Microsoft Word - Sák et al. final.doc 162 Nova Biotechnologica et Chimica 13-2 (2014) DOI 10.1515/nbec-2015-0006  University of SS. Cyril and Methodius in Trnava ELICITATION OF PHENOLIC COMPOUNDS IN CELL CULTURE OF Vitis vinifera L. BY Phaeomoniella chlamydospora MARTIN SÁK1,2, IVANA DOKUPILOVÁ1,2, DANIEL MIHÁLIK3,4, JANA LAKATOŠOVÁ1,2, MARCELA GUBIŠOVÁ3,5, JÁN KRAIC3,6* 1Research Institute of Viticulture and Enology, Hlavná ulica 326, SK-90041, Rovinka, Slovak Republic 2Faculty of Chemical and Food Technology, Slovak University of Technology, Radlinského 9, SK-81237 Bratislava, Slovak Republic 3Research Institute of Plant Production, Bratislavská cesta 122, 921 68, Piešťany, Slovak Republic 4Institute of High Mountain Biology, University of Žilina, SK-05956 Tatranská Javorina 7, Slovak Republic 5Department of Botany and Genetics, Faculty of Natural Sciences, Constantine The Philosopher University, Tr. A. Hlinku 1, SK-94974 Nitra, Slovak Republic 6Department of Biotechnology, Faculty of Natural Sciences, University of SS. Cyril and Methodius, J. Herdu 2, SK-91701 Trnava, Slovak Republic (kraic@vurv.sk) Abstract: The in vitro cell cultures of Vitis vinifera L. cv. St. Laurent were treated with two elicitors - synthetic methyl jasmonate and natural, prepared from grapevine plant infected with the Phaeomoniella chlamydospora, the agent causing the Esca disease of grapevine. Efficiency of phenolic compounds production after elicitation of cell culture was analysed immediately after treatment (15 min, 30 min, 60 min) and later (after 24, 48, and 72 hours). The cell growth and content of phenolic compounds (+)-catechin, (-)-epicatechin, p-coumaric acid, syringaldehyde, rutin, vanillic acid, and trans-resveratrol were analysed in cultivated cells as well as in cultivation medium. Pch-treatment increased production of total polyphenols the most significantly 15 min after the elicitation and in optimal time was 2.86 times higher than in non- elicited culture and 1.44 times higher than in MeJa induced cell culture. Abstract: Vitis vinifera L., Phaeomoniella chlamydospora, phenolics, cell culture, elicitation 1. Introduction Plant cells cultivated in vitro could potentially be competitive systems for effective production of marketable secondary metabolites possessing biological activities which can not be produced by microorganisms or by chemical synthesis. Production of such molecules and compounds has been demonstrated in different plant species (MULABAGAL and TSAY, 2004) as well as by in vitro cultivation of organs, tissues, or cells (reviewed by RAO and RAVISHANKAR, 2002). An overproduction of some secondary metabolites, in the comparison with level in intact plants, was achieved in in vitro systems, e.g. production of rosmarinic acid in cell cultures of Salvia officinalis L. and Coleus blumei (ULBRICH et al., 1985; HIPPOLYTE et al., 1992), antraquinones in cell cultures of Morinda citrifolia L. (ZENK et al., 1975). The cell cultures in vitro have been used advantageously in the production of substances such as vincristine, Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 16.01.20 16:35 UTC Nova Biotechnologica et Chimica 13-2 (2014) 163 vinblastin, taxol, camptothecin, ellipticine, and others (RAO and RAVISHANKAR, 2002). The most attractive compounds among them, from the commercial point of view, are plant-derived pharmaceuticals (XU et al., 2011; ABDULLAHIL BAQUE et al., 2012) and food additives (JIMÉNEZ-APARICIO et al., 1999; MATKOWSKI, 2008). The plant biotechnology tools are instruments also for industrial