Abstract

Pereskia aculeata Miller is a native cactaceae found from the Northeast to the South of Brazil. This plant is recognized by the high nutritional value of their leaves, which are the most used in cooking and folk medicine. However, studies on the chemical characteristics and antioxidant capacity of the ora-pro-nobis fruits are scarce. Therefore, the aim of this study was to determine the best harvest point of the ora-pro-nobis fruits to optimize the content of bioactive compounds and their antioxidant capacity. The fruits were manually harvested, defined by their peel colors in three maturity stages: unripe (green), intermediate (yellowish green), and ripe (yellow) stages. The following attributes were evaluated: soluble solids (SS), titratable acidity (TA), SS/TA ratio, pH, and content of bioactive compounds, such as total chlorophylls, carotenoids, yellow flavonoids, total phenolic compounds, and antioxidant capacity. There was a decrease in the content of chlorophyll followed by an increase in the of total carotenoids and yellow flavonoids, due to the maturity stage. For the total phenolic compounds, it was not observed significant difference between the stages. The antioxidant capacity was quantified by the ORAC method in lyophilized pulp in the unripe (1.95 mmol 100 g-1 trolox) and ripe (3.85 mmol 100 g-1 trolox) stages. The lowest contents were observed in the intermediate (0.80 mmol 100 g-1 trolox in lyophilized pulp) stage. The maturity stage significantly influenced the bioactive compounds of ora-pro-nobis, which presented higher values of total carotenoids, yellow flavonoids, and antioxidant capacity in ripe fruits.

Index terms
Pereskia aculeata Miller; Maturity index; Harvest point; Postharvest; Brazilian native fruits

Resumo

Pereskia aculeata Miller é uma cactaceae nativa encontrada do Nordeste ao Sul Brasileiro. A planta é reconhecida pelo alto valor nutritivo das folhas, parte mais utilizada na culinária e na medicina popular. Entretanto, trabalhos sobre as características químicas e a capacidade antioxidante dos frutos de ora-pro-nóbis são escassos. Diante disso, o objetivo deste estudo foi determinar o melhor ponto de colheita em frutos de ora-pro-nóbis, visando a otimizar a presença de compostos bioativos e a capacidade antioxidante. Os frutos foram colhidos manualmente, e os três estádios de maturação foram definidos pela coloração da casca, sendo: estádio verde (coloração verde), intermediário (coloração verde - amarelada) e maduro (coloração amarela). Os atributos avaliados foram os sólidos solúveis (SS), acidez titulável (AT), relação SS/AT, pH, e os compostos bioativos, como as clorofilas totais,carotenoides totais, flavonoides amarelos, compostos fenólicos totais e capacidade antioxidante. Houve diminuição da clorofila e aumento no teor de carotenoides totais e flavonoides amarelos, em função do avanço no estádio de maturação. Para os compostos fenólicos totais, não houve diferença significativa entre os estádios avaliados. A capacidade antioxidante foi quantificada pelo método ORAC, em polpa liofilizada no estádio verde, (1,95 mmol 100 g-1 trolox) e maduro (3,85 mmol 100 g-1 trolox). Os menores teores foram observados no estádio intermediário (0,80 mmol 100 g-1 trolox em polpa liofilizada). O estádio de maturação influenciou de forma significativa sobre os compostos bioativos de ora-pro-nóbis, que apresentaram valores mais elevados de carotenoides totais, flavonoides amarelos e capacidade antioxidante em frutos maduros.

Termos para indexação
Pereskia aculeata Miller; Índice de maturação; Ponto de colheita; Pós-colheita; Frutos nativos brasileiros

