Abstract
The fruiting capacity of grapevines in a given climatic region is largely determined by their total leaf area and by the percentage of the total leaf surface area that is exposed to full sunlight, provided other factors are not limiting growth and the initiation of fruit primordia. A wide range of leaf area/crop weight ratios were investigated by pruning to different levels of buds per vine, by different degrees of defoliation, and/or by cluster thinning of grape cultivars Thompson Seedless, Tokay, Chenin blanc, and Cabernet Sauvignon located at Davis or Oakville, California. For single-canopy (SC) type trellis-training systems, the leaf area/crop weight ratio required for maximum level of total soluble solids, berry weight, and berry coloration at harvest ranged from 0.8 to 1.2 m2/kg, whereas for horizontally divided-canopy (DC) type trellis-training systems (GDC, lyre, wye), this ratio was reduced to 0.5 to 0.8 m2 leaf area per kg fruit. Optimal crop yield/pruning weight, pruning weight (kg) per m canopy length, leaf area (m2) per m canopy length, and leaf area density (m2/m3) for SC systems ranged from 4.0 to 10, 0.5 to 1.0 kg/m, 2 to 5 m2/m, and 3 to 7 m2m−3, respectively. Similarly, for DC systems these ratios ranged from 5.0 to 10, 0.4 to 0.8 kg/m, 2 to 4 m2/m, and 3 to 6 m2m−3, respectively. Grapevines with ratios that fell within the ranges given above for each of these five parameters were considered well balanced and capable of producing high-quality fruit and wines.
Vine balance can be characterized in several different ways. Winkler (1930, 1954, 1958) and Winkler and Williams (1939) defined a grapevine as being well balanced and not overcropped when the vine brings its fruit from flowering to a given degree Brix, depending on the use to which the fruit will be used, with a given summation of degree days of heat, which is constant for a given variety. Dormant vine pruning weights, expressed as kg per meter of canopy length, has also been widely used to indicate if vines are well balanced, i.e., with neither too little nor too much growth (Shaulis 1982, Shaulis et al. 1966, Smart and Robinson 1991). Values of 0.3 to 0.6 kg pruning weight per meter of canopy length are generally considered to be in the optimal range (Shaulis 1982, Smart and Robinson 1991); however, recent studies in California (Dokoozlian 1990, Dokoozlian and Kliewer 1995, Kliewer et al. 1988, 2000) showed that values up to 1.0 kg/m for Cabernet Sauvignon were capable of producing high-quality wines without loss in productivity due to excessive canopy shading. More recently, crop load or the ratio between crop yield and dormant vine pruning weight, has gained wide acceptance as a good criterion of vine balance (Bravdo et al. 1984, 1985, Kliewer et al. 2000, Smart 1985, Smart and Robinson 1991). Generally, vines with crop load values between 5 to 10 are considered in the optimal range (Bravdo et al. 1984, 1985). However, for small-clustered wine cultivars, such as Pinot noir, grown in cool climates, the optimum crop load ratio appears to be somewhat lower, in a range from 3 to 6 (unpublished information).
Smart (1985), Smart et al. (1991), and Smart and Robinson (1991) introduced an 80-point scoring system to evaluate vineyard balance and potential fruit quality assurance through the use of point quadrant analyses of canopy density and microclimate. These analyses took into account leaf layer number, percent canopy gaps, and percentage interior and exterior leaves and clusters, while five other measures related to the physiological status of grapevines (leaf size, leaf color, shoot length, lateral growth, and presence of active shoot tips during the ripening period). These latter five characteristics are assessed by visual observation and require some advanced experience of what is desirable. Each of the eight characteristics is assigned zero to 10 points (maximum). Open-type canopies that have moderate shoot vigor and minimal amounts of lateral shoot growth are rated highest. However, more data is needed to determine how each of the eight characteristics should be weighed for their effects on wine quality. In general, canopies with well-exposed leaves and fruits have scored highest in wine quality by taste panels (Dokoozlian 1990, Kliewer 1982, Kliewer et al. 1988, Schuck 1987, Smart 1982, Smart et al. 1991).
