Abstract
Chemical and descriptive sensory analysis was conducted on nine (2005) and eight (2006) experimental Niagara Peninsula Cabernet franc wines to illustrate differences that might support the subappellation system in Niagara. Twelve trained judges evaluated six aroma and flavor (red fruit, black cherry, black currant, black pepper, bell pepper, and green bean) and three mouthfeel (astringency, bitterness, and acidity) sensory attributes plus color intensity. Data were analyzed using analysis of variance (ANOVA), principal component analysis (PCA), and discriminant analysis. ANOVA of sensory data showed regional differences for all sensory attributes. In 2005, wines from Château des Charmes (CDC), Henry of Pelham (HOP), and Hernder sites showed highest red fruit aroma and flavor. Wines from Lakeshore and Niagara River sites (Harbour, Reif, George, and Buis) showed higher bell pepper and green bean aroma and flavor due to the cool growing conditions in proximity to the large bodies of water. In 2006, all sensory attributes except black pepper aroma were different. PCA revealed that wines from HOP and CDC sites were higher in red fruit, black currant, and black cherry aroma and flavor, and black pepper flavor, while wines from Hernder, Morrison, and George sites were high in green bean aroma and flavor. Buis wines were high in bell pepper aroma and flavor and acidity due to cooler conditions within the proximity of Lake Ontario. ANOVA of chemical data in 2005 indicated that hue, color intensity, and titratable acidity were different across the sites, while in 2006, hue, color intensity, and ethanol were different. These data indicate that there is the likelihood of substantial chemical and sensory differences between clusters of subappellations within the Niagara Peninsula.
The Ontario, Canada, grape and wine industry has expanded rapidly in recent years. Total output from ~6870 ha of vineyards averaged about 53,000 tonnes annually between 2004 and 2008. About 40% of the wine sales in Ontario between 2004 and 2008 originated chiefly from the Niagara region and smaller amounts from the wine-producing regions of Pelee Island, Lake Erie North Shore, and Prince Edward County. In the 2008 vintage, Ontario growers produced a crop of 60,780 tonnes, generating a farm gate value of $77.1 million ($79.5 million CD) (Grape Growers of Ontario 2009).
The Ontario Vintners Quality Alliance (VQA) was established in 1988 to set standards for producing premium wines in Ontario. Initially, VQA recognized three viticultural areas or appellations—Lake Erie North Shore, Pelee Island, and Niagara Peninsula—that were considered to have the potential to produce wines of different quality due to various soil and climatic conditions. Prince Edward County became Ontario’s most recent Designated Viticultural Area in 2006. The Niagara Peninsula, with its relatively mild winter climate, favors a wide range of grape cultivars. The position of Niagara Peninsula between Lake Ontario and Lake Erie exposes the region to lake breezes that moderate high summer and cold winter temperatures (Shaw 2002).
Climatic factors, such as distance from the lake, slope, elevation, and airflow patterns, as well as soil type and parent material create a wide range of mesoclimates with various potential for producing quality winegrapes. The soils in the region range in texture from poorly drained heavy clays, clay loam tills, imperfectly drained silty clay, to moderately well-drained sandy loams, with a wide range of water-holding capacities. Consequently, the Niagara Peninsula has been further divided into subappellations. Climatological differences have been identified among the Lakeshore, Lakeshore Plain, and Escarpment Bench regions of Niagara, using infrared and aerial photography (Wiebe and Anderson 1977). Geographical and geological data have also highlighted regional differences (Sayed 1992). Most recently, Ontario VQA established 10 subappellations in the Niagara Peninsula based on a combination of climate, elevation, and soil characteristics (Figure 1⇓).
Previous sensory studies on commercial Riesling and Chardonnay wines showed differences among the Lakeshore, Lakeshore Plain, and Escarpment Bench regions of the Niagara Peninsula (Douglas et al. 2001, Schlosser et al. 2005). Bordeaux red wine cultivars in the Niagara Peninsula also showed significant regional differences based on red fruit, dried fruit, fresh vegetable, canned vegetable, spice, and oak sensory attributes among the Lakeshore, Lakeshore Plain, and Bench regions (Kontkanen et al. 2005). Sensory descriptive analysis found that Ontario icewines had the higher fruity and floral aromas and a golden copper color, while British Columbia icewines had higher sweetness, body, and intensity of aftertaste (Cliff et al. 2002).
Thus far, the 10 subappellations established by the VQA have not been validated. The purpose of this study was to develop sensory and analytical methodologies for characterization of Cabernet franc wines from typical vineyards within these 10 subappellations within the Niagara Peninsula to determine the degree and nature of any differences. Over 5900 tons of Cabernet franc were harvested in Ontario in 2008, making it the most widely planted red wine cultivar in the province (Grape Growers of Ontario 2009).
Materials and Methods
Site selection.