Introduction

Pereskia aculeata Miller is a creeper plant, which belongs to the Cactaceae family, being native of South and Central America, and tropical America which is naturally distributed from the Northeast to the South of Brazil (SHARIF et al., 2013 SHARIF, K.M.; RAHMAN, M.M.; ZAIDUL, I.S.M.; JANNATUL, A.; AKANDA, M.J.H.; MOHAMED, A.; SHAMSUDIN, S.H. Pharmacological relevance of primitive leafy cactuses Pereskia. Research Journal of Biotechnology, Karachi, v.8, n.12, p.134-142, 2013. ). It is highlighted as a native plant of excellent potential, being a source of bioactive and nutrient substances (BRASIL, 2004 BRASIL. Ministério da Saúde. Guia alimentar para a população brasileira. Brasília, DF, 2004. 210p. ). In Brazil, it is known as ora-pro-nobis, and its leaves are the only part traditionally consumed, being used in culinary and folk medicine (SOUZA et al., 2015 SOUZA, M.S.S.; BARBALHO, S.M.; GUIGUER, E.L.; ARAÚJO, A.C.; BUENO, P.C.S.; FARINAZZI-MACHADO, F.M.V.; LIMA, L.M.L.; SILVA, B.C.; MENDES, C.G. Effects of Pereskia aculeata Miller on the Biochemical Profiles and Body Composition of Wistar Rats. Journal of Biosciences and Medicines, Zurich, v.3, n.7, p.82-89, 2015. ).

Recent studies have reported the fruits from Pereskia aculeata Miller (AGOSTINI-COSTA et al., 2012 AGOSTINI-COSTA, T. D.S.; WONDRACECK, D. C.; ROCHA, W. D. S.; SILVA,D. B. D. Carotenoids profile and total polyphenols in fruits of Pereskia aculeata Miller. Revista Brasileira de Fruticultura, Jaboticabal, v. 34, n. 1, p. 234-238, 2012. ) and the leaves from Pereskia grandifolia Haw (SIM et al., 2010 SIM, K.S.; NURESTRI, A.M.S.; NORHANOM, A.W. Phenolic content and antioxidant activity of crude and fractionated extracts of Pereskia bleo (Kunth) DC. (Cactaceae). African Journal of Pharmacy and Pharmacology, Nairobi, v.4, n.5, p.193-201, 2010. ) and Pereskia bleo (Kunth) DC. (BAKHARI et al., 2010 BAKHARI, N.A.; ABDULLAH, A.R.; OSMAN, H.; NORDIN, N.H. The relationship between phenolic, tannin and flavonoid content with the antioxidant activity of Pereskia bleo (Kunth). In: INTERNATIONAL CONFERENCE ON SCIENCE AND SOCIAL RESEARCH, 2010, Malysia. Abstracts… Malysia: IEEE, 2010. p. 494-498. ) are good sources of carotenoids with antioxidant activities.

Although the fruits of ora-pro-nobis have been underused, they are commonly recognized as nutraceutic, or functional and medicinal food, with anti-inflammatory and antinociceptive effects (BARBALHO et al. 2016 BARBALHO, S.M.; GUIGUER, E.L.; MARINELLI, P.S.; DO SANTOS BUENO, P.C.; PESCININI-SALZEDAS, L.M.; SANTOS, M.C.B.; OSHIIWA, M.; MENDES, C.G.; DE MENEZES, M.L.; NICOLAU, C.C.T.; OTOBONI, A.M.; DE ALVARES, G.R. Pereskia aculeata Miller Flour: metabolic effects and composition. Journal of Medicinal Food, New York, v.19, n.9, p.890-894, 2016. ; SILVA JÚNIOR et al., 2010 SILVA JÚNIOR, A.A.; NUNES, D.G.; BERTOLDI, F.C.; PALHANO, M.N.; KOMIEKIEWICZ, N.L.K. Pão de ora-pro-nóbis um novo conceito de alimentação funcional. Agropecuária Catarinense, Santa Catarina, v.23, n.1, p.35-37, 2010. ). The ora-pro-nobis fruits have oval, piriform or rounded shape, yellowish-green, yellow-orange or reddish color (BRASIL, 2010 BRASIL. Ministério da Agricultura, Pecuária e Abastecimento. Manual de hortaliças não-convencionais. Brasília: MAPA/ACS, 2010. p.62-64. ). They are pomaceous, cacti type, with pericarp and seeds dipped in a gelatinous mass (ROSA; SOUZA, 2003 ROSA, S.M.; SOUZA, L.A. Morfo-anatomia do fruto (hipanto, pericarpo e semente) em desenvolvimento de Pereskia aculeata Miller (Cactaceae). Acta Scientiarum Biological Sciences, Maringá, v.25, n.2, p.415-428, 2003. ). According to AGOSTINI-COSTA et al. (2012) AGOSTINI-COSTA, T. D.S.; WONDRACECK, D. C.; ROCHA, W. D. S.; SILVA,D. B. D. Carotenoids profile and total polyphenols in fruits of Pereskia aculeata Miller. Revista Brasileira de Fruticultura, Jaboticabal, v. 34, n. 1, p. 234-238, 2012. , the ora-pro-nobis fruits present protein (1%), fibers (0.7-9.4%), lipids (0.7%), carbohydrates (6.3%); vitamin C (2-125 mg 100 g-1); calcium (174-206 mg 100 g-1), niacin (0.9 mg 100 g-1) and phosphorus (26 mg 100 g-1).

