Yeast Multi-Enzymatic Systems for Improving Colour Extraction, Technological Parameters and Antioxidant Activity of Wine

Study area, sampling and microorganism isolation

Grape samples were taken from the San Rafael wine region, Mendoza, Argentina. Microorganisms were isolated from the surface of grape berries of Bonarda, Cabernet Sauvignon and Malbec cultivars (Vitis vinífera L.). Twenty grape berries of each cultivar were taken, placed in a container with 20 mL of sterile 0.1% peptone water and stirred for 1 h at 165 rpm (0.6×g). Samples were plated on solid WL (Wallerstein Laboratory) medium, nutrient agar and malt extract agar (MEA). The incubation time was 5 and 7 days at 28 and 15 °C, respectively. Culture media were purchased from Sigma-Aldrich Co. Ltd., Merck KGaA (Darmstadt, Germany).

Primary selection

Plate screening for the selection of microorganisms producing grape berry cell wall-depolymerizing enzymes

For detection of pectinase activity, isolates were inoculated in mineral medium with citric pectin as the sole carbon source according to the method by Moyo et al. (21) with modifications and with the following composition (in g/L): citric pectin 2.0, yeast extract 1.0, agar 15.0, KH₂PO₄ 0.2, CaCl₂ 0.05, (NH₄)₂SO₄ 1.0, MgSO₄·7H₂O 0.8, MnSO₄ 0.05; pH=4.5. To demonstrate xylanase, cellulase and amylase activities, isolates were plated onto selective medium containing 6.7 g/L yeast nitrogen base (YNB) and 20 g/L agar, plus 0.2% birchwood xylan for xylanase, 0.5% carboxymethylcellulose for cellulase or 2% starch for amylase activity. All reagents and YNB medium were from Sigma-Aldrich Co. Ltd., Merck KGaA. Enzyme production was detected using the qualitative method that consists of the development of hydrolysis halos. Pectinase, xylanase and amylase were detected with a lugol solution (22) and cellulase activity with a 0.2% (m/V) Congo Red solution. Activity was detected when a clarification halo was formed around the colonies against a brown-purple background of the medium with non-degraded polymers after all polysaccharidases had been developed, except for amylase, which had a blue background (23).

Pheno- and genotype identification of selected yeasts

Yeasts demonstrating highest hydrolytic enzyme production were identified at species level following the taxonomic criteria described by Kurtzman et al. (26) based on their morphological and physiological characteristics as well as the polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) analysis of the ITS1-5.8S–ITS2 region from the rRNA gene. PCR was carried out according to protocols described by Esteve-Zarzoso et al. (27) with some modifications using universal primers ITS1 (5′-TCCGTAGGTGAACCTGCGG-3′) and ITS4 (5′-TCCTCCGCTTATTGATATGC-3′; Integrated DNA Technologies, Coralville, IA, USA), already described by White et al. (28), using a thermal cycler TC-312 (Techne, Waltham, MA, USA). PCR products were digested with CfoI, HinfI and HaeIII restriction enzymes following the supplier's instructions (Promega Co., Madison, WI, USA). Amplified products and their restriction fragments were electrophoresed on 1.4 and 2.2% agarose gels, respectively, in 1×TAE (Tris-acetic acid-EDTA) buffer, using a horizontal electrophoresis cell (Labnet International, Inc., Edison, NJ, USA). Gels were stained with ethidium bromide, visualized and photographed under UV light (NYX Technyk Inc., San Diego, CA, USA). Fragment sizes were estimated by comparison with a DNA standard (100-bp ladder). All PCR-RFLP reagents were purchased from Promega Co.).

Pectinolytic yeasts used as reference strains

In addition to the microorganisms isolated in the present study, the following pectinolytic microorganisms were obtained from the Biodiversidad San Rafael (Mendoza) culture collection of the FCAI-UNCUYO (San Rafael, Mendoza, Argentina) belonging to the SCCM-AAM (Argentine Association of Microbiology), affiliated to the FELACC (Latin-American Federation of Culture Collections): Aureobasidium pullulans GM-R-22 (in this manuscript referred to as Ap-R-22), Cryptococcus saitoi GM-4 (Crs-GM-4), Filobasidium capsuligenum B-13 (Fc-B-13), Rhodotorula dairenensis GM-15 (Rd-GM-15) and S. cerevisiae B-17 (Sc-B-17). These strains had been selected in our previous works (3,4,19,20) for their pectinolytic activity with oenological importance and were included in the present study to expand the analyses of unexplored aspects.