Ten commercial vineyard blocks of Cabernet franc were selected in spring 2005. Each vineyard block was located in one of 10 subappellations of the Niagara Peninsula recently approved by the Ontario VQA: Niagara Lakeshore, St. David’s Bench, Creek Shores, Four Mile Creek, Niagara River, Lincoln Lakeshore, Beamsville Bench, Short Hills Bench, Vinemount Ridge, and Twenty Mile Bench (Figure 1⇑, Table 1⇓ [see abbreviations]). An 8 m x 8 m grid pattern of 75 to 80 sentinel vines was used in each vineyard block for all data collection. Sentinel vines were geolocated using a Raven Invicta 115 global positioning system (Raven Industries, Sioux Falls, SD).
Vine water status.
Midday leaf water potential (ψ) was determined between 1100 hr and 1600 hr for fully exposed, mature leaves of similar physiological stage that showed no visible sign of damage and had been in full sunlight. Each leaf sample was covered in a plastic bag and sealed immediately after excision at the petiole to suppress transpiration. The leaf petiole was cut with a sharp razor blade and then inserted into a pressure chamber (model 3005, Plant Water Status Console; Soil Moisture Equipment, Santa Barbara, CA) with the cut edge of the petiole facing the outside surface. After sealing the chamber, pressure was increased slowly by opening the compressed nitrogen valve. As soon as sap emerged at the cut end of the petiole, gas flow was stopped and the corresponding pressure was recorded from the gauge, which was in negative bar units (10 bars = 1 MPa). A total of 15 to 20 leaves per vineyard block were used to estimate leaf ψ for each sampling date. Overall, there were five sampling dates during the growing season, occurring biweekly between late June and early September for each site.
Soil water status.
Soil moisture data were taken biweekly with a soil moisture probe (Fieldscout TDR-300; Spectrum Technologies, East Plainfield, IL) between late June and early September in the 2005 and 2006 growing seasons for a total of five sampling dates each season. Readings (% water by volume) were taken at each experimental vine in each block. A total of 72 to 80 vines per site were measured between 0800 hr and 1800 hr. Measurements were taken in the row ~10 cm from the base of each vine trunk over a 20 cm depth. The mean soil moisture at each sentinel vine was calculated from the five separate readings.
Soil sampling.
Soil samples were collected from every fourth sentinel vine with an auger from within the row, 40 to 50 cm from the trunk. Soil was taken from a 0 to 75 cm depth, with a total ~350 g of a homogenized sample. Based on the area of each vineyard block, 15 to 20 soil samples were taken. Soil samples were analyzed for pH, organic matter, P, K, Mg, Ca, texture, cation exchange capacity, and base saturation using standard procedures (CSSS 1993). Soil samples were air-dried, pulverized, and sieved to remove particles >2 mm in diameter. Subsamples were retained for elemental analysis (P, K, Ca, Mg) using inductively coupled plasma emission spectroscopy (ICP) (Optima 3000; Perkin-Elmer, Waltham, MA). Organic matter (OM) analysis was performed using standard colorimetric methods (CSSS 1993). Cation exchange capacity and base saturation were measured using standard methods (CSSS 1993). All soil analyses were carried out at Agri-Food Laboratories, Guelph, ON.
Yield components and vine size.
Prior to the harvest of each block in September/October, 100-berry samples were collected from random clusters in each experimental vine and stored at −25°C until analysis. All berry samples and fruit were collected one day before the commercial harvest. These samples were eventually used to determine berry weights, soluble solids (Brix), pH, titratable acidity, color intensity (A420 + A520), hue (A420/A520), total anthocyanins, and total phenols. All sentinel vines were hand-harvested and yield and cluster numbers were determined for each vine. Vines were pruned during the dormant season in accordance to the corresponding training system, and weights of cane prunings were collected from each vine to determine vine size in kg.
Berry and wine composition.
The frozen berry samples were thawed, weighed, and placed in 250 mL beakers and then heated to 80°C in a water bath and held for one hour to dissolve any precipitated tartrates. Samples were cooled to the room temperature and juiced in an Omega 500 fruit juicer. The resulting juice was centrifuged at 4500 rpm for 10 min in a centrifuge (IEC Centra CL2; International Equipment, Needham Heights, MA) to remove debris. The supernatant was retained for analysis of pH via a pH meter (Accumet model 25; Denver Instrument Company, Denver, CO), titratable acidity (TA) with an autotitrator (PC-Titrate; Man-Tech Associates, Guelph, ON) by titration with 0.1 N NaOH to an end point of pH 8.2, and Brix using an Abbé refractometer (model 10450; American Optical, Buffalo, NY). The remaining juice was centrifuged at 12000 g for 10 min and stored at −25°C for further analysis for phenolic analytes. Wine samples were analyzed for TA and pH using the above method.
Ethanol was determined using a gas chromatograph (6890 series; Agilent, Wilmington, DE) equipped with an Omegawax 250 fused silica column (30.0 m x 250.00 μm x 0.25 μm). Other conditions of operation included: carrier gas helium, split ratio of 100.183:1, oven initial temperature 60°C, injection temperature 230°C, and detector temperature 225°C. Wine samples or standards were diluted 1:10 with 2% 1-butanol as an internal standard. A 1.0 μL wine sample or standard was injected by an automatic injector with a run time of 5.07 min.
