Maturation and quality of ‘BRS Magna’ grapes influenced by rootstocks in rainy season

Santos, Luana Ferreira dos; Nascimento, José Henrique Bernardino; Rodrigues, Antônio Augusto Marques; Andrade Neto, Eugenio Ribeiro de; Lima, Maria Auxiliadora Coêlho de

doi:10.1590/1678-992X-2020-0216

ABSTRACT:

Seasonal variations and production factors can influence the quality of grapes. Considering the Sub-middle region of the São Francisco Valley, Brazil, differentiated by production in rainy and warmer periods of the year, the climatic conditions in each season affect the duration of the phenological phases and quality of the grapes. The objective of this study was to characterize the changes in the quality components during maturation of ‘BRS Magna’ grapes on different rootstocks, in rainy seasons under tropical conditions, as a support to define the harvest time. The experiment was conducted in Petrolina, Pernambuco, Brazil, from Jan to Apr 2017 (cycle 1) and Dec 2017 to Apr 2018 (cycle 2) evaluating rootstocks and age of the fruits. Bunches were picked from the start of maturation to the harvest: 49, 56, 61, 64 and 68 days after fruit set (DAF) for cycle 1, and 35, 41, 48, 55, 61, and 66 DAF for cycle 2. In cycle 1 ‘IAC 572’ and ‘Paulsen 1103’ rootstocks provided higher sugar contents in grapes, which was only repeated in cycle 2 for ‘Paulsen 1103’. The accumulation of anthocyanins and yellow flavonoids was favored by ‘IAC 313’ and ‘IAC 572’ rootstocks in cycle 1, and by ‘IAC 313’ and ‘IAC 766’ in cycle 2. A higher content of polyphenols was conferred on ‘IAC 572’ in cycle 1 and on ‘IAC 766’ in cycle 2, which also had a greater antioxidant capacity. Although there were differences between rootstocks, harvesting at approximately 64 DAF maximized grape quality for all treatments.

Keywords
harvest time; hybrid grapes; juice grapes; tropical viticulture

Introduction

Vine cultivation is spread throughout various countries and climatic conditions, serving different markets. In addition to increasing consumption of fresh grapes, as observed in the last decade, there has been an increasing interest in grape products, especially juices (FAO, 2017Food and Agriculture Organization [FAO]. 2017. Table and Dried Grapes: World Data Available. FAO-OIV, Rome, Italy.). Grape production in the tropical zone of Brazil has increased considerably and the Sub-middle region of the São Francisco Valley, northwest of São Paulo State, and north of Minas Gerais State are the main producing centers. In these regions, the lowest temperatures are insufficient to induce dormancy; nevertheless, the use of technology allows for two or more annual harvests (Oliveira et al., 2018Oliveira, J.B.; Faria, D.L.; Duarte, D.F.; Egipto, R.; Laureano, O.; Castro, R.; Ricardo-da-Silva, J.M. 2018. Effect of the harvest season on phenolic composition and oenological parameters of grapes and wines cv. ‘Touriga Nacional’ (Vitis vinifera L.) produced under tropical semi-arid climate, in the state of Pernambuco, Brazil. Ciência e Técnica Vitivinícola 33: 145-166.).

In the Sub-middle region of the São Francisco Valley, grape production is aimed mainly at fresh consumption. However, production of grapes for the juice industry has increased by the introduction of Brazilian cultivars, such as Isabel Precoce (Vitis labrusca) and hybrids ‘BRS Violeta’, ‘BRS Cora’ and ‘BRS Magna’ (Dutra et al., 2018bDutra, M.C.P.; Rodrigues, L.L.; Oliveira, D.; Pereira, G.E.; Lima, M.S. 2018b. Integrated analyses of phenolic compounds and minerals of Brazilian organic and conventional grape juices and wines: validation of a method for determination of Cu, Fe and Mn. Food Chemistry 269: 157-165.).

Since grapes can be produced in any period of the year, climatic conditions in each period can alter the synthesis of chemical compounds, which can add value to products from tropical regions when stimulated (Padilha et al., 2017Padilha, C.V.S.; Miskinis, G.A.; Souza, M.E.A.O.; Pereira, G.E.; Oliveira, D.; Bordignon-Luiz, M.T.; Lima, M.D.S. 2017. Rapid determination of flavonoids and phenolic acids in grape juices and wines by RP-HPLC/ DAD: method validation and characterization of commercial products of the new Brazilian varieties of grape. Food Chemistry 228: 106-115.; Dutra et al., 2018aDutra, M.C.P.; Souza, J.F.; Viana, A.C.; Oliveira, D.; Pereira, G.E.; Lima, M.S. 2018a. Rapid determination of the aromatic compounds methyl-anthranilate, 2’-aminoacetophenone and furaneol by GC-MS: method validation and characterization of grape derivatives. Food Research International 107: 613-618.). In these regions, temperature differences can affect duration of the cycles (Oliveira et al., 2018Oliveira, J.B.; Faria, D.L.; Duarte, D.F.; Egipto, R.; Laureano, O.; Castro, R.; Ricardo-da-Silva, J.M. 2018. Effect of the harvest season on phenolic composition and oenological parameters of grapes and wines cv. ‘Touriga Nacional’ (Vitis vinifera L.) produced under tropical semi-arid climate, in the state of Pernambuco, Brazil. Ciência e Técnica Vitivinícola 33: 145-166.); however, the intensity of these variations has not yet been characterized.

Agronomic components are also determinants of fruit quality. For viticulture, rootstocks play an important role in commercial production in most producing areas worldwide. Rootstock vigor allows to control plant growth and improve grape quality, mitigating climate influence between cycles. Some studies have confirmed this response (Li et al., 2019Li, M.; Guo, Z.; Jia, N.; Yuan, J.; Han, B.; Yin, Y.; Zhao, S. 2019. Evaluation of eight rootstocks on the growth and berry quality of ‘Marselan’ grapevines. Scientia Horticulturae 248: 58-61.; Silva et al., 2018Silva, M.J.R.; Paiva, A.P.M.; Pimentel Junior, A.; Sánchez, C.A.P.C.; Callili, D.; 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.; Bascunán-Godoy et al., 2017Bascunán-Godoy, L.; Franck, N.; Zamorano, D.; Sanhueza, C.; Carvajal, D.E.; Ibacache, A. 2017. Rootstock effect on irrigated grapevine yield under arid climate conditions are explained by changes in traits related to light absorption of the scion. Scientia Horticulturae 218: 284-292.; Lo’ay and El-Khateeb, 2017Lo’ay, A.A.; El-Khateeb, A.Y. 2017. Evaluation the effect of rootstocks on postharvest berries quality of ‘Flame Seedless’ grapes. Scientia Horticulturae 220: 299-302.). However, specificities for scion cultivars and cultivation regions require evaluations for each situation.

