Effect of climatic conditions on the productive and biochemical characteristics of grape varieties grown on sierozem soil

Year 2022, Volume: 11 Issue: 2, 174 - 183, 01.04.2022

Shokan N. Kulzhanov Saule Z. Kazybayeva Tolepbergen S. Tazhibaev Laura A. Azhitaeva Maira Yessenaliyeva

https://doi.org/10.18393/ejss.1057156

Cited By: 2

Abstract

The aim of this study was to evaluate the effect of climatic conditions on phenological observations, yield components and biochemical characteristics of grape varieties grown on sierozem soil of Turkestan region, Southern Kazakhstan. A total of 13 different medium and late grape ripening varieties known, loved and widely used by the local people for many years in cultivation were chosen. The phenological observations (date of budding and removable maturity date of grape) yield components (yield of grape, weight of bunch of grape, number of bunch of grapes, as well as productivity) and the biochemical characteristics (titratable acidity, glucoacidimetric index, glucose content, fructose content) of grape varieties were evaluated in three seasons (2018-2020). During the vegetation period, date of budding and removable maturity date observations were made and recorded as day/month. As a result of the study, differences were found among local genotypes in terms of phenological stages. On the average of years, the earliest date of budding was recorded on 21 March with Children’s early and the latest date of budding was observed on 02 April Moldova and Victory. The highest yield and productivity were obtained from varieties Husayn kelin barmak and Chocolate grape varieties. Titratable acidity range was between 5 g/L – 8g/L, in average of years, the highest titratable acidity in late ripening grape varieties was found in Victory (7.3 g/L) while Moldova (6.0 g/L) had the lowest. Titratable acidity of Husayn kelin barmak (7.3 g/L) was determined also higher than the medium ripening grape varieties while Guzal Kara had the lowest, only 5.3 g/L. Glucose and fructose contents were determined as 8.58% and 11.04 in different grape varieties, respectively.