After thawing to room temperature for several hours, color, anthocyanins, and total phenols were determined on juice and wine samples. Total phenols were estimated using standard methods (Slinkard and Singleton 1977). Anthocyanin measurements were performed on wine samples using the pH shift method by measuring the differential absorbance at 520 nm between wines at pH 1.0 and pH 4.5 (Mazza et al. 1999). Color intensity was determined according to a modified method (Mazza et al. 1999). Color intensity and hue were calculated from absorbance values measured at 420 nm and 520 nm on a spectrophotometer (Ultrospec 2100 Pro UV/VIS; Biochrom Ltd., Cambridge, UK).
Origin of wines.
Four fermentation replicates each of nine (2005) and eight (2006) experimental Cabernet franc wines from the Niagara Peninsula, ON, were compared. Within each vineyard block, the four winemaking replicates were taken from one large homogeneous lot of grapes that was divided into four lots. In 2005, four wines were from east of St. Catharines in the Niagara-on-the-Lake area and the other five were from west of St. Catharines in the Jordan, Vineland, and Beamsville areas. In 2006, only four wines were from west of St. Catharines because of a severe powdery mildew problem in one of the subject vineyards. Each wine originated from zones of moderate water status (≈ mean ψ for the season) within each vineyard block, based on maps created using MapInfo and VerticalMapper geographical information system software (Northwood GeoScience, Ottawa, ON). The inverse-distance weighting algorithm was used for creation of the grid files and maps.
All wines were produced by one winemaker according to standard procedures from the 2005 and 2006 vintages at the Brock University winery facilities. Each of the 20 L fermentation replicates from each site was based on a subsection of the vineyard block. Grapes from each vineyard block were destemmed, crushed, and treated with potassium metabisulfite at 25 mg/L, and then inoculated with Lalvin Selection ICV 254 (Saccharomyces cerevisiae) yeast (Lallemand, Montreal, QB). The fermentation took place at 23°C in 30 L food-grade plastic pails for 10 days until capfall with three daily punchdowns, during which the cap was also completely submerged. Wines were then pressed at 2 bars pressure and were maintained at −2°C for cold stabilization for 10 days; they were then racked and inoculated with malolactic bacteria (Lalvin VP41, St. Simon, France). Upon completion of malolactic fermentation, all wines were racked again, stored at −2°C for 7 days, sulfited with an additional 50 mg/L, filtered through a 1.0 μ pad filter and 0.45 μ cartridge filter, and bottled under cork.
Sensory evaluation.
The initial group of 20 judges composed of Brock University faculty, staff, and students were selected for the panel based on their availability and motivation. Six judges were experienced tasters and the others were students with limited wine-tasting experience. Eight judges either withdrew or were dropped from the panel by the end of the training sessions. The final panel consisted of five females and seven males, ranging from 22 to 54 years.
Nine (2005) and eight (2006) wines were evaluated by 12 judges (t = 9/8, k = 8, r = 4, b = 12), where t, k, r, and b are the number of treatments (wines), number of samples/session, number of replicates, and sample sets in each session (or number of panelists), respectively. At the initial point of training, wine samples were presented to the panel to evaluate and identify relevant aroma, flavor, and mouthfeel attributes. The six experienced tasters individually evaluated these wines and wrote relevant attributes on evaluation sheets. Eight training sessions were thereafter held for all judges. Reference standards were available to define descriptors. In each training session, judges were asked to independently rate the intensity of the descriptive terms in the wine samples as well as standards themselves and to add terms if necessary. There were also three mouthfeel standards (astringency, bitterness, and acidity) for evaluating sample wines (Table 2⇓). In each training session, three sample wines were served with random codes to all judges to train them to evaluate all wine samples as accurately and consistently as possible. After each training session, data were analyzed to evaluate the performance of each judge. Each attribute was also examined by analysis of variance to determine if that attribute varied across the wine samples and if the judges were consistent and reproducible.
In each tasting session, each judge evaluated eight wines in two flights of four. Judges were given 30 mL wine samples to evaluate at room temperature (~22°C) for the sensory (aroma, flavor, and mouthfeel) attributes. Samples were in 210 mL ISO-approved wineglasses covered with petri dishes to prevent volatile loss. Glasses were labeled with three-digit random numbers and presented to judges in random order according to the design. All evaluations were conducted using Compusense five (release 4.8, Compusense Inc., Guelph, ON) in isolated booths under red light to mask the color differences among wine samples. For color intensity evaluation, 10 mL samples were also presented in 5 cm diameter petri dishes against a white background under natural light, with the same random numbers.
