Callus culture as a new approach for the production of high added value compounds in <i>Ilex paraguariensis</i>: genotype influence, medium optimization and compounds identification

GRUNENNVALDT, RENATA LÚCIA; DEGENHARDT-GOLDBACH, JULIANA; BROOKS, PETER; TOMASI, JÉSSICA DE CÁSSIA; HANSEL, FABRÍCIO AUGUSTO; TRAN, TRONG; GOMES, ERIK N.; DESCHAMPS, CÍCERO

doi:10.1590/0001-3765202020181251

Abstract

Ilex paraguariensis (yerba mate) is a native species from South America and is a rich source of bioactive compounds. There is a lack of research efforts on the phytochemical investigation of callus culture from this species. In the present study, an effort was made to optimize callus culture conditions and to identify secondary compounds. Calli were induced from 10 genotypes using leaf explants and the best genotype was selected to evaluate the effects of cytokinin types and concentrations on callus induction and biomass accumulation. The best genotype and cytokinin treatment were used to conduct one last experiment with sucrose concentrations in culture media and its effects on calli biomass, antioxidant activity and secondary compounds accumulation. Callus initiation was genotype dependent, and the 6-156-6 line had the best response. Zeatin supplemented medium showed higher callus induction rate (82%) and higher biomass accumulation after 120 days (328.2 mg). Higher biomass and secondary compounds accumulation were observed for calli on 3% sucrose medium. Antioxidant activity was not affected by sucrose concentrations. Yerba mate callus culture allowed the accumulation of chlorogenic acid, cryptochlorogenic acid, neochlorogenic acid, 3,4-dicaffeoylquinic acid, 3,5-dicaffeoylquinic acid, 4,5-dicaffeoylquinic acid, theobromine and caffeine.

Key words
antioxidant activity; biomass accumulation; plant growth regulators; sucrose; yerba mate

INTRODUCTION

Ilex paraguariensis (Aquifoliaceae), popularly known as ‘yerba mate’, is a traditional plant species from South America, whose leaves are used mainly for the preparation of stimulant beverages (Filip et al. 2001FILIP R, LÓPEZ P, GIBERTI G, COUSSIO J & FERRARO G. 2001. Phenolic compounds in seven South American Ilex species. Fitoterapia 72: 774-778.). The first report on the antioxidant activity of yerba mate was brought to public only in the late 1990s, and since then the interest in this plant is gradually increasing (Markowicz Bastos et al. 2007MARKOWICZ BASTOS DHM, OLIVEIRA DD, MATSUMOTO RT, CARVALHO PDO & RIBEIRO ML. 2007. Yerba mate: pharmacological properties, research and biotechnology. Med Aromat Plant Sci Biotechnol 1: 37-46.). Nowadays, the leaves of this species are exported to several countries around the world for addition in cosmetics, foods and mainly to soft drinks (Pozebon et al. 2015POZEBON D, DRESSLER VL, MARCELO MCA, OLIVEIRA TC & FERRÃO MF. 2015. Toxic and nutrient elements in yerba mate (Ilex paraguariensis). Food Addit Contam Part B 8: 215-220.).

Several studies concerning yerba mate potential for medicinal uses were carried out and some properties of this plant have already been reported, such as antiobesity action (Arçari et al. 2009ARÇARI DP, BARTCHEWSKY W, SANTOS TW, OLIVEIRA KA, FUNCK A, PEDRAZZOLI J & CARVALHO PDO. 2009. Antiobesity Effects of yerba maté Extract (Ilex paraguariensis) in High-fat Diet–induced Obese Mice. Obesity 17: 2127-2133.), antimutagenic (Miranda et al. 2008MIRANDA DD, ARÇARI DP, PEDRAZZOLI J, CARVALHO PDO, CERUTTI SM, BASTOS DH & RIBEIRO ML. 2008. Protective effects of mate tea (Ilex paraguariensis) on H2O2-induced DNA damage and DNA repair in mice. Mutagenesis 23: 261-265.), anti-depressive and neuroprotective activities (Ludka et al. 2016LUDKA FK, FÁTIMA TANDLER L, KUMINEK G, OLESCOWICZ G, JACOBSEN J & MOLZ S. 2016. Ilex paraguariensis hydroalcoholic extract exerts antidepressant-like and neuroprotective effects: involvement of the NMDA receptor and the L-arginine-NO pathway. Behav Pharmacol 27: 384-392.).

The medicinal properties of this species are related to its leaves main constituents. Natural antioxidant defense systems are reported in Ilex paraguariensis and are attributed, mainly, to the high content of phenolic compounds (Bravo et al. 2007BRAVO L, GOYA L & LECUMBERRI E. 2007. LC/MS characterization of phenolic constituents of mate (Ilex paraguariensis, St. Hil.) and its antioxidant activity compared to commonly consumed beverages. Food Res Int 40: 393-405.). In addition to phenolic acids, methylxanthines, saponins, flavonoids, amino acids, minerals and vitamins are also reported as significant bioactive compounds in the leaves of this species (Boaventura et al. 2015BOAVENTURA BCB, SILVA EL, LIU RH, PRUDÊNCIO ES, DI PIETRO PF, BECKER AM & AMBONI RDDMC. 2015. Effect of yerba mate (Ilex paraguariensis A. St. Hil.) infusion obtained by freeze concentration technology on antioxidant status of healthy individuals. LWT - Food Sci Technol 62: 948-954.).

The main phenolic acids present in yerba mate are known as chlorogenic acids (Filip et al. 2001FILIP R, LÓPEZ P, GIBERTI G, COUSSIO J & FERRARO G. 2001. Phenolic compounds in seven South American Ilex species. Fitoterapia 72: 774-778., Heck & de Mejia 2007HECK CI & DE MEJIA EG. 2007. Yerba Mate Tea (Ilex paraguariensis): a comprehensive review on chemistry, health implications, and technological considerations. J Food Sci 72: 138-151., Markowicz Bastos et al. 2007MARKOWICZ BASTOS DHM, OLIVEIRA DD, MATSUMOTO RT, CARVALHO PDO & RIBEIRO ML. 2007. Yerba mate: pharmacological properties, research and biotechnology. Med Aromat Plant Sci Biotechnol 1: 37-46.). Chlorogenic acids are extensively employed as additives in food industries for preparation of beverages, as well as medicinal substances and cosmetics. This class of compounds is considered as part of the Fine Chemicals category, products characterized by high added value (Butiuk et al. 2016BUTIUK AP, MARTOS MA, ADACHI O & HOURS RA. 2016. Study of the chlorogenic acid content in yerba mate (Ilex paraguariensis St. Hil.): Effect of plant fraction, processing step and harvesting season. J Appl Res Med Aromat Plants 3: 27-33.).