This study aimed to characterize changes in the quality components during maturation of ‘BRS Magna’ grapes grafted onto different rootstocks in rainy seasons under tropical conditions as a support to define the harvesting time.

Materials and Methods

Study site

The study was carried out during two productive cycles (2017/2018) in an experimental site at 09°08’03” S, 40°18’40” W, altitude 372 m, in a Plinthic Eutrophic Red-Yellow Argisol with a medium/clayey texture and flat relief in Petrolina, Pernambuco, Brazil. According to the Köppen classification, the climate in this municipality is the BSh type, with very hot and dry periods of nine months and rainfall from Feb to Apr (Alvares et al., 2013Alvares, C.A.; Stape, J.L.; Sentelhas, P.C.; Gonçalves, J.L.M.; Sparovek, G. 2013. Köppen’s climate classification map for Brazil. Meteorologische Zeitschrift 22: 711-728.).

Table 1 shows the meteorological data for the study period registered by an agrometeorological station situated at the experimental site.

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Table 1
Monthly meteorological data during the two production cycles when maturation and quality of 'BRS Magna' grapes were studied from production pruning to harvest.

Cultivation conditions and production pruning

The study was carried out in a BRS Magna cultivar (‘BRS Rubea’ × ‘IAC 1398-21’) vineyard planted in Aug 2014 with the plants trained to overhead trellis system, spaced at 4.0 × 2.0 m and irrigated using microsprinklers. Two production cycles were studied: from 9 Jan to 17 Apr 2017 and from 27 Dec 2017 to 2 Apr 2018. The first fruiting cycle started on 8 Feb 2017 and the second cycle on 27 Jan 2018.

Treatments

The treatments corresponded to rootstocks and age of fruits, characterizing the maturity stages. We evaluated six rootstocks among the most important adopted for grapevines for fresh consumption and for winemaking in the region: ‘IAC 313’ (‘Golia’ × Vitis smalliana), ‘IAC 572’ (Vitis caribaea × ‘101-14 Mgt’), ‘IAC 766’ (‘106-8 Mgt’ × Vitis caribaea), ‘Paulsen 1103’ (Vitis berlandieri × Vitis rupestris), ‘Harmony’ and ‘Freedom’, both having the same parents (Vitis champinii × Vitis vinifera × Vitis labrusca × Vitis riparia). Bunches were taken periodically from the start of grape maturation, recognized from the color change of berries and the start of softening. The collections were made 49, 56, 61, 64, and 68 days after fruit set (DAF) for the first cycle, and 35, 41, 48, 55, 61, and 66 DAF for the second cycle.

Variables analyzed

The bunches were analyzed for: bunch weight (BuW), berry weight (BeW), berry resistance to compression (COMP), titratable acidity (TA), soluble solids content (SS), total soluble sugars (TSS), total anthocyanins (ANT), yellow flavonoids (FLA), total extractable polyphenols (TEP), and the total antioxidant capacity (TAC).

Bunch weight (g) corresponded to the average weight of five recently picked bunches weighed using a semi-analytical balance. Berry weight (g) was determined by the average of 10 grapes from different regions of each bunch, weighed on a semi-analytical balance. Berry resistance to compression (N) was determined in 20 grapes placed longitudinally in a digital texturometer equipped with a P/75 pressure plate, which allowed pressing to 20 % of the volume using a pre-test velocity of 1.00 mm s–1, test velocity of 2.00 mm s–1, pressure of 5.0 g, and distance of 5.00 mm.

The SS content (%) was measured in the must (AOAC, 2010Association of Official Agricultural Chemists [AOAC]. 2010. Official Methods of Analysis of the Association of the Agricultural Chemists. 18ed. AOAC, Gaithersburg, MD, USA.) using a portable digital refractometer with temperature compensation. The TSS contents (g 100 g–1) were quantified using the anthrone reagent and a spectrophotometer at 620 nm (Yemn and Willis, 1954Yemn, E.W.; Willis, A.J. 1954. The estimation of carbohydrate in plant extracts by anthrone. The Biochemical Journal 57: 504-514.). The TA (g tartaric acid 100 mL–1) was determined by titrating with 0.1 N NaOH to the neutral point (AOAC, 2010) using a digital automatic titrator.

The ANT and FLA contents (mg 100 g–1) were quantified in grape skins in an acidified alcoholic solution with readings at 535 nm and 374 nm, respectively (Francis, 1982Francis, F.J. 1982. Analysis of anthocyanins. p. 181-207. In: Markakis, P., ed. Anthocyanins as food colors. Academic Press, New York, NY, USA.). The TEP contents (mg gallic acid 100 g–1) were quantified at 700 nm in the ground skin extracts and pulp macerated in 50 % methanol and 70 % acetone solutions using the Folin Ciocalteau reagent (Larrauri et al., 1997Larrauri, J.A.; Rupérez, P.; Saura-Calixto, F. 1997. Effect of drying temperature on the stabilitity of polyphenols and antioxidant activity of red grape pomace peels. Journal of Agriculture and Food Chemistry 5: 1390-1393.).

The TAC was determined in the same extracts used to quantify the TEP, using the free radical capture methods 2,2-diphenyl-1-picrylhydrazyl (DPPH•) and 2,2’-azino-bis 3-ethylbenzene-thiazoline-6-sulfonic acid (ABTS•+), aiming to obtain more information on the functional potential of the samples, since there are differences in the reactive mechanisms and sensitivities of the methods, for example. The ABTS radical method, expressed in μM Trolox g–1, followed the recommendations of Miller et al. (1993)Miller, N.J.; Diplock, A.T.; Rice-Evans, C.; Davies, M.; Gopinathan, V.; Milner, A. 1993. A novel method for measuring antioxidant capacity and its application to monitoring the antioxidant status in premature neonates. Clinical Science 84: 407-412. with adaptations proposed by Rufino et al. (2010)Rufino, M.M.; Alves, R.E.; Brito, E.S.; Pérez-Jiménez, J.; Saura-Calixto, F.; Mancini-Filho, J. 2010. Bioactive compounds and antioxidant capacities of 18 non-traditional tropical fruits from Brazil. Food Chemistry 121: 996-1002.. Diluted aliquots of samples together with the ABTS•+ radical were read at 734 nm. The DPPH radical capture method (g grape g–1 DPPH) was used according to Sánchez-Moreno et al. (1998)Sánchez-Moreno, C.; Larrauri, J.A.; Saura-Calixto, F. 1998. A procedure to measure the antiradical efficiency of polyphenols. Journal of the Science of Food and Agriculture 76: 270-276. with adaptations suggested by Rufino et al. (2010)Rufino, M.M.; Alves, R.E.; Brito, E.S.; Pérez-Jiménez, J.; Saura-Calixto, F.; Mancini-Filho, J. 2010. Bioactive compounds and antioxidant capacities of 18 non-traditional tropical fruits from Brazil. Food Chemistry 121: 996-1002. with extracts of aliquots in a 0.06 mM solution of DPPH and readings at 515 nm.