The judges evaluated aroma and flavor in the first four wines, took a short break, evaluated color intensity for the same wines, and finished the session by evaluating the second flight of four wines. The magnitude of each attribute was evaluated on a 15 cm unstructured line scale, where 0 and 15 were anchored with the labels “absent” and “high,” respectively. Sensory scores were determined by measuring the judges’ scored marks from the origin in cm. Judges rinsed with water and thereafter with a water and pectin solution between flavor evaluations to prevent a carryover effect. Evaluations were started in the morning at 1100 hr and continued until late afternoon to accommodate judge schedules. All evaluations were done at Brock University’s sensory evaluation facility. All wine samples were poured from the same bottles (750 mL) to avoid bottle-to-bottle variation. Aroma standards developed during the training sessions were available to judges before each session as a reference (Table 2⇑).
Statistical analysis.
Data were analyzed using the SAS statistical package (SAS Institute, Cary, NC). A correlation matrix was created on the sensory attributes to illustrate the relationship among variables. Using GLM, analysis of variance was performed on chemical and sensory attributes. Three-way ANOVA (site, judge, and replicate) was also performed on sensory attributes to ascertain main effects as well as interactions. Duncan’s multiple range test was used to separate the means for both sensory and chemical data. Principal component analysis (PCA) and discriminant analysis were performed using XLSTAT 2008 on the mean sensory scores for the aroma, flavor, and mouthfeel attributes. Partial least squares (PLS) was performed on the field, berry composition, and sensory data.
Results and Discussion
Sensory analysis.
2005. Results from the ANOVA show the sources of variation for each of the sensory attributes for the main effects: wine (W), judge (J), and replication (R), and the interactions (WXJ), (JXR), and (WXR). Judges were a significant source of variation for all attributes because of the use of different parts of the line scale by judges (Poste et al. 1991). All attributes were significantly different, illustrating that the chosen terms were useful in characterizing differences among Cabernet franc wines in the Niagara region (Table 3⇓). The reproducibility of the panel was shown by a nonsignificant effect of replication (data not shown). Likewise, the J X R and W X R (except one case) interactions were not significant, indicating similarity of wine bottles and good reproducibility of judges (data not shown). However, there were significant regional differences as indicated by comparing mean scores (Table 3⇓). For instance, wines from Escarpment Bench (St. David’s, Short Hills, Twenty Mile, and Beamsville subappellations) and Lake Plain sites (e.g., Four Mile subappellation) were higher in red fruit aroma and flavor, while Lakeshore (e.g., Niagara Lakeshore and Lincoln) or Niagara River sites were lower, suggesting that the sites closer to Lake Ontario or the Niagara River were generally low in red fruit character. Wines from Cave, Reif, and Harbour sites were highest in black cherry aroma, while CDC, Cave, Reif, HOP, and Hernder wines were highest in black cherry flavor (Table 3⇓).
Highest black currant aroma was detected in Cave, Reif, and HOP, and there was also more black currant flavor in CDC, Cave, Reif, and Hernder wines. Black pepper aroma was highest in CDC, Cave, George, Reif, and Vieni, while Buis, Cave, George, Reif, and Hernder wines were most intense in black pepper flavor. Wines from Lakeshore and Niagara River sites had highest green bean aroma and flavor. More intense bell pepper aroma and flavor were detected in Cave, George, Reif, and Harbour wines. CDC, Buis, Cave, and Hernder wines were more astringent, while bitterness was highest in CDC, Buis, and George wines. Wines from Cave Spring and George were more acidic. High color intensity was observed in CDC, Cave, George, and Harbour wines (Table 3⇑).
For the relationships between aroma and flavor attributes, the PCA explained 52.1% of the variability in the data in the first two dimensions (Figure 2⇓). PC1 accounted for 29.7% of the variability and was most heavily loaded in the positive direction with red fruit, black cherry, and black currant aroma and flavor and black pepper aroma and acidity. PC2 explained 22.4% of the variation in the data set and was positively loaded with green bean and bell pepper aroma and flavor and black pepper flavor. The third PC explained another 13.5% of the variation (data not shown); however, there was substantial unexplained variability in the data that could not be attributed to the first three vectors.
The distribution of wines on the PCA illustrates that CDC wines were located in the right and lower part of the plot, dominated by red fruit aroma and flavor and black pepper aroma. HOP and Hernder wines were grouped in the lower right quadrant and were explained by red fruit aroma and flavor; HOP was more intense in the above characters because it was farther away from the center. Astringency and bitterness appeared to explain a very small percentage of variability because of the shorter vector length. The Cave wines were located in the upper right of the plane and were characterized by high black cherry aroma and flavor, black currant flavor, and high color and acidity. The relatively short length of the color intensity eigenvector showed that the wines evaluated were not high in color intensity. Harbour, George, and Reif wines (all either from adjacent to Lake Ontario or from the Niagara River) were grouped in the upper left of the plane, lacking in fruity characters but associated with green bean aroma and flavor, bell pepper aroma and flavor, and black pepper flavor (Figure 2⇑). Replicate 1 of Buis wines (also from adjacent to Lake Ontario) was also explained by green bean aroma and flavor, while Buis replicates 2 and 3 and Vieni wines (from south of the Niagara Escarpment) were grouped in the lower left of the plane and were low in black pepper flavor and acidity. Buis wines were grouped in the upper left of the plane in PC2 and were explained by green bean aroma and flavor. Vieni wines were grouped in the lower left of the plane and were characterized by low color intensity, astringency, and bitterness.