Callus cultures are often used as alternative systems to whole plant cultivation, and can represent an efficient approach for producing natural compounds for pharmaceutical, fragrances, flavours, food additives, colouring agents, and agrochemicals applications (Kikowska et al. 2012KIKOWSKA M, BUDZIANOWSKI J, KRAWCZYK A & THIEM B. 2012. Accumulation of rosmarinic, chlorogenic and caffeic acids in in vitro cultures of Eryngium planum L. Acta Physiol Plant 34: 2425-2433., Wang et al. 2017WANG J, LI JL, LI J, LI JX, LIU SJ, HUANG LQ & GAO WY. 2017. Induction of active compounds in medicinal plants: from plant tissue culture to biosynthesis. Chinese Herb Med 9: 115-125.). Plant cell cultures have been widely used as raw materials for cosmetics commercial products and added as bioactive ingredients for nutritional, pharmaceutical, dermo-cosmetic and animal health applications (PhytoCellTec 2012PHYTOCELLTEC. 2012. Uma tecnologia revolucionária para proteção das células-tronco da nossa pele. Avalailable online from: <http://www.phytocelltec.com.br/a-tecnologia/> Accessed on May 3, 2017.
http://www.phytocelltec.com.br/a-tecnolo... , Morus et al. 2014MORUS M, BARAN M, ROST-ROSZKOWSKA M & SKOTNICKA-GRACA U. 2014. Plant stem cells as innovation in cosmetics. Acta Pol Pharm Res 71: 701-707., L’Oréal 2017L’ORÉAL. 2017. Para criar novos ingredientes ativos altamente eficientes, os pesquisadores da L’Oréal fazem uso da química sintética e das biotecnologias. Available online from <http://www.loreal.com.br/pesquisa-,-a-,-inovação/nossas-grandes-descobertas/principais-ingredientes-ativos> Accessed on June 13, 2018.
http://www.loreal.com.br/pesquisa-,-a-,-... ).

Callus and cell cultures follow two steps before secondary compounds production. Initially, biomass accumulation occurs when callus and cells grow and multiply (step one) and, subsequently, the biosynthesis of compounds from the biomass ensues (step two). Initiation of callus and cell cultures begins with choosing adequate parent plants, since the high-producing callus and cells as well as the accumulation of secondary compounds in plants may be genotype specific (Castro et al. 2016CASTRO AHF, BRAGA KDQ, SOUSA FMD, COIMBRA MC & CHAGAS RCR. 2016. Callus induction and bioactive phenolic compounds production from Byrsonima verbascifolia (L.) DC.(Malpighiaceae). Rev Ciênc Agron 47: 143-151.).

Several chemical and physical factors have been identified as influencing biomass accumulation and secondary compounds biosynthesis in plant cell cultures (Shen et al. 2008SHEN X, KANE ME & CHEN J. 2008. Effects of genotype, explant source, and plant growth regulators on indirect shoot organogenesis in Dieffenbachia cultivars. In Vitro Cell Dev Biol Plant 44: 282-288.). Auxins and cytokinins are usually employed to induce callus formation, as they promote cell growth by stimulating cell division and elongation (Castro et al. 2016CASTRO AHF, BRAGA KDQ, SOUSA FMD, COIMBRA MC & CHAGAS RCR. 2016. Callus induction and bioactive phenolic compounds production from Byrsonima verbascifolia (L.) DC.(Malpighiaceae). Rev Ciênc Agron 47: 143-151.). Therefore, optimizing the type and level of growth regulators in culture medium is necessary to obtain maximum calli yield (Wani et al. 2014WANI SJ, KAGDI IA, TAMBOLI PS, NIRMALKAR VS, PATIL SN & SIDHU AK. 2014. Optimization of MS media for callus and suspension culture of Costus pictus. Int J Scient Eng Res 5: 390-394.). In addition to plant growth regulators, plant cell cultures grow as a function of a carbohydrate source. For that reason, improvement of carbohydrates supplemental concentration in the medium can greatly affect biomass and compounds production in callus cultures (Castro et al. 2016CASTRO AHF, BRAGA KDQ, SOUSA FMD, COIMBRA MC & CHAGAS RCR. 2016. Callus induction and bioactive phenolic compounds production from Byrsonima verbascifolia (L.) DC.(Malpighiaceae). Rev Ciênc Agron 47: 143-151.). Sucrose, for example, is used as a vital carbon and energy source at concentrations of 3%. Higher concentrations of this carbohydrate in the culture medium, however, might cause osmotic stress on callus tissues (Gertlowski & Petersen 1993GERTLOWSKI C & PETERSEN M. 1993. Influence of the carbon source on growth and rosmarinic acid production in suspension cultures of Coleus blumei. Plant Cell Tissue Organ Cult 34: 183-190.). This type of stress may influence secondary metabolites biosynthesis, mainly the phenylpropanoid pathway, that are associated to phenolic acids yields (Kikowska et al. 2012KIKOWSKA M, BUDZIANOWSKI J, KRAWCZYK A & THIEM B. 2012. Accumulation of rosmarinic, chlorogenic and caffeic acids in in vitro cultures of Eryngium planum L. Acta Physiol Plant 34: 2425-2433.).

With this in mind, the present study aimed to select a suitable genotype to callus induction and subsequently optimize culture medium composition to obtain an efficient callus culture of Ilex paraguariensis, in order to produce highly valued secondary compounds under controlled conditions. The results are also discussed in terms of the antioxidant activity and distribution of major secondary compounds identified in Ilex paraguariensis callus culture according to changes in sucrose concentration.

MATERIALS AND METHODS

Establishment and proliferation of callus culture

Callus tissues were induced from leaves of Ilex paraguariensis plants grown in greenhouse at EMBRAPA Forestry (Brazilian Agricultural Research Corporation). The 2^nd/3^rd pairs of elite clones leaves were collected and immediately placed in antioxidant solution (0.5% ascorbic acid and 0.5% citric acid, w/v). The leaves were washed with neutral detergent in tap water and disinfested as follows: 10 min in Cercobin® 1% solution (w/v), 5 min in 0.05% mercury chloride (w/v) and finally rinsing three times with sterile distilled water.

