Rootstock-scion interaction: 4. Effect on the sensory characteristics of Cabernet Sauvignon wine

Miele, Alberto; Rizzon, Luiz Antenor

doi:10.1590/0100-29452019043

Abstract

It is known that rootstock can induce changes on grapevine yield components and on the physicochemical composition of musts and wines. However, its effect on the sensory characteristics of wines has been scarcely studied. For this reason, an experiment was conducted to determine the effect of 15 rootstocks on the sensory characteristics of Cabernet Sauvignon wine, whose grapevines were grafted on Rupestris du Lot, 101-14 Mgt, 3309 C, 420A Mgt, 5BB K, 161-49 C, SO4, Solferino, 1103 P, 99 R, 110 R, Gravesac, Fercal, Dogridge and Isabel, which feature some genetic diversity altogether. The experimental design was in randomized blocks, with 15 treatments, three replicates, 10 vines per plot. Mature grapes were harvested, and wines were made in 20-L glass recipients. When alcoholic and malolactic fermentations were finished, the wines were bottled and stored at 18°C. Sensory analysis was performed in the next year, following international procedures. The tasting panel was formed by 12 experienced enologists, who evaluated the wines in individual cells separated by opaque glass. They were served monadically and the perception of each taster was recorded in 9-cm unstructured scale sheets. Twenty-two variables were evaluated, which were related to the visual, olfactory and taste aspects. The results show that the tasting panel was not able to detect significant differences (p> 0.05) of rootstocks in any variable related to the sensory characteristics of Cabernet Sauvignon wine.

Index terms
Vitis vinifera; grapevine; Cabernet Sauvignon; wine tasting

Resumo

Sabe-se que o porta-enxerto pode causar modificações nos componentes de produção da videira e na composição físico-química do mosto e do vinho. Entretanto, seu efeito nas características sensoriais do vinho tem sido pouco estudado. Por essa razão, conduziu-se um experimento para determinar o efeito de 15 porta-enxertos nas características sensoriais do vinho Cabernet Sauvignon, cujas videiras foram enxertadas em Rupestris du Lot, 101-14 Mgt, C 3309, 420A Mgt, K 5BB, C 161-49, SO4, Solferino, P 1103, R 99, R 110, Gravesac, Fercal, Dogridge e Isabel, os quais apresentam certa diversidade genética. O delineamento experimental foi em blocos ao acaso, com 15 tratamentos, três repetições, 10 videiras por parcela. As uvas foram colhidas quando maduras, e os vinhos foram elaborados em recipientes de vidro de 20 L. Após a conclusão das fermentações alcoólica e malolática, os vinhos foram engarrafados e armazenados a 18°C. No ano seguinte, procedeu-se à análise sensorial, que foi realizada segundo procedimentos internacionais. O painel de degustação foi formado por 12 experientes enólogos que avaliaram os vinhos em celas individuais, separadas por vidro opaco. Os vinhos foram servidos monadicamente, e sua avaliação foi registrada em fichas não estruturadas com escala de 9 cm. Avaliaram-se 22 variáveis relacionadas aos aspectos visual, olfativo e gustativo. Os resultados mostram que o painel de degustação não detectou diferença significativa (p> 0,05) dos porta-enxertos em nenhuma variável relacionada às características sensoriais do vinho Cabernet Sauvignon.

Termos para indexação
Vitis vinifera; videira; Cabernet Sauvignon; degustação de vinho

Introduction

Studies related to the effect of rootstock on the grapevine performance have been carried out around the world. These works focused mainly on yield components (KELLER et al., 2012 KELLER, M.; MILLS, L.J.; HARBERTSON, F. Rootstock effects on deficit-irrigated winegrapes in a dry climate: vigor, yield formation, and fruit ripening. American Journal of Enology and Viticulture, Davis, v.63, p.29-39, 2012. ; MIELE; RIZZON, 2017 MIELE, A.; RIZZON, L.A. Rootstock-scion interaction: 1. Effect on the yield components of the Cabernet Sauvignon grapevine. Revista Brasileira de Fruticultura, Jaboticabal, v.39, n.1, p.1-9, 2017. ), must composition (JONES et al., 2009 JONES, T.H.; CULLIS, B.R.; CLINGELEFFER, P.R.; RÜHL, E.H. Effects of novel hybrid and traditional rootstocks on vigour and yield components of Shiraz grapevines. Australian Journal of Grape and Wine Research, Oxford, v.15, n.3, p.284-292, 2009. ; CHOU; LI, 2014 CHOU, M-I.; LI, K-T. Rootstock and seasonal variations affect anthocyanin accumulation and quality traits of ‘Kyoho’ grape berries in subtropical double cropping system. Vitis, Sielbeldingen, v.53, n.4, p.193-199, 2014. ) and wine composition (HARBERTSON; KELLER, 2012 HARBERTSON, J.F.; KELLER, M. Rootstock effects on deficit-irrigated winegrapes in a dry climate: grape and wine composition. American Journal of Enology and Viticulture, Davis, v.63, n.1, p.40-48, 2012. ; STEVENS et al., 2016 STEVENS, R.M.; PECH, J.M.; TAYLOR, J.; CLINGELEFFER, P.; WALKER, R.R.; NICHOLAS, P.R. Effects of irrigation and rootstock on Vitis vinifera (L.) cv. Shiraz berry composition and shrivel, and wine composition and wine score. Australian Journal of Grape and Wine Research, Oxford, v.22, n.1, p.124-136, 2016. ). Often, the results of these works are similar, but they may be different depending on how and where the studies were conducted. The differences among these works could be due to several factors most of them mainly related to scion and rootstock genetics, soil types, climatic conditions, vineyard management and winemaking practices.

However, the sensory characteristics, typicality and overall quality of wines are a complex issue. Indeed, the results of this job depends on the experience and knowledge of the judge. It should also be considered that each taster has his/her own perception about a particular wine descriptor and this perception may be different according to the time and place for the same wine (MEILGAARD et al., 1999 MEILGAARD, M.; CIVILLE, G.V.; CARR, B.T. Sensory evaluation techniques. 3rd ed. Boca Raton: CRC, 1999. 387p. ). Lastly, it is time consuming, and because of it, there are not many studies about the effect of rootstock on wine sensory characteristics.