In this communication, emphasis on defining the optimum level of cropping will be in terms of leaf area required per unit weight of fruit, expressed as m2/kg, to produce berries of maximum total soluble solids, skin color, and total sugar accumulation in fruits. The premise for this criterion is that the ultimate source of sugar produced in grapevines is from leaf photosynthesis, which is dependent on the total amount of exposed leaf area. Since the type of trellis-training system used has such a dominant influence on the amount of leaf area exposure, the optimal leaf area/crop weight ratio of single- and divided-canopy training systems are compared from field experiments of several cultivars conducted at Davis and Oakville, California (Johnson 1988, Kliewer et al. 1988, 2000, Schuck 1987, Yang 1991). Most of the data presented are from grapevines grown in warm-climate regions (>3000 degree-days) of California. Since temperature and light for maximum photosynthesis are frequently more limiting in cool-climate regions, it is likely that the leaf area/fruit weight ratios for optimal fruit composition and wine quality will be somewhat higher for these regions.
The ratio between crop weight and dormant pruning weight per vine is also used as an indication of good vine balance in the field studies presented herein. The relationship between crop weight/pruning weight and leaf area/ crop weight ratios was also investigated.
Materials and Methods
Some of the data here are from studies previously published (Kliewer 1970, Kliewer and Ough 1970, Kliewer and Weaver 1971) and are appropriately referenced where used. However, a considerable amount of the material is from unpublished information of the author and from student thesis projects supervised by Kliewer (Johnson 1988, Schuck 1987, Yang 1991).
Tokay pruning-level cluster-thinning trial.
A wide range in leaf area/crop weight ratios in the cultivar Tokay was obtained by differential vine pruning and cluster thinning. The trial was conducted at Davis, California, and each treatment was replicated five times in randomized blocks, four vines per replicate. Regression analysis was conducted to determine the relationship between leaf area per unit weight of fruit and total soluble solids at harvest, proline level in berry juice, fruit coloration of berry skins, and berry weight. See Kliewer and Weaver (1971) for further details of the methods used.
Thompson Seedless defoliation cluster-thinning trials.
The Thompson Seedless data presented herein was obtained from three trials conducted at the UC Davis Experimental vineyard using own-rooted vines growing in an irrigated vineyard pruned to three or four 15-node canes (Kliewer 1970, Kliewer and Ough 1970). The canes were trained to two horizontal wires 0.8 m apart and 1.4 m from the ground. A wide range of leaf area/crop weight ratios was obtained by either defoliating every fifth, fourth, third, or second leaf on each shoot and lateral per vine at two weeks post anthesis or by thinning the crop to 80, 60, 40, and 20 clusters per vine with no defoliation. In another trial conducted at the same site, 0, 25%, and 50% of the leaves were removed at three different times (2 June, 25 June, and 18 July). There were six vines in each treatment with each vine serving as a replicate in a randomized complete block design. The treatments were continued over a period of four years (1970 to 1973). The total leaf area per vine was determined in early October by leaf weight-leaf area relationship as described previously (Kliewer and Antcliff 1970).
Thompson Seedless trellis-canopy exposure trial.
In another experiment at the same Davis site described above, four different trellis-training systems were compared with widely different canopy volumes and amounts of leaf area exposure. The four systems consisted of a single open canopy, a divided GDC-type canopy, and restricted horizontal and vertical canopies with estimated canopy volumes of 1.9, 2.6, 1.3, and 1.3 m3 per vine, respectively. The restricted horizontal and vertical canopies were obtained by using shoot-positioning wires to restrict the canopy within the dimensions of 1.2 x 1.2 x 0.3 m and 1.2 x 0.3 x 1.2 m, l x width x height, respectively. All treatments were pruned to 60 nodes per vine (four 15-node canes). The single-canopy trellis system had dimensions of 1.8 x 1.2 x 0.9 m, while the divided-canopy system consisted of two curtains of foliage, each curtain with a volume of about 1.8 x 1.2 x 0.6 m. The single-curtain and restricted vertical and horizontal trellised vine were each comprised of six single-vine replicates, whereas there were 18 double-curtain trained vines.
Cabernet Sauvignon pruning-level trellising trial.