Afterwards, leaf discs with 2 cm diameter were placed in Petri dishes containing 20 mL autoclaved MS medium (Murashige and Skoog 1964MURASHIGE T & SKOOG F. 1964. A revised medium for rapid growth and bioessays with tobacco tissue cultures. Physiol Plant 15: 473-479.) reduced to quarter strength (¼-strength MS) and supplemented with 4.52 µM 2,4-dichlorophenoxyacetic acid (2.4-D). The concentrations of cytokinin and sucrose were modified according to the experiment. The pH was adjusted to 5.8 prior to addition of 0.7% agar. The Petri dishes containing the explants were incubated in the dark at 23 ± 2 ºC, and the explants were subcultured to freshly medium every 60 days.

Selection of clones for callus induction

Leaves from ten yerba mate elite clones (A3, A35, A7, F1, F2, M7, 3-65-2, 4-56-2, 4-76-2 and 6-156-6) from EMBRAPA Forestry breeding program (Resende et al. 2000RESENDE MDV, STURION JA & CARVALHO AP. 2000. Programa de melhoramento da erva-mate coordenado pela EMBRAPA resultados da avaliação genética de populações, progênies, indivíduos e clones, 1a ed., Colombo: Embrapa Florestas, 66 p.) were collected, disinfected and placed in culture medium ¼ MS, containing 3% sucrose, 4.52 μM 2,4-D, 4.56 μM zeatin and 0.7% agar for callus induction. After 30 days, the callus culture was evaluated according to the induction coefficient for each clone: induction coefficient = (total number of induced callus/number of cultured explants) * 100.

Cytokinins and callus proliferation

The best callogenesis response genotype (6-156-6) was tested on medium previously described varying the concentrations and types of cytokinins as follows: zeatin (2.26, 4.56 or 9 μM), 2-isopentenyladenine (2iP) (2.5, 5 or 7.5 μM), thidiazuron (TDZ) (0.125, 0.25 or 0.5 μM) or kinetin (2.5, 5 or 7.5 μM). After 30 days, callus induction percentage was evaluated and after 120 days, calli fresh mass was measured. The calli were transferred every 60 days for fresh media of the same composition.

Effects of sucrose concentration on callus proliferation and secondary metabolites

The best yerba mate genotype and cytokinin supplemented medium were used to study the effects of sucrose concentrations on callus growth and secondary compounds production. Calli were grown for 60 days in ¼ MS medium with 0.7% agar, 4.52 μM 2,4-D, 4.56 μM zeatin and 3% sucrose and then transferred to the same medium but with different sucrose supplementation (3, 6, and 9%). Calli fresh weight was measured every 15 days up to 120 days of culture. After this period, calli were stored at -80 ºC for further analysis of secondary compounds.

Extraction of secondary compounds from Ilex paraguariensis calli

Calli were frozen in liquid nitrogen and lyophilized for 72 h. Samples (10 mg) were extracted with hydroalcoholic solution (ethanol: water, 1:1, 1 mL). The extract solutions were mixed for 30 s, sonicated for 30 s, and kept on a rotatory shaker (450 rpm) for 1 h at 60 ºC. The extracts were centrifuged (13000 rpm) for 40 min, and the supernatants were collected and filtered (0.22 µm). Part of the extracts was used for biochemical analysis (phenolic content and antioxidant activity) and 500 µL of each were transferred to vials (2 mL) containing 25 µg of the internal standard umbelliferone, added for quality control (Sigma®).

Determination of total phenolic content

Total phenolic content (TPC) was determined using Folin-Ciocalteu (FC) reagent according to the method reported by Horžić et al. (2009)HORŽIĆ D, KOMES D, BELŠČAK A, GANIĆ KK, IVEKOVIĆ D & KARLOVIĆ D. 2009. The composition of polyphenols and methylxanthines in teas and herbal infusions. Food Chem 115: 441-448. with modifications. Briefly, 0.1 mL of the extracted sample was mixed with 6.0 mL of deionized water and 0.5 mL of the Folin-Ciocalteu reagent and subsequently incubated for 5 min at room temperature (25 ± 2 °C). After incubation, 2 mL of Na₂CO₃ (15%, w/v) was added to the mixture and the final volume was adjusted to 10 mL. The absorbance was measured at 760 nm using UV–Visible spectrophotometer (Shimadzu-1800, Japan) after 2 h. Gallic acid (0.25-10 mg.L^-1) was used to create the standard curve for quantification. The results were expressed as milligrams of gallic acid equivalents per gram of dried weight (DW) (mgGAE.g^-1).

Determination of antioxidant activity by DPPH and ABTS assay

The effect of yerba-mate callus extracts on 2,2-diphenyl-1-picrylhydrazyl (DPPH) radicals was estimated using the method described by Brand-Willians et al. (1995). Each yerba mate extract (0.1 mL) was added to 3.9 mL of DPPH in methanol (6x10^-5 mol.L^-1). The mixture was shaken vigorously and incubated for 30 min at room temperature. After this period, absorbance was determined at 515 nm in a UV-Vis spectrophotometer (Shimadzu-1800, Japan).

Total antioxidant activity was measured by 2,2`-Azinobis (3-ethylbenzothiazoline 6-sulphonic acid) radical scavenging (ABTS) method. The ABTS cation radical was produced by the reaction between 7 mM ABTS and 140 mM potassium persulfate. This mixture was stored in the dark at room temperature for 16 h. Before it was used, the ABTS solution was diluted until reaching an absorbance of 0.7 ± 0.2 at 734 nm in a spectrophotometer (Shimadzu-1800, Japan). Subsequently, 30 µL of the yerba mate callus extract was added to 3 mL of ABTS solution and the reduction was determined after 2 h in a spectrophotometer at 734 nm (Re et al. 1999RE R, PELLEGRINI N, PROTEGGENTE A, PANNALA A, YANG M & RICE-EVANS C. 1999. Antioxidant activity applying an improved ABTS radical cation decolorization assay. Free Radic Biol Med 26: 1231-1237., Yim et al. 2013YIM HS, CHYE FY, RAO V, LOW JY, MATANJUN P, HOW SE & HO CW. 2013. Optimization of extraction time and temperature on antioxidant activity of Schizophyllum commune aqueous extract using response surface methodology. J Food Sci Technol 50: 275-283.).