Experimental design and statistical analyses

The experimental design was a randomized block with plots subdivided in time for each production cycle studied. The rootstocks were distributed among the plots and dates or ages of the grapes in the sub-plots. Four replicates were made with six plants in each, from which five bunches were picked for each collection. For cycle 1, 120 plots were studied (6 rootstocks × 5 collection dates × 4 blocks), while in cycle 2, 144 plots were studied (6 rootstocks × 6 collection dates × 4 blocks).

The data of each cycle that presented a normal distribution analyzed by the Shapiro-Wilk test were submitted separately to an analysis of variance. When significant, the data were submitted to a regression analysis using the program Statistical Analysis System, version 9.2. Polynomial equations up to the 3rd degree were accepted, since most variables related to grape quality have their contents stabilized at the end of the maturation stage. This biological behavior can be better represented by the 3rd degree polynomial equations than by the 2nd degree. In addition, determination coefficients above 70 % and significance of regression parameters according to the t test are considered. The Tukey test was applied to compare rootstocks. The data that did not characterize a normal distribution were shown using means at the 95 % of confidence level.

The Pearson’s coefficient correlation was analyzed to infer the contributions of compounds associated to the functional potential on the total antioxidant capacity. The principal component analysis (PCA) was applied to all variables in order to recognize the ones that most differed between the rootstocks and identify the importance of each variable for each component. Two components were studied according to the criterion of the minimum number of components reaching at least 70 % of the total variance.

Results and Discussion

In both cycles, bunch weight was influenced by the isolated effect of fruit age and rootstock (Figures 1A and 1B). In cycle 1, first semester of 2017, there was a decrease during maturation. The use of ‘Harmony’ rootstock resulted in a lower bunch weight for the scion cultivar than for ‘IAC 313’, not differing from the others (Figure 1A). In cycle 2, first semester of 2018, bunch weight increased from the start of maturation to 61 DAF, followed by a slight drop until harvest. In turn, bunch weight of plants grafted onto ‘IAC 572’ was greater than in ‘Freedom’ and ‘Harmony’ (Figure 1B). Even with the shorter maturation period in cycle 1, after 61 DAF, bunches of the scion cultivar were characterized by a regular standard of weight between the cycles. In this phenological phase, increases in bunch weight and grape volume are due to greater translocation of water induced by an accumulation of solutes in the cells (Doumouya et al., 2014Doumouya, S.; Lahaye, M.; Maury, C.; Siret, R. 2014. Physical and physiological heterogeneity within the grape bunch: impact on mechanical properties during maturation. American Journal of Enology and Viticulture 65: 170-178.), as characterized in cycle 2.

Figure 1
Bunch weight (A and B), berry weight (C and D), and berry resistance to compression (E and F) during the maturation of grapes from ‘BRS Magna’ vines cultivated by grafting onto different rootstocks and evaluated from Jan to Apr 2017 (to the left) and from Dec 2017 to Apr 2018 (to the right) cycles. Means followed by the same letter in the graphs with internal bars in Figures 1A, 1B, and 1D, evaluating the isolated effect of the rootstocks, did not differ from one another according to the Tukey test (p < 0.05). *, **Statistical significance by the t test at p < 0.05 and p < 0.01, respectively. Vertical bars in Figure 1F represent the confidence interval at 95 % confidence level. Rootstocks: IAC 313 (ŷ1); IAC 572 (ŷ2); IAC 766 (ŷ3); Freedom (ŷ4); Harmony (ŷ5); Paulsen 1103 (ŷ6).

The interaction between the rootstock and fruit age only affected berry weight in cycle 1 (Figure 1C), in which rootstock ‘IAC 313’ provided a greater increase in weight of the scion cultivar grapes up to 61 DAF and berry weight tended to stabilize after this point. Grapes of plants grafted onto ‘Freedom’, ‘Harmony’ and ‘Paulsen 1103’ rootstocks weighed less at the end of maturation than in an intermediate phase. In cycle 2, berries increased in weight throughout maturation (Figure 1D). The use of ‘IAC 572’ rootstock resulted in heavier grapes than in treatments grafting onto ‘Freedom’, ‘Harmony’ and ‘Paulsen 1103’.

The increase in size and berry weight during maturation is related to the increase in cell volume, especially of the vacuoles (Borghezan, 2017Borghezan, M. 2017. Formation and ripening of grape and effects on the wines: review. Ciência e Técnica Vitivinícola 32: 126-141 (in Portuguese, with abstract in English).), which is influenced by the genotype, number of seeds, the source-sink ratio, and the plant response to climatic conditions of each semester associated to accumulation of solutes and water (Borghezan, 2017Borghezan, M. 2017. Formation and ripening of grape and effects on the wines: review. Ciência e Técnica Vitivinícola 32: 126-141 (in Portuguese, with abstract in English).; Doumouya et al., 2014Doumouya, S.; Lahaye, M.; Maury, C.; Siret, R. 2014. Physical and physiological heterogeneity within the grape bunch: impact on mechanical properties during maturation. American Journal of Enology and Viticulture 65: 170-178.). Regarding the effects of rootstocks on the quality components, Borges et al. (2014)Borges, R.S.; Roberto, S.R.; Yamashita, F.; Assis, A.M.; Yamamoto, L.Y. 2014. Production and quality of ‘Concord’ clones of grapevine fruits on different rootstocks. Pesquisa Agropecuária Tropical 44: 198-204 (in Portuguese, with abstract in English). observed no differences in the number of bunches per plant or of berries per bunch for cultivar Concord grafted onto ‘IAC 766’ and ‘IAC 572’. Thus, specific responses for the scion cultivars grafted onto the same rootstock are highlighted.