exploitation of plant cell cultures, but the economical point of view is very important and always predominant. Moreover, efficient in vitro production of secondary metabolites needs high effective systems with optimized cultivation conditions, methods of extraction of secondary metabolism products as well as specific factors improving production such as biotic and abiotic elicitors (DÖRNENBURG and KNORR, 1995; ZHAO et al., 2005), or simulation of nutritional deficiency of cells (TAVARES et al., 2013). The grapevine (Vitis vinifera L.), especially ripe berries, contain many phenolic compounds. LIANG et al. (2011) identified 36 polyphenols including anthocyanins, flavanols, flavonols, hydroxycinnamic derivatives, and hydroxybenzoic acid, and 48 different polyphenols in berries of wild Vitis species (LIANG et al., 2012). Grapevine phytochemicals consumed in berries and wine are associated with the positive health benefits and relevant dietary style (IRITI and FAORO, 2006). They contain compounds with antioxidant and antibacterial activities, compounds decreasing cholesterol level, protecting against reactive oxygen species inducing DNA damages, modulating glucose uptake, and anticancer activities (WILLIAMSON and CARUGHI, 2010; DELGADO ADÁMEZ et al., 2012; APOSTOLOU et al., 2013). Aqueous extracts from grapevine leaves also contain phenolic compounds with antioxidant activity (FERNANDES et al., 2013). Production of secondary metabolites in the grapevine cell cultures in vitro has been presented in many studies and most of these experiments have been focused to improvement of in vitro production by adding of precursors, by genetic transformation of plants, or by elicitation. Application of specific precursors and genetic transformations are expensive and laborious, therefore the most common approach is the induction of defence mechanisms by elicitors which are signalling triggers of secondary metabolite formation (MULABAGAL and TSAY, 2004). ZHANG et al. (2002) induced biosynthesis of anthocyanins by irradiation and by jasmonic acid, CAI et al. (2012) enhanced production of anthocyanins and resveratrol by indanoyl isoleucine, N-linolenoyl-l-glutamine, and insect saliva. SAW et al. (2012) stimulated synthesis of anthocyanins by ethephon and pulsed electric field. Also other elicitors were tested, well-known and frequently used are synthetic methyl jasmonate and salicylic acid. Infections of plants by pathogens induce upregulation of plant defence mechanisms and production of anti-pathogen phenolic compounds. The fungal pathogen Phaeomoniella chlamydospora (Pch), associated with the Esca-disease, also increased accumulation of phenolic components in infected young grapevine plants (MARTIN et al., 2009). BRUNO and SPARAPANO (2006) applied three Esca-disease associated fungi - Phaeomoniella chlamydospora, Togninia minima, and Fomitiporia mediterranea as elicitors in dual in vitro cultivation with grapevine calluses. Each fungus reduced growth of calluses but only T. minima induced higher production of total phenols in callus cultures. New, effective, and especially natural elicitors could improve production of secondary metabolites in vitro. Therefore ESCORIAZA et al. Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 16.01.20 16:35 UTC 164 Sák, M. et al. (2013) treated grapevine (cv. Chardonnay) callus and cell cultures by the fungus Phaeoacremonium parasiticum associated with disease known as "hoja de malvón". The main response of plant tissue and cell defensive mechanism to the pathogen attack was increased terpene synthase activity and the production of nerolidon through de novo synthesis. Nerolidon is able to retard the fungal growth. The broader spectrum of elicitors, the more their combinations could be used. The species-specific elicitors are very perspective and also desired for the production of secondary metabolites used for plant protection. Natural elicitors should be also easily available for industrial (pharmaceutical, nutritional) applications. Therefore the aims of this study were to: i) study response of grapevine cell culture in vitro to the species- specific natural elicitor prepared from Phaeomoniella chlamydospora, ii) analyse time course of polyphenols production in elicited cell cultures, and iii) compare production of secondary metabolites in cell cultures treated with this elicitor and with widely used methyl jasmonate. 2. Material and methods The callus cultures were initiated from sterile leaf segments of grapevine (Vitis vinifera L.) cultivar St. Laurent. The leaf segments of size 1 cm2 were cultivated on the MURASHIGE and SKOOG medium (1962) with salt concentration reduced to one half (½ MS), containing 3 % sucrose, 0.7 % (w/v) agar, 0.1 mg/l NAA, and 0.2 mg/l BAP, pH 5.8, at 25±1°C under a photoperiod 16 h light/8 h dark and were transferred to fresh cultivation medium every 30 days. The cell cultures have been initiated from calluses in 100 ml Erlenmeyer flasks containing 40 ml of ½ MS liquid medium and cultivated with shaking (120 rpm) under the same conditions as callus cultures. Elicitor from the P. chlamydospora (Pch) was prepared from the cortex of grapevine plant infected by this fungus according to the procedure described by YU et al. (2001). Carbohydrate concentration was determined by the orcinol-sulfuric acid method (FRANCOIS et al., 1962). One-month old cell cultures were elicited by adding either of Pch (0.2 g/l) or MeJa (0.18 g/l) and cultivated for 1 hour at 50°C. Three parallel experiments for each cultivation were carried. Reagents of analytical grade were used for HPLC analysis including standards (+)- catechin, vanillic acid, (-)-epicatechin, p-coumaric acid, syringaldehyd, rutin, and trans-resveratrol (Sigma-Aldrich, St. Louis, USA). Reference standard solutions of polyphenols were prepared in 50 % aqueous methanol and stored at 4°C in the dark. Other used reagents were Evans blue, fluorescein diacetate (FDA), methyl jasmonate (MeJa), (Sigma-Aldrich, St. Louis, USA), 1-naphthaleneacetic acid (NAA), 6- benzylaminopurine (BAP), sucrose, agar, yeast extract, bacto-peptone, magnesium sulphate heptahydrate, potassium dihydrogen phosphate, sodium dodecylsulphate (SDS) (Sigma-Aldrich, St. Louis, USA). Water was prepared by the Direct-Q® 3 UV Water Purification System (Merck Millipore, Darmstadt, Germany). Polyphenols were extracted from the cultivation medium as well as from cells according to CAI et al. (2011) and LIU et al. (2010) and analysed by HPLC (Agilent 1200 Series system with photo-diode-array detector, operated under the Agilent ChemStation Software). The plant cell cultures were separated from cultivation Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 16.01.20 16:35 UTC Nova Biotechnologica et Chimica 13-2 (2014) 165 medium by vacuum filtration and fresh weight was determined. Dry cell weight was determined after freezing and lyophilisation. Homogenised dry cells were extracted with ethyl acetate and methanol (1:1, v/v) in the ratio 1:10 (w/v) overnight at the room temperature. Supernatant obtained after centrifugation (10 min at 10°C and 10 000 rpm) was collected