The scavenging capacity of DPPH radicals and ABTS was calculated using the equation obtained from the standard Trolox analytical curve at range of 0-1000 mg.L^-1 and 0-2500 mg.L^-1, respectively. The results were expressed in µmoles Trolox equivalent per gram of DW (µmolTE.g^-1).

Identification and quantification of secondary compounds

Chromatographic analyses were conducted on an Agilent 1290 Infinity Liquid Chromatograph (HPLC), using a UV detector and a C18 Synergy Fusion-RP 80A (75 x 4.6 mm, d.i. 4 μm) column, with a C18 pre column. The UV spectra were recorded in 208, 260, 280 and 328 nm. The mobile phases consisted of a gradient elution of acetonitrile, water and formic acid (5:94.9:0.1, v/v/v, solvent A), and acetonitrile and formic acid (99.9:0.1, v/v, solvent B). The gradient profile was: 0–3 min (0% B), 3–23 min (0%–3% B), 23–28 min (30%–100% B), 28–30 min (100% B), 30-31 min (100%-0% B), 31-35 (0% B) at 1 mL.min^-1. The injected volume was 20 μL.

The semi-quantification of the compounds was calculated by 5 point external analytical curves, the caffeine and theobromine were performed using a caffeine curve at range of 0 to 0.5 mg.mL^-1. The caffeoylquinic derivatives were semi-quantified using a chlorogenic acid curve at range of 0 to1 mg.mL^-1. The secondary compounds amounts were expressed in mg compound per gram of DW of caffeine equivalent (mgCafE.g^-1) or chlorogenic acid equivalent (mgCAE.g^-1).

The identification of the compounds was carried out by LC-MS/MS analysis using the SCIEX X500R QTOF system with Turbo V™ source and Electrospray Ionization (ESI). The positive mode was used for caffeine and theobromine and a negative mode was used for caffeoylquinic derivatives. The IS voltage was set to 5500 V. The mobile phases consisted of a gradient elution of acetonitrile and water and formic acid (5:94.9:0.1, v/v/v) (solvent A), and acetonitrile and formic acid (99.9:0.1, v/v/v) (solvent B). The gradient profile was: 0–0.5 min (5% B), 0.5–25 min (5%–40% B), 25–28 min (40%–60% B), 28–30 min (60% B), 30-31 min (60%-0% B), 31-35 (0% B) at 0.5 mL.min−¹. The injected volume was 2 μL of sample injection.

Statistical analyses

Completely randomized experimental designs were used for all experiments. For the evaluations of genotype, cytokinin and sucrose effects, 10 Petri dishes (replications) with 5 explants each (experimental unit) per treatment were used. In the cytokinin experiment, after 120 days, 10 calli of each treatment were weighed to determine callus fresh mass. Data of the abovementioned experiments were analysed by Barttlet test and ANOVA, followed by a Tukey test (p<0.05). For evaluation of sucrose effects on different times, after 60 days on culture, 10 calli were weighed each 15 days, until 120 days. Regression analysis (p <0.05) was performed to the variable of callus growth. The analyses of total phenolics, antioxidant activity, and HPLC analysis were carried out in quintuplicate.

RESULTS AND DISCUSSION

Effects of genotype on callus induction

The percentage of callus induction varied according to the genotype (Figure 1), suggesting a strong genotype dependent response. Leaf explants of 6-156-6 clone had the higher induction rates (77%). The lowest induction rates (1% and 0%) were observed in leaf explants from 4-76-2 and A7 clones.

Figure 1
Callus induction on leaf explants of 10 clones of I. paraguariensis after 30 days on culture. Bars followed by the same letter do not show significant differences [P < 0.05 (Tukey)].

Genotypic differences in callus forming ability in vitro culture have been observed in a wide range of species. Some genotypes can exhibit high capacity, while others are recalcitrant for callus induction (Atak & Çelik 2009ATAK Ç & ÇELIK Ö. 2009. Micropropagation of Anthurium Andraeanum from leaf explants. Pak J Bot 41: 1155-1161., Głowacka et al. 2010GŁOWACKA K, JEŻOWSKI S & KACZMAREK Z. 2010. The effects of genotype, inflorescence developmental stage and induction medium on callus induction and plant regeneration in two Miscanthus species. Plant Cell Tissue Organ Cult 102: 79-86., Liu et al. 2010LIU W, LIU C, YANG C, WANG L & LI S. 2010. Effect of grape genotype and tissue type on callus growth and production of resveratrols and their piceids after UV-C irradiation. Food Chem 122: 475-481.). Kandasamy et al. (2001)KANDASAMY MK, GILLILAND LU, MCKINNEY EC & MEAGHER RB. 2001. One plant actin isovariant, ACT7, is induced by auxin and required for normal callus formation. Plant Cell 13: 1541-1554. reported that specific genes, capable of responding rapidly to auxin and other plant growth regulators, are required for the growth and proliferation of tissues in cultures and its low expression might inhibit callus formation.

The callus appearance was similar for all clones: yellowish with compact texture. As Clone 6-156-6 had the highest percentage of callus induction, it was selected as the explants source for the following experiments.

Cytokinins effects on callus induction and growth

The type, concentration, and combination of plant growth regulators (PGR) in media may also affect callus induction. The present study showed that cytokinin type and concentration have significant effects on the induction and growth of yerba mate callus. The 2,4-D has been shown to be the most effective auxin for callus induction from leaf explant of a variety of species (Santos et al. 2008SANTOS CG, PAIVA R, PAIVA PDO & PAIVA E. 2008. Indução e análise bioquímica de calos em segmentos foliares e nodais de Coffea canephora L. Cv. Apoatã. Magistra 20: 22-29., Vasconcelos et al. 2012VASCONCELOS JNC, CARDOSO NSN, OLIVEIRA LM, SANTANA JRF, FERNANDEZ LG, BELLO KOBLITZ MG & SILVA MLC. 2012. Indução, caracterização bioquímica e ultra-estrutural de calos de aroeira-do-sertão (Myracrodruon urundeuva Fr. All.). Rev Bras Plantas Med 14: 592-597.). Previous studies showed the necessity of using 2,4-D to induce callus in yerba mate leaves, being the amount of 4.52 µM giving the higher callus induction, thus such concentration was fixed in this experiments.