Discriminant analysis of sensory data (F1 and F2 = 81.4% of the variability) showed that wines from Harbour and George sites (both situated on the Lake Ontario shoreline) were clearly grouped and separated from other wines, characterized by bell pepper aroma and flavor, black pepper and green bean flavor, and acidity. CDC and Buis wines were also clearly separated from other groups, characterized by astringency and bitterness. The Vieni and Hernder sites were grouped together and separated from the other sites, with high red fruit aroma/flavor and black pepper aroma. Cave, Reif, and HOP were also grouped together and clearly separated from other groups, characterized by black cherry and black currant aroma and flavor (Figure 3⇓).
A compelling feature of the 2005 data was the tendency for sites near Lake Ontario to produce wines with pronounced green bean and bell pepper aromas and flavors. Proximity to large bodies of water plays a significant role in climatic patterns worldwide. Cabernet Sauvignon wines from cool areas south of San Francisco Bay were characterized by intense vegetative notes (Heymann and Noble 1989). The cool air of the sea breeze in the Western Cape in South Africa prevents high day temperatures (Bonnardot et al. 2002); the cooling effect of the breeze decreased rapidly with distance from the sea, resulting in higher temperature variability in the inland sites. A related study reported higher tropical fruit aroma character in Sauvignon blanc wines from warmer inland locations (Conradie et al. 2002). In our study in 2005, wines from Lakeshore and Niagara River sites (Harbour, Reif, George, and Buis) exhibited green bean aroma and flavor characters and a lack of fruity aroma and flavor. These sites were in close proximity to either Lake Ontario or the Niagara River and were characterized by lower growing season temperatures and heat unit accumulation (growing degree-days; GDD). Wines from CDC (St. David’s Bench subappellation), HOP (Short Hills), Hernder (Four Mile), and Cave (Beamsville Bench) were located far from large water bodies, and showed the highest fruity character and less green bean aroma and flavor. These sites received a greater number of GDD than the sites close to the lake or river early in the season (Grape Growers of Ontario 2009). The more rapid GDD accumulation typically results in early budburst and bloom as well as earlier harvest, compared to the sites where temperatures are moderated by Lake Ontario or are south of the Niagara escarpment (Vieni).
2006. Analysis of variance showed significant differences among sites in all attributes except black pepper aroma (Table 3⇑). There was no significant replication effect, indicating that judges were consistent from one session to the next (data not shown). Despite holding eight training sessions for judges to score attributes of different intensities in a similar manner, there were significant judge effects for all attributes (data not shown), indicating that the judges used different parts of the intensity scale. As a result there were significant differences among the means for each judge. This difference among judges is typical in many studies. Except for one case, J X R interactions were not significant; W X R interactions were also not significant except in four cases (data not shown).
Red fruit aroma was highest at Buis, HOP, CDC, Reif, Morrison, and Cave, while red fruit flavor was most intense at HOP, CDC, Reif, and Cave sites. Highest black cherry aroma was observed at HOP, CDC, and Reif sites; Buis, HOP, CDC, Reif, and Cave sites had most intense black cherry flavor. Black currant aroma was highest at Buis, HOP, and CDC sites, while HOP, CDC, and Morrison sites were high in black currant flavor. The CDC and Reif sites were highest in the intensity of black pepper flavor. Green bean aroma and flavor were most intense at George and Hernder sites. Buis, HOP, George, CDC, and Hernder sites were high in bell pepper aroma and flavor, while Morrison was high in bell pepper flavor only. Wines from Buis, George, Hernder, and Cave were more astringent. CDC wines were highest in bitterness, and Buis and George wines were most acidic. Highest color intensity was observed at the George, CDC, Hernder, and Cave sites (Table 3⇑).
The first two factors of the PCA mean sensory scores explained 52.5% of the variability in the data set (Figure 4⇓). The PC3 explained another 11.9% of the variability in the data set (data not shown), so there was a substantial amount of unexplained variability in the data that could not be attributed to the first three factors. CDC and HOP wines were located in the upper left of the plane and were associated with red fruit aroma/flavor, black cherry aroma/flavor, black currant aroma/flavor, and black pepper flavor. All Cave and Reif wines were in the lower left quadrant and were low in bell pepper aroma/flavor, green bean aroma/flavor, astringency, and acidity. Hernder, George, and Morrison wines were in both the upper and lower right of the plane and were explained by green bean aroma/flavor and color intensity; however, Morrison wines were closer to the center and were lower in the intensities of the above attributes. Buis wines were in the upper right quadrant and were associated with bell pepper aroma/flavor, black pepper aroma, acidity, and astringency (Figure 4⇓).