A reduction in berry resistance to compression and subsequent stabilization is expected during maturation. However, the grapes from plants grafted onto ‘IAC 313’ showed an increase after 56 DAF as compared to the first evaluations, which could be associated with sampling variation (Figure 1E). After this period, the values decreased and tended to stabilize. The variation throughout the maturation period could be related to changes in translocation of water and nutrients to the grapes, determining their turgidity. When the whole period was considered, grapes from plants grafted onto the ‘Freedom’ rootstock were only more resistant to compression in the initial phase and practically stabilized after 64 DAF. For cycle 2, responses between the rootstocks were equivalent after 55 DAF with a tendency to stabilize afterward (Figure 1F). Few studies address the issue, particularly referring to plant management. Lo’ay and El-khateeb (2017Lo’ay, A.A.; El-Khateeb, A.Y. 2017. Evaluation the effect of rootstocks on postharvest berries quality of ‘Flame Seedless’ grapes. Scientia Horticulturae 220: 299-302.) reported greater resistance for berries from ‘Flame Seedless’ vine grafted onto ‘Paulsen 1103’, a moderate vigor rootstock.

The different responses in both cycles could be attributed to the duration of maturation. In cycle 2, maturation was identified in the initial phase and started relatively slower, highlighting the loss of compression resistance. In cycle 1, response of stabilization of the loss of compression resistance of grapes was already observed at the start of the sampling of grapes. For grapes allocated for juice production, a reduced compression resistance of berries facilitates separation of the peduncle. This effect may be due to enzymatic degradation of cell wall in this part of the grape (Lo’ay, 2011Lo’ay, A.A. 2011. Biological indicators to minimize berry shatter during handling of Thompson seedless grapevines. World Applied Sciences Journal 12: 1107-1113.), resulting in greater yield during the destemming phase, which favors the grape maceration phase. In addition, skin components, such as pigments, may be easier to extract from grapes showing less resistance to compression (Coletta et al., 2018Coletta, C.; Botondi, R.; Forniti, R.; Baccelloni, S.; Bellincontro, A.; Mencarelli, F. 2018. Alternating temperature in postharvest cooling treatment of ‘Fiano’ and ‘Falanghina’ grapes affects cell wall enzyme rate, berry softening, and polyphenols. Journal of the Science of Food and Agriculture 99: 3142-3148.).

There was significant interaction in both cycles between fruit age and rootstock on soluble solids contents (SS) and the total soluble sugar contents (TSS), ratifying the progressive increase during maturation (Figures 2A, 2B, 2C, and 2D). For cycle 1, the SS contents in the first sampling were higher than for cycle 2 (Figures 2A and 2B), when the response of rootstocks on the scion grapes was more uniform, reaching 21.2 % in vines grafted onto ‘Freedom’ rootstock (Figure 2B). In cycle 1, fruits from plants grafted onto ‘IAC 572’ were highlighted for their SS content of 23.2 %, higher than that reported by Ritschel et al. (2015)Ritschel, P.S.; Girardi, C.L.; Zanus, M.C.; Fajardo, T.V.M.; Maia, J.D.G.; Souza, R.T.; Camargo, U.A. 2015. Novel Brazilian grape cultivars. Acta Horticulturae 1082: 157-163. for this cultivar, followed by the treatments with ‘IAC 766’ and ‘Paulsen 1103’. Grapes from plants grafted onto ‘IAC 313’ showed a slower increase in the SS content.

Figure 2
Soluble solids (A and B) content, total soluble sugars (C and D), and titratable acidity (E and F) during the maturation of grapes from ‘BRS Magna’ vines cultivated by grafting onto different rootstocks and evaluated from Jan to Apr 2017 (to the left) and Dec 2017 to Apr 2018 (to the right) cycles; *, **Statistical significance by the t test at p < 0.05 and p < 0.01, respectively. Vertical bars in Figure 2E represent the confidence interval at 95 % confidence level. In Figure 2F, it is evaluated the isolated effect of the age of fruits (days after fruit set). Rootstocks: IAC 313 (ŷ1); IAC 572 (ŷ2); IAC 766 (ŷ3); Freedom (ŷ4); Harmony (ŷ5); Paulsen 1103 (ŷ6).

In a study evaluating rootstocks for Syrah grapevines grown under autumn-winter season through double pruning management, Dias et al. (2017)Dias, F.A.N.; Mota, R.V.; Souza, C.R.; Pimentel, R.M.A.; Souza, L.C.; Souza, A.L.; Regina, M.A. 2017. Rootstock on vine performance and wine quality of ‘Syrah’ under double pruning management. Scientia Agricola 74: 134-141. observed improvement in grape and wine quality when high vigor rootstocks were adopted. Wooldridge et al. (2016)Wooldridge, J.; Louw, P.J.E.; Conradie, W.J. 2016. Effects of rootstock on grapevine performance, petiole and must composition, and overall wine score of Vitis vinifera cv. Chardonnay and Pinot Noir. South African Journal of Enology and Viticulture 31: 45-48. reported that grapes from a ‘Pinot Noir’ vine grafted onto ‘110 R’ produced better wine than when grafted onto ‘Richter 99’, ‘Ruggeri 140’, or ‘SO4’. For grape cultivars for juice production produced in Brazil, such as Isabel Precoce, BRS Carmem, Bordo, BRS Violeta and Concord Clone 30, Mota et al. (2018)Mota, R.V.D.; Glória, M.B.A.; Souza, B.S.D.; Peregrino, I.; Pimentel, R.M.D.A.; Dias, F.A.N.; Regina, M.D.A. 2018. Bioactive compounds and juice quality from selected grape cultivars. Bragantia 77: 62-73. reported values for SS lower than those observed in our study for vines grafted onto ‘Paulsen 1103’ in tropical conditions. The values reported by Silva et al. (2018)Silva, M.J.R.; Paiva, A.P.M.; Pimentel Junior, A.; Sánchez, C.A.P.C.; Callili, D.; 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. for ‘BRS Cora’, ‘Isabel Precoce’, and ‘BRS Carmem’ grafted on ‘IAC 572’ or ‘IAC 766’, were also lower than those found for ‘BRS Magna’ in our study.

The SS content is an indirect measurement of the sugar content and depends on factors, such as the cultivar, grape size, plant yield, and climatic conditions. It can also suffer variations due to water loss, which concentrates the solutes, or an increase in water absorption after rain or excess of irrigation (Kuhn et al., 2014Kuhn, N.; Guan, L.; Dai, Z.; Wu, B.; Lauvergeat, V.; Gomès, E.; Li, S.; Godoy, F.; Arce-Johnson, P.; Delrot, S. 2014. Berry ripening: recently heard through the grapevine. Journal of Experimental Botany 65: 4543-4559.). The period of cycle 2 was characterized by greater precipitation (Table 1), which may have increased grape volume and diluted the solutes (sugars, acids, tannins, anthocyanins, and others).