Scarce information on the bioactive compounds and antioxidant capacity of ora-pro-nobis fruits is available; less information about the physicochemical characteristics developed during different maturation stages is also available in the literature. Therefore, this study aimed to determine the best harvesting point in ora-pro-nobis fruits to optimize the presence of bioactive compounds and their antioxidant capacity.

The ora-pro-nobis fruits were collected in June 2014, in a private property, municipality of Campina do Monte Alegre (SP; latitude 23º35’31” S and longitude 48º28’38” W). The fruits were manually harvested in three maturity stages, defined by the peel color. The stages were: unripe (green), intermediate (yellowish green), and ripe (yellow). Then the fruits were transported and selected for no defect to obtain uniform batches.

In the different maturity stages, the fruit pulps were homogenized and submitted to the following analyzes, in triplicates: a) soluble solids (SS) content: quantified in the pulp by direct reading in digital refractometer (Atago PR-101, Palette), and the results were expressed in ºBrix (AOAC, 2012 AOAC - Association of Official Analytical Chemists. Official methods of analysis of AOAC international. 19th ed. Gaithersburg: AOAC International, 2012. 1015p. ); b) titratable acidity (TA): according to methodology described by AOAC (2012) AOAC - Association of Official Analytical Chemists. Official methods of analysis of AOAC international. 19th ed. Gaithersburg: AOAC International, 2012. 1015p. ; the results were expressed as citric acid percentages; c) SS/TA ratio: obtained by the ratio between the SS and TA contents; d) pH: measured in liquefied samples using a potentiometer, according to the methodology described by the AOAC (2012) AOAC - Association of Official Analytical Chemists. Official methods of analysis of AOAC international. 19th ed. Gaithersburg: AOAC International, 2012. 1015p. ; e) content of total chlorophylls and carotenoids: determined by the method described by Lichtenthaler (1987) LICHTENTHALER, H. K. Chorophylls and carotenoids: pigments of photosynthetic biomembranes. In: PACKER, L.; DOUCE, R. (Ed.). Methods in enzymology. London: Academic Press, 1987. p.350-382. ; f) content of yellow flavonoids: determined according to the methodology described by Francis (1982) FRANCIS, F. J. Analysis of anthocyanins. In: MARKAKIS, P. Anthocyanins as food colors. New York: Academic Press, 1982. p. 181-207. ; g) total phenolic compounds (WOISKY; SALATINO, 1998 WOISKY, R.G.; SALATINO, A. Analysis of propolis: some parameters and procedure for chemical quality control. Journal of Apicultural Research, Cardiff, v.37, n.2, p.99-105, 1998. ); h) antioxidant capacity by sequestration of the DPPH and ABTS free radicals (RUFINO et al., 2007 RUFINO, M.S.M.; ALVES, R.E.; BRITO, E.; MORAIS, S.M.; SAMPAIO, C.G.; PÉREZ-JIMÉNEZ, J.; SAURA-CALIXTO, F.D. Metodologia científica: determinação da atividade antioxidante total em frutas pela captura do radical livre ABTS. Fortaleza: Embrapa Agroindústria Tropical, 2007. (Comunicado Técnico). ) and ORAC method (MELO et al., 2015 MELO, P.S.; MASSARIOLI, A.P.; DENNY, C.; SANTOS, L.F.; FRANCHIN, M.; PEREIRA, G.E.; VIEIRA, T.M.F.S.; ROSALEN, P.L.; ALENCAR, S.M. Winery by-products: extraction optimization, phenolic composition and cytotoxic evaluation to act as a new source of scavenging of reactive oxygen species. Food Chemistry, Easton, v. 181, p. 160-169, 2015. ).