and sediment was extracted for the second time. Pooled supernatants were evaporated by vacuum and diluted in 1.5 ml of methanol. Ten microliters of internal standard was added to samples for better identification. Samples were filtered with syringe membrane filters (0.45 µm) before HPLC analysis. Twenty microliters of sample were injected into the SupelcosilTM LC-18 column (250 mm × 4,6 mm, 5 μm particle size) warmed up to 30°C. Program of HPLC measurements was carried out according to RODRIGUEZ-BERNALDO de QUIRÓS et al. (2009). Total content of selected phenolic compounds was established as a sum of all quantified phenolic compounds. 3. Results and discussion The cell cultures of Vitis vinifera (cv. St. Laurent) were elicited with the commercially produced and commonly available MeJa or by elicitor prepared from grapevine plant infected by the fungus Phaeomoniella chlamydospora. This pathogen acts as an inducer of oxidative burst also in grapevine in vitro cell culture (LIMA and DIAS, 2012). Both used elicitors induced change in the colour of cell cultures from green to brown and inhibited cell growth as reported by TASSONI et al. (2005). The non-elicited (control) cell cultures had a higher mass of growing cells measured as fresh weight of cells. Growth of cells decreased during the first 24 hours in MeJa- and Pch-treated cell cultures and during the first 4 hours in non-elicited culture. After maximal decreasing of growth, i.e. 24 hours after elicitation, cell growth increased in both elicited cultures, nevertheless did not reach levels of non-elicited control culture (Fig. 1). Fresh weight of cells in culture elicited by MeJa after 72 hours of cultivation was similar to non-elicited culture. The lower fresh weight of cells elicited by Pch was caused probably by polypeptides secreted by P. chlamydospora inhibiting plant cell activities and growth (LUINI et al., 2010). P. chlamydospora cultivated in vitro produced large amounts of extracellular polysaccharides containing pullulans and addition of crude extract or filtrate from culture to grapevine calluses reduced their growth by 85 % (SPARAPANO et al., 2000). Another group of chemical compounds produced by P. chlamydospora are extracellular enzymes also inhibiting growth of calluses (SANTOS et al., 2006). The pH of the cultivation medium measured in samples for polyphenol analysis was almost constant in non-elicited sample (difference was ± 0.01) but decreased in average by 0.15 after each day of cultivation in elicited cultures. It can also reduce fresh cell weight as was described by TASSONI et al. (2005) after using of MeJa. The total contents of polyphenols produced in cell cultures in vitro were determined immediately after treatment by elicitors (15 min, 1 hour, and 4 hours after) and later (1, 2, and 3 days after), respectively (Fig. 1). The total content of polyphenols in non-elicited cultures increased continuously during 3 days but only moderately. The Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 16.01.20 16:35 UTC 166 Sák, M. et al. impact of both elicitors on polyphenols production was different. Their accumulation culminated 48 hours after MeJa addition then declined. The addition of the Pch elicited the highest polyphenolic production immediately (15 - 60 min) after treatment, after 4 hours were minimal, then increased again and 72 hours after treatment polyphenols production was higher than producing MeJa-elicited cells. Elicitation with the Pch had a biphasic mode of production with two maxima - immediately after elicitation and 3 days