The results indicated that all treatments induced callus from yerba mate leaves (Table I. However, differences based on cytokinins types and concentrations were observed. Among the cytokinins tested, higher zeatin concentrations (4.56 and 9 µM) were the most effective in stimulating callus induction, not differing statistically from 0.15 µM and 0.5 µM TDZ, 2.5 µM and 7.5 µM kinetin (p>0.05). Regarding calli fresh weight at 120 days, higher zeatin amounts were also found the most effective, together with 0.5 µM TDZ and 7.5 µM 2iP (p>0.05) (Table I). When both variables (i.e. callus induction and fresh weights) were taken together, higher zeatin concentration (4.56 and 9 µM) and 0.5 µM TDZ provided similar results. However, calli grown in culture medium with TDZ oxidized after 120 days, whereas those cultivated with zeatin showed better appearance and colour (Figure 2).

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Table I
Effects of cytokinin type and concentrations on callus induction and calli fresh weight in callus culture from I. paraguariensis (clone 6-156-6) leaf explants.

Figure 2
Effect of cytokinins on I. paraguariensis calli at 120 days of induction. a) 2.25 μM zeatin, b) 4.56 μM zeatin, c) 9 μM zeatin, d) 0.15 μM TDZ, e) 0.25 μM TDZ, f) 0.5 μM TDZ, g) 2.5 μM 2iP, h) 5 μM 2iP, i) 7.5 μM 2iP, j) 2.5 μM kinetin, k) 5 μM kinetin, l) 7.5 μM kinetin.

Zeatin was previously described as effective for conversion of rudimentary embryos of Ilex paraguariensis (Sansberro et al. 1998SANSBERRO P, REY H, MROGINSKI LA & COLLAVINO M. 1998. In vitro culture of rudimentary embryos of Ilex paraguariensis (Aquifoliaceae). J Plant Growth Regul 17: 101-105.). In previous experiments with other Ilex species such as I. crenata (Yang et al. 2015YANG Y, ZHANG D, LI Z, JIN X & DONG J. 2015. Immature embryo germination and its micropropagation of Ilex crenata Thunb. HortScience 50: 733-737.), Ilex brasiliensis, I. pseudoboxus and I. theezans (Dolce et al. 2015DOLCE NR, MEDINA RD, MROGINSKI LA & REY HY. 2015. Sowing pyrenes under aseptic conditions enhances seed germination of Ilex brasiliensis, I. pseudoboxus and I. theezans (Aquifoliaceae). Seed Sci Technol 43: 273-277.), zeatin also shown to be the best cytokinin for plants shoot regeneration.

According to Schuch et al. (2008)SCHUCH MW, DAMIANI CR, COUTO L & ERIG AC. 2008. Micropropagação como técnica de rejuvenescimento em mirtilo (Vaccinium ashei Reade) cultivar Climax. Ciênc Agrotecnol 32: 814-820., 2iP also occurs naturally in plants, but it is considered a weaker cytokinin when compared to zeatin. This fact is in agreement with our results, since calli grown in medium with this plant growth regulator showed the lower callus induction percentage and only the highest concentration of 2iP (7.5 μM) showed good results for yerba mate calli yield.

The opposite trend was observed in callus supplemented with kinetin. Data obtained showed that calli biomass was decreased when the concentrations of kinetin increased. At the same time, intermediate concentrations of kinetin and TDZ showed lower callus induction, while the extreme concentrations showed higher callus induction rate. This was also observed in Centella asiatica callus culture suplemented with 2,4-D and 6- Benzylaminopurine (BAP).

Manipulation of the auxin/cytokinin ratio in culture media is often a crucial factor for increasing calli growth. The exogenous supplemented auxins and cytokinins act by interaction with endogenous plant hormones and consequently, the concentration and combination of these regulators need to be defined for each species (Loredo-Carrillo et al. 2013LOREDO-CARRILLO SE, LOURDES SANTOS-DÍAZ M, LEYVA E & SOCORRO SANTOS-DÍAZ M. 2013. Establishment of callus from Pyrostegia venusta (Ker Gawl.) Miers and effect of abiotic stress on flavonoids and sterols accumulation. J Plant Biochem Biotechnol 22: 312-318.).

Additionally, the manipulation of PGR concentrations in the culture media might also influence secondary compounds accumulation (Rodrigues & Almeida 2010RODRIGUES FR & ALMEIDA WAB. 2010. Calogênese em Cissus sicyoides L. a partir de segmentos foliares visando à produção de metabólitos in vitro. Rev Bras Plantas Med 12: 333-340.). PGR manipulation, in most of the cases, is carried out in the first step of metabolite production, by altering the factors which could improve the callus growth during the biomass accumulation phase (Castro et al. 2016CASTRO AHF, BRAGA KDQ, SOUSA FMD, COIMBRA MC & CHAGAS RCR. 2016. Callus induction and bioactive phenolic compounds production from Byrsonima verbascifolia (L.) DC.(Malpighiaceae). Rev Ciênc Agron 47: 143-151.).

Taking together the results for callus induction and calli fresh weight, the concentration of 4.56 µM zeatin showed the better results and, in addition, promoted a better colour and aspect in yerba mate calli. Therefore, this cytokinin type and concentration were chosen to perform the experiment with variable sucrose concentrations.

Effects of sucrose on callus growth and total phenolics content

The effect of sucrose on I. paraguariensis callus induction was investigated by varying sucrose concentration (from 3 to 9%) after 60 days on culture. At this time, calli weights were, on average, 100 mg of fresh weight.

Figure 3a shows the biomass accumulation over the time for calli under different sucrose concentrations. The medium supplemented with 3% sucrose was superior to the others after 90 days culture. Concentrations of 6 and 9% sucrose were suboptimal for yerba mate calli growth. Higher concentrations of sucrose may reduce calli fresh mass by increasing the medium osmotic potential, hindering the absorption of salts and water (Jesus et al. 2011JESUS AMS, VILLA F, DA COSTA LARA AC & PASQUAL M. 2011. Avaliação do efeito das concentrações de sacarose e dos estádios de desenvolvimento do fruto no cultivo in vitro de embriões de frutos de cafeeiro. Rev Ceres 58: 679-684.). As observed in Vitis vinifera (Do & Cormier 1990DO CB & CORMIER F. 1990. Accumulation of anthocyanins enhanced by a high osmotic potential in grape (Vitis vinifera L.) cell suspensions. Plant Cell Rep 9: 143-146.) and Panax notoginseng (Zhang et al. 1996ZHANG YH, ZHONG JJ & YU JT. 1996. Enhancement of ginseng saponin production in suspension cultures of Panax notoginseng: Manipulation of medium sucrose. J Biotechnol 51: 49-56.) cell suspension cultures, high concentrations of sucrose repressed cell growth, but, in both species, favoured the synthesis of secondary compounds and could be used as strategies to improve the accumulation of such compounds in the culture.