Most of the study emphasizes the effect of the rootstock on the overall quality of wines (OUGH et al., 1968 OUGH, C.S.; COOK, J.A.; LIDER, L.A. Rootstock-scion interactions concerning wine making. II. Wine compositional and sensory changes attributed to rootstock and fertilizer level differences. American Journal of Enology and Viticulture, Davis, v.19, n.4, p.254-265, 1968. ; OLLAT et al., 2003 OLLAT, N.; TANDONNET, J.P.; LAFONTAINE, M.; SCHULTZ, H.R. Short and long term effects of three rootstocks on Cabernet Sauvignon vine behaviour and wine quality. Acta Horticulturae, Leuven, n.617, p.95-100B, 2003. ; RENOUF et al., 2010 RENOUF, V.; TREGOAT, O.; ROBY, J-P.; VAN LEEUWEN, C. Soils, rootstocks and grapevine varieties in prestigious Bordeaux vineyards and their impact on yield and quality. Journal International des Sciences de la Vigne et du Vin, Talence, v.44, n.3, p.127-134, 2010. ; WOOLDRIDGE et al., 2010) and others on the wine color (WALKER; BLACKMORE, 2012 WALKER, R.R.; BLACKMORE, D.H. Potassium concentration and pH inter-relationships in grape juice and wine Chardonnay and Shiraz from a range of rootstocks in different environments. Australian Journal of Grape and Wine Research, Oxford, v.18, n.2, p.183-193, 2012. ; STEVENS et al., 2016 STEVENS, R.M.; PECH, J.M.; TAYLOR, J.; CLINGELEFFER, P.; WALKER, R.R.; NICHOLAS, P.R. Effects of irrigation and rootstock on Vitis vinifera (L.) cv. Shiraz berry composition and shrivel, and wine composition and wine score. Australian Journal of Grape and Wine Research, Oxford, v.22, n.1, p.124-136, 2016. ). Concerning wine characteristics, there are two works, one reporting nine descriptors (SILVILOTTI et al., 2007 SILVILOTTI, P.; ZULINI, L.; PETERLUNGER, E.; PETRUSSI, C. Sensory properties of ‘Cabernet Sauvignon’ wines as affected by rootstock and season. Acta Horticulturae, Leuven, n.654, p.443-448, 2007. ) and the other one describing appearance, aroma and taste (TREEBY et al., 2000 TREEBY, M.T.; HOLZAPFEL, B.P.; PICKERING, G.J.; FRIEDRICH, C.J. Vineyard nitrogen supply and Shiraz grape and wine quality. Acta Horticulturae, Leuven, n. 512, p.77-92, 2000. ). However, as far as it is known there are no studies to date that have been done in Brazil in relation to this topic.

As the result of published works may differ from one another and because the terroir can play an important role in the composition and characteristics of wine, an experiment was conducted to determine the effect of 15 rootstocks on the sensory characteristics of Cabernet Sauvignon wine.

Material and Methods

The trial was carried out in the 1999 vintage in the Serra Gaúcha winegrowing region in Brazil (coordinates: 29°09’44” S and 51°31’50” W; altitude: 640 m; the climatological normal for annual mean temperature is 17.3°C and 1,683 mm for rain). The vineyard was established in a Cambissolo soil (FLORES et al., 2012 FLORES, C.A.; PÖTTER, R.O.; SARMENTO, E.C.; WEBER, E.J.; HASENACK, H. Os solos do vale dos vinhedos. Pelotas: Embrapa Clima Temperado, 2012. ), which is equivalent to an Inceptisol, according to the Soil Taxonomy. Data related to the vineyard, such as soil characteristics, planting, trellising, spaces between rows and plants, pruning and training grapevines, canopy management and control of diseases, pests and weeds were described in previous paper (MIELE; RIZZON, 2017 MIELE, A.; RIZZON, L.A. Rootstock-scion interaction: 1. Effect on the yield components of the Cabernet Sauvignon grapevine. Revista Brasileira de Fruticultura, Jaboticabal, v.39, n.1, p.1-9, 2017. ).

The Cabernet Sauvignon grapevines were grafted on fifteen rootstocks, i.e., Rupestris du Lot, 101-14 Millardet et de Grasset, 3309 Couderc, 420A Millardet et de Grasset, 5BB Kober, 161-49 Couderc, SO4, 1103 Paulsen, 99 Richter, 110 Richter, Gravesac, Fercal, Dogridge, Isabel and Solferino (local name of an unknown rootstock).

Indeed, Isabel (V. labrusca L.) is not a rootstock, but the most cultivated grapevine (mostly own rooted) in Serra Gaúcha, whose production goes primarily to wineries to make wine and grape juice.

The experimental design was completely randomized blocks, with 15 treatments (CS/rootstocks), three replicates, 10 vines per plot. The area of each block was 675 m2 and the entire experiment 2,025 m2.

Grape ripening was evaluated by determining the total soluble solids (°Brix) content of grapes from the 45 plots, which was done by a hand refractometer. When the °Brix of the grape juice was stabilized, the grapes of all plots were harvested on the same day. Then, they were placed in plastic boxes, weighted and taken to the winery for processing. Grapes were destemmed, crushed and the liquid and solid phases were transferred to 20-L glass recipients. Sucrose was not added to grape musts for correction. Then, 50 mg L-1 of SO2 were added to each recipient. In addition, 0.20 g L-1 of active dry yeast (Saccharomyces cerevisiae) was added and the glass recipients were fitted with rubber stoppers and waterfilled airlocks. After eight days of alcoholic fermentation, the wines were pressed off the skins and transferred to 9-L glass containers also fitted with rubber stoppers and water-filled airlocks. These containers were kept at 24ºC±1ºC until sugar concentration was less than 4.0 g L-1. Malolactic fermentation was naturally processed, which was regularly evaluated by paper chromatography, and then total SO2 was adjusted to 50 mg L-1. When this fermentation ended, wines were transferred to 750-mL glass bottles, sealed with cork, and stored at 18ºC in a temperature-controlled room.