after. This could relate to a biphasic model of oxidative burst induced by extract of P. chlamydospora in grapevine cell suspension (LIMA et al., 2012), although the cultivar Vinhão used in their study responded slightly differently and they analysed other phenolic compounds – viniferin-type and piceid-type stilbenes. Time of accumulation and intensity of oxidative burst induced by pathogen can be very diverse, depending on plant species, used plant system, and resistance or tolerance level of specific cultivar. Fig. 1. The effect of PCh and MeJa elicitors on cell growth (curves with symbols ▲, □, ○) and the sum of detected phenolic compounds (columns). Individual polyphenols determined in cultivation medium were: (+)-catechin, (-)- epicatechin, vanillic acid, p-coumaric acid, syringaldehyde, trans-resveratrol, and rutin (Table 1). Significant differences in content of generated polyphenols were among the non-elicited and MeJa-elicited culture, between non-elicited and Pch-elicited cultures, as well as between MeJa- and Pch-elicited cultures. Polyphenols in the cultivation medium in non-elicited cultures were not detected. Very low quantity of polyphenols was released by MeJa-treated (vanillic acid, p-coumaric acid, and trans-resveratrol, Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 16.01.20 16:35 UTC Nova Biotechnologica et Chimica 13-2 (2014) 167 totally 1.27 mg/l) and Pch-treated cells (p-coumaric acid and trans-resveratrol, totally 0.53 mg/l) into cultivation medium 72 hours after elicitation. The vanillic acid and trans-resveratrol were present only in the cultivation medium. Table 1. Concentration of phenolics (±SD = standard deviation) in cultivation medium (A) (mg/l) and cultivated cells (B) (mg/g FW) (n.d. = not detected). Time [hours] Vanillic acidA p-Coumaric acidA MeJa PCh MeJa PCh 0.25 n.d. n.d. 0.07±0.01 0.07±0.02 1 n.d. n.d. 0.05±0.004 0.05±0.02 4 n.d. n.d. n.d. 0.05±0.04 24 0.33±0.02 n.d. n.d. 0.14±0.08 48 0.49±0.03 0.32±0.19 0.06±0.005 0.15±0.05 72 0.73±0.05 0.34±0.20 0.09±0.01 0.19±0.06 Control after 72 hours n.d. n.d. Time [hours] trans-ResveratrolA (+)-CatechinB MeJa PCh MeJa PCh 0.25 n.d. n.d. 0.58±0.03 2.74±0.18 1 0.36±0.004 n.d. 0.58±0.03 2.40±0.16 4 0.41±0.01 n.d. 0.66±0.04 0.46±0.02 24 0.43±0.01 n.d. 0.83±0.05 0.79±0.05 48 0.45±0.01 n.d. 1.48±0.05 0.92±0.05 72 0.45±0.01 n.d. 0.99±0.06 1.34±0.07 Control after 72 hours n.d. 0.82±0.05 Time [hours] (-)-EpicatechinB p-Coumaric acidB MeJa PCh MeJa PCh 0.25 0.43±0.01 0.73±0.03 n.d. 0.08±0.01 1 0.38±0.01 0.70±0.03 n.d. 0.07±0.01 4 0.43±0.01 0.26±0.01 n.d. 0.05±0.004 24 0.48±0.01 0.44±0.01 n.d. n.d. 48 2.05±0.02 0.69±0.02 n.d. 0.04±0.004 72 0.73±0.02 1.16±0.03 n.d. 0.08±0.01 Control after 72 hours 0.37±0.012 0.06±0.004 Time [hours] RutinB SyringaldehydeB MeJa PCh MeJa PCh 0.25 0.59±0.03 3.10±0.20 0.39±0.03 1.53±0.01 1 0.69±0.04 1.99±0.13 0.30±0.02 1.76±0.12 4 0.66±0.04 0.37±0.02 0.44±0.03 0.27±0.02 24 1.11±0.07 0.54±0.03 0.73±0.05 0.72±0.05 48 1.32±0.05 0.64±0.03 0.84±0.06 1.62±0.11 72 0.72±0.04 1.01±0.05 0.96±0.07 2.77±0.19 Control after 72 hours 0.69±0.04 0.92±0.06 Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 16.01.20 16:35 UTC 168 Sák, M. et al. The non-elicited cells contained (+)-catechin, (-)-epicatechin, p-coumaric acid, rutin, and syringaldehyde, totally 2.86 mg of phenolic compounds per gram of fresh weight of cell biomass (mg/g fwb). Addition of MeJa increased polyphenolic production, except the p-coumaric acid. The total amount of other four polyphenols at time of maximal production (48 hours after elicitation) was 