Figure 3
a) Growth parameters of I. paraguariensis callus culture supplemented with increasing sucrose concentrations. Callus growth was expressed as milligrams of fresh weight. b) Total phenolic accumulating after 120 days of culture of I. paraguariensis. Data are the mean ± SE (n = 10) ( ) 3% sucrose; ( ) 6% sucrose; ( ) 9% sucrose. Means with different letters are significantly different at the 5% level of probability using Tukey’s multiple range test. The vertical bars represent the standard error of five replicates.

In Ilex paraguariensis, however, total phenols were not positively influenced by higher levels of sucrose, since the higher content was observed in calli supplemented with 3% sucrose (Figure 3b). Similar results were observed for biomass and phenolic compounds accumulation in Hypericum perforatum root cultures (Cui et al. 2010CUI XH, MURTHY HN, WU CH & PAEK KY. 2010. Sucrose-induced osmotic stress affects biomass, metabolite, and antioxidant levels in root suspension cultures of Hypericum perforatum L. Plant Cell Tissue and Organ Cult 103: 7-14.) and for Prunella vulgaris cell suspension cultures (Fazal et al. 2016FAZAL H, ABBASI BH, AHMAD N, ALI M & ALI S. 2016. Sucrose induced osmotic stress and photoperiod regimes enhanced the biomass and production of antioxidant secondary metabolites in shake-flask suspension cultures of Prunella vulgaris L. Plant Cell Tissue Organ Cult 124: 573-581.), with maximum yields when treated with low sucrose concentrations.

In contrast, a 5% sucrose supply was shown to be optimal for enhancement of Morinda citrifolia root growth, but the maximum production of phenolics was achieved at 1% sucrose-treated culture (Baque et al. 2012BAQUE MA, ELGIRBAN A, LEE EJ & PAEK KY. 2012. Sucrose regulated enhanced induction of anthraquinone, phenolics, flavonoids biosynthesis and activities of antioxidant enzymes in adventitious root suspension cultures of Morinda citrifolia (L.). Acta Physiol Plant 34: 405-415.). The results indicate that the optimal sucrose concentration for phenolic compounds accumulation is not always related to the biomass accumulation, which justifies species-specific studies to improve secondary metabolites yield.

Identification of secondary compounds from yerba mate callus culture

Six major phenolic constituents and two methylxanthines present in yerba mate callus cultures were identified by LC-MS-MS (Table II. Three caffeoylquinic acids were identified as 3-O-caffeoylquinic acid (chlorogenic acid), 4-O-caffeoylquinic acid (crypto-chlorogenic acid) and 5-O-caffeoylquinic acid (neochlorogenic acid). These compounds have been previously reported as major constituents of mate (Bravo et al. 2007BRAVO L, GOYA L & LECUMBERRI E. 2007. LC/MS characterization of phenolic constituents of mate (Ilex paraguariensis, St. Hil.) and its antioxidant activity compared to commonly consumed beverages. Food Res Int 40: 393-405.).

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Table II
Ion MS fragmentation data of secondary compounds in I. paraguariensis callus.

Three dicaffeoylquinic acid isomers were also identified, corresponding to 3,4-dicaffeoylquinic acid, 3,5-dicaffeoylquinic acid, and 4,5-dicaffeoylquinic acid. The compounds identified as the major constituents in yerba mate callus culture in the present study have a significant potential for use in different industrial applications, such as pharmaceutical drugs, cosmetics and food preservatives. Caffeine and theobromine, for example, play an important role against physical and mental fatigue (Filip et al. 2001FILIP R, LÓPEZ P, GIBERTI G, COUSSIO J & FERRARO G. 2001. Phenolic compounds in seven South American Ilex species. Fitoterapia 72: 774-778.). Due to their higher antioxidant activity, the caffeoylquinic acids have a great range of applications in the pharmacy and cosmetic industries. In addition, caffeoylquinic acids have been recently reported to present digestive and hepatoprotective activities (Azzini et al. 2007AZZINI E, BUGIANESI R, ROMANO F, DI VENERE D, MICCADEI S, DURAZZO A & MAIANI G. 2007. Absorption and metabolism of bioactive molecules after oral consumption of cooked edible heads of Cynara scolymus L.(cultivar Violetto di Provenza) in human subjects: a pilot study. Br J Nutr 97: 963-969.).

Dicaffeoylquinic acids also show strong antioxidant activity and several potential uses. The 4,5-dicaffeoylquinic acid has been reported as an inhibitor of pigmentation and can be used to treat pigmentation disorders (Tabassum et al. 2016TABASSUM N, LEE JH, YIM SH, BATKHUU GJ, JUNG DW & WILLIAMS DR. 2016. Isolation of 4, 5-O-dicaffeoylquinic acid as a pigmentation inhibitor occurring in Artemisia capillaris Thunberg and its validation in vivo. Evidence-based Complement Altern Med 2016: 1-11.). The 3,5-dicaffeoylquinic acid, in turn, is a potent anti-inflammatory (Hong et al. 2015HONG S, JOO T & JHOO JW. 2015. Antioxidant and anti-inflammatory activities of 3, 5-dicaffeoylquinic acid isolated from Ligularia fischeri leaves. Food Sci Biotechnol 24: 257-263.) and has been reported to inhibit the replication of the human immunodeficiency virus, HIV-1 (Zhu et al. 1999ZHU K, CORDEIRO ML, ATIENZA J, ROBINSON WE & CHOW SA. 1999. Irreversible inhibition of human immunodeficiency virus type 1 integrase by dicaffeoylquinic acids. J Virol 73: 3309-3316.). In the same context, 3,4-dicaffeoylquinic acid has been reported as a potent lead compound for anti-influenza activity (Takemura et al. 2012TAKEMURA T, URUSHISAKI T, FUKUOKA M, HOSOKAWA-MUTO J, HATA T, OKUDAY & KUWATA K. 2012. 3, 4-dicaffeoylquinic acid, a major constituent of Brazilian propolis, increases TRAIL expression and extends the lifetimes of mice infected with the influenza a virus. Evidence-based Complement Altern Med 2012: 1-7.). The presence of all these compounds in yerba mate callus culture makes it a potential source of raw-material for many industrial applications.

