenic acid from Extrasynthese (France). Eriodictyol-7-gluc- uronide was identified according to the literature data (Justesen et al. 1998). Skupień, K. & Oszmiański, J. Mineral fertilization of chokeberry fruit 50 A G R I C U L T U R A L A N D F O O D S C I E N C E Vol. 1 (2007): 46–55 Proanthocyanidin analysis The direct thiolysis on freeze-dried berries was performed. Powders were precisely weighed (30–50 mg) in 1.5 ml Eppendorf vials, acidified methanol (3.3% v/v, 400 ml) and toluene alpha-thiol (5% in methanol, 800 ml) were added. The vials were closed and incubated at 40°C for 30 min with agita- tion on vortex every 10 min. Then, the vials were cooled in ice water and centrifuged immediately at 4°C in a refrigerated centrifuge for 10 min. Samples were stored at 4°C until RP-HPLC analysis. Each sample was performed in triplicate. The thiolysis products were separated on Merck Purospher RP 18 end-capped column 250 × 4 mm, 5mm (Merck, Darmstadt, Germany). The HPLC apparatus employed was a Waters (Milford, MA, USA) system (DAD and Scanning Fluorescence detectors). The solvent system was composed of solvent A (aqueous acetic acid, 2.5% v/v) and solvent B (acetonitrile). The following gradient was applied: initially 3% B; 0–5 min 9% B linear; 5–15 min 16% B linear; and 15–45 min 50% B linear, followed by washing and reconditioning the column. The flow rate was 1 ml · min–1 and oven temperature was 30°C. Compounds for which reference standards were available were identified on chromatograms according to their retention times and UV-visible spectra. The fluorescence detection was recorded at excitation wavelength 278 and emission wavelength 360 nm. The calibra- tion curves (based on peak area at 280 nm) were established using flavan-3-ol and benzylthioether standards. The average degree of polymerization was measured by calculating the molar ratio of all the flavan-3-ol units (thioether adducts + terminal units) to (-)epicatechin and (+)catechin correspond- ing to terminal units. Statistical analysis Statistical analysis was done by using Statistica software package version 7.1 (Statsoft, Poland). The data were subjected to one-way analysis of variance. Values of P < 0.05 (Tukey multiple com- parison test) were considered significant. Results and discussion Data presenting the basic chemical composition of treated and untreated chokeberry fruits is listed in Table 1. Chokeberry fruits in control treatment (basic ni- trogen + Superam) showed significantly higher dry weight content compared to berries of Mn treatment (by 13%), higher by 9% than that of Mn + Alkalin treatment, and by 6% compared to that of Alkalin treatment. The dry weight content obtained in our experiment (30.76–26.67%) exceeds the values reported by Kleparski and Domino (1990). In their experiments, dry weight content varying from 17% to 26% was observed. Berries of control treatment showed also the highest soluble solids content, surpassing treated variants by 10% (Mn), 9% (Mn + Alkalin) and 5% (Alkalin). However, the differ- ences were not statistically significant. Soluble sol- ids content ranged from 21.7 0Bx (Mn) to 24.1 0Bx (control). The values were much higher compared to that determined by Jeppsson (2000) 16.3–17.8 0Bx. In our experiment, favourable weather condi- tions occurred during fruit ripening (warm, sunny August and September) and this could stimulate synthesis of different compounds (mainly sugars) which yield soluble solids content. The weather factor may have considerably contributed to the differences observed between the two studies. On the other hand, all the fertilizer treatments applied in this experiment caused the increase of total acid content in the fruits. Berries obtained from Alkalin and manganese treatments showed sig- nificantly higher titratable acidity than control ones (by 11% and 9%, respectively) whereas the fruit of combined Mn + Alkalin fertilization exhibited total acidity higher by 5%, in comparison to control chokeberries. Jeppsson (2000) noted that increased rates of N, P, and K fertilization reduced total acid- ity in chokeberries. In our experiment, Alkalin (N, K, and Si), Mn, and combined fertilization (Mn + Alkalin) exerted opposite effect. Total sugar content estimated in aronia berries was high (19.32–20.92 g per 100 g), compared to 6.2–10.8 g per 100 g reported by Kleparski and Domino (1990). Alkalin fertilization is recom- Vol. 16 (2007): 46–55 51 A G R I C U L T U R A L A N D F O O D S C