Production of extracellular enzyme extracts

The yeasts under study were inoculated in liquid medium according to Moyo et al. (21) with modifications and with the following composition in 50 mM citric-citrate buffer, pH=3.8 (in g/L): CaCl₂ 0.05, KH₂PO₄ 0.2, MnSO₄ 0.05, (NH₄)₂SO₄ 1.0, citric pectin 1.0, dextrose 1.0.; Sigma-Aldrich Co. Ltd., Merck KGaA. Cultures were incubated under shaking conditions (130 rpm, i.e. 0.4×g) at 28 °C for 3 days, using a water bath shaker (SHZ-88; Semedix, Buenos Aires, Argentina). Cells were separated by centrifugation (10 000×g for 15 min at 4 °C; Presvac EPF-12R, Buenos Aires, Argentina) and cell-free supernatants were used as enzyme extracts.

Quantitative evaluation of enzyme activities under oenological conditions

Pectinolytic activity was assayed by measuring the amount of reducing sugars released from a pectin dispersion (0.25% pectin in 50 mM citric acid-citrate buffer, pH=3.8) using 3,5-dinitrosalicylic acid (DNS) reagent (29). Galacturonic acid was used as standard. All reagents were purchased from Sigma-Aldrich Co. Ltd., Merck KGaA. Reaction mixtures (enzyme extract/substrate ratio 1:10) were incubated at 15 and 28 °C for 20 min. One pectinase unit (U) was defined as the enzyme activity that released 1 µmol of reducing sugars per min under the given assay conditions.

The conditions for the determination of cellulase, xylanase and amylase activities were the same as those described for pectinolytic activity but using 0.25% (m/V) carboxymethyl cellulose, 0.25% (m/V) birchwood xylan and 1% (m/V) soluble starch (Sigma-Aldrich Co. Ltd., Merck KGaA), dissolved in 50 mM citric acid-citrate buffer (pH=3.8). The reaction mixture was incubated for 20 min at 15 and 28 °C. One unit of cellulase, xylanase or amylase activity was defined as the activity necessary to produce 1 µmol of reducing sugars (glucose or xylose) per min under the assay conditions.

β-Glucosidase activity was assayed by incubating 100 µL of enzyme extract with 100 μL of 15 mM d-(+)-cellobiose (Sigma-Aldrich Co. Ltd., Merck KGaA) solution in 50 mM citric acid-citrate buffer (pH=3.8) at 15 and 28 °C for 30 min. Glucose production was quantified using the enzymatic colorimetric glucose oxidase peroxidase (GOD-POD) method (Wiener Lab, Rosario, Argentina) (25). One β-glucosidase unit was defined as the enzyme activity necessary to release 2 µmol of glucose from cellobiose per min under the assay conditions.

Secondary selection

Statistical analysis

All experimental data are the average of three repetitions±standard deviation. Analysis of variance (ANOVA) was applied to these data, and the mean values were compared by means of Fisher's test of significant differences, with a level of significance of p<0.05, and using Statgraphics Plus software v. 5.1. (36). In addition, R software v. x64 3.6.3 (37), Rcmdr and FactoMindeR were used for principal component analysis (PCA).

Screening of enzyme activities and identification of wine grape yeasts

A total of 366 yeast and yeast-like microorganisms was isolated and 96 of them showed pectinase, xylanase and cellulase activities with the plate technique, indicating that 26.2% of the isolates showed at least some of the assayed enzyme activities. Of the 96 isolates demonstrating enzyme activity, 28 only presented pectinase and 13 only xylanase activity, while no isolate showed cellulase activity without being positive for the other two activities. This suggests that cellulolytic activity would be an adjunct to pectinolytic and xylanolytic activity during degradation of plant organic matter. The remaining isolates had at least two of the assayed activities, indicating that 57.3% of the isolates with enzyme activity showed the activity of multiple enzymes that are necessary to degrade a material as complex as the plant cell wall.