Sucrose effects on antioxidant activity and secondary compounds production

The compounds identified by LC-MS/MS were semi-quantified by HPLC-UV. Figure 4 shows a typical chromatogram of the extract obtained from callus, as well as the corresponding on line UV spectra. The compounds from peaks 1 and 3, were identified as theobromine and caffeine, respectively, which belong to the class of methylxanthines.

Figure 4
Typical HPLC chromatogram for I. paraguariensis callus extract. a) The UV spectra was 260 nm for caffeine and theobromine and b) 328 nm for caffeic acid derivatives. Peaks: (1) theobromine; (2) neochlorogenic acid; (3) caffeine; (4) chlorogenic acid; (5) cryptochlorogenic acid; (6) Internal standard umbelliferone; (7) 3,4-dicaffeoylquinic acid; (8) 3,5-dicaffeoylquinic acid; and (9) 4,5-dicaffeoylquinic acid.

Three caffeoylquinic acids were identified as 5-O-caffeoylquinic acid (neochlorogenic acid), 3-O-caffeoylquinic acid (chlorogenic acid) and 4-O-caffeoylquinic acid (crypto-chlorogenic acid), respectively peaks 2, 4 and 5. Peaks 7, 8 and 9 correspond to the three dicaffeoylquinic acid isomers: 3,4-dicaffeoylquinic acid, 3,5-dicaffeoylquinic acid, and 4,5-dicaffeoylquinic acid, respectively.

Data show that antioxidant activities and the compounds caffeine and 3,5-dicaffeoylquinic are not significantly affected by changes in sucrose concentration (Figure 5a, c and d). 3,5-dicaffeoylquinic acid is a compound with strong antioxidant activity (Hong et al. 2015HONG S, JOO T & JHOO JW. 2015. Antioxidant and anti-inflammatory activities of 3, 5-dicaffeoylquinic acid isolated from Ligularia fischeri leaves. Food Sci Biotechnol 24: 257-263., Menin et al. 2013MENIN B, MOGLIA A, COMINO C, HAKKERT JC, LANTERI S & BEEKWILDER J. 2013. In vitro callus-induction in globe artichoke (Cynara cardunculus L. var. scolymus) as a system for the production of caffeoylquinic acids. J Hortic Sci Biotechnol 88: 537-542.), and its amount in yerba mate callus culture was higher than other dicaffeoylquinic acids. This fact may justify the stability of the antioxidant activity as a function of sucrose concentration, regardless of the analytical method (Figure 5a, c and d). Both methods for measuring antioxidant potential used in this work (ABTS and DPPH assays) are known to be the easiest to implement and to yield the most reproducible results (Dudonne et al. 2009).

Figure 5
Effect of sucrose concentration on the: a) Antioxidant activity, b) Theobromine and caffeine, c) Chlorogenic acids and d) Dicaffeoylquinic acids of I. paraguariensis callus culture after 120 days. Means with different letters are significantly different at the 5% probability level according to the Tukey’s multiple range test. The vertical bars represent the standard error of five replicates.

The accumulation of chlorogenic acid, neochlorogenic acid, crypto-chlorogenic acid, 3,4-dicaffeoylquinic acid, and 4,5-dicaffeoylquinic acid in yerba mate callus was higher in the medium supplemented with 3% sucrose. Higher sucrose concentrations inhibited the accumulation of these compounds (Figure 5c and d).

An opposite result was reported for Eryngium planum callus culture, where concentrations of 5 and 6% sucrose in the medium led to increasing chlorogenic acid contents (Kikowska et al. 2012KIKOWSKA M, BUDZIANOWSKI J, KRAWCZYK A & THIEM B. 2012. Accumulation of rosmarinic, chlorogenic and caffeic acids in in vitro cultures of Eryngium planum L. Acta Physiol Plant 34: 2425-2433.). For Gymnema sylvestre cell suspension culture system, 3% sucrose favoured the accumulation of biomass, whereas the highest amount of gymnemic acid was accumulated at 4% sucrose (Nagella et al. 2011NAGELLA P, CHUNG IM & MURTHY HN. 2011. In vitro production of gymnemic acid from cell suspension cultures of Gymnema sylvestre R Br Eng Life Sci 11: 537-540.). In Solanum aviculare hairy root cultures, the optimum alkaloid content was obtained in medium supplemented with 6% sucrose (Yu et al. 1996YU S, KWOK KH & DORAN PM. 1996. Effect of sucrose, exogenous product concentration, and other culture conditions on growth and steroidal alkaloid production by Solanum aviculare hairy roots. Enzyme Microb Technol 18: 238-243.).

In most of the cases, the enhanced induction of metabolites production is found to be associated with elevated levels of sucrose in culture media. A higher carbohydrate content in the medium might promote stress on plant cells and tissues, changing cellular metabolism, tissues growth and secondary compounds production (Cui et al. 2010CUI XH, MURTHY HN, WU CH & PAEK KY. 2010. Sucrose-induced osmotic stress affects biomass, metabolite, and antioxidant levels in root suspension cultures of Hypericum perforatum L. Plant Cell Tissue and Organ Cult 103: 7-14.). In yerba mate callus culture, however, this behaviour was not observed for any compound analysed (Figure 5).