The completely randomized experimental design was used, with three replicates (10 fruits each); the data were submitted to analysis of variance and the means were compared using the Tukey’s test (5%). The variables were processed using the SAS software, v. 9.3 (2010) STATSOFT. Statistica: data analysis software system. Version 7. 2004. Disponível em: https://www.statsoft.com.
https://www.statsoft.com.... .

Correlations between bioactive compounds (content of total chlorophylls, carotenoids, and total phenolic compounds, yellow flavonoids, and antioxidant capacity by the ORAC method) were calculated using the Statsoft (2004) STATSOFT. Statistica: data analysis software system. Version 7. 2004. Disponível em: https://www.statsoft.com.
https://www.statsoft.com.... software and coefficients with indices greater than 0.90 were selected.

During fruit ripening, a 91% increase in the SS/ TA ratio between the unripe (2.77) and ripe (5.29) stages was observed (Table 1). Thus, the fruits acquired a more attractive taste for consumption along the maturation stages. The increase in the SS/TA ratio occurred due to an intrinsic ripening processes, mainly degradation of organic acids, and maintenance of soluble solids contents (Table 1). The values for the SS/TA ratio observed in ora-pro-nobis fruits were higher than those evaluated in four passion fruit cultivars (3.15-3.99) (CAVALCANTE et al., 2016 CAVALCANTE, N.R.; KRAUSE, W.; CARVALHO, J.F.; ROCHA, M.K.P.; PALU, E.G.; SILVA, C.A. Productivity, fruit physicochemical quality and distinctiveness of passion fruit populations. Revista Brasileira de Fruticultura, Jaboticabal, v.38, n.4, p.e-142, 2016. ). For soluble solids, the difference between the unripe and ripe stages reached the value of 0.45 ºBrix.

The titratable acidity (TA) of ripe fruits was 1.06% citric acid, which corresponds to a 57% decrease relative to green fruits. Decrease in acidity (about 55%) was also observed in pineapple cv. Vitória fruits when harvested in five different maturity stages (OWAGA et al., 2017 OGAWA, E.M.; COSTA, H.B.; VENTURA, J.A.; CAETANO, L.; PINTO, F.E.; OLIVEIRA, B.G.; BARROSO, M.E.S.; SCHERER, R.; ENDRINGER, D.C.; ROMÃO, W. Chemical profile of pineapple cv. vitória in different maturation stages using electrospray ionization mass spectrometry. Journal of the Science of Food and Agriculture, London, v.98, n.3, p.1105-1116, 2017. ).

The pH values measured in ora-pro-nobis fruits were 3.27 in the unripe stage and 3.58 in ripe stage (Table 1). The decrease in the pH value relates to TA and consumption of organic acids during ripening, when these acids act as substrates in the respiratory process (SILVA et al., 2005 SILVA, T.V.; RESENDE, E.D.; VIANA, A.P.; ROSA, R.C.C.; PEREIRA, S.M.F.; CARLOS, L.A.; VITORAZI, L. Influência dos estádios de maturação na qualidade do suco do maracujá-amarelo. Revista Brasileira de Fruticultura, Jaboticabal, v.27, n.3, p.472-475, 2005. ). However, increase in these values may occur in some fruits along storage, as can be observed in yellow passion fruits (2.74-2.80) (ARAÚJO et al., 2017 ARAÚJO, L.S.; COSTA, E.M.R.; SOARES, T.L.; SANTOS, I.S.; JESUS, O.N. Effect of time and storage conditions on the physical and physico-chemical characteristics of the pulp of yellow and purple passion fruit. Food Science and Technology, Campinas, v. 37, n. 3, p. 500-506, 2017. ).