Sensory analysis sessions were conducted in April 2000, evaluating wines from each replicate on three different days. The tasting panel was formed by 12 panelists with extensive enology background and experience in wine sensory description. Thus, the result of each variable of each CS/rootstock combination represented the average of 36 sensory analyses. The sessions were performed according to international rules (AFNOR, 1995 AFNOR. Contrôle de qualité des produits alimentaires. Analyse sensorielle. Paris: Afnor, 1995. 420p. (Collection Afnor Recueil de Normes Françaises). ; SSHA, 1998 SSHA - Société Scientifique D'Hygiène Alimentaire. Évaluation sensorielle: manuel méthodologique. 2.ed. Paris: Tec e Doc, 1998. 353p. (Collection Sciences &Techniques Agroalimentaires). ; MEILGAARD et al., 1999 MEILGAARD, M.; CIVILLE, G.V.; CARR, B.T. Sensory evaluation techniques. 3rd ed. Boca Raton: CRC, 1999. 387p. ).

Tasters were in individual cells separated by an opaque glass and the sessions began at 10h00 where the wine samples were served monadically in ISO glasses and then evaluated blindly. Each glass was identified with three digits and after that, 50 mL of wine sample were poured into the glasses and tasted at 15°C. The perception of each taster was recorded in a sheet with unstructured scales of 9 cm in length.

The following variables were evaluated in the Cabernet Sauvignon wine, which were related to the visual, olfactory and taste aspects: visual – limpidity, intensity and hue; olfactory – intensity, green bell pepper, fruity, spicy, vegetal and animal; taste/flavor – intensity, body, astringency, acidity, balance, typicality, persistence, green bell pepper, fruity, spicy, vegetal, animal and overall quality.

The data were submitted to Anova and Tukey’s multiple range test at 5% probability error using the Statistica program. In addition, correlations were made between the scores of the sensory analysis and data of variables of the grapevine yield components according to the work of Miele and Rizzon (2017) MIELE, A.; RIZZON, L.A. Rootstock-scion interaction: 1. Effect on the yield components of the Cabernet Sauvignon grapevine. Revista Brasileira de Fruticultura, Jaboticabal, v.39, n.1, p.1-9, 2017. .

Results and Discussion

The sensory analysis of the 1999 Cabernet Sauvignon wines shows that tasters found no significant differences (p> 0.05) in any descriptor related to the visual (Table 1), olfactory (Table 1) and taste/flavor (Table 2) aspects. This result is generally in accordance with the physicochemical composition of these wines where only two variables ─ pH and alcohol/reduced dry extract ratio ─ were significantly (p< 0.05) affected by the rootstock (MIELE; RIZZON, 2018 MIELE, A.; RIZZON, L.A. Rootstock-scion interaction: 3. Effect on the Cabernet Sauvignon wine composition. Revista Brasileira de Fruticultura, Jaboticabal, 2018. ). The organoleptic characteristics of the wines are shown in Figure 1.

Figure 1
Mean score (over 9) of the sensory analysis of Cabernet Sauvignon wine, whose grapevines were grafted onto 15 rootstocks. Legend: V= visual, O= olfact, T= taste, Li= limpidity, In= intensity, Hu= hue, Ty= typicality, Gp= green bell pepper, Fr= fruity, Sp= spicy, Ve= vegetal, An= animal, Bo= body, As= astringency, Ac= acidity, Ba= balance, Pe= persistence, Qu= overall quality.

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Table 1
Visual and olfactory scores of the 1999 Cabernet Sauvignon wines according to the rootstock.

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Table 2
Taste/flavor scores of the 1999 Cabernet Sauvignon wines according to the rootstock.

The correlations between the data of the sensory analysis and that of wine composition show that the green bell pepper character of Cabernet Sauvignon wine was positively correlated (p< 0.05) with its density, which means that higher the density (and lower the alcohol content) the higher the perception of green bell pepper. In another word, wine from mature grapes has lower concentration of the substance responsible for the green bell pepper character. However, there was no significant correlation (p> 0.05) between wine quality (MIELE; RIZZON, 2018 MIELE, A.; RIZZON, L.A. Rootstock-scion interaction: 3. Effect on the Cabernet Sauvignon wine composition. Revista Brasileira de Fruticultura, Jaboticabal, 2018. ) and the variables related to yield components (MIELE; RIZZON, 2017 MIELE, A.; RIZZON, L.A. Rootstock-scion interaction: 1. Effect on the yield components of the Cabernet Sauvignon grapevine. Revista Brasileira de Fruticultura, Jaboticabal, v.39, n.1, p.1-9, 2017. ). Indeed, there was no significant (p> 0.05) correlation between the wine composition and the grapevine yield, even though productivity differences had been significant ─ grapevines grafted on the Solferino rootstock had 2.07 times more yield than those on 101-14 Mgt, which were 44.33 t ha-1 and 21.45 t ha-1, respectively. It should be emphasized that the 101-14 Mgt rootstock has low vigor, a condition that recommends it for quality wines (OLLAT et al., 2003 OLLAT, N.; TANDONNET, J.P.; LAFONTAINE, M.; SCHULTZ, H.R. Short and long term effects of three rootstocks on Cabernet Sauvignon vine behaviour and wine quality. Acta Horticulturae, Leuven, n.617, p.95-100B, 2003. ).