In a simulated mechanical pruning trial at the UC Oakville Experimental Vineyard with Cabernet Sauvignon vines on A5R#1 rootstock, three types of pruning were imposed on vines trained to a single-canopy two-wire bilateral cordon as well as to a horizontally divided canopy quadrilateral cordon system. The three pruning methods were standard spur pruning to 24 two-node spurs, hedge pruning to a single level plane with spur lengths averaging two to three nodes, and minimal pruning leaving all buds above the cordon wires. The three pruning methods produced an average of 36, 191, and 314 shoots, respectively, per vine on single-canopy trained vines and 41, 244, and 362 shoots on the divided-canopy vines. Each of the six treatments was replicated six times, three vines per replicate, in a randomized complete block design. Spacing was 2.2 m between vines and 3.6 m between rows. Regression analysis was conducted to determine the relationship between leaf area (m2) per kg crop weight and the level of total soluble solids (Brix) in individual treatment replicates at harvest. Leaf area of 10 random shoots per vine was determined with a decagon leaf area meter, which was then used to estimate the total leaf area per vine from total shoot counts per vine. For more details of experimental methods see Johnson (1988).
Cabernet Sauvignon trellising, vine spacing, rootstock trial.
In a trial comprised of six trellis-training systems (vertical-shoot position, Scott-Henry, Te Kauwhata Two Tier [TK2T], GDC, lyre, and a wide V), three in-row vine spacings (1, 2, and 3 m), and two rootstocks (O39-16 and 110R) located at the Oakville Experimental Vineyard, a wide range of leaf area/crop weight ratios was produced with Cabernet Sauvignon vines over a period of three years (1993 to 1995). Each spacing and rootstock treatment was replicated four times with three vines per replicate in a randomized split plot design. The vines of each treatment were pruned leaving a two-node spur approximately every 15 cm along the length of the cordons. Thus the one-, two-, and three-meter single-canopy vines were pruned to 12, 24, and 36 nodes/vines, respectively; the divided-canopy vines were pruned to 24, 48, and 72 nodes/vine, respectively. The vines were not hedged or cluster thinned, except for the TK2T trained vines, which required shoots originating from the lower cordon to be trimmed to prevent their growth into the upper-cordon fruit zone. The vines were drip irrigated beginning at about fruit set with neutron probes used to monitor soil moisture. Vine growth, leaf area, crop yield, and fruit composition were determined as described by Kliewer et al. (2000).
Chenin blanc trellising trial.
Eight-year-old Chenin blanc vines grafted on A5R#1 rootstock were used in this study conducted from 1988 to 1990 at the UC Davis experiment vineyard. The row and vine spacing was 3.2 x 2.1 m. The treatments consisted of three trellis systems (vertical, lyre, and GDC) with the dimensions and wire locations indicated in Figure 15⇓. Each of the three trellis systems was replicated six times in a randomized block design, each replicate consisting of three 24-vine rows, the center row used for data collection. Half of the vines within each trellis system were shoot-positioned, beginning at flowering, as depicted in Figure 15⇓; the remaining half were not shoot-positioned. All vines were cordon trained and pruned to 24 two-node spurs. The soil was a deep alluvial Yolo fine sandy loam with very high potential for vine growth and crop yields. The vineyard was clean cultivated and furrow irrigated, receiving two 15-cm irrigations. Standard pest and disease control measures were used. Leaf area per vine was determined shortly before harvest with a delta T decagon leaf area meter on 10 random shoots of buffer vines adjacent to data vines. The total amount of primary and lateral leaf area per vine was estimated by multiplying the averages of the 10 shoots by the total number of shoots per vine. For more details of the experimental methods used see Yang (1991).
Results and Discussion
Over the past 30 years, numerous field experiments were conducted with table, raisin, and winegrape varieties in which the leaf area/crop weight and crop yield/pruning weight ratios differed over a wide range by imposing different levels of pruning, cluster thinning, differential defoliation and by using different types of trellis-training systems (Johnson 1988, Kliewer 1970, Kliewer and Antcliff 1970, Kliewer and Ough 1970, Kliewer and Weaver 1971, Kliewer et al. 2000, Schuck 1987, Yang 1991). Some of this information has been published and will be reviewed in this communication. However, a considerable amount of the data presented has not been published previously in reviewed journals and provides new information for defining vine balance in terms of leaf area/fruit weight ratios needed to fully ripen fruit to an acceptable level of sugar.
Tokay pruning-level and cluster-thinning trial.