5.69 mg/g fwb. The addition of Pch increased level of monitored polyphenols after 48 hours to 3.91 mg/g fwb, after 72 hours to 6.36 mg/g fwb, but the most significantly immediately, i.e. 15 min after elicitation, to 8.18 mg/g fwb (especially content of rutin to 3.1 mg/g fwb). Production of total polyphenols elicited by Pch at time of maximal production was 2.9 times higher than in non-elicited culture and 1.4 times higher than in MeJa-induced culture. Water content in cultivated cells in our cell cultures was 89.7 %. Lima et al. (2012) increased production of other types of phenolic compounds – piceid-type and viniferin-type stilbenes by MeJa and Pch elicitors, in comparison to non-treated control, 9-fold and 20-fold, respectively, but grapevine genotypes and evaluated phenolic compounds were different in their experiments. Polyphenols are synthesised during the normal development of grapevine plant. The basic effect of genotype on polyphenols production documented LIANG et al. (2011) in European Vitis vinifera L. germplasm as well as in accessions of wild Vitis species (LIANG et al., 2011). The plant genotype determines this production essentially nevertheless their synthesis correlates with response to different environmental biotic and abiotic factors. Plant tissues and cells cultivated in vitro, moreover affected by elicitors, can respond more sensitively. Extract from the P. chlamydospora used in our study represented effective elicitor for polyphenols production in grapevine cell cultivation system in vitro and the Vitis cell cultures might be a practicable system for biotechnological production of valuable compounds. The advantage of the Pch-originated elicitor is also lower price and less health hazard during operation. 4. Conclusions The present paper demonstrates enhancement of polyphenols production by application of synthetic and native elicitors – methyl jasmonate and extract from the grapevine pathogen Phaeomoniella chlamydospora, respectively. Different progress in elicitation of polyphenols production in cell culture was observed. Elicitation with MeJa culminated 48 hours after addition Pch elicited the highest polyphenols production immediately after treatment and again 72 hours later. Finally, it could be concluded that elicitation by Pch was more effective than by MeJa. Acknowledgments: This study was supported by the project no. APVV 0550-11 funded by the Slovak Research and Development Agency. References ABDULLAHIL BAQUE, M., MOH, S.-H., LEE, E.-J., ZHONG, J.-J., PAEK, K.-Y.: Production of biomass and useful compounds from adventitious roots of high-value added medicinal plants using bioreactor. Biotechnol. Adv., 30, 2012, 1255-1267. Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 16.01.20 16:35 UTC Nova Biotechnologica et Chimica 13-2 (2014) 169 APOSTOLOU, A., STAGOS, D., GALITSIOU, E., SPYROU, A., HAROUTOUNIAN, S., PORTESIS, N., TRIZOGLOU, I., WALLACE HAYES, A., TSATSAKIS, A.M., KOURETAS, D.: Assessment of polyphenolic content, antioxidant activity, protection against ROS-induced DNA damage and anticancer activity of Vitis vinifera stem extracts. Food Chem. Toxicol., 61, 2013, 60-68. BRUNO, G., SPARAPANO, G.: Effects of three esca-associated fungi on Vitis vinifera L.: I. Characterization of secondary metabolites in culture media and host responses to the pathogens in calli. Physiol. Mol. Plant Pathol., 69, 2006, 209-223. CAI, Z., KNORR, D., SMETANSKA, I.: Enhanced anthocyanins and resveratrol production in Vitis vinifera cell suspension culture by indanoyl-isoleucine, N- linolenoyl-l