The quality of wine was significantly (p< 0.05) correlated with some descriptors, especially green bell pepper (r= -0.880), fruity (r= 0.846), typicality (r= 0.834), persistence (r= 0.734) and spicy (r= 0.570). Green bell pepper is a vegetal character due to a substance belonging to the group of methoxypyrazines, the 3-isobutyl-2- methoxypyrazine, which is a primary aroma synthesized in the Cabernet Sauvignon grape (RIBÉRAU-GAYON et al., 1998 RIBÉRAU-GAYON, P.; GLORIES, Y.; MAUJEAN, A.; DUBOURDIEU, D. Traité d’œnologie. 2. Chimie du vin. Stabilisation et traitements. Paris: Dunod, 1998. ). During the fruit development in the season, the concentration of this substance decreases, especially in hot regions. In this case, their concentration in the wine generally is low. Unlike this, in cool climates where the Cabernet Sauvignon grape does not complete its maturation, the methoxypyrazines are present in wines giving the vegetal character of green bell pepper which may not be considered as good elsewhere. Also, there are two other methoxypirazines with vegetal character, but not of green bell pepper, the 3-isoproyl-2-methoxypyrazine and, to a lesser extent, the 3-sec-isobutyl-2-methoxypyrazine (RIBÉREAU-GAYON et al., 1998 RIBÉRAU-GAYON, P.; GLORIES, Y.; MAUJEAN, A.; DUBOURDIEU, D. Traité d’œnologie. 2. Chimie du vin. Stabilisation et traitements. Paris: Dunod, 1998. ).

The rootstocks used in this experiment have a certain genetic diversity and can therefore influence several physiological and biochemical grapevine aspects, which could have a reflection on vine productivity, grape and wine composition and quality. Indeed, results of studies have shown effect on the grapevine physiology (COOKSON et al., 2012 COOKSON, S.J.; HEVIN, C.; DONNART, D.; OLLAT, N. Grapevine rootstock effects on scion biomass are not associated with large modifications on primary shoot growth under non limiting conditions in the first year of growth. Functional Plant Biology, Collingwood, v.39, p.650-660, 2012. ), biochemistry (SOMKUWAR et al., 2014 SOMKUWAR, R.G.; JOGAIAH, S.; SAWANT, S.D.; TAWARE, P.B.; BONDAGE, D.D.; ITROUTWAR, P. Rootstocks influence the growth, biochemical contents and disease incidence in Thompson Seedless grapevines. British Journal of Applied Science &Technology, London, v.4, p.1030-1041, 2014 ), mineral nutrition (KODUR et al., 2011 KODUR, S.; TISDALL, J.M.; TANG, C.; WALKER, R.R. Uptake, transport, accumulation and translocation of potassium in grapevine rootstocks (Vitis). Vitis, Sielbeldingen, v.50, p.145-149, 2011. ), yield (KELLER et al., 2012 KELLER, M.; MILLS, L.J.; HARBERTSON, F. Rootstock effects on deficit-irrigated winegrapes in a dry climate: vigor, yield formation, and fruit ripening. American Journal of Enology and Viticulture, Davis, v.63, p.29-39, 2012. ), water deficiency or stress (SERRA et al., 2014 SERRA, I.; STREVER, A.; MYBURGH, P.A.; DELOIRE, A. Review: the interaction between rootstocks and cultivars (Vitis vinifera L.) to enhance drought tolerance in grapevine. Australian Journal of Grape and Wine Research, Oxford, v.20, p.1-14, 2014. ), fungal diseases (WALLIS et al., 2013 WALLIS, C.M.; WALLINGFORD, A.K.; CHEN, J.C. Grapevine rootstock effects on scion sap levels, resistance to Xylella fastidiosa infection, and progression of Pierce’s disease. Frontiers in Plant Science, New Haven, v.4, p.816-826, 2013. ), viruses (ROSA et al., 2011 ROSA, C.; JIMENEZ, J.F.; MARGARIA, P.; ROWHANI, A. Symptomatology and effects of viruses associated with rugose wood complex on the growth of four different rootstocks. American Journal of Enology and Viticulture, Davis, v.62, p.207-213, 2011. ) and nematodes (FERRIS et al., 2012 FERRIS, H.; ZHENG, L.; WALKER, M.A. Resistance of grape rootstocks to plant-parasitic nematodes. Journal of Nematology, College Park, v.44, p.377-386, 2012. ).

A previous study (MIELE; RIZZON, 2017 MIELE, A.; RIZZON, L.A. Rootstock-scion interaction: 1. Effect on the yield components of the Cabernet Sauvignon grapevine. Revista Brasileira de Fruticultura, Jaboticabal, v.39, n.1, p.1-9, 2017. ) conducted at the same vineyard as this work showed that the rootstock had significant (p< 0.05) effect on the Cabernet Sauvignon yield components, the number of grape clusters per vine, yield per vine, cluster weight, yield per pruning weight, leaf area per vine, leaf area index and leaf area per fresh fruit weight. These results could have influenced many variables related to the wine composition, but effectively they were partially affected (MIELE; RIZZON, 2018 MIELE, A.; RIZZON, L.A. Rootstock-scion interaction: 3. Effect on the Cabernet Sauvignon wine composition. Revista Brasileira de Fruticultura, Jaboticabal, 2018. ). This shows that these grapevines may have regulatory mechanisms between the vegetative and the reproductive systems.

There are few studies conducted worldwide where the rootstock had a significant effect on the wine sensory characteristics. Considering the color, the Shiraz wine from Salt Creek was less dense in color and duller in hue than those from own rooted Shiraz grapevines (HALE; BRIEN, 1978 HALE, C.R.; BRIEN, C.J. Influence of salt creek rootstock on composition and quality of Shiraz grapes and wine. Vitis, Sielbeldingen, v.17, p.139-146, 1978. ). In another experiment, this same Shiraz wine from the rootstocks Teleki and Schwartzman gave higher color intensity than those from Ramsey (TREEBY et al., 2000 TREEBY, M.T.; HOLZAPFEL, B.P.; PICKERING, G.J.; FRIEDRICH, C.J. Vineyard nitrogen supply and Shiraz grape and wine quality. Acta Horticulturae, Leuven, n. 512, p.77-92, 2000. ) and the aroma of Cabernet Sauvignon wine was enhanced when grapevines were grafted on the Ruggeri rootstock compared to those of Salt Creek (BRAVDO; SHOSEYOV, 2000 BRAVDO, B.; SHOSEYOV, O. Aroma studies on fruits and wine in Israel. Acta Horticulturae, Leuven, n.526, p.399-405, 2000. ).

