Seasonal Changes in Black Currant Fruit Quality

Document Type : Original Research

Authors
S. Paunovic 1
P. Maskovic 2
M. Milinkovic 1
Z. Karaklajic-Stajic 1
J. Tomic 1
B. Rilak 1
1 Department of Fruit Growing Technology, Fruit Research Institute, Čačak, Republic of Serbia.
2 Department of Chemistry and Chemical Engineering, University of Kragujevac, Faculty of Agronomy, Čačak, Republic of Serbia
10.22034/jast.25.5.1155
Abstract
An experiment was conducted during eight years (2012–2019) to examine the effect of climatic variations (air temperature and precipitation) on the nutritional quality of berries of three black currant cultivars (‘Ben Lomond’, ‘Titania’ and ‘Čačanska Crna’). HPLC was used for the determination of sugars and organic acids extracted from berries, while ascorbic acid and minerals were evaluated by spectrophotometry. Results indicated that the chemical profile of black currants varied among cultivars. ‘Ben Lomond’ and ‘Čačanska Crna’ exhibited excellent chemical characteristics of the berries, primarily in terms of their high sugars and organic acids content, but ‘Čačanska Crna’ stood out for its highest values of ascorbic acid. Also, seasonal variations caused by temperatures and precipitation affected the biosynthesis of primary metabolites in berries. The heavier precipitation and lower temperatures during berry formation and ripening promoted the accumulation of organic acids and ascorbic acid, as well as minerals P and Fe. Conversely, moderate temperatures and rainfall amounts promoted the synthesis of soluble solids, sugars and proteins, whereas higher temperatures and lower precipitation amount enhanced accumulation of the other tested minerals. PCA analysis showed the correlations among the cultivar/year interactions and identified group patterns. The results showed that the chemical properties of black currant not only depend on the genetic predisposition of the cultivar but also on climatic conditions like air temperature and precipitation, which have an important effect on nutrient metabolism in plants and promote biosynthesis and accumulation of primary metabolites in berries.