Ripening of the ora-pro-nobis fruits was externally characterized by a marked change in color. With degradation of the green color, result from a decrease in chlorophyll content, predominate the yellow color and the carotenoids pigments. It was observed that the chlorophyll content in the ripe stage of fruits decreased almost three times as compared to the initial value (Table 1). On the other hand, the value of the total carotenoid content in the ripe stage (2.14 mg g-1) contrasted compared to the initial content (1.82 mg g-1) (Table 1). This behavior was validated by the strong negative correlation obtained between the chlorophyll and total carotenoid variables (Table 2). Qin et al. (2015) QIN, Y.; LI, G.; WANG, L.; TEIXEIRA, J.A.; YE, Z.; FENG, Q.; HU, G.A. comparative study between a late-ripening mutant of citrus and its original line in fruit coloration, sugar and acid metabolism at all fruit maturation stage. Fruits, Paris, v.70, n.1, p.5-11, 2015. also observed an increase in total carotenoid contents in two citrus cultivars at the end of fruit ripening.

Carotenoid and flavonoid pigments have antioxidant properties, associated with the reduction in chronicdegenerative diseases (such as cancer and cardiovascular diseases), besides their anti-inflammatory properties (KAULMANN; BOHN, 2014 KAULMANN, A.; BOHN, T. Carotenoids, inflammation, and oxidative stress—implications of cellular signaling pathways and relation to chronic disease prevention. Nutrition Research, New York, v.34, n.11, p.907-929, 2014. ). The ora-pro-nobis fruits showed an increase in the content of yellow flavonoids between the different ripening stages. In ripe fruits, the contents observed in fresh pulp (9.38 mg 100 g-1) (Table 1) were higher than the mean contents (4.70-6.05 mg 100 g-1) described for passion fruit cultivated in the conventional and organic systems (OLIVEIRA et al., 2017 OLIVEIRA, A.B.; LOPES, M.M.A.; MOURA, C.F.H., OLIVEIRA, L.S.; SOUZA, K.O.; GOMES FILHO, E.; URBAN, L.; MIRANDA, M.R.A. Effects of organic vs. conventional farming systems on quality and antioxidant metabolism of passion fruit during maturation. Scientia Horticulturae, New York. v.222, p.84-89, 2017. ). In the unripe stage, the yellow flavonoids content presented a high negative correlation (-0.99) with the total phenolic compounds contents (Table 2).