For the table-grape cultivar Tokay grown at Davis and trained to a single-canopy three-wire “T”-trellis, the crop level per vine ranged from 11.0 to 26.7 kg, imposed by differential pruning, with or without cluster thinning (Kliewer and Weaver 1971). The m2 leaf area per kg fruit required for maximum sugar concentration in fruit at harvest (20 Brix) was 1.1 to 1.2 (Figure 1⇓). In addition, maximum berry weight, fruit skin coloration, and proline concentration in berry juice was also obtained when m2 leaf area per kg fruit ranged between 1.1 to 1.4 (Figures 2⇓, 3⇓, and 4⇓). These ratios were equivalent to 38 to 42 primary leaves per kg fruit weight at harvest with a crop yield pruning weight ratio of approximately 6. When the leaf area (m2) per kg fruit of vines fell below 1.0, the crop yield/pruning weight ratios were always above 10, indicative of overcropping (Kliewer 1970, 1982). These data indicate that a minimum of 1.0 to 1.4 m2 leaf area per kg fruit was needed to fully mature the Tokay crop grown at Davis on a single-canopy-type trellis system. The finding that berry weight, fruit coloration, and the proline concentration in berry juice also reach maximum levels at 1.2 to 1.4 m2 leaf area per kg fruit further supports the leaf area data needed for maximum fruit sugar.
Thompson Seedless defoliation and cluster-thinning trials.
Three other field trials were conducted at Davis with Thompson Seedless grapevines over a period of four years (1969 to 1972). One trial used differential defoliation in which every fifth, fourth, third, or second leaf on every shoot and lateral per vine was removed 15 days after an-thesis. In a second trial, 0, 25%, and 50% of the leaves were removed at three different times: 2 June (fruit set), 25 June, and 18 July (veraison). In the third crop level trial, the number of clusters per vine were adjusted to 80, 60, 40, and 20 with no defoliation (Kliewer 1970, Kliewer and Ough 1970). These treatments produced a wide range of leaf area/crop weight ratios and were used to calculate the amount of leaf area needed to fully ripen the fruit. In each of the three trials the relationship between the level of total soluble solids of fruits at harvest and leaf area per unit weight of fruit for all vines, irrespective of treatment, was determined each year. In the differential defoliation trial, 1.0 to 1.4 m2 leaf area per kg fruit was required to mature the crop to 23 Brix in both the 1969 and 1972 seasons (Figures 5⇓ and 6⇓). Based on the total number of leaves per vine and average leaf size, it was estimated that about 4000 cm2 leaf area was required per average size cluster, which was equivalent to 16 to 18 primary leaves per cluster or 32 to 36 leaves per kg fruit. In the trial in which vines were defoliated to either 0, 25%, or 50% at three different stages of fruit development, the data also revealed that 1.0 to 1.2 m2 leaf area per kg fruit was needed to maximize the concentration of sugar in the fruits at harvest (Figure 7⇓). These data indicate that even after four years of defoliation at the levels indicated above, the amount of leaf area needed to ripen the fruit to 23 Brix did not change materially nor did the time of leaf removal significantly alter the leaf area/crop weight ratio required to fully ripen the crop.
In the third Thompson Seedless trial, comparison of the growth, fruit composition, and wine quality of Thompson Seedless vines cropped at 20, 40, 60, and 80 clusters per vine showed leaf area (m2)/crop weight (kg) ratios of 4.0 (20 clusters/vine) to 0.8 (80 clusters/vine) and crop weight/pruning weight ratios of 1.57 to 7.4 (Table 1⇓). Fruit from vines thinned to 20 clusters reached 22 Brix about 20 days earlier than vines cropped at 80 clusters and had considerable higher titratable acidity and lower pH and Brix/acid ratios (Table 1⇓). Even though there was a 3-fold range in crop level per vine (9 to 28 kg), sensory evaluation of the vines showed no significant differences in wine-tasting scores (Table 1⇓). These data suggest that a leaf area/crop weight ratio of 0.8 m2/kg was adequate for producing good fruit and wine quality.
Thompson Seedless trellis-canopy exposure trial.