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Subjects

Anttonen, M. J., Hoppula, K. I., Nestby, R., Verheul, M. J. and Karjalainen, R. O. 2006. Influence of fertilization, mulch color, early forcing, fruit order, planting date, shading, growing environment, and genotype on the contents of selected phenolics in strawberry (Fragaria × ananassa Duch.) fruits. J. Agric. Food Chem., 54: 2614–2620.
Boccorh R. K., Paterson A. and Piggott J. R. 1998. Factors influencing quantities of sugars and organic acids in blackcurrant concentrates. LWT-Food Sci. Technol., 206: 273–278.
Brennan, R. M. 1996. Currants and gooseberries. In: Janick J & Moore JN (Eds.) Fruit Breeding, Vol. II: Vine and Small Fruits Crops. John Wiley and Sons, Inc, New York, PP. 191–295.
Colaric, M., Veberic, R., Stampar, F. and Hudina, M. 2005. Evaluation of peach and nectarine fruit quality and correlations between sensory and chemical attributes. J. Sci. Food Agric., 85: 2611–2616.
Cosmulescu, S., Trandafir, I. and Nour, V. 2015. Mineral composition of fruit in black and red currant. South-Western J. Hortic., Biol. Environ., 6: 43–51.
Davik, J., Bakken, A. K., Holte, K. and Blomhoff, R. 2006. Effects of genotype and environment on total anti-oxidant capacity and the content of sugars and acids in strawberries (Fragaria × ananassa Duch.). J. Hortic. Sci. . Biotech., 81: 1057–1063.
Egan, H., Kirk, R. and Sawyer, R. (Eds) 1981. The Luff Schoorl method. Sugars and preserves. In Pearson's chemical analysis of foods. 8th edn. Harlow. UK: Longman Scientific and Technical., PP. 151–153.
Gorinstein, S., Zachwieja, Z., Folta, M., Barton, H., Piotrowicz, J., Zemser, M., Weisz, M., Trakhtenberg, S. and Màrtín-Belloso, O. 2001. Comparative contents of dietary fiber, total phenolics, and minerals in persimmons and apples. J. Agric. Food Chem., 49: 952–957.
Hegedűs, A., Balogh, E., Engel, R., Sipos, B. Z., Papp, J., Blázovics, A. and Stefanovits-Bányai, E. 2008. Comparative nutrient element and antioxidant characterization of berry fruit species and cultivars grown in Hungary. Hortic. Sci., 43: 1711–1715.
Kaldmae, H., Kikas, A., Arus, L. and Libek, A. 2013. Genotype and microclimate conditions influence ripening pattern and quality of blackcurrant (Ribes nigrum L.) fruit. Zemdirbyste-Agric., 2: 164–174.
Kafkas, E., Kosar, M., Paydas, S., Kafkas, S. and Baser, K. H. C. 2006. Quality characteristics of strawberry genotypes at different maturation stages. Food Chem., 100: 1229–1236.
Lister, E. C., Wilson, E. P., Sutton, H. K. And Morrison, C. S. 2002. Understanding the health benefits of blackcurrants. Acta Hortic., 585: 443–449.
Lefevre, I., Ziebel, J., Guignard, C., Sorokin, A., Tikhonova, O., Dolganova, N., Hoffmann, L., Eyzaguirre, P. and Hausman, J. F. 2011. Evaluation and comparison of nutritional quality and bioactive compounds of berry fruits from Lonicera caerulea, Ribes L. species and Ribes ideaus grown in Russia. J. Berry Res., 3: 159–167.
Moretti, C. L., Mattos, M. L., Calbo, G. A. and Sargent, A. S. 2010. Climate changes and potential impacts on postharvest quality of fruit and vegetable crops: A review. Food Res. Inter., 43: 1824–1832.
Milivojević, J., Maksimović V. and Nikolić M. 2009. Sugar and organic acids profile in the fruits of black and red currant cultivars. J. Agric. Sci., 54: 105–117.
Nikolić, M., Vulić, T., Milivojević, J. and Đorđević B. 2006. Pomological characteristic of newly introducted black currant cultivars (Ribes nigrum L.). Proceeding of International Conference of Perspectives in European Fruit Growing. Lednice, Czech Republic, PP. 200–203.
Nikolić, M. and Milivojević, J. 2010. Small fruit crops. Production technology. Scientific Pomological Society of Serbia.
Perkins-Veazie, P. and Collins, K. J. 2001. Contribution of nonvolatile phytochemicals to nutrition and flavor. HortTchnol., 11: 539–546.
Raudsepp, P., Kaldmae, H., Kikas, A., Libek, A. V. and Pussa, T. 2010. Nutritional quality of berries and bioactive compounds in the leaves of black currant (Ribes nigrum L.) cultivars evaluated in Estonia. J. Berry Res., 1: 53–59.
Rubinskiene, M., Viskelis, P., Jasutiene, I., Duchovskis, P. and Bobinas, C. 2006. Changes in biologically active constituents during ripening in black currants. J. Fruit and Ornamental Plant Res., 14: 237–246.
Shivashankara, K. S., Rao, N. K. S. and Geetha, G. A. 2013. Impact of climate change on fruit and vegetable quality. Climate-Resilient Horticulture: Adaptation and Mitigation Strategies, 237–244.
Sim, I., Suh, D. H., Singh, D., Do, S. G., Moon, K. H., Lee, J. H., Ku, K. M. and Lee, C. H. 2017. Unraveling metabolic variation for blueberry and chokeberry cultivars harvested from different geo‐climatic regions in Korea. J. Agric. Food Chem., 65: 9031–9040.
Stewart, L.A. and Ahmed, S. 2020. Effects of climate change on fruit nutrition. Fruit Crops, Diagnosis and Management of Nutrient Constraints, 77–93.
Sturm, K., Koron, D. and Stampar, F. 2003. The composition of fruit of different strawberries varieties depending on maturity stage. Food Chem., 83: 417–422.
Tiwari, U. and Cummins, E. 2013. Factors influencing levels of phytochemicals in selected fruit and vegetables during pre-and post-harvest food processing operations. Food Res. Inter., 50: 497–506.
Uleberg, E., Rohloff, J., Jaakola, L., Trôst, K., Junttila, O., Haggman, H. and Martinussen, I. 2012. Effects of temperature and photoperiod on yield and chemical composition of northern and southern clones of bilberry (Vaccinium myrtillus L.). J. Agric. Food Chem., 60: 10406–10414.
Vagiri, M., Ekholm, A., Oberg, E., Johansson, E., Andersson, C. S. and Rumpunen, K. 2013. Phenols and ascorbic acid in black currants (Ribes nigrum L.): Variation due to genotype, location, and year. J. Agric. Food Chem., 61: 9298–9306.
Walker, P. G., Viola, R., Woodhead, M., Jorgensen, L., Gordon, S. L., Brennan, R. M. and Hancock, R. D. 2010. Ascorbic acid content of black currant fruit is influenced by both genetic and environmental factors. Func. Plant Sci. Biotechol., 4: 40–52.
Watson, R., Wright, C. J., Mcburney, T., Taylor, A. J.and Linforth, R. S. T. 2002. Influence of harvest date and light integral on the development of strawberry flavor compounds. J. Exp. Bot., 53: 2121–2129.
Woznicki, L. T., Sønsteby, A., Aaby, K., Martinsen, K. B., Heide M. O., Wold, A. B. and Remberg, F. S. 2017. Ascorbate pool, sugars and organic acids in black currant (Ribes nigrum L.) berries are strongly influenced by genotype and post-flowering temperature. J. Sci. Food Agric., 97: 1302–1309.
Woolf, A. B., Ferguson, I. B., Requejo-Tapia, L. C., Boyd, L., Laing, W. A. and White, A. 1999. ‘Impact of sun exposure on harvest quality of ‘Hass’ avocado fruit. Revista Chaingo Ser. Hortic., 5: 352–358.
Journal of Agricultural Science and Technology
Volume 25, Issue 5
September and October 2023
Pages 1155-1166