I E N C E mended to increase sugar content in the yield (ef- fect of K). Similarly, Mn activates many enzymes involved in sugar synthesis. Mn shortage results in drastic sugar content decline (Starck 2002). In contrast to our expectations, significantly higher total sugar content was found in control fruits. Fruits obtained from Alkalin treatment displayed a decrease of total sugar by 1.60 g per 100 g, and berries from Mn + Alkalin treatment by 1.10 g per 100 g compared to control ones. Further, combined treatment (Mn + Alkalin) caused significant lower- ing of reducing sugar content (by > 1 g per 100 g) compared to other treatments. All these changes were reflected in sucrose content. Similar level of sucrose was observed in control berries and that of combined treatment (Mn + Alkalin) ~ 1.5 g per 100 g, while no sucrose was measured in manganese fertilizer treatment and only negligible in Alkalin treatment. Chokeberry fruits do not contain considerable amounts of vitamin C. According to Kalemba et al. (1995), vitamin C content in aronia ranges from 14 to 28 mg per 100 g fresh weight. The content of ascorbic acid found in the study was very low 1.9–8.4 mg per 100 g. The most distinct differences were determined between control fruits and berries of fertilizer treatments. Control berries showed significantly more ascorbic acid (~ 4-times) than fruit of Mn treatment, and 2.5 and 2.2-times more ascorbic acid than berries of Alkalin and combined treatment (Mn +Alkalin), respectively. Total polyphenol content in chokeberries pre- sented in the literature on dry weight basis varied from 40.1 mg GAE per g – 4210 mg GAE per 100 g (Kähkönen et al. 1999, 2001, respectively) to 7849.21 mg per 100 g (lyophilized berries) (Oszmiański and Wojdylo 2005). Benvenuti et al. (2004) reported total polyphenol content for fresh aronia fruit 690.2 mg per 100 g. In this study, in all tested treatments, total polyphenol content was >2000 mg per 100g (according to GAE and HPLC). Environmental and agronomic conditions and date of harvest may have contributed to the differences observed between the two studies. Control choke- berries displayed significantly higher amount of total polyphenol (2377.1 mg GAE per 100 g per fresh weight) compared to the fruit of fertilizer treatments. Chokeberries of Mn treatment had by 195 mg per 100 g, berries of Alkalin treatment by 212 mg per 100 g and fruit of Mn + Alkalin treatment by 272 mg per 100 g less phenolics than control ones. High content of polyphenols is Table 1. Chemical composition and 2, 2-diphenyl-1-picrylhydrazyl radical (DPPH˙) % inhibition of chokeberry fruit in different fertilization treatments. Characteristics a Control Manganese Alkalin Manganese + Alkalin Dry weight (%) 30.76a 26.67b 28.76ab 28.06ab Soluble solids (0 Bx) 24.1a 21.7a 23.0a 21.9a Titratable acidity (g citric acid per 100 g) 0.493b 0.535a 0.548a 0.519ab Total sugar (g per 100 g) 20.92a 19.36b 19.32b 19.82b Reducing sugar (g per 100 g) 19.35a 19.36a 19.27a 18.21b Saccharose (g per 100 g) 1.50a 0.00b 0.05b 1.53a Vitamin C (mg per 100 g) 8.4a 1.9b 3.4b 3.9b Total polyphenol (mg gallic acid per 100 g) 2377.1a 2181.9b 2165.2b 2105.0b DPPH˙ % inhibition b 38.1a 31.6a 29.8a 31.6a a Values are the mean of three determinations and are expressed per fresh weight. Different letters in the same row indi- cate significant differences at P < 0.05. b DPPH-radical % inhibition was calculated on the basis of DPPH˙ scavenging activity of chokeberry juice diluted 400 times in reaction mixture consisting of: 1 ml of diluted juice + 3 ml of absolute methanol + 1 ml of DPPH˙ solution. Skupień, K. & Oszmiański, J. Mineral fertilization of chokeberry fruit 52 A G R I C U L T U R A L A N D F O O D S C I E N C E Vol. 1 (2007): 46–55 associated with high activity of L-phenylalanine ammonia-lyase (PAL), a key enzyme in the bio- synthesis of phenolic compounds in fruit tissues of several species (Cheng and Breen 1991). Carver et al. (1998) reported a higher increase in PAL activity in Si-deprived plants. The authors suggested that this rise in PAL activity is to compensate the lack of Si, and this compensation contributed to pathogen resistance in Si-deficient oat leaves. DPPH˙ % inhibition Antioxidant properties of aronia fruits are evidenced in the literature. Nakajima et al. (2004) estimated DPPH-radical scavenging activity of aronia extract nearly identical to bilberry extract, though weaker than that of Trolox. Oszmiański and Wojdylo (2005) determined DPPH˙ quenching activity for aronia lyophilized fruits 279.38 μM Trolox per 100 g on dry weight basis. Matsumoto et al. (2004) showed that the chokeberry red pigment fraction scavenged >44% of DPPH-radicals at a concentration 25 μg ml–1 compared to the control solution. In this study, DPPH˙ % inhibition of aronia juice (diluted 1: 400) ranged from 29.8 to 38.1%, but the variants did not vary significantly. The highest DPPH˙ % inhibi- tion was observeded for the control berries which showed the highest total polyphenol content (as GAE and HPLC). The results obtained by Yilmaz and Toledo (2004) indicated that polymeric pro- cyanidins accounted for a most of the antioxidant activity of grape seeds. In our experiment, it was confirmed for the fruit from control group, which exhibited high procyanidin content with the highest degree of polymerization (Table 2). On the other hand, the same DPPH˙ % inhibition was found for the berries of Mn and Mn + Alkalin treatments (31.6%), though chokeberries of combined treat- ment showed procyanidin content almost as high as control berries (1645.57 mg per 100 g), but with the lowest degree of polymerization (42), while berries of Mn treatment displayed the lowest procyanidin content (1426.66 mg per 100 g), but with higher degree of polymerization (52) compared to fruit of combined treatment (Table 2). Table 2. Phenolic compounds pattern of chokeberry fruits in different fertilization treatments. Items a Control Manganese Alkalin Manganese + Alkalin Chlorogenic acid 110.62a 83.97c 94.34b 91.50b Neochlorogenic acid 99.76a 79.09b 82.42b 74.60c Nonidentified phenolic acid (r.t. 16.4 min) 6.08b 13.88a 0.00c 0.00c Nonidentified phenolic acid (r.t. 35.4 min) 7.69b 87.27a 0.00c 0.00c (-)epicatechin 32.18a 15.76c 17.47b 17.35b Polymeric procyanidins 1645.64a 1426.66b 1616.50a 1645.57a Degree of polymerization 59a 52b 45c 42d Quercetin 3-rutinoside b 6.14a 5.50b 6.27a 6.02a Quercetin 3-galactoside 13.18b 9.91c 14.57a 13.08b Quercetin 3-glucoside 8.06b 7.07c 8.87a 7.83b Quercetin 3-vicianoside 5.38a 3.84c 5.41a 5.12b Quercetin 3-robinobioside 5.42b 5.66ab 5.76a 5.51ab Eriodictyol 7-glucouronide 24.41ab 22.11b 26.43a 23.46ab Cyanidin 3-galactoside 515.22a 512.93a 477.77b 473.54b Cyanidin 3-glucoside 21.51a 18.15c 19.81b 19.36b Cyanidin 3-arabinoside 238.73b 249.46a 223.44c 220.27c Cyanidin 3-xyloside 33.39a 33.21a 30.27b 30.63b Total 2773.41a 2574.47b 2629.33b 2633.84b a Values are the mean of three determinations and are expressed as mg per 100 g of fresh weight. b Rutin was used as an equivalent for quantifications. Vol. 16 (2007): 46–55 53 A G R I C U L T U R A L A N D F O O D S C I E N C E Phenolic profile The results of the qualitative and quantitative composition of phenolic compounds in choke- berry fruits are presented in Table 2 and for con- trol treatment in Figure 1. Chlorogenic acid and neochlorogenic acid were the two dominating phenolic acids identified in aronia fruits. Phenolic acids, among other phenolic compounds, impart the sour and bitter taste and astringent effect while consuming fruit. Oszmiański and Wojdylo (2005) found in lyophilized chokeberries 301.85 and 290.81 mg per 100 g per dry weight chlorogenic and neochlorogenic acid, respectively. Slimestad et al. (2005) estimated in fresh aronia fruit higher amount of neochlorogenic acid (123 mg per 100 g) than chlorogenic acid (61 mg per 100 g). In our study, chlorogenic acid amounts were higher than neochlorogenic acid. Significantly higher content of chlorogenic and neochlorogenic acid was found in control berries (110.62 and 99.76 mg per 100 g fresh weight, respectively). Manganese treatment lowered the amount of chlorogenic acids by 23%, while Alkalin usage caused a 16% decline. Two unidentified phenolic acids with retention times of 16.4 min and 35.4 min were determined only in control and Mn treated chokeberries. Especially high levels of the latter acid were observed in Mn treated fruits. The contribution of both unidentified phenolic acids in total phenolic acid content in these berries was 38%. Significantly higher level of (-)epicatechin was found in control fruits compared to fertilizers treated berries. Polymeric flavan-3-ols of Aronia melanocarpa are mainly composed of (-)epicat- echin (Fig. 1). Our results confirm previous data obtained by Oszmiański and Wojdylo (2005) that polymeric procyanidins constitute the major class of phenolics in chokeberries. Manganese treated fruits had