The response for the TSS content followed the same tendency for the SS content, highlighting the values found for grape vines grafted onto ‘Paulsen 1103’ in cycle 1, which accumulated 21.43 g 100 g–1 when ripe (Figure 2C). Differently from the other rootstocks, ‘IAC 572’ promoted greater TSS and SS contents in scion grapes after 56 DAF. However, the use of this rootstock resulted in ripe grapes with lower TSS contents (20.44 g 100 g–1) than with ‘Paulsen 1103’. In cycle 2, the use of rootstock ‘Freedom’ favored grapes with higher TSS contents, reaching 20.05 g 100 g–1 at the end of the maturation period (Figure 2D). The response for this rootstock in this cycle is consistent with the high SS contents (Figure 2B). These values were higher than those reported by Ritschel et al. (2015)Ritschel, P.S.; Girardi, C.L.; Zanus, M.C.; Fajardo, T.V.M.; Maia, J.D.G.; Souza, R.T.; Camargo, U.A. 2015. Novel Brazilian grape cultivars. Acta Horticulturae 1082: 157-163. of 17 and 19 °Brix for ‘BRS Magna’ grapes in tropical and temperate climates.

The sugar content maintains a relationship with accumulated solar radiation and high temperatures (Kuhn et al., 2014Kuhn, N.; Guan, L.; Dai, Z.; Wu, B.; Lauvergeat, V.; Gomès, E.; Li, S.; Godoy, F.; Arce-Johnson, P.; Delrot, S. 2014. Berry ripening: recently heard through the grapevine. Journal of Experimental Botany 65: 4543-4559.) and greater accumulation of SS and TSS under these conditions must be due to stimulation of the photosynthetic rates (Gatti et al., 2014Gatti, M.; Garavani, A.; Cantatore, A.; Parisi, M.G.; Bobeica, N.; Merli, M.C.; Vercesi, A.; Poni, S. 2014. Interactions of summer pruning techniques and vine performance in the white Vitis vinifera cv. Ortrugo. Australian Journal of Grape and Wine Research 21: 80-89.). Concerning the cycles, in addition to higher mean temperatures, the low relative humidity and reduced rainfall in cycle 1 possibly favored a higher sugar concentration. Air temperature influences transpiration and thus regulates the hydric needs of the vine. The higher the temperature, the lower the relative humidity and the greater the water loss by transpiration, resulting in concentration of SS (Tarara et al., 2008Tarara, J.M.; Lee, J.; Spayd, S.E.; Scagel, C.F. 2008. Berry temperature and solar radiation alter acylation, proportion, and concentration of anthocyanin in Merlot grapes. American Journal of Enology and Viticulture 59: 235-247.).

In cycle 1, the common reduction in titratable acidity (TA) tending to stabilize at the end of maturation was observed with slight significant differences between the rootstocks: 0.08 g tartaric acid 100 mL–1 at 68 DAF (Figure 2E). Ritschel et al. (2015)Ritschel, P.S.; Girardi, C.L.; Zanus, M.C.; Fajardo, T.V.M.; Maia, J.D.G.; Souza, R.T.; Camargo, U.A. 2015. Novel Brazilian grape cultivars. Acta Horticulturae 1082: 157-163. mentioned that mean TA of cultivar BRS Magna grafted on ‘Paulsen 1103’ or ‘IAC 572’ was 0.90 g tartaric acid 100 mL–1 in a temperate climate region. Silva et al. (2018)Silva, M.J.R.; Paiva, A.P.M.; Pimentel Junior, A.; Sánchez, C.A.P.C.; Callili, D.; 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. mentioned a mean value of 0.87 g tartaric acid 100 mL–1 for ‘Isabel Precoce’, ‘BRS Carmem’ and ‘IAC 138-22 Máximo’ grapes under tropical conditions. These values are higher than those observed for ‘BRS Magna’ grapes in our study in the Brazilian semiarid tropical region.

Observations of both cycles suggest a lower TA for grapes of cycle 1 (Figures 2E and 2F), when temperatures were higher during the maturation (Table 1). Temperature has a strong influence on the organic acid contents, since degradation is accelerated under high temperatures (Kuhn et al., 2014Kuhn, N.; Guan, L.; Dai, Z.; Wu, B.; Lauvergeat, V.; Gomès, E.; Li, S.; Godoy, F.; Arce-Johnson, P.; Delrot, S. 2014. Berry ripening: recently heard through the grapevine. Journal of Experimental Botany 65: 4543-4559.). The ripening process also accelerates degradation and increases membrane permeability. These phenomena allow sugars and organic acids stored in vacuoles to be consumed by respiration (Kliewer et al., 1967Kliewer, W.M.; Howarth, L.; Omori, M. 1967. Concentrations of tartaric acid and malic acids and their salts in Vitis vinifera grapes. American Journal of Enology and Viticulture 18: 42-54.).

Tartaric and malic acids account for about 90 % of the organic acids in the cell vacuoles of grapes. The decrease on the contents of both acids during maturation is mainly explained by the dilution of tartaric acid, while malate is intensely used in respiration (Borghezan, 2017Borghezan, M. 2017. Formation and ripening of grape and effects on the wines: review. Ciência e Técnica Vitivinícola 32: 126-141 (in Portuguese, with abstract in English).).

In addition to quantifying organic acids and sugars as quality indicators, the phenolic composition should also be considered in grapes. An effect of the interaction between rootstock and fruit age was verified for the yellow flavonoid contents in cycle 1, but not in cycle 2, when data did not have a normal distribution (Figures 3A and 3B). In cycle 1 after 64 DAF, rootstocks ‘Harmony’, ‘Freedom’ and ‘IAC 572’ promoted greater accumulation of these pigments in scion grapes (Figure 3A). However, treatment ‘IAC 572’ resulted in the highest value at the end of maturation. Variations in the contents of different flavonoids can be attributed to genetic factors, climate, vine handling, grape maturity state, and grape size (Rockenbach et al., 2011Rockenbach, I.I.; Gonzaga, L.V.; Rizelio, V.M.; Gonçalves, A.E.S.S.; Genovese, M.I.; Fett, R. 2011. Phenolic compounds and antioxidant activity of seed and skin extracts of red grape (Vitis vinifera and Vitis labrusca) pomace from Brazilian winemaking. Food Research International 44: 897-901.), as well as the extraction and evaluation methods of these compounds.