Most studies, however, refer to the general quality of wines instead of evaluating wine descriptors.

Working with many rootstocks and cultivars in France, the highest quality of wines was achieved with grapes on the rootstocks 420A Mgt, 3309 C, Gravesac and Riparia Gloire de Montpellier (RENOUF et al., 2010 RENOUF, V.; TREGOAT, O.; ROBY, J-P.; VAN LEEUWEN, C. Soils, rootstocks and grapevine varieties in prestigious Bordeaux vineyards and their impact on yield and quality. Journal International des Sciences de la Vigne et du Vin, Talence, v.44, n.3, p.127-134, 2010. ); Chardonnay and Pinot Noir wines had higher quality on 110 R (WOOLDRIGE et al., 2010 WOOLDRIDGE, J.; LOUW, P.J.E.; CONRADIE, W.J. Effects of rootstocks 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, Stellenbosh, v.31, n.1, p.45-48, 2010. ); Cabernet Sauvignon wine had the highest scores when grafted on 161-49 C and 420A Mgt rootstocks (SILVILOTTI et al., 2007 SILVILOTTI, P.; ZULINI, L.; PETERLUNGER, E.; PETRUSSI, C. Sensory properties of ‘Cabernet Sauvignon’ wines as affected by rootstock and season. Acta Horticulturae, Leuven, n.654, p.443-448, 2007. ); in another trial, Cabernet Sauvignon wine was scored higher with Riparia Gloire de Montpellier compared with 101-14 Mgt and SO4 (OLLAT et al., 2003 OLLAT, N.; TANDONNET, J.P.; LAFONTAINE, M.; SCHULTZ, H.R. Short and long term effects of three rootstocks on Cabernet Sauvignon vine behaviour and wine quality. Acta Horticulturae, Leuven, n.617, p.95-100B, 2003. ); in Austria, a work with 31 rootstocks showed that the best wines were those from the rootstocks 5BB K, SO4 and 5C Teleki (MENHOFER et al., 2011 MENHOFER, M.; SCHMUCKENSCHLAGER, B.; VITOVEC, N.; HANAK, K.; REGNER, F.; RIEDLE-BAUER, M. Field studies on the effect of 31 rootstock varieties on yield and selected quality parameters of the grapevine variety ‘Zweigelt’ over a period of twelve years. Mitteilungen Klosterneuburg, Klosterneuburg, v.61, p.196-215, 2011. ); in the United States, an early work with 10 cultivars showed that wines from the St. George rootstock had higher quality than 99 R, some did not differ greatly and several responded more favorable to the 99 R (OUGH et al., 1968 OUGH, C.S.; COOK, J.A.; LIDER, L.A. Rootstock-scion interactions concerning wine making. II. Wine compositional and sensory changes attributed to rootstock and fertilizer level differences. American Journal of Enology and Viticulture, Davis, v.19, n.4, p.254-265, 1968. ).

The differences found in these studies were due to the experiments being done with different rootstocks and scions and in soils and climate with their own characteristics. In addition, vineyard management and winemaking practices could also have influence on the outcome of the studies.

Conclusion

The rootstocks used in the present research have no significant effect on variables related to the visual, olfactory and taste/flavor aspects of Cabernet Sauvignon wine from a Cambissolo soil of Serra Gaúcha.

Acknowledgements

The authors are grateful to colleagues of Embrapa Uva e Vinho who managed the vineyard, made the wine and were on the tasting panel. Thanks also go to Dr. Adeliano Cargnin for his collaboration.