Discriminant analysis on 2006 sensory data (F1 and F2 explained 62.2% of the variability) showed that the Buis, George, and Hernder sites were grouped together and separated from other sites. These sites were characterized by acidity, astringency, green bean aroma and flavor, and bell pepper aroma. Buis and George were located adjacent to Lake Ontario, while Hernder was likely overcropped. Morrison was separated from other sites and characterized by bell pepper flavor and black pepper aromas. Cave was separated from the other sites and characterized as high in color, bitterness, and black pepper flavor. HOP, CDC, and Reif were grouped together and characterized by red fruit and by black cherry and black currant aroma and flavor (Figure 5⇓).
In cool climates, particularly in less-than-optimal vintages such as 2006 in Niagara, warm mesoclimates have a positive effect on grape and wine quality. This relationship between accumulated heat units and wine characteristics is worldwide. With Pinot gris grown in containers in warm and cool sites, some of the revealed quality differences were attributed to aroma and flavor compounds (Becker 1985). In a comparison of cool and warm vineyard sites in South Australia, volatile terpenes increased more slowly in cool sites but finally attained higher concentrations (Ewart 1987). Wine scores were also higher from grapes grown on the cool sites. Nonetheless, some compounds such as methoxypyrazines that give green bean and bell pepper aromas and flavors to cultivars such as Cabernet franc may be at high concentrations in cooler climates, particularly under shaded situations (Lacey et al. 1991). In our study, high bell pepper and green bean aromas and flavors at Harbour, George, Reif, and Buis sites in 2005 and at George and Buis sites in 2006 were attributable to proximity of these sites to Lake Ontario and the Niagara River, resulting in less GDD accumulation and, consequently, unripe fruit, characterized by vegetal aroma and flavor. The HOP and CDC sites both had more heat units, which enabled them to ripen their fruit by the end of growing season; hence, the most intense fruity aroma and flavor were found in these wines.
The 2006 growing season in Niagara was characterized by several substantial precipitation events, including many during the harvest period. Excess rainfall or irrigation may result in delayed fruit ripening, and as a consequence may prevent grapes reaching full maturity, therefore reducing wine quality. Rain, especially before harvest, plus humidity also increases the chance of Botrytis and other fungal diseases, which decrease the quality of grapes and wine. Rain or the threat of rainfall may sometimes force growers to harvest unripe fruit with high vegetal character. Jackson and Cherry (1988), using climatic indices for predicting site suitability for viticulture, found that areas with high rainfall had lower ripening capacity. In our study, Buis, George, Morrison, and Hernder wines in 2006 were high in bell pepper and green bean aromas and flavors. Higher available water and less heat unit accumulation may both explain the pronounced vegetal characteristics in Buis and George wines; in Hernder and Morrison wines, high vegetal characteristics could have possibly been due to early harvest and unripe fruit.
Chemical analysis.
2005. ANOVA for chemical attributes showed that except hue, color intensity, and TA, all other attributes were not different across the sites (Table 4⇓). Reif, Hernder, and Harbour sites were highest in hue while CDC, Cave, and Buis sites were highest in color intensity and TA.
PCA on the chemical variables explained 71.2% of the variance in the data in the first two dimensions (Figure 6⇓). The first PCA explained 52.5% of the variance among the wines while PC2 accounted for 18.7% with an additional 15.3% explained by PC3 (data not shown). Color, anthocyanins, TA, and ethanol had positive loadings on PC1, while it was highly negatively loaded with hue and pH. Color and TA were negatively correlated with pH. Color was positively correlated with TA, anthocyanins, and ethanol. CDC and Cave wines were in the upper right quadrant and associated with high color intensity, anthocyanins, phenols, and ethanol. Buis wines were located in the lower right quadrant and were explained by high TA. Reif and Harbour wines were in the lower left quadrant and were associated with high hue, high pH, and low ethanol and anthocyanins. Vieni, Hernder, George, and HOP wines were located in the upper left of the plane and were associated with high pH and low color intensity and TA.
Discriminant analysis, with F1 and F2 explaining 83.1% of the variability, showed that the Cave and Hernder sites were separated from other groups and explained by low color, anthocyanins, phenols, TA, and ethanol. George and Reif (both adjacent to Lake Ontario or the Niagara River) were associated with high hue and pH. CDC, Vieni, and HOP were explained by low hue and pH. Buis and Harbour (both adjacent to Lake Ontario) were characterized by high TA, anthocyanins, and color (Figure 7⇓).
2006. Analysis of variance for chemical attributes revealed that, except for hue, color intensity, and ethanol, all attributes were not different among sites (Table 4⇑). The Morrison site had the lowest color intensity and the highest hue. Color intensity was highest at the Cave, George, and Reif sites. Highest ethanol was observed at the Cave, Reif, and CDC sites.