A primary isolate selection was carried out based on the halo diameter vs colony diameter ratio (D_h/D_c) at 15 and 28 °C, selecting isolates that presented D_h/D_c ratios between 2 and 7 and a colony diameter greater than 5 mm. Additionally, other enzyme activities complementary to polysaccharidases such as proteases, amylases and β-glucosidases were assayed for their positive effect on various technological and sensorial parameters. As can be seen inTable 1, nine yeast and yeast-like isolates were selected at 15 °C and 7 at 28 °C.

Table 2 shows the identification of the selected strains based on PCR-RFLP analyses of the ITS1-5.8S-ITS2 region of the rRNA gene, defining them as Aureobasidium (3 strains), Candida (1), Debaryomyces (2), Hanseniaspora (2), Metschnikowia (3), Pichia (1), Saccharomyces (1) and Torulaspora (3) genera. It can be seen that the ability to produce polysaccharidases, necessary to survive in such a complex niche, was present in various microbial genera. This result differs from that reported by Belda et al. (1), who assayed 462 yeast isolates for different enzyme activities of oenological interest and observed that only the Metschnikowia and Aureobasidium genera were positive for polygalacturonase activity, while cellulase activity was only observed in Aureobasidium.

According to Barata et al. (38), the different genera found on the grape surface can be classified into three main groups, which are successively detected as maturation progresses: (i) oligotrophic oxidative basidiomycetous yeasts, the yeast-like fungus A. pullulans and lactic acid bacteria, (ii) copiotrophic oxidative ascomycetes (several Candida spp.), weakly fermentative apiculate yeasts (Hanseniaspora spp.), film-forming yeasts (Pichia spp.) and fermentative yeasts (C. zemplinina, Metschnikowia spp.), and (iii) copiotrophic strong fermentative yeasts (Saccharomyces spp., Torulaspora spp.). In agreement with this classification and because the samples were ripe grapes, our results revealed a great diversity of strains belonging to the three microbial groups on the grape surface. The ability to produce cell wall-degrading enzymes may be closely related to these population dynamics. Consequently, during the first stages, oligotrophic microorganisms that are able to survive with few available nutrients are more abundant. These microorganisms produce enzymes that make gaps in the plant cell walls, thus creating favourable conditions like a greater availability of nutrients for the development of copiotrophic species. The latter species do not require their own enzyme activities because the enzymes for the degradation of cell walls would already be present in the environment.

Hydrolytic enzyme activities under oenological conditions

Fig. 1 shows the different activities assayed in the enzyme extracts and produced by the strains under study at two temperatures, 15 and 28 °C. Pectinolytic activity was the main observed enzyme activity, reaching significant levels compared with the other two assayed activities. This activity was particularly predominant at low temperature and was the only activity detected in several of the studied strains, with the exception of A. pullulans and T. delbrueckii, which demonstrated a very broad enzyme profile.

Fig. 1 Enzyme activities of oenological importance at: a) 28 °C and b) 15 °C of selected strains (mean value±S.D., N=3). One unit of enzyme activity (U) was defined as the amount of enzyme required to release 1 μmol of reducing sugar per min at pH=3.8

As observed in previous studies, A. pullulans is the most abundant species on the grape surface, in fresh grape juice and during very early fermentation stages (4,19,39,40). This species has been reported to produce a great diversity of extracellular enzymes such as pectinases, cellulases, xylanases, glycosidases and proteases (1,3,19). In fact, in the present study it was the only species that showed an enzyme pool containing all five aforementioned activities, confirming the presence of a very extensive polysaccharidase enzyme system, at least consisting of the assayed activities (pectinase, xylanase, cellulase and amylase) as well as other complementary activities such as proteases and β-glucosidases. Within this species, the Ap-R-22 and Td-m11-2 strains were remarkable, as they showed the highest values of pectinolytic activity at both assay temperatures (1.149 and