significantly lower (-)epicatechin and polymeric procyanidin content. The size of proan- thocyanidin molecules can be described by their degree of polymerization (DP) (Wu et al. 2004b). Degree of procyanidins polimerization ranged from 42 (Mn + Alkalin) to 59 (control), and the values were lower than determined previously by Oszmiański and Kucharska (1995) 70. Wu et al. (2004b) determined much lower total procyanidin concentrations in chokeberries (663.7 mg per 100 g of fresh weight) compared to our results Fig. 1. Chromatogram HPLC (280 nm) of Aronia melanocarpa (Michx) Elliot fruit extract (con- trol variant). Neochlorogenic acid – 14.34 min, (-)epicatechin – 18.69 min, chlorogenic acid – 20.33 min, cyanidin 3-galactoside – 22.13 min, cyanidin 3-glucoside – 23.30 min, cyanidin 3-arabinoside – 24.58 min, cyanidin 3-xyloside – 27.60 min, eriodictyol 7-gluc- uronide – 30.93 min, quercetin 3-galactoside – 32.62 min. 32 ,6 2 30 ,2 227 ,6 0 23 ,3 0 24 ,5 8 22 ,1 3 20 ,3 3 18 ,6 9 14 ,3 4 3, 91 3, 29 3, 60 30 ,9 3 Intensity (Au) Retention Time (min) 0.70 0.65 0.60 0.55 0.50 0.45 0.40 0.35 0.30 0.25 0.20 0.15 0.10 0.05 0.00 -0.05 0 5 10 15 20 25 30 35 Skupień, K. & Oszmiański, J. Mineral fertilization of chokeberry fruit 54 A G R I C U L T U R A L A N D F O O D S C I E N C E Vol. 1 (2007): 46–55 (1645.64–1426.66 mg per 100 g). The authors found that polymers with degree of polymeriza- tion > 10 constituted predominating subclass of procyanidins (542.6 mg per 100 g of fresh weight). According to Ursini et al. (2001), procyanidins are considered to be superior antioxidants compared to their corresponding monomers. The content of flavonols (quercetin glycosides) ranged from 31.54 (Mn variant) to 40.88 mg per 100 g (Alkalin), and their participation in total polyphenol content was rather low compared to polymeric procyanidins, cyanidins, and chlorogenic acids. Quercetin 3-galactoside was the main gly- coside between quercetin derivatives. Slimestad et al. (2005) determined higher amount of flavonols in chokeberry fruits exceeding 71 mg per 100 g fresh weight. In chokeberry fruits, the anthocyanins are the mixture of four cyanidin glysosides: 3-galactoside, 3-arabinoside, 3-glucoside, and 3-xyloside. Simi- larly, as observed by Wu et al. (2004b) and Slimes- tad et al. (2005), cyanidin 3-galactoside turned out to be the dominating glycoside of cyanidin, but its content in our experiment (515.22–473.54 mg per 100 g) was much higher than estimated by the above authors (315 mg per 100 g). The highest content of cyanidins was observed in Mn treated variant (813.75 mg per 100 g), and the lowest in Mn + Alka- lin combination (743.80 mg per 100 g). Our obser- vations corroborate previous data (Oszmiański and Wojdylo 2005) that anthocyanins constitute second main group of phenolics in aronia fruit. The presence of flavanone eriodictyol 7- glucuronide in chokeberries was first reported by Slimestad et al. (2005). In our experiment, berries of Alkalin treatment showed slightly higher (by 2–4 mg per 100 g) eriodictyol content compared to other variants. Conclusions Aronia melanocarpa within Rosaceae family is one of the species with lower cultivation requirements. In addition to natural fertility of the soil (P and K) and applied nitrogen fertilization, extra fertilization with Mn, Alkalin (N, K and Si), and Mn + Alkalin caused multi-directional alterations in the content of nutritive and biologically active compounds. Usage of manganese, Alkalin, and manganese + Alkalin significantly lowered total sugar and total polyphenol content in aronia fruit. Berries treated with Alkalin showed negligible sucrose content. No sucrose was found in chokeberries treated with manganese. On the other hand, all the fertil- izers increased titratable acidity in chokeberries. Regarding phenolic compounds, all the treatments caused lowering of chlorogenic and neochlorogenic acids, reduced (-)epicatechin content and degree of procyanidins polymerization compared to control fruit. Moreover, Mn treated fruit had significantly higher content of two unidentified phenolic acids with retention times 16.4 min. and 35.4 min com- pared to the control; whereas, these acids were not detected in berries treated with Alkalin and Mn + Alkalin. Although still preliminary, these results have provided evidence that mineral fertilization may in- fluence the chemical composition of aronia fruits. Acknowledgements. 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