Figure 3
Contents of yellow flavonoids (A and B) and total anthocyanins in grape skins (C and D) and total extractable polyphenols - TEP (E and F) during maturation of grapes from ‘BRS Magna’ vines cultivated by grafting onto different rootstocks and evaluated from Jan to Apr 2017 (to the left) and from Dec 2017 to Apr 2018 (to the right) cycles; *, **Statistical significance by the t test at p < 0.05 and p < 0.01, respectively. Vertical bars in Figures 3B and 3D represent the confidence interval at 95 % confidence level. Rootstocks: IAC 313 (ŷ1); IAC 572 (ŷ2); IAC 766 (ŷ3); Freedom (ŷ4); Harmony (ŷ5); Paulsen 1103 (ŷ6).

In our study, the contents of yellow flavonoid decreased with the proximity of harvest. The higher yellow flavonoid contents in cycle 2 (Figure 3B) can be justified by the greater global solar radiation (Table 1). Impacts of solar light and temperature on grape composition on the synthesis of these compounds have been studied. For example, grape temperature can influence the activity of enzymes flavonoid-3’,5’-hydroxylase and flavonoid-3’hydroxylase, inducing changes in accumulation (Angelotti-Mendonça et al., 2018Angelotti-Mendonça, J.; Moura, M.F.; Scarpare Filho, J.A.; Vedoato, B.T.F.; Tecchio M.A. 2018. Rootstock on production and quality of ‘Niagara Rosada’ grapevine. Revista Brasileira de Fruticultura 40: 1-9.). The use of ‘IAC 313’, a very high vigor rootstock, favored the accumulation of yellow flavonoids in the ‘BRS Magna’ grapes at harvest compared to ‘IAC 572’ and ‘Harmony’, which are considered moderate vigor rootstocks (Figure 3B).

There was an interaction between rootstocks and fruit age for the anthocyanin content in grape skins only for cycle 1 (Figure 3C). The content increased during maturation up to 64 DAF, when it reached its maximum value, such as yellow flavonoids, and then decreased. Some authors reported that exposure of vines to solar radiation or to temperatures below 25 °C stimulated the synthesis and accumulation of anthocyanins in grapes. On the other hand, temperatures above 35 °C have been associated to anthocyanin degradation (Hickey and Woolf, 2018Hickey, C.C.; Wolf, T.K. 2018. Leaf removal effects on Cabernet franc and Petit Verdot. I. Crop yield components and primary fruit composition. American Journal of Enology and Viticulture 69: 221-230.; Tarara et al., 2008Tarara, J.M.; Lee, J.; Spayd, S.E.; Scagel, C.F. 2008. Berry temperature and solar radiation alter acylation, proportion, and concentration of anthocyanin in Merlot grapes. American Journal of Enology and Viticulture 59: 235-247.). A decrease in the contents of these pigments may also be associated to a decrease in synthesis (Fernández-López et al., 1998Fernández-López, J.A.; Almela, L.; Muñoz, J.A.; Hidalgo, V.; Carreño, J. 1998. Dependence between colour and individual anthocyanin content in ripening grapes. Food Research International 31: 667-672.). At the end of maturation in cycle 1, the highest anthocyanin contents were found for vines grafted onto the most vigorous rootstocks evaluated, ‘IAC 313’ and ‘Freedom’ (Figure 3C).

In cycle 2, the anthocyanin contents increased with all rootstocks, despite lower values at the start of maturation, when grapes started to change color. In this cycle, the highest contents were found mainly in grapes from plants grafted onto ‘IAC 313’ and ‘IAC 766’, reaching values of 673.16 mg, 100 g–1 and 708.02 mg, 100 g–1, respectively at harvest. Silva et al. (2017)Silva, M.J.R.; Vedoato, B.T.I.F.; Lima, G.P.P.; Moura, M.F.; Coser, G.M.D.A.G.; Watanabe, C.Y.; Tecchio, M.A. 2017. Phenolic compounds and antioxidant activity of red and white grapes on different rootstocks. African Journal of Biotechnology 16: 664-671. studied cultivars Cabernet Sauvignon, Cabernet Franc, and IAC 138-22 Máximo and reported higher anthocyanin contents for grapes of vines grafted onto ‘IAC 766’. The authors also observed that grapes of ‘BRS Violeta’ accumulated more anthocyanins when vines were grafted onto ‘106-8 Mgt’. Another study found no differences in quality attributes for ‘Concord’ grapes grafted onto rootstocks ‘IAC 766’ and ‘IAC 572’ (Borges et al., 2014Borges, R.S.; Roberto, S.R.; Yamashita, F.; Assis, A.M.; Yamamoto, L.Y. 2014. Production and quality of ‘Concord’ clones of grapevine fruits on different rootstocks. Pesquisa Agropecuária Tropical 44: 198-204 (in Portuguese, with abstract in English).). In addition to the distinct responses between scion cultivars and climate influence, vigor intensity conferred by different rootstocks to scion cultivars may be fundamental for changes in physicochemical attributes of grapes (Bascunán-Godoy et al., 2017Bascunán-Godoy, L.; Franck, N.; Zamorano, D.; Sanhueza, C.; Carvajal, D.E.; Ibacache, A. 2017. Rootstock effect on irrigated grapevine yield under arid climate conditions are explained by changes in traits related to light absorption of the scion. Scientia Horticulturae 218: 284-292.). However, the physiological and/or biochemical interactions between scion grapes and rootstocks associated to these effects are still an object of study.