To test the leaf area/fruit weight requirement of single-curtain-(SC) compared to double-curtain- (DC) type trellised vines and how restricting the canopy volume by shoot positioning influences this ratio, a replicated field experiment was conducted at the same site as described above with Thompson Seedless vines over a period of four years (1970 to 1973). The four-year summary data are presented in Table 2⇓. The restricted vertical- (RV) and restricted horizontal- (RH) trained vines had significantly lower crop yield and total vine leaf area than the DC vines (Table 2⇓). Pruning weight and leaf area per m canopy length were significantly greater in the SC, RV, and RH vines compared to DC vines (Table 2⇓). The leaf area/fruit weight ratio when DC fruit reached 23 Brix did not differ significantly between treatments; however, the level of total soluble solids and total amount of sugar in fruits of SC, RH, and RV fruits were significantly less than in DC fruits (Table 2⇓). Regression analysis conducted to show the relationship between the level of TSS of fruits at harvest and cm2 leaf area per gram of fruit in 1972 (Figure 8⇓) and 1973 (Figure 9⇓) revealed that the DC vines required about 0.8 m2 leaf area per kg fruit to reach 23 Brix compared to 1.1 to 1.4 m2/kg for SC, RV, and RH fruits. The rate of sugar accumulation and the level of TSS in fruits of SC, RH, and RV vines were significantly less in DC fruits at all sampling dates during the 1973 season (Figure 10⇓). These data clearly show that the leaf area/fruit weight ratio of DC vines needed to ripen fruits to 23 Brix was about 50% less than that needed for SC, RV, and RH vines.
Cabernet Sauvignon trellising, vine spacing, rootstock trial, Oakville.
The three-year average crop yield of the six trellis-training systems ranged from 9.9 (single canopy vertical) to 18.6 (divided canopy “V” trellis) mt/ha (Table 3⇓). The number of shoots and leaf area (m2) per m of canopy length ranged from 9 to 14 and 2.9 to 4.7, respectively. Pruning weight (kg) per m of canopy length ranged from 0.48 to 0.9; weight per cane (g) ranged from 38 to 64; and yield/pruning weight ratio ranged from 4.9 to 7.5 for the six trellis systems (Table 3⇓). Only the VSP-trained vines at 1.0 m in-row vine spacing had excessively dense vine canopy as judged by leaf layer number in fruiting region (2.5), total leaf area per m canopy length (6.8 m2/m), and pruning weight per m canopy length (1.52 kg/m). With increased in-row vine spacing from 1.0 to 3.0 m, there were more shoots per vine but shoot length and internode length were shorter, less leaf area and weight per shoot, higher crop yield/pruning weight ratios, and lower leaf area/crop weight ratios (Kliewer et al. 2000). All vine growth measurements were less for vines grafted to O39-16 compared to 110R rootstock.
Regression analyses were conducted between the concentration of total soluble solids of fruits at harvest and leaf area (m2) per kg of fruit for all vines, irrespective of treatment, for data obtained in 1994 (Figure 11⇓). The data show that 0.9 to 1.1 m2 leaf area per kg fruit was required to mature the fruit to 22.5 to 23.0 Brix and that differences between treatments were mainly due to variations in leaf area per unit weight of fruit. Regression analysis was also conducted between the ratios of crop weight/pruning weight and leaf area/crop weight of individual vines, disregarding treatment. The data in Figure 12⇓ reveal a close negative linear relationship, i.e., as the leaf area/crop weight ratio increased the crop weight/pruning weight ratio decreased. If we accept the published values (Bravdo et al. 1984, 1985) of crop weight/pruning weight ratios within the range of 5 to 10 as indicative of vines well balanced (not over- or undercropped), then the corresponding leaf area/crop weight ratios fall between 0.8 to 1.2 m2 leaf area per kg fruit and agree very closely with the fruit total soluble solids leaf area/crop weight relationship shown in Figures 11⇓ and 12⇓. The data indicate that crop yield/pruning weight ratios within the range of 5 to 10 and leaf area/fruit weight ratios between 0.8 and 1.2 m2/kg are both good indices of vines well balanced between the amounts of crop and foliage leaf area for Cabernet Sauvignon grown at the site of this trial. There were no significant differences in wine-tasting scores between trellis systems, vine spacing, and rootstock treatments from the 1994 vintage (Table 3⇑).
Cabernet Sauvignon pruning-level trellising trials, Oakville.