glutamine and insect saliva. Enzyme Microb. Technol., 50, 2012, 29- 34. CAI, Z., RIEDEL, H., SAW, N.M.M.T, MEWIS, I., REINEKE, K., KNORR, D., SMETANSKA, I.: Effects of elicitors and high hydrostatic pressure on secondary metabolism of Vitis vinifera suspension culture. Process Biochem., 46, 2011, 1411- 1416. DELGADO ADÁMEZ, J., GAMERO SAMINO, E., VALDÉS SÁNCHEZ, E., GONZÁLEZ-GÓMEZ, D.: In vitro estimation of the antibacterial activity and antioxidant capacity of aqueous extracts from grape-seeds (Vitis vinifera L.). Food Control, 24, 2012, 136-141. DÖRNENBURG, H., KNORR, D.: Strategies for the improvement of secondary metabolite production in plant cell cultures. Enzyme Microb. Technol., 17, 1995, 674-684. ESCORIAZA, G., SANSBERRO, P., GARCÍA-LAMPASONA, S., GATICA, M., BOTTINI, R., PICCOLI, P.: In vitro cultures of Vitis vinifera L. cv. Chardonnay synthesize the phytoalexin nerolidol upon infection by Phaeoacremonium parasiticum. Phytopath. Mediterranea, 52, 2013, 289-297. FERNANDES, F., RAMALHOSA, E., PIRES, P., VERDIAL, J., VALENTÃO, P., ANDRADE, P., BENTO, A., PEREIRA, J.A.: Vitis vinifera leaves towards bioactivity. Ind. Crops Prod., 43, 2013, 434-440. FRANCOIS, C., MARSHALL, R.D., NEUBERGER, A., Carbohydrates in proteins. 4. The determination of mannose in hen’s-egg albumin by radioisotope dilution. J. Biochem., 83, 1962, 335-341. HIPPOLYTE, I., MARIN, B., BACCOU, J.C., JONARD, R.: Growth and rosmarinic acid production in cell suspension cultures of Salvia officinalis L. Plant Cell Rep., 11, 1992, 109-112. IRITI, M., FAORO, F.: Grape phytochemicals: A bouquet of old and new nutraceuticals for human health. Med. Hypotheses, 67, 2006, 833-838. JIMÉNEZ-APARICIO, A., GUTIÉRREZ-LÓPEZ, G.: Production of food related colorants by culture of plant cells. In: SHAHIDI, F., KOLODZIEJCZYK, P., WHITAKER, J.R., LOPEZ MUNGUIA, A., FULLER, G. (Eds.) Chemicals via higher plant bioengineering (Advances in experimental medicine and biology). Springer Science + Business Media, New York, 1999, 195-210. LIANG, Z., OWENS, C.L., ZHONG, G.-Y., CHENG, L.: Polyphenolic profiles detected in the ripe berries of Vitis vinifera germplasm. Food Chem., 129, 2011, 940-950. Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 16.01.20 16:35 UTC 170 Sák, M. et al. LIANG, Z., YANG, Y., CHENG, L., ZHONG, G.-Y.: Polyphenolic composition and content in the ripe berries of wild Vitis species, Food. Chem., 132, 2012, 730-738. LIMA, M.R.M., DIAS, A.C.P.: Phaeomoniella chlamydospora - induced oxidative burst in Vitis vinifera cell suspensions: Role of NADPH oxidase and Ca2+. J. Phytopathol., 160, 2012, 129-134. LIMA, M.R.M., FERRERES, F., DIAS, A.C.P.: Response of Vitis vinifera cell cultures to Phaeomoniella chlamydospora: changes in phenolic production, oxidative state and expression of defence-related genes. Eur. J. Plant Pathol., 132, 2012, 133-146. LIU, W., LIU, C., YANG, C., WANGA, L., LI, S.: Effect of grape genotype and tissue type on callus growth and production of resveratrols and their piceids after UV-C irradiation. Food Chem., 122, 2010, 475-481. LUINI, E., FLEURAT-LESSARD, P., ROUSSEAU, L., ROBLIN, G., BERJEAUD, J.-M.: Inhibitory effects of polypeptides secreted by the grapevine pathogens Phaeomoniella chlamydospora and Phaeoacremonium paleophilum on plant cell activities. Physiol. Mol. Plant Pathol., 74, 2010, 403-411. MARTIN, N., VESENTINI, D., REGO, C., MONTEIRO, S. OLIVEIRA, H., BOAVIDA FERREIRA, R.: Phaeomoniella chlamydospora infection induces changes in phenolic compounds content in Vitis vinifera, Phytopathol. Mediterr., 48, 2009, 101-116. MATKOWSKI, A.: Plant in vitro culture for the production of antioxidants - A review. Biotechnol. Adv., 26, 2008, 548-560. MULABAGAL, V., TSAY, H.