The PCA plot indicated that PC1 and PC2 accounted for 61.3% and 22.3% of the variability in the data set, respectively (Figure 8⇓), with an additional 10.0% explained by PC3 (data not shown). Color intensity, anthocyanins, and TA were highly positively loaded on PC1, while highly negatively loaded with hue and pH. Total phenols and ethanol both were highly positively loaded on PC2. Again, George and Buis wines were together in the lower right quadrant and associated with high TA and low hue and pH. The Cave wines were associated with high color intensity, anthocyanins, and ethanol. The Morrison, CDC, and Reif sites were in the upper left quadrant; CDC and Reif wines were explained by high phenols and Morrison wines were explained by high hue and pH. The Hernder and HOP sites were not readily explained; however, these sites were lower in ethanol, color intensity, and phenols.
Discriminant analysis, with F1 and F2 explaining 89.2% of the variability, indicated that Morrison, CDC, and Reif were grouped together and characterized by high hue, phenol, and anthocyanins. Cave separated as a single group, with high TA, color, and anthocyanins. Buis, Hernder, George, and HOP were grouped, with low phenols and ethanol (Figure 9⇓).
In many grapegrowing areas, the choice of grape cultivar is such that the maturity of the berries occurs just before the mean monthly temperature drops to 10°C (Jackson 1991). In cool climates, warm seasons and warm mesoclimates are an advantage. Generally, cool climates encourage low sugar levels and higher TA in grapes, while hot climates have opposite effects (Alleweldt et al. 1984). Berry maturation is typically associated with a rise in juice pH and lowering of TA, with the rate of malic acid decline typically related to temperatures in growth stage III (Alleweldt et al. 1984). In Australia, wines made in warmer viticultural regions were reported to have higher pH levels than wines made in cooler regions (Rankine et al. 1971). Likewise, pH and total volatile esters in Okanagan Riesling wines were higher in those from a warmer site (Reynolds et al. 1995). Herrick and Nagel (1985) found that the mean phenol concentration of Riesling wines from Alsace was very low (13 mg/L), while that from eastern Washington State and California was 123 mg/L. These patterns are consistent with our results, which showed high TA at a cooler site (Buis in 2005 and 2006) and low TA (HOP, Vieni, and Hernder in 2005), high ethanol (Cave in 2005 and 2006), and high pH (Morrison in 2006) at warmer sites, possibly because the warmer temperatures led to metabolism of malic acid. Also, there were higher anthocyanins and phenols at Vieni, HOP, and Hernder in 2005 and Cave and CDC in 2006, perhaps because of greater heat unit accumulations at these warmer mesoclimates.
Partial least squares analysis (PLS).
PLS was performed on the entire 2005 and 2006 data sets to show relationships among yield components, berry composition, vine size, soil attributes, and sensory data. PLS explained 84.3% of the variability in the 2005 data sets (Figure 10⇓). The absolute value of leaf ψ was positively correlated with red fruit aroma/flavor, berry pH, berry color intensity, wine color intensity, total phenols, and Brix, while negatively correlated with soil moisture, green bean aroma/flavor, and bell pepper aroma/flavor. This suggests that sites with lower vine water status were also those with the most intense color and ripe fruit characteristics. Vine size was positively correlated with bell pepper flavor, green been aroma, and acidity. Soil moisture was positively correlated with acidity, bitterness, vine size, bell pepper aroma/flavor, green bean aroma/flavor, and black cherry aroma/flavor. Clay was positively correlated with black currant and black pepper flavor (Figure 10⇓). PLS analysis in 2006 explained 53.9% of the variation in the data sets and indicated that soil moisture was positively correlated with green bean aroma/flavor, bell pepper aroma, yield, and total phenols. Clay also was positively correlated with red fruit aroma and flavor, black currant aroma, and black cherry flavor (Figure 11⇓).
Chemical and sensory differences in the wines were believed to be due to climatic conditions, which in turn are related to the topography of the region. East- and south-facing slopes in cool-climate wine regions of the northern hemisphere receive more sunlight because of their early exposure during the growing season; as a consequence north-facing slopes of the Niagara Escarpment receive less sunlight late in the summer (Shaw 2005). In subappellations located closer to Lake Ontario or the Niagara River (Figure 1⇑), temperatures remain cool in April, budburst begins late in the season, and GDD are sometimes not sufficient to ripen Cabernet franc. Subappellations far from the lake experience early warming in the spring, and therefore GDD are sufficient for ripening Cabernet franc (Table 1⇑) (Shaw 2005). However, although climate appears to be the most important driving force affecting grape and wine composition, the role of other factors such as vine water status (leaf ψ), vine size, and soil texture cannot be discounted, as suggested elsewhere (Chapman et al. 2005).
Vine water status influences almost every aspect of plant metabolism (Bradford and Hsiao 1982) and as a result it affects most aspects of fruit composition. Low vine water status may be associated with reduced vegetal characteristics and increased fruity aroma and flavor in red wines. In one study, limited water availability increased the main aromatic compounds of grapes and the resultant wines were preferred in tasting trials (Koundouras et al. 2006). This finding is consistent with our 2005 results, which indicate that absolute value of leaf ψ (low water status) was positively correlated with fruity characters and negatively correlated with vegetal characters (Figure 10⇑); however, it was not entirely consistent with 2006 results, perhaps because of excess precipitation that season (Figure 11⇑).