Both cycles showed a differential accumulation on TEP as a function of the rootstock (Figures 3E and 3F). For cycle 1, the highest contents were observed for grapes from vines grafted onto ‘IAC 572’ and ‘IAC 313’: 397.12 and 358.84 mg 100 g–1, respectively, after 68 DAF. This is coherent with the high yellow flavonoid content associated to ‘IAC 572’ in cycle 1 at harvest time and represents an important part of the total polyphenol compound contents. In general, the differences promoted by rootstocks on the polyphenol compound contents of grapes are related to vigor, water and nutrient absorption capacity, and disease resistance, as well as their interaction with scion, affecting the metabolites of plants and consequently the productive capacity and quality of grapes (Tecchio et al., 2014Tecchio, M.A.; Moura, M.F.; Teixeira, L.A.J.; Pires, E.J.P.; Leonel, S. 2014. Influence of rootstocks and pruning times on yield and on nutrient content and extraction in Niagara Rosada grapevine. Pesquisa Agropecuária Brasileira 49: 340-348.). In cycle 2, the highest TEP contents were observed at the end of the maturation period in grapes from plants grafted onto ‘IAC 766’ (Figure 3F). This response could be related to vigor levels conferred by the rootstocks ‘IAC 572’, known to be more vigorous than ‘IAC 766’. When grafted onto rootstocks that induce less vigor, grapes have a higher phenolic compound content (Silva et al., 2017Silva, M.J.R.; Vedoato, B.T.I.F.; Lima, G.P.P.; Moura, M.F.; Coser, G.M.D.A.G.; Watanabe, C.Y.; Tecchio, M.A. 2017. Phenolic compounds and antioxidant activity of red and white grapes on different rootstocks. African Journal of Biotechnology 16: 664-671.). Conversely, higher yielding and vigorous rootstocks possibly induce sufficient phenolic composition for a good quality of the product, as reported by Dias et al. (2017)Dias, F.A.N.; Mota, R.V.; Souza, C.R.; Pimentel, R.M.A.; Souza, L.C.; Souza, A.L.; Regina, M.A. 2017. Rootstock on vine performance and wine quality of ‘Syrah’ under double pruning management. Scientia Agricola 74: 134-141. in ‘Syrah’ grapevine.

Habran et al. (2016)Habran, A.; Commisso, M.; Helwi, P.; Hilbert, G.; Negri, S.; Ollat, N.; Gomès, E.; van Leeuwen, C.; Guzzo, F.; Delrot, S. 2016. Roostocks/scion/nitrogen interactions affect secondary metabolism in the grape berry. Frontiers of Plant Science 7: 1134. discussed interactions between soil composition, rootstocks, and scion as selective parameter for a variety, a rootstock, a compound, and a berry compartment, which also depend on climate. The authors highlighted that a rootstock can favor a higher amount of phenolics, as anthocyanins, hydroxycinnamic acids, stilbenes, and flavan-3-ols. However, the effect can vary even within the same group of chemical compounds.

Distinct responses were also observed during maturation between rootstocks for TAC, as determined by the DPPH• method (Figures 4A and 4B). In cycle 1, differences between rootstocks could have been related to fruit age (Figure 4A) with values decreasing from 56 to 61 DAF and then stabilizing. Using this method, lower values represent more TAC since they indicate that less fruit mass needs to be consumed to correspond to the radical activity (Floegel et al., 2011Floegel, A.; Kim, D.O.; Chung, S.J.; Koo, S.I.; Chun, O.K. 2011. Comparison of ABTS/DPPH assays to measure antioxidant capacity in popular antioxidant-rich US foods. Journal of Food Composition and Analysis 24: 1043-1048.). In cycle 2, TAC increased up to 61 DAF and the values decreased afterward in grapes from plants grafted onto all rootstocks. The distinct responses for different cycles corroborated observations of Xu et al. (2011)Xu, C.; Zhang, Y.; Zhu, L.; Huang, Y.; Lu, J. 2011. Influence of growing season on phenolic compounds and antioxidant properties of grape berries from vines grown in subtropical climate. Journal of Agricultural and Food Chemistry 59: 1078-1086. in that, in subtropical areas, climate conditions affect the accumulation of phenolic compounds in vine cultivars, leading to differences in TAC in grapes.

Figure 4
Total antioxidant capacity measured by 2,2-diphenyl-1-picrylhydrazyl - DPPH• (A and B) and 2,2’-azino-bis; 3-ethylbenzene-thiazoline-6-sulfonic acid - ABTS•⁺ (C and D) free radical capture methods during maturation of grapes from ‘BRS Magna’ vines cultivated by grafting onto different rootstocks and evaluated from Jan to Apr 2017 (to the left) and from Dec 2017 to Apr 2018 (to the right) cycles; *, **Statistical significance by the t test at p < 0.05 and p < 0.01, respectively. Vertical bars in Figures 4A and 4C represent the confidence interval at 95 % confidence level. Rootstocks: IAC 313 (ŷ1); IAC 572 (ŷ2); IAC 766 (ŷ3); Freedom (ŷ4); Harmony (ŷ5); Paulsen 1103 (ŷ6).

Using the ABTS•+ free radical capture method, TAC also increased for all rootstocks and all fruit ages in both cycles (Figures 4C and 4D). In cycle 1, grapes from plants grafted onto ‘Harmony’ and ‘Paulsen 1103’ showed a great variation in TAC during maturation, presenting the highest values at harvest. In cycle 2, the highest TAC values were observed in grapes from plants grafted onto ‘IAC 766’ and ‘Harmony’ at the end of maturation. The evaluation of TAC by the ABTS method corroborated the responses observed using DPPH for the treatment with rootstock ‘Paulsen 1103’.

The values obtained for TAC by the ABTS and DPPH methods are correlated to each other, indicating that one method can extract equivalent conclusions from one or the other techniques, even under the influence of rootstocks (Figures 5A and 5B). The highest correlation coefficients were observed between the yellow flavonoid contents and the anthocyanin contents for both cycles. Separately, these variables presented correlation coefficients close to 70 % for TEP in cycle 1 and 85 % in cycle 2. In general, the TEP content was the variable that best correlated with the methods used to determine TAC. Contributions of yellow flavonoids and anthocyanins to the TEP content were also verified, with correlation coefficients especially high in cycle 2.

Figure 5
Pearson’s coefficients of correlation of bioactive compounds yellow flavonoids in skin (FLA), total anthocyanins in skin (ANT), total extractable polyphenols (TEP), and the total antioxidant capacity determined by 2,2’-azino-bis; 3-ethylbenzene-thiazoline-6-sulfonic acid (ABTS•⁺) and 2,2-diphenyl-1-picrylhydrazyl (DPPH•) free radical capture methods during maturation of grapes from ‘BRS Magna’ vines cultivated by grafting onto different rootstocks and evaluated from Jan to Apr 2017 (A) and from Dec 2017 to Apr 2018 (B) cycles; *Significant at p < 0.05.

The PCA showed that 85.6 % of data variability was explained by the two principal components (Figure 6). The first component (PC1) highlighted the data representativeness for all the variables, except bunch weight, also showed the differences due to rootstocks and maturity stages/fruit ages for both cycles. Among the variables, only TA, COMP, and DPPH presented negative auto-vectors. PC1 separated the treatments corresponding to more advanced maturity stages from the initial one (M1), particularly for cycle 1. The auto-values for PC1 suggested that grapes with higher contents of TSS, anthocyanins, yellow flavonoids, TEP, and TAC, evaluated by the ABTS method, were associated to maturity stages after 60 DAF. In addition, rootstocks ‘Freedom’ and ‘Paulsen 1103’ promoted greater SS and TSS contents to grapes, while the use of ‘IAC 313’ and ‘Freedom’ resulted in grapes with high contents of anthocyanins. In turn, rootstocks ‘Freedom’ and ‘Harmony’ were associated to the highest value for TAC by the ABTS•+ method, while the initial maturity stages were characterized by the lowest value for TAC by the DPPH• method.