The total phenolic compounds did not show statistically significant differences between ripening stages (Table 1). The total phenolic compounds content in orapro- nobis fruits were higher than those observed in some traditional fruits, such as pineapple (33 mg GAE 100 g-1), papaya (33.4 mg GAE 100 g-1), and mango (41.1 mg GAE 100 g-1) (SEPTEMBRE-MALATERRE et al., 2016 SEPTEMBRE-MALATERRE, A.; STANISLAS, G.; DOURAGUIA, E.; GONTHIER, M. P. Evaluation of nutritional and antioxidant properties of the tropical fruits banana, litchi, mango, papaya, passion fruit and pineapple cultivated in Réunion French Island. Food Chemistry, Easton, v.212, p.225-233, 2016. ). The contents of bioactive compounds in ora-pro-nobis fruits explicit their potential to complement the human diet (BARBALHO et al., 2016 BARBALHO, S.M.; GUIGUER, E.L.; MARINELLI, P.S.; DO SANTOS BUENO, P.C.; PESCININI-SALZEDAS, L.M.; SANTOS, M.C.B.; OSHIIWA, M.; MENDES, C.G.; DE MENEZES, M.L.; NICOLAU, C.C.T.; OTOBONI, A.M.; DE ALVARES, G.R. Pereskia aculeata Miller Flour: metabolic effects and composition. Journal of Medicinal Food, New York, v.19, n.9, p.890-894, 2016. ). The antioxidant capacity of native cacti fruits in Brazil is of most importance, since the food-health relationship is being explored and highlighted by the scientific community in this scenario (AGOSTINICOSTA et al., 2012 AGOSTINI-COSTA, T. D.S.; WONDRACECK, D. C.; ROCHA, W. D. S.; SILVA,D. B. D. Carotenoids profile and total polyphenols in fruits of Pereskia aculeata Miller. Revista Brasileira de Fruticultura, Jaboticabal, v. 34, n. 1, p. 234-238, 2012. ; ARAUJO et al., 2016 ARAUJO, R.D.; LUCENA, E.M.P.; GOMES, J.P.; FIGUEIRÊDO, R.M.F.; SILVA, C.P. Characterization of ripening stages of Myrtle fruit. Revista Brasileira de Fruticultura, Jaboticabal, v.38, n.2, 2016. ; BARBALHO et al., 2016 BARBALHO, S.M.; GUIGUER, E.L.; MARINELLI, P.S.; DO SANTOS BUENO, P.C.; PESCININI-SALZEDAS, L.M.; SANTOS, M.C.B.; OSHIIWA, M.; MENDES, C.G.; DE MENEZES, M.L.; NICOLAU, C.C.T.; OTOBONI, A.M.; DE ALVARES, G.R. Pereskia aculeata Miller Flour: metabolic effects and composition. Journal of Medicinal Food, New York, v.19, n.9, p.890-894, 2016. ; MORZELLE et al., 2015 MORZELLE, M.C.; BACHIEGA, P.; SOUZA, E.C.; VILAS BOAS, E.V.B.; LAMOUNIER, M.L. Caracterização química e física de frutos de curriola, gabiroba e murici provenientes do cerrado brasileiro. Revista Brasileira de Fruticultura, Jaboticabal, v.37, n.1, p.96-103, 2015. ). The antioxidant capacity was determined using the ORAC (peroxyl radical sequestering) and synthetic DPPH and ABTS free-radical sequestration methods. DPPH and ABTS methods were not capable to detect antioxidant capacity at all ripening stages (Table 1). However, the antioxidant capacity was measured (ORAC method) in the unripe (1.95 mmol 100 g-1 trolox), intermediate (0.80 mmol 100 g-1 trolox), and ripe (3.85 mmol 100 g-1trolox) stages. Ripe tangerine fruits (Citrus reticulata Blanco cv. Chachiensis), presented an oxidative capacity of 1.7 mmol 100 g-1 trolox (WANG et al., 2016 WANG, H.; CHEN, G.; GUO, X.; ABBASI, A.M.; LIU, R.H. Influence of the stage of ripeness on the phytochemical profiles, antioxidant and antiproliferative activities in different parts of Citrus reticulata Blanco cv.Chachiensis. LWT-Food Science and Technology, Zurich, v.69, p.67-75, 2016. ). In kiwi fruits (Actinidia deliciosa, cv. Hayward), contents of 0.62 mmol 100 g-1 trolox were reported (D’EVOLI et al., 2013 D'EVOLI, L.; MOSCATELLO, S.; BALDICCHI, A.; LUCARINI, M.; CRUZ-CASTILLO, J. G.; AGUZZI, A.; GABRIELLI, P.; PROIETTI, S.; BATTISTELLI, A.; FAMIANI, F.; BÖHM, V.; LOMBARDI-BOCCIA, G. Post-harvest quality, phytochemicals and antioxidant activity in organic and conventional kiwifruit (Actinidia deliciosa, cv. Hayward). Italian Journal of Food Science, Pinerolo, v. 25, n. 3, p. 362-368, 2013. ). Thus, integrates ora-pronobis fruits into the human diet can bring health benefits, since they have a high content of bioactive compounds and a significant antioxidant capacity. In green fruits, a high negative correlation between antioxidant capacity (ORAC) and content of total phenolic compounds was observed, indicating that these components have inverse behaviors at this maturity stage.

Given the results, the progress in the maturity stage positively influences the bioactive and antioxidant compounds of ora-pro-nobis fruits. Harvesting of ripe ora-pronobis fruits provide higher content of total carotenoids, yellow flavonoids, and antioxidant capacity.

Acknowledgments

The authors thank the São Paulo Research Foundation (FAPESP) – grant #2014/13473-7 (scholarship); the Coordination of Improvement of Higher Education Personnel (CAPES) (scholarship); the National Council for Scientific and Technological Development (CNPq) – process #308521/2015-3 (research productivity grant) and 458123/2014-5 (research funding); and the rural producer Helton Muniz, from Campina do Monte Alegre, SP, Brazil, for providing the fruits.

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