Vine growth, crop yield, fruit total soluble solids, and crop load ratios of Cabernet Sauvignon vines spur pruned (SP) to 48 nodes/vine, hedge pruned (HP), and minimal pruned (MP) on vines trained to either a single-canopy (SC) two-wire bilateral cordon or to a horizontally divided-canopy (DC) quadrilateral cordon are presented in Tables 4⇓ and 5⇓. HP and MP vines had 6 to 9 times more shoots per vine than SP vines and 3 to 4 times more clusters. Crop yield of HP and MP vines were approximately twice that of SP vines. Shoot length and nodes per shoot of HP and MP vines were about one-third and one-fourth that of SP vines. A negative curvilinear relationship was found between shoot number per vine and shoot length with a correlation coefficient of 0.70 (Figure 13⇓). Leaf area/ crop weight ratios of SC spur-, hedge-, and minimal-pruned vines were 1.65, 1.17, and 1.26, respectively, and similarly for DC-trained vines the ratios were 1.25, 0.86, and 0.82, respectively (Tables 4⇓ and 5⇓). The yield/pruning weight ratios of spur-pruned SC and DC vines were well within the acceptable range of “normal” cropped vines; however, HP and MP vines had ratios well over 10, indicative of overcropping. The high yield/pruning weight ratios of HP and MP vines were reflected in the lower level of sugars in fruits at harvest compared to SP vines (Tables 4⇓ and 5⇓).
Regression analysis was done to determine the relationship between fruit total soluble solids at harvest and leaf area/crop weight ratios of individual vine replicates of SP, HP, and MP single-canopy and divided-canopy trained vines (Figure 14⇓). For DC fruits to reach 22 Brix required 0.9 to 1.0 m2 leaf area per kg fruit, whereas SC fruits needed 1.3 to 1.4 m2 leaf area for each kg fruit to reach 22 Brix (Figure 14⇓). These data agree with the finding of Thompson Seedless vines trained to a DC trellis system reported previously and indicate the greater efficiency of DC-trained vines to ripen fruit per m2 leaf area. This finding is not unexpected since several investigators have shown that DC-trained vines have a higher percentage of their leaf area at light saturation than SC-trained vines (Amberg and Shaulis 1966, Gladstone 1999, Kliewer 1982, Kliewer et al. 1988, May et al. 1976, Schultz 1995, Shaulis 1982, Shaulis et al. 1966, Shaulis and May 1971, Smart 1982, Smart et al. 1991, 1982).
Sensory evaluation of wines from the different treatments revealed than the taste panel could distinguish between SP wines compared to HP and MP wines made from the SC training system (Tables 6⇓ and 7⇓). They could also distinguish between HP and MP wines from both SC and DC training systems (Table 6⇓). However, the taste panel could not tell a DC-SP wine from a DC-HP wine. The general consensus of the taste panel was that SP vines produced the most fruity and herbal wines; SP wines were the most astringent, but still fairly fruity; and MP wines were the least fruity, had weedy, stemmy character, were more acidic, and had some aldehyde off odor compared to SP and HP wines (Table 7⇓).
Chenin blanc trellising trials.
Chenin blanc grapevines grown on a very deep, irrigated, fertile soil at the UC Davis vineyard were trained to two horizontally divided canopy trellis systems (GDC and lyre) and compared to a single-canopy vertical (V) trellis system (Figure 15⇓). At this site the vines were very productive, producing yields of 40 to 49 mt/ha for the V trellis and 52 to 60 mt/ha for the GDC and lyre trellis systems. The crop yield/pruning weight ratios of the V-, lyre-, and GDC-trellised vines averaged 8.0, 8.5, and 12.1, respectively, with corresponding leaf area/crop weight ratios of 0.68, 0.55, and 0.40 m2/kg (Table 8⇓). The level of total soluble solids in fruits at harvest for the V, lyre, and GDC trellis systems averaged 19.8, 21.6, and 20.6 Brix, respectively (Table 8⇓). The leaf area/crop weight data of individual replicates of each of the three trellis systems was regressed against the level of total soluble solids at harvest (Figure 16⇓). The data in Figure 16⇓ shows that the m2 of leaf area per kg fruit required to mature Chenin blanc fruit to 22 Brix for V-, lyre-, and GDC-trellised vines was approximately 0.9, 0.6, and 0.5, respectively. The average area per primary leaf of V, lyre, and GDC vines was 123, 102, and 74 cm2, respectively. Based on these values, the number of primary leaves required per cluster to ripen fruit to 22 Brix for V-, lyre-, and GDC-trellised vines was 12 to 13, 10 to 11, and 10 to 11, respectively. These data indicate that the amount of leaf area needed to support a unit weight of fruit was considerably less for lyre- and GDC-trellised vines compared to V vines, in agreement with the findings of trellising trials with Thompson Seedless and Cabernet Sauvignon reported above. It is interesting to note that the leaf area/crop weight ratio needed to mature Chenin blanc fruit to 22 Brix for both single-canopy and divided-canopy trained vines was less than that found for Cabernet Sauvignon. Chenin blanc, a medium-clustered to large-clustered wine variety, generally produces higher yields than small-clustered wine varieties such as Cabernet Sauvignon (Winkler et al. 1994). Whether the differences in leaf area/crop weight ratios required to mature fruit between cultivars were due to genetic, physiological, or site location differences is not known.