AFNOR. Contrôle de qualité des produits alimentaires. Analyse sensorielle. Paris: Afnor, 1995. 420p. (Collection Afnor Recueil de Normes Françaises).
BRAVDO, B.; SHOSEYOV, O. Aroma studies on fruits and wine in Israel. Acta Horticulturae, Leuven, n.526, p.399-405, 2000.
CHOU, M-I.; LI, K-T. Rootstock and seasonal variations affect anthocyanin accumulation and quality traits of ‘Kyoho’ grape berries in subtropical double cropping system. Vitis, Sielbeldingen, v.53, n.4, p.193-199, 2014.
COOKSON, S.J.; HEVIN, C.; DONNART, D.; OLLAT, N. Grapevine rootstock effects on scion biomass are not associated with large modifications on primary shoot growth under non limiting conditions in the first year of growth. Functional Plant Biology, Collingwood, v.39, p.650-660, 2012.
FERRIS, H.; ZHENG, L.; WALKER, M.A. Resistance of grape rootstocks to plant-parasitic nematodes. Journal of Nematology, College Park, v.44, p.377-386, 2012.
FLORES, C.A.; PÖTTER, R.O.; SARMENTO, E.C.; WEBER, E.J.; HASENACK, H. Os solos do vale dos vinhedos. Pelotas: Embrapa Clima Temperado, 2012.
HALE, C.R.; BRIEN, C.J. Influence of salt creek rootstock on composition and quality of Shiraz grapes and wine. Vitis, Sielbeldingen, v.17, p.139-146, 1978.
HARBERTSON, J.F.; KELLER, M. Rootstock effects on deficit-irrigated winegrapes in a dry climate: grape and wine composition. American Journal of Enology and Viticulture, Davis, v.63, n.1, p.40-48, 2012.
JONES, T.H.; CULLIS, B.R.; CLINGELEFFER, P.R.; RÜHL, E.H. Effects of novel hybrid and traditional rootstocks on vigour and yield components of Shiraz grapevines. Australian Journal of Grape and Wine Research, Oxford, v.15, n.3, p.284-292, 2009.
KELLER, M.; MILLS, L.J.; HARBERTSON, F. Rootstock effects on deficit-irrigated winegrapes in a dry climate: vigor, yield formation, and fruit ripening. American Journal of Enology and Viticulture, Davis, v.63, p.29-39, 2012.
KODUR, S.; TISDALL, J.M.; TANG, C.; WALKER, R.R. Uptake, transport, accumulation and translocation of potassium in grapevine rootstocks (Vitis). Vitis, Sielbeldingen, v.50, p.145-149, 2011.
MEILGAARD, M.; CIVILLE, G.V.; CARR, B.T. Sensory evaluation techniques. 3rd ed. Boca Raton: CRC, 1999. 387p.
MENHOFER, M.; SCHMUCKENSCHLAGER, B.; VITOVEC, N.; HANAK, K.; REGNER, F.; RIEDLE-BAUER, M. Field studies on the effect of 31 rootstock varieties on yield and selected quality parameters of the grapevine variety ‘Zweigelt’ over a period of twelve years. Mitteilungen Klosterneuburg, Klosterneuburg, v.61, p.196-215, 2011.
MIELE, A.; RIZZON, L.A. Rootstock-scion interaction: 1. Effect on the yield components of the Cabernet Sauvignon grapevine. Revista Brasileira de Fruticultura, Jaboticabal, v.39, n.1, p.1-9, 2017.
MIELE, A.; RIZZON, L.A. Rootstock-scion interaction: 3. Effect on the Cabernet Sauvignon wine composition. Revista Brasileira de Fruticultura, Jaboticabal, 2018.
OLLAT, N.; TANDONNET, J.P.; LAFONTAINE, M.; SCHULTZ, H.R. Short and long term effects of three rootstocks on Cabernet Sauvignon vine behaviour and wine quality. Acta Horticulturae, Leuven, n.617, p.95-100B, 2003.
OUGH, C.S.; COOK, J.A.; LIDER, L.A. Rootstock-scion interactions concerning wine making. II. Wine compositional and sensory changes attributed to rootstock and fertilizer level differences. American Journal of Enology and Viticulture, Davis, v.19, n.4, p.254-265, 1968.
RENOUF, V.; TREGOAT, O.; ROBY, J-P.; VAN LEEUWEN, C. Soils, rootstocks and grapevine varieties in prestigious Bordeaux vineyards and their impact on yield and quality. Journal International des Sciences de la Vigne et du Vin, Talence, v.44, n.3, p.127-134, 2010.
RIBÉRAU-GAYON, P.; GLORIES, Y.; MAUJEAN, A.; DUBOURDIEU, D. Traité d’œnologie. 2. Chimie du vin. Stabilisation et traitements. Paris: Dunod, 1998.
ROSA, C.; JIMENEZ, J.F.; MARGARIA, P.; ROWHANI, A. Symptomatology and effects of viruses associated with rugose wood complex on the growth of four different rootstocks. American Journal of Enology and Viticulture, Davis, v.62, p.207-213, 2011.
SERRA, I.; STREVER, A.; MYBURGH, P.A.; DELOIRE, A. Review: the interaction between rootstocks and cultivars (Vitis vinifera L.) to enhance drought tolerance in grapevine. Australian Journal of Grape and Wine Research, Oxford, v.20, p.1-14, 2014.
SILVILOTTI, P.; ZULINI, L.; PETERLUNGER, E.; PETRUSSI, C. Sensory properties of ‘Cabernet Sauvignon’ wines as affected by rootstock and season. Acta Horticulturae, Leuven, n.654, p.443-448, 2007.
SOMKUWAR, R.G.; JOGAIAH, S.; SAWANT, S.D.; TAWARE, P.B.; BONDAGE, D.D.; ITROUTWAR, P. Rootstocks influence the growth, biochemical contents and disease incidence in Thompson Seedless grapevines. British Journal of Applied Science &Technology, London, v.4, p.1030-1041, 2014
SSHA - Société Scientifique D'Hygiène Alimentaire. Évaluation sensorielle: manuel méthodologique. 2.ed. Paris: Tec e Doc, 1998. 353p. (Collection Sciences &Techniques Agroalimentaires).
STEVENS, R.M.; PECH, J.M.; TAYLOR, J.; CLINGELEFFER, P.; WALKER, R.R.; NICHOLAS, P.R. Effects of irrigation and rootstock on Vitis vinifera (L.) cv. Shiraz berry composition and shrivel, and wine composition and wine score. Australian Journal of Grape and Wine Research, Oxford, v.22, n.1, p.124-136, 2016.
TREEBY, M.T.; HOLZAPFEL, B.P.; PICKERING, G.J.; FRIEDRICH, C.J. Vineyard nitrogen supply and Shiraz grape and wine quality. Acta Horticulturae, Leuven, n. 512, p.77-92, 2000.
WALKER, R.R.; BLACKMORE, D.H. Potassium concentration and pH inter-relationships in grape juice and wine Chardonnay and Shiraz from a range of rootstocks in different environments. Australian Journal of Grape and Wine Research, Oxford, v.18, n.2, p.183-193, 2012.
WALLIS, C.M.; WALLINGFORD, A.K.; CHEN, J.C. Grapevine rootstock effects on scion sap levels, resistance to Xylella fastidiosa infection, and progression of Pierce’s disease. Frontiers in Plant Science, New Haven, v.4, p.816-826, 2013.
WOOLDRIDGE, J.; LOUW, P.J.E.; CONRADIE, W.J. Effects of rootstocks 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, Stellenbosh, v.31, n.1, p.45-48, 2010.

Publication Dates

Publication in this collection
2019

History

Received
20 Mar 2017
Accepted
05 June 2017

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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[2] BRAVDO, B.; SHOSEYOV, O. Aroma studies on fruits and wine in Israel. Acta Horticulturae, Leuven, n.526, p.399-405, 2000.

[3] CHOU, M-I.; LI, K-T. Rootstock and seasonal variations affect anthocyanin accumulation and quality traits of ‘Kyoho’ grape berries in subtropical double cropping system. Vitis, Sielbeldingen, v.53, n.4, p.193-199, 2014.