These unusual results may be related to the class of compounds that higher sucrose concentrations can induce or hinder through metabolic alterations caused by osmotic or carbonyl stress. For example, the osmotic stress caused by sugars may favour the increase of the concentration of endogenous abscisic acid in cultured plant cells (Mishra & Singh 2016MISHRA VK & SINGH RM. 2016. Sorbitol and sucrose- induced osmotic stress on growth of wheat callus and plant regeneration. Curr Trends Biotechnol Pharm 10: 20-28.), which in turn regulates negatively the accumulation of some secondary compounds, like phenylpropanoids (Graham & Graham 1996GRAHAM TL & GRAHAM MY. 1996. Signaling in soybean phenylpropanoid responses (dissection of primary, secondary, and conditioning effects of light, wounding, and elicitor treatments). Plant Physiol 110: 1123-1133.). In addition, the most suitable carbohydrate source and its optimal concentration should be identified for the production of secondary compounds in cell and callus cultures. These factors depend on plant species and compounds of interest. Therefore it is necessary to optimize the carbon sources in each case as suggested by Misawa (1994)MISAWA M. 1994. Plant tissue culture: an alternative for production of useful metabolites, 1st ed., Rome: Food and Agriculture Organization of the United Nations (FAO), 87 p. and Murthy et al. (2014)MURTHY HN, LEE EJ & PAEK KY. 2014. Production of secondary metabolites from cell and organ cultures: Strategies and approaches for biomass improvement and metabolite accumulation. Plant Cell Tissue Organ Cult 118: 1-16..

Sucrose at 3% concentration was efficient for the production of compounds with high added value (i.e. caffeoylquinic and dicaffeoylquinic acids), which may be used in different industrial segments. In this way, yerba mate callus culture might be considered as an alternative source of such compounds, allowing the continuous production through plant callus culture-based technology. New elicitors should be evaluated in order to improve the compounds accumulation and calli biomass.

CONCLUSIONS

The clone 6-156-6 is the most responsive genotype among the tested ones for callus induction. Medium supplemented with 4.56 µM zeatin and 4.52 µM 2,4-D is efficient for callus induction and biomass accumulation.

Medium supplementation with 3% sucrose results in higher calli biomass accumulation, and higher total phenolics and caffeoylquinic acids content.

Two methylxanthines, three caffeoylquinic acids and three dicaffeoylquinic acids were identify as the major compounds in yerba-mate callus culture.

ACKNOWLEGMENTS

We thank the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) the and Empresa Brasileira de Pesquisa Agropecuária (EMBRAPA – Forestry).

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Publication Dates

Publication in this collection
11 Nov 2020
Date of issue
2020

History

Received
26 Nov 2018
Accepted
20 May 2019

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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Cytokinins (µM)		Callus induction (%)	Fresh weight (mg) (120 days)
Zeatin	2.25	36 ± 4 ^b	175.5 ± 9.5 ^b
	4.56	82 ± 5.5 ^a	328.2 ± 23.4 ^a
	9	56 ± 6.5 ^ab	299.2 ± 15.7 ^a
TDZ	0.15	60 ± 7.8 ^ab	123.0 ± 7.6 ^b
	0.25	44 ±5.8 ^b	166.1 ± 4.6 ^b
	0.5	58 ± 5.3 ^ab	295.6 ± 23.5 ^a
2 iP	2.5	46 ± 4.2 ^b	177.3 ± 14.4 ^b
	5	48 ± 8.5 ^b	194.7 ± 8.6 ^b
	7.5	42 ± 5.4 ^b	295.6 ± 23.5 ^a
Kinetin	2.5	58 ± 6.9 ^ab	191.2 ± 23.8 ^b
	5	44 ± 7.7 ^b	150.6 ± 7.9 ^b
	7.5	60 ± 7.3 ^ab	143.8 ± 12.4 ^b

RT (min)	Compound	Formula	Found mass	MS–MS	Reference
4.39	Theobromine	C₇H₈N₄O₂	[M+1] 181.0723	67.02, 138.06, 163.06, 181.07	(Choi et al. 2013CHOI EJ, BAE SH, PARK JB, KWON MJ, JANG SM, ZHENG YF & BAE SK. 2013. Simultaneous quantification of caffeine and its three primary metabolites in rat plasma by liquid chromatography–tandem mass spectrometry. Food Chem 141: 2735-2742.)
4.96	5-O-caffeoylquinic acid - neochlorogenic acid	C₁₆H₁₈O₉	[M-1] 353.0878	191, 135.04, 179.03, 134.03	Standard, (Carini et al. 1998CARINI M, FACINO RM, ALDINI G, CALLONI M & COLOMBO L. 1998. Characterization of phenolic antioxidants from mate (Ilex paraguayensis) by liquid chromatography/mass spectrometry and liquid chromatography/tandem mass spectrometry. Rapid Commun Mass Spectrom 12: 1813-1819., Dartora et al. 2011DARTORA N, DE SOUZA LM, SANTANA-FILHO AP, IACOMINI M, VALDUGA AT, GORIN PA & SASSAKI GL. 2011. UPLC-PDA–MS evaluation of bioactive compounds from leaves of Ilex paraguariensis with different growth conditions, treatments and ageing. Food Chem 129: 1453-1461.)
6.63	4-O-Caffeoylquinic acid -Cryptochlorogenic acid	C₁₆H₁₈O₉	[M-1] 355.1030	173, 179	Standard, (Carini et al. 1998, Dartora et al. 2011)
6.76	Chlorogenic acid (3-O-Caffeoylquinic acid)	C₁₆H₁₈O₉	[M-1] 353.0878	191, 135.04, 173.04	Standard, (Dartora et al. 2011)
6.85	Caffeine	C₈H₁₀N₄O₂	[M+1] 195.0878	138.06, 110.07, 83.06, 123.04, 195	Standard, (Choi et al. 2013).
13.19	3,4-O-[E]-dicaffeoylquinic acid (3,4-diCQA)-	C₂₅H₂₄O₁₂	[M-1] 515.1195	173.04 , 179.03, 191.05, 353.08, 135.04, 335.07, 160, 155.03, 137.02	(Dartora et al. 2011, Aboy et al. 2012ABOY AL, APEL MA, DEBENEDETTI S, FRANCESCATO L, ROSELLA MA & HENRIQUES AT. 2012. Assay of caffeoylquinic acids in Baccharis trimera by reversed-phase liquid chromatography. J Chromatogr A 1219: 147-153.)
13.92	3,5-O-[E]-dicaffeoylquinic acid (3,5-diCQA)	C₂₅H₂₄O₁₂	[M-1] 515.1195	191.05, 179.03, 353.08, 135.04	(Dartora et al. 2011, Aboy et al. 2012)
14.78	4,5-O-[E]-dicaffeoylquinic acid (4,5-diCQA)	C₂₅H₂₄O₁₂	[M-1] 515.1195	173.04, 179.03, 353.08, 191.05, 135.04	(Dartora et al. 2011, Aboy et al. 2012)

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