High vine size due to high vegetative growth is frequently correlated with vegetal characteristics of wines induced by methoxypyrazines. Hashizume and Samuta (1997) indicated that methoxypyrazines were present at high concentrations in grape berries and these compounds might contribute to the vegetal flavor of wines. They also proved the effect of photodecomposition on methoxypyrazines in several grape cultivars, including Cabernet Sauvignon, Merlot, Pinot noir, Muscat Bailey, Semillon, Sauvignon blanc, Chardonnay, and Riesling (Hashizume and Samuta (1999). In 2005, high vine size was correlated with bell pepper flavor and green bean aroma and black cherry and black pepper flavor (Figure 10⇑). High vine size (hence high vegetative growth) creates more within-canopy shade that often leads to excessive vegetal characteristics in wines. In 2006, vine size correlated with bell pepper aroma and flavor, green bean flavor, and some fruity characteristics (Figure 11⇑). Vegetative growth is stimulated by high soil water availability in the postveraison period, which can delay sugar accumulation in grapes (Smart and Coombe 1983). In addition, excessive vegetative growth can create canopy shading, which has negative effects on red wine quality (Smart 1982).
The importance of soil type on wine quality has long been a subject of speculation. Gladstones (1992) suggested that wines from sandy soils often lack strength and color but are rich in aroma and that rocky, stony, or chalky soils gave the best wines. Wines from limestone soils allegedly have high alcoholic strength, while clay soils produce acidic grapes, high in tannins that lead to rich red wines. Seguin (1986), on the other hand, reported that clay may have an influence on sensory character and the type of wine, but it is also possible to produce high-quality wines on stony soils with low pebble content. Likewise, a study in the Franken region of Germany that investigated the impact of soil type on wine composition and sensory quality of Silvaner by moving seven different soil types to the same vineyard site in lysimeters found no significant impact of soil type on wine flavor (Wahl 1988). These findings are consistent with our results in 2005, showing that clay was only correlated with black currant flavor and sand was only correlated with black pepper aroma (Figure 10⇑); however, these relationships were somewhat different in 2006 because of higher precipitation and lower temperatures, whereby sand was correlated with acidity and bitterness while clay was correlated with some red and black fruit aroma and flavor descriptors (Figure 11⇑).
The data presented here strongly suggest that vineyards are a rather stable terroir, and each wine estate has developed a method of grapegrowing that yields wines of similar and consistent sensory profiles across vintages, assuming the same winemaker and vinification processes. Thus, for consumers who seek specific sensory properties from a wine, vineyard designation is a meaningful label for the wines.
Conclusions
The sensory and chemical methodologies that were developed for this study separated clusters of subappellations for Niagara Peninsula Cabernet franc wines. The PCA and discriminant analysis plots of sensory and chemical analysis showed that the attributes were useful in describing differences among the wines. In 2005, sites from the Escarpment Bench and Lake Plain subappellations were associated with red fruit aroma and flavor. All these sites were warm with low water status. Sites located in Lakeshore and Niagara River subappellations were associated with green bean and bell pepper aroma and flavor, which may indicate insufficient heat to ripen the fruit. Harbour Estate and all Niagara-on-the-Lake sites showed highest pH, TA, phenols, and hue, while sites west of St. Catharines were associated with high color, anthocyanins, and ethanol. Despite two different vintages, including a hot and dry year (2005) and a cool and wet year (2006), similar trends were observed. Except for black pepper aroma, all other attributes were substantially different among the sites in 2006. Most notably, wines from Buis (Niagara Lakeshore subappellation), Morrison (Twenty Mile Bench), Hernder (Four Mile Creek), and George (Lincoln Lakeshore) were high in bell pepper and green bean aroma and flavor, astringency, and acidity. Similarly, wines from CDC (St. David’s Bench) and HOP (Short Hills Bench) were associated with red fruit aroma and flavor, black currant aroma and flavor, black cherry aroma and flavor, black pepper flavor, and bitterness.
The location of wines on the PCA plots indicates their sensory and chemical profiles and allows regional differences to be identified. Although it was not possible to assign each site into a unique subappellation that produces a specific lexicon of wine characteristics, it was possible to separate sites in terms of clusters of subappellations based on dominant sensory attributes. Also, this study provided evidence for proper site selection for Cabernet franc in the Niagara region, since certain areas produced wines that were clearly dominant in herbaceous notes. This study was ideal for assessing chemical and sensory differences among subappellations in Niagara by producing Cabernet franc wines with minimal enological intervention, a single winemaker, and single vintage comparisons. However, more investigation is required to further determine the basis of terroir effects in Niagara for other important winegrape cultivars.
Footnotes
Acknowledgments: The authors thank the Natural Sciences and Engineering Research Council of Canada and the Wine Council of Ontario for funding. The participation of all sensory panelists is hereby acknowledged.
- Received April 2009.
- Revision received June 2009.
- Revision received July 2009.
- Accepted August 2009.
- Published online March 2010
- Copyright © 2010 by the American Society for Enology and Viticulture