Figure 6
Dispersion of variables based on auto-vectors of quality characteristics and the antioxidant capacity during ripening of grapes on the ‘BRS Magna’ vines cultivated after grafting onto different rootstocks and evaluated from Jan to Apr 2017 (cycle 1,•) and from Dec 2017 to Apr 2018 (cycle 2, □) cycles. Treatments: M1 = maturity stage 1 corresponding to 49 days after fruiting (DAF) in the 1^st productive cycle (C1), and 35 DAF in the 2^nd productive cycle (C2); M2 = maturity stage 2 corresponding to 56 DAF in C1 and 41 DAF in C2; M3 = maturity stage 3 corresponding to 61 DAF in C1 and 48 DAF in C2; M4 = maturity stage 4, corresponding to 64 DAF in C1 and 55 DAF in C2; M5 = maturity stage 5 corresponding to 68 DAF in C1 and 61 DAF in C2; M6 = maturity stage 6 corresponding to 66 DAF; P1 = rootstock ‘IAC 313’; P2 = rootstock ‘IAC 572’; P3 = rootstock ‘IAC 766’; P4 = rootstock ‘Freedom’; P5 = rootstock ‘Harmony’; P6 = rootstock ‘Paulsen 1103’. Variables: BuW = bunch weight; BeW = berry weight; SS = soluble solids; TSS = soluble sugars content; TA = titratable acidity; COMP = berry resistance to compression; FLAV = yellow flavonoids in skin; ANT = total anthocyanins in skin; TEP = total extractable polyphenols; ABTS = antioxidant capacity by 2,2’-azino-bis; 3-ethylbenzene-thiazoline-6-sulfonic acid (ABTS•⁺) method; DPPH = antioxidant capacity by 2,2-diphenyl-1-picrylhydrazyl (DPPH•) method.

PC2 distinguished the rootstock treatments in particular, the most representative data were obtained for bunch and berry weights, for which the auto-vectors were positive (Figure 6). For both cycles, treatments ‘IAC 313’, ‘IAC 572’, and ‘IAC 766’ were separated from the others in PC2. The variable TA was efficient in separating grapes harvested in each cycle and grapes from the second cycle were characterized by lower values.

Even rootstocks that did not promote the greatest accumulation of compounds or mass values or even high berry resistance to compression in ‘BRS Magna’ grapes showed adequate quality for juice production. Thus, increments in grapes derived from some rootstocks represent opportunities for differentiation in the market.

Conclusions

In the cycle characterized by low relative humidity and rainfall, rootstock ‘IAC 313’ favored bunch weight, berry weight, and total anthocyanins content of the ‘BRS Magna’ grapes, whereas ‘IAC 572’ promoted higher soluble solids, yellow flavonoids, and total extractable polyphenols contents, as well as lower acidity.

Rootstocks ‘IAC 572’, ‘Paulsen 1103’, and ‘Freedom’ favored the basic quality characteristics, such as sugars and titratable acidity, in addition to the functional potential due to the phenolic composition and antioxidant capacity. Increases in pigments, polyphenol compounds, and antioxidant capacity were pronounced in grafting onto ‘IAC 766’, configuring an advantage for the use of this raw material. However, there were significant differences between the cycles associated to the use of this rootstock.

In rainy seasons, the greatest quality potential of the ‘BRS Magna’ grapes occurred approximately 64 DAF, considered adequate harvesting time, regardless of the rootstock.

References

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Tecchio, M.A.; Moura, M.F.; Teixeira, L.A.J.; Pires, E.J.P.; Leonel, S. 2014. Influence of rootstocks and pruning times on yield and on nutrient content and extraction in Niagara Rosada grapevine. Pesquisa Agropecuária Brasileira 49: 340-348.
Wooldridge, J.; Louw, P.J.E.; Conradie, W.J. 2016. Effects of rootstock on grapevine performance, petiole and must composition, and overall wine score of Vitis vinifera cv. Chardonnay and Pinot Noir. South African Journal of Enology and Viticulture 31: 45-48.
Yemn, E.W.; Willis, A.J. 1954. The estimation of carbohydrate in plant extracts by anthrone. The Biochemical Journal 57: 504-514.
Xu, C.; Zhang, Y.; Zhu, L.; Huang, Y.; Lu, J. 2011. Influence of growing season on phenolic compounds and antioxidant properties of grape berries from vines grown in subtropical climate. Journal of Agricultural and Food Chemistry 59: 1078-1086.

Edited by

Edited by: Lincoln Zotarelli

Publication Dates

Publication in this collection
14 June 2021
Date of issue
2022

History

Received
22 July 2020
Accepted
25 Jan 2021

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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Month/year	T (°C)			RH	Rad	Ws	Rainfall^* * Total monthly rainfall. Source: Agrometeorological Station of Bebedouro, Petrolina, Pernambuco, Brazil – Embrapa (2018).	ET0
Month/year	Max.	Mean	Min.	RH	Rad	Ws
				%	MJ m^–2 d^–1	m s^–1	mm	mm d^–1
Jan to Apr 2017 (Production cycle 1)
Jan/17	36.0	29.3	23.4	45.1	18.2	2.4	10.0	6.3
Feb/17	35.8	29.1	23.4	54.0	19.8	2.0	24.0	5.8
Mar/17	34.2	28.8	22.6	57.6	19.8	1.8	6.0	5.5
Apr/17	32.7	28.0	21.9	62.0	17.4	2.4	3.0	5.4
Mean	34.7	28.8	22.8	54.7	18.8	2.1	10.8	5.7
Dec 2017 to Apr 2018 (Production cycle 2)
Dec/17	36.1	29.3	24.0	59.7	25.7	1.9	20.0	6.5
Jan/18	35.0	28.3	23.3	65.1	23.7	2.0	43.0	6.0
Feb/18	33.7	27.3	23.1	80.0	21.5	1.2	66.0	4.9
Mar/18	34.1	27.5	22.9	81.2	22.9	0.9	109.0	4.8
Apr/18	32.2	26.2	21.6	79.3	20.6	1.1	101.0	4.3
Mean	34.2	25.6	25.0	73.0	22.8	1.4	67.8	5.3