[4] COOKSON, S.J.; HEVIN, C.; DONNART, D.; OLLAT, N. Grapevine rootstock effects on scion biomass are not associated with large modifications on primary shoot growth under non limiting conditions in the first year of growth. Functional Plant Biology, Collingwood, v.39, p.650-660, 2012.

[5] FERRIS, H.; ZHENG, L.; WALKER, M.A. Resistance of grape rootstocks to plant-parasitic nematodes. Journal of Nematology, College Park, v.44, p.377-386, 2012.

[6] FLORES, C.A.; PÖTTER, R.O.; SARMENTO, E.C.; WEBER, E.J.; HASENACK, H. Os solos do vale dos vinhedos. Pelotas: Embrapa Clima Temperado, 2012.

[7] HALE, C.R.; BRIEN, C.J. Influence of salt creek rootstock on composition and quality of Shiraz grapes and wine. Vitis, Sielbeldingen, v.17, p.139-146, 1978.

[8] HARBERTSON, J.F.; KELLER, M. Rootstock effects on deficit-irrigated winegrapes in a dry climate: grape and wine composition. American Journal of Enology and Viticulture, Davis, v.63, n.1, p.40-48, 2012.

[9] JONES, T.H.; CULLIS, B.R.; CLINGELEFFER, P.R.; RÜHL, E.H. Effects of novel hybrid and traditional rootstocks on vigour and yield components of Shiraz grapevines. Australian Journal of Grape and Wine Research, Oxford, v.15, n.3, p.284-292, 2009.

[10] KELLER, M.; MILLS, L.J.; HARBERTSON, F. Rootstock effects on deficit-irrigated winegrapes in a dry climate: vigor, yield formation, and fruit ripening. American Journal of Enology and Viticulture, Davis, v.63, p.29-39, 2012.

[11] KODUR, S.; TISDALL, J.M.; TANG, C.; WALKER, R.R. Uptake, transport, accumulation and translocation of potassium in grapevine rootstocks (Vitis). Vitis, Sielbeldingen, v.50, p.145-149, 2011.

[12] MEILGAARD, M.; CIVILLE, G.V.; CARR, B.T. Sensory evaluation techniques. 3rd ed. Boca Raton: CRC, 1999. 387p.

[13] MENHOFER, M.; SCHMUCKENSCHLAGER, B.; VITOVEC, N.; HANAK, K.; REGNER, F.; RIEDLE-BAUER, M. Field studies on the effect of 31 rootstock varieties on yield and selected quality parameters of the grapevine variety ‘Zweigelt’ over a period of twelve years. Mitteilungen Klosterneuburg, Klosterneuburg, v.61, p.196-215, 2011.

[14] MIELE, A.; RIZZON, L.A. Rootstock-scion interaction: 1. Effect on the yield components of the Cabernet Sauvignon grapevine. Revista Brasileira de Fruticultura, Jaboticabal, v.39, n.1, p.1-9, 2017.

[15] MIELE, A.; RIZZON, L.A. Rootstock-scion interaction: 3. Effect on the Cabernet Sauvignon wine composition. Revista Brasileira de Fruticultura, Jaboticabal, 2018.

[16] OLLAT, N.; TANDONNET, J.P.; LAFONTAINE, M.; SCHULTZ, H.R. Short and long term effects of three rootstocks on Cabernet Sauvignon vine behaviour and wine quality. Acta Horticulturae, Leuven, n.617, p.95-100B, 2003.

[17] OUGH, C.S.; COOK, J.A.; LIDER, L.A. Rootstock-scion interactions concerning wine making. II. Wine compositional and sensory changes attributed to rootstock and fertilizer level differences. American Journal of Enology and Viticulture, Davis, v.19, n.4, p.254-265, 1968.

[18] RENOUF, V.; TREGOAT, O.; ROBY, J-P.; VAN LEEUWEN, C. Soils, rootstocks and grapevine varieties in prestigious Bordeaux vineyards and their impact on yield and quality. Journal International des Sciences de la Vigne et du Vin, Talence, v.44, n.3, p.127-134, 2010.

[19] RIBÉRAU-GAYON, P.; GLORIES, Y.; MAUJEAN, A.; DUBOURDIEU, D. Traité d’œnologie. 2. Chimie du vin. Stabilisation et traitements. Paris: Dunod, 1998.

[20] ROSA, C.; JIMENEZ, J.F.; MARGARIA, P.; ROWHANI, A. Symptomatology and effects of viruses associated with rugose wood complex on the growth of four different rootstocks. American Journal of Enology and Viticulture, Davis, v.62, p.207-213, 2011.

[21] SERRA, I.; STREVER, A.; MYBURGH, P.A.; DELOIRE, A. Review: the interaction between rootstocks and cultivars (Vitis vinifera L.) to enhance drought tolerance in grapevine. Australian Journal of Grape and Wine Research, Oxford, v.20, p.1-14, 2014.

[22] SILVILOTTI, P.; ZULINI, L.; PETERLUNGER, E.; PETRUSSI, C. Sensory properties of ‘Cabernet Sauvignon’ wines as affected by rootstock and season. Acta Horticulturae, Leuven, n.654, p.443-448, 2007.

[23] SOMKUWAR, R.G.; JOGAIAH, S.; SAWANT, S.D.; TAWARE, P.B.; BONDAGE, D.D.; ITROUTWAR, P. Rootstocks influence the growth, biochemical contents and disease incidence in Thompson Seedless grapevines. British Journal of Applied Science &Technology, London, v.4, p.1030-1041, 2014

[24] SSHA - Société Scientifique D'Hygiène Alimentaire. Évaluation sensorielle: manuel méthodologique. 2.ed. Paris: Tec e Doc, 1998. 353p. (Collection Sciences &Techniques Agroalimentaires).

[25] STEVENS, R.M.; PECH, J.M.; TAYLOR, J.; CLINGELEFFER, P.; WALKER, R.R.; NICHOLAS, P.R. Effects of irrigation and rootstock on Vitis vinifera (L.) cv. Shiraz berry composition and shrivel, and wine composition and wine score. Australian Journal of Grape and Wine Research, Oxford, v.22, n.1, p.124-136, 2016.