Sensory analysis of the Chenin blanc wines with duo trio comparisons of the three trellis treatments revealed that the taste panel could detect differences between wines made from V- and lyre-trellised vines and between V and GDC wines, but not between the lyre and GDC wines (Table 9⇓). The lyre and GDC wines were generally less vegetative and more fruity than wines made from the V-trellised vines.
Values given in the literature for the amount of leaf area needed to support a unit weight of fruit vary considerably, depending on the cultivar, climatic region, cultural conditions, and method of measurement. May et al. (1969) reported that about 0.7 m2 of leaf area per kg of fruit was required to ripen Thompson Seedless berries, whereas Kliewer and Antcliff (1970), Kliewer and Ough (1970), and Kliewer (1970), using the same cultivar, found that 1.0 to 1.2 m2 of leaf surface was necessary. Winkler (1930), using girdled shoots of Muscat of Alexandria, reported 1.1 to 1.5 m2 leaf area per kg of fruit was needed for full maturation of a cluster. Buttrose (1966), using the same cultivar, indicated that 1.7 m2 per kg of fruit was needed for unhindered development of all parts of one-year-old vines grown in pots. Amberg and Shaulis (1966) indicated a requirement of 1.5 m2/kg fruit for the cultivar Concord grown under New York conditions. Kaps and Cahoon (1992), using the French-American hybrid cultivar Seyval blanc grown under greenhouse conditions in pots, found 0.8 to 1.0 m2 leaf area per kg fruit was needed to produce maximum berry weight and Brix in fruits; however, 1.5 m2/kg was required to maximize dry weight of leaves, stems, and roots. In the current study, the leaf area/crop weight ratio required to mature fruit from vines trained to divided-canopy trellis systems generally ranged from 0.5 to 0.8 m2/kg; whereas for single-canopy trellis systems, values of 0.8 to 1.4 m2/ kg were needed. This finding agrees with the data of Williams et al. (1987), which found that removing all the interior leaves of Thompson Seedless vines, representing 27% to 35% of the total vine leaf area, had no significant effect on berry weight and level of sugars in fruits. The leaf area/fruit ratio (m2/kg) before defoliation was approximately 1.0 and after defoliation ranged from 0.5 to 0.65. Several studies have shown that divided canopy training systems, such as GDC and lyre, have considerably higher percentage of their leaf area at light saturation compared to single-canopy systems (Kliewer 1982, Kliewer et al. 1988, May et al. 1976, Shaulis et al. 1966), and therefore, a lower leaf area/fruit weight ratio to mature fruit would be expected, as demonstrated by the data presented above.
Conclusions
In a series of field experiments using canopy management and trellising treatments, a wide range of leaf area/ crop weight and crop yield/pruning weight ratios were investigated to determine how much leaf area was required to fully ripen several grape cultivars. The results found that about 0.8 to 1.2 m2 leaf area per kg fruit was needed to mature fruit trained to single-canopy trellis systems and 0.5 to 0.8 m2/kg for vines trained to divided-canopy trellis systems. The corresponding crop yield/pruning weight ratios for SC and DC trellised vines were 4 to 10 and 5 to 10, respectively. The amount of leaf area (m2) per m canopy length of SC and DC trained vines that had crop load values as indicated above generally ranging from 2 to 5 and 2 to 4, respectively. Vines that fell within the ranges of these indices were considered well balanced and capable of fully ripening their crop as well as producing high-quality wines.
Footnotes
This article was first presented at the ASEV Annual Meeting, 19–23 June 2000, Seattle, Washington and published in the Proceedings of the ASEV 50th Anniversary Annual Meeting. J.M. Rantz (Ed.), pp. 285–289 (2001).
From Proceedings of the ASEV 50th Anniversary Annual Meeting
- Copyright © 2005 by the American Society for Enology and Viticulture