Keywords

Sierozem soil, grape, climate, sugar, phenological observations

References

• Absatova, B., Orazbayev, S., Yelibayeva, G., Shoibekova, A., Sydyk, D., 2022. Productivity of indigenous alfalfa (Medicago sativa) cultivar depending on agricultural practices on sierozem soils in South Kazakhstan. Eurasian Journal of Soil Science 11(1): 61-65.
• AOAC, 2000, AOAC Official method 942.15 Acidity (Titrable) of fruit products.
• Ashenfelter, O., Storchmann, K., 2014. Wine and Climate Change. American Association of Wine Economists. AAWE Working Paper No. 152. 43p.
• Bock, A., Sparks, T.H., Estrella, N., Menzel, A., 2013. Climate-Induced Changes in Grapevine Yield and Must Sugar Content in Franconia (Germany) between 1805 and 2010. PLoS ONE 8: e69015.
• Bonada, M., Sadras, V.O., 2015. Critical appraisal of methods to investigate the effect of temperature on grapevine berry composition. Australian Journal of Grape and Wine Research 21(1): 1–17.
• Botelho, R.V., Pavanello, A.P., Pires, E.J.P.,Terra, M.M., Müller, M.M.L.,2011. Organic production of red wine grapes under plastic cover in subtropical region of Brazil. Ciência e Agrotecnologia 35(6): 1186-1195.
• Cangi, R., Bekar, T., 2017. Determination of phenological development phases and effective temperature aggregation requests of narince grape cultivars grown in different ecologies in Tokat. Turkish Journal of Applied Sciences and Technology 1(2): 86-90.
• Chmielewski, F.M., Müller, A., Bruns, E., 2004. Climate changes and trends in phenology of fruit trees and field crops in Germany, 1961–2000. Agricultural and Forest Meteorology 121 (1-2): 69–78.
• Cleland, E.E., Chuine, I., Menzel,A., Mooney, H.A., Schwartz, M.D., 2007. Shifting plant phenology in response to global change. Trends in Ecology and Evoluation 22(7): 357–365.
• Costa, C., Graça, A., Fontes, N., Teixeira, M., Gerós, H., Santos, J.A., 2020. The interplay between atmospheric conditions and grape berry quality parameters in Portugal. Applied Sciences 10(14): 4943. da Silva, M.J.R., Paiva, A.P.M., Junior, A.P., Sáncheza, C.A.P.C., Callili, D.C., Moura, M.F., Leonel, S., Tecchio, M.A., 2018. Yield performance of new juice grape varieties grafted onto different rootstocks under tropical conditions. Scientia Horticulturae 241: 194-200.
• de Orduña, M.R., 2010. Climate change associated effects on grape and wine quality and production. Food Research International 43(7): 1844–1855.
• Estrella, N., Menzel, A., 2006. Responses of leaf colouring in four deciduous tree species to climate and weather in Germany. Climate Research 32(3): 253–267.
• FAO-OIV Focus, 2016. Table and dried grapes: Non-alcoholic products of the vitivinicultural sector intended for human consumption. Food and Agriculture Organization of the United Nations (FAO) and the International Organisation of Vine and Wine (OIV). 64p. Avaliable at [Access date: 15.06.2021]: http://www.fao.org/3/a-i7042e.pdf
• Fraga, H., Santos, J.A., Moutinho-Pereira, J., Carlos, C., Silvestre, J., Eiras-Dias, J., Mota, T., Malheiro, A.C., 2016. Statistical modelling of grapevine phenology in Portuguese wine regions: Observed trends and climate change projections. The Journal of Agricultural Science 154(5): 795–811.
• Gordo, O., Sanz, J.J., 2009. Long-term temporal changes of plant phenology in the Western Mediterranean. Global Change Biology 15(8): 1930–1948.
• Granato, D., Carrapeiro, M.M., Fogliano, V., Van Ruth, S.M., 2016. Effects of geographical origin, varietal and farming system on the chemical composition and functional properties of purple grape juices: a review. Trends in Food Science & Technology 52: 31–48.
• Hernandes, J.L., Pedro Júnior, M.J., Santos, A.O., Tecchio, M.A., 2010. Phenology and yield of american and hybrid grapevine cultivars in Jundiaí, state of São Paulo (Brazil). Revista Brasileira de Fruticultura 32: 135–142.
• Jackson, D.I., Lombard, P.B., 1993. Environmental and management practices affecting grape composition and wine quality: a review. American Journal of Enology and Viticulture 4: 409–430.
• Jones, G., Reid, R., Vilks, A., 2012. Climate, Grapes, and Wine: Structure and Suitability in a Variable and Changing Climate. In: The Geography of Wine. Dougherty, P.H. (Ed.). Springer: Dordrecht, The Netherlands, pp. 109–133.
• Kafkas, E., Koşar, M., Türemiş, N., Başer, K.H.C., 2006. Analysis of sugars, organic acids and vitamin C contents of blackberry genotypes from Turkey. Food Chemistry 97(4): 732-736.
• Kliewer, W.M., 1973. Berry composition of Vitis vinifera cultivars as influenced by photo and nycto-temperatures during maturation. Journal of the American Society for Horticultural Science 98: 153-159.
• Kose, B., 2014. Phenology and ripening of Vitis vinifera L. and Vitis labrusca L. varieties in the maritime climate of Samsun in Turkey’s Black Sea Region. South African Journal for Enology and Viticulture 35: 90-102.
• Menzel, A., Jakobi, G., Ahas, R., Scheifinger, H., Estrella, N., 2003. Variations of the climatological growing season (1951–2000) in Germany compared with other countries. International Journal of Climatology 23(7): 793–812.
• Menzel, A., Sparks, T.H., Estrella, N., Aasa, A., Alm-Kübler, K., Bissolli, P., … Zach, S., Zust, A., 2006. European phenological response to climate change matches the warming pattern. Global Change Biology 12(10): 1969-1976.
• Nelson, N., 1944, A photometric adaptation of the Somogyi method for the determination of glucose. Journal of Biological Chemistry 153(2): 375-379.
• Nurgel, C., Erten, H., Canbaş, A., Cabaroglu, T., Selli, S., 2002. Contribution by Saccharomyces cerevisiae yeasts to fermentation and flavour compounds in wines from cv. Kalecik karasi grape. Journal of the Institute Brewing 108(1): 68-72.
• Pérez-Magariño, S., González-San José, M.L., 2006. Polyphenols and colour variability of red wines made from grapes harvested at different ripeness grade. Food Chemistry 96(2): 197-208.
• Santos, J., Graetsch, S., Karremann, M., Jones, G., Pinto, J., 2013. Ensemble projections for wine production in the Douro Valley of Portugal. Climatic Change 117: 211–225.
• Santos, J.A., Fraga, H., Malheiro, A.C., Moutinho-Pereira, J., Dinis, L.-T., Correia, C., Moriondo, M., Leolini, L., Dibari, C., Costafreda-Aumedes, S., Kartschall, T., Menz, C., Molitor, D., Junk, J., Beyer, M., Schultz, H.R., 2020. A Review of the potential climate change impacts and adaptation options for european viticulture. Applied Sciences 10(9): 3092.
• Saxton, V.P., Creasy, G.L., Paterson, A.M., Trought, M.C.T., 2009. Behavioral responses of European blackbirds and Australasian silvereyes to varying acid and sugar levels in artificial grapes. American Journal of Enology and Viticulture 60(1): 82-86.
• Schwartz, M.D., Ahas, R., Aasa, A., 2006. Onset of spring starting earlier across the Northern Hemisphere. Global Change Biology 12(2): 343–351.
• Varandas, S., Teixeira, M.J., Marques, J.C., Aguiar, A., Alvesa, A., Bastos, M.M.S.M., 2004. Glucose and fructose levels on grape skin: interference in Lobesia botrana behaviour. Analytica Chimica Acta 513(1): 351-355.
• Yoncheva, T., Haygarov, V., Dimitrov, D., 2019. Study of weather conditions infl uence on the grapes quality and some technological practices on the chemical composition, aromatic profile and organoleptic characteristics of white wines. Bulgarian Journal of Agricultural Science 25(6): 1151–1160.