-S.: Plant cell cultures - An alternative and efficient source for the production of biologically important secondary metabolites. Int. J. Appl. Sci. Eng., 2, 2004, 29-48. MURASHIGE, T., SKOOG, F.: Revised medium for rapid growth and bio assays with tobacco tissue cultures. Physiol. Plant., 15, 1962, 473-497. RAO, S.R., RAVISHANKAR, G.A., Plant cell cultures: Chemical factories of secondary metabolites. Biotechnol. Adv., 20, 2002, 101-153. RODRIGUEZ-BERNALDO DE QUIRÓS, A., LAGE-YUSTY, M.A., LÓPEZ- HERNÁNDEZ, J.: HPLC-analysis of polyphenolic compounds in Spanish white wines and determination of their antioxidant activity by radical scavenging assay. Food Res. Inter., 42, 2009, 1018-1022. SANTOS, C., FRAGOEIRO, S., VALENTIM, H., PHILLIPS, A.: Phenotypic characterisation of Phaeoacremonium and Phaeomoniella strains isolated from grapevines: enzyme production and virulence of extra-cellular filtrate on grapevine calluses. Sci. Hort., 107, 2006, 123-130. SAW, N.M.M.T., RIEDEL, H., CAI, Z., KÜTÜK, O., SMETANSKA, I.: Stimulation of anthocyanin synthesis in grape (Vitis vinifera) cell cultures by pulsed electric fields and ethephon. Plant Cell Tissue Organ Cult., 108, 2012, 47-54. SPARAPANO, L., BRUNO, G., GRANITI, A.: Effects on plants of metabolites produced in culture by Phaeoacremonium chlamydosporum, P. aleophilum and Fomitiporia punctata. Phytopathol. Mediterr., 39, 2000, 169-177. TASSONI, A., FORNALÈ, S., FRANCESCHETTI, M., MUSIANI, F., MICHAEL, A.J., PERRY, B.: Jasmonates and Na-orthovanadate promote resveratrol Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 16.01.20 16:35 UTC Nova Biotechnologica et Chimica 13-2 (2014) 171 production in Vitis vinifera cv. Barbera cell cultures. New Phytol., 166, 2005, 895- 905. TAVARES, S., VESENTINI, D., FERNANDES, J.C., FERREIRA, R.B., LAUREANO, O., RICARDO-DA-SILVA, J.M., AMÂNCIO, S.: Vitis vinifera secondary metabolism as affected by sulfate depletion: Diagnosis through phenylpropanoid pathway genes and metabolites. Plant Physiol. Biochem., 66, 2013, 118-126. ULBRICH, B., WIESNER, W., ARENS, H.: Large scale production of rosmarinic acid from plant cell cultures of Coleus blumei Benth. In: DEUS-NEUMANN, B., BARZ, W., REINHARD, E. (Eds.) Secondary metabolism of plant cell culture. Springer-Verlag, Berlin, 1985, 293-303. WILLIAMSON, G., CARUGHI, A.: Polyphenol content and health benefits of raisins. Nutr. Res., 30, 2010, 511-519. XU, J., GE, X., DOLANA, M.C.: Towards high-yield production of pharmaceutical proteins with plant cell suspension cultures. Biotechnol. Adv., 29, 2011, 278-299. YU, L.-J., LAN,W.-Z., QIN, W.-M., XU, H.-B., Effects of salicylic acid on fungal elicitor-induced membrane-lipid peroxidation and taxol production in cell suspension cultures of Taxus chinensis. Process Biochem., 37, 2001, 477-482. ZENK, M.H., EI-SHAGI, H., SCHULTE, U., Anthraquinone production by cell suspension cultures of Morinda citrifolia. Planta Medica Suppl., 75, 1975, 79-101. ZHANG, W., CURTIN, C., KIKUCHI, M., FRANCO, C.: Integration of jasmonic acid and light irradiation for enhancement of anthocyanin biosynthesis in Vitis vinifera suspension cultures. Plant Sci., 162, 2002, 459-468. ZHAO, J., LAWRENCE, T., DAVIS, C., VERPOORTE, R.: Elicitor signal transduction leading to production of plant secondary metabolites. Biotechnol. Adv., 23, 2005, 283-333. Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 16.01.20 16:35 UTC