[26] TREEBY, M.T.; HOLZAPFEL, B.P.; PICKERING, G.J.; FRIEDRICH, C.J. Vineyard nitrogen supply and Shiraz grape and wine quality. Acta Horticulturae, Leuven, n. 512, p.77-92, 2000.

[27] WALKER, R.R.; BLACKMORE, D.H. Potassium concentration and pH inter-relationships in grape juice and wine Chardonnay and Shiraz from a range of rootstocks in different environments. Australian Journal of Grape and Wine Research, Oxford, v.18, n.2, p.183-193, 2012.

[28] WALLIS, C.M.; WALLINGFORD, A.K.; CHEN, J.C. Grapevine rootstock effects on scion sap levels, resistance to Xylella fastidiosa infection, and progression of Pierce’s disease. Frontiers in Plant Science, New Haven, v.4, p.816-826, 2013.

[29] WOOLDRIDGE, J.; LOUW, P.J.E.; CONRADIE, W.J. Effects of rootstocks 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, Stellenbosh, v.31, n.1, p.45-48, 2010.

Rootstock	Visual			Olfactory
Rootstock	Li	In	Hu	In	Gp	Fr	Sp	Ve	An
Rupestris du Lot	8.6	6.8	3.4	6.9	4.8	3.4	2.5	3.5	1.7
101-14 Mgt	8.6	7.2	2.7	6.8	4.6	3.8	2.6	3.3	1.5
3309 C	8.7	6.5	3.1	6.7	4.9	3.1	2.9	5.6	1.1
420A Mgt	8.5	7.5	2.5	6.7	4.2	3.2	2.6	3.2	2.0
5BB K	8.6	7.6	2.1	6.6	4.2	3.7	2.7	2.9	1.1
161-49 C	8.5	7.1	3.2	6.6	4.4	3.8	3.0	3.0	1.0
SO4	8.6	7.0	2.8	6.6	5.2	3.4	2.6	3.5	1.1
Solferino	8.7	6.6	3.0	6.0	4.3	3.7	2.5	3.0	0.8
1103 P	8.5	7.6	2.8	6.8	4.4	3.0	2.2	3.2	1.7
99 R	8.6	7.3	2.8	6.6	5.2	3.6	2.6	3.5	1.0
110 R	8.7	6.4	3.5	6.7	4.0	3.1	2.6	3.6	1.7
Gravesac	8.6	6.7	3.5	6.1	4.6	2.9	2.7	3.6	1.3
Fercal	8.7	7.8	2.1	6.4	4.4	3.6	2.7	3.0	0.9
Dogridge	8.5	6.7	3.3	7.0	4.2	2.0	1.9	3.9	2.5
Isabel	8.4	7.2	3.3	6.5	4.3	3.2	2.7	3.2	1.0
Mean	8.6	7.1	2.9	6.6	4.5	3.3	2.6	3.3	1.4
P>F (p value)	0.0743^ns	0.5048^ns	0.5523^ns	0.9618^ns	0.5452^ns	0.4668^ns	0.9683^ns	0.6812^ns	0.8091^ns

Rootstock	Taste/Flavor
Rootstock	In	Bo	As	Ac	Ba	Ty	Pe	Gp	Fr	Sp	Ve	An	Qu
Rupestris du Lot	6.2	5.3	3.9	5.6	5.5	5.8	3.4	4.3	2.8	2.4	3.5	1.5	7.3
101-14 Mgt	6.0	4.9	4.0	5.3	5.2	5.4	5.3	4.5	3.0	2.2	3.7	1.6	7.3
3309 C	6.2	5.0	4.2	5.7	5.1	6.3	5.4	5.0	2.8	2.3	3.9	1.5	7.4
420A Mgt	6.4	5.8	4.6	5.5	5.2	5.7	5.6	4.5	3.0	2.5	3.7	1.7	7.4
5BB K	6.4	5.6	4.4	5.5	5.8	6.3	5.9	4.7	3.4	2.6	3.3	1.5	7.5
161-49 C	6.2	5.5	4.5	5.6	5.8	6.0	5.8	4.5	3.5	2.7	3.1	1.0	7.6
SO4	6.2	5.5	4.4	5.3	5.7	6.3	5.6	5.2	3.1	2.6	3.4	0.9	7.5
Solferino	5.6	5.1	4.0	5.4	5.3	5.8	5.4	4.3	3.0	2.6	3.2	0.7	7.4
1103 P	6.6	5.7	4.4	5.4	5.8	6.1	5.9	4.4	3.3	2.7	3.4	1.3	7.5
99 R	6.2	5.6	4.2	5.6	5.9	6.4	5.8	5.8	3.3	2.6	3.5	0.9	7.6
110 R	6.1	4.9	4.3	5.5	4.9	5.4	5.6	4.3	2.8	2.3	3.1	1.7	7.3
Gravesac	5.9	4.8	4.2	5.2	4.8	5.7	5.4	4.3	2.8	2.4	3.4	1.3	7.3
Fercal	6.3	5.8	4.4	5.5	5.6	5.9	6.0	4.2	3.5	2.4	3.2	0.9	7.7
Dogridge	6.1	5.1	4.2	5.5	4.8	5.3	5.6	4.1	2.1	1.9	3.9	2.5	7.2
Isabel	6.1	5.5	4.3	5.4	5.8	6.2	5.9	4.4	3.3	2.6	3.4	1.0	7.6
Mean	6.2	5.3	4.3	5.5	5.4	6.0	5.6	4.6	3.1	2.5	3.5	1.3	7.4
P>F (p value)	0.5434^ns	0.7317^ns	0.4445^ns	0.6402^ns	0.2080^ns	0.7856^ns	0.9856^ns	0.4878^ns	0.7706^ns	0.8282^ns	0.5246^ns	0.4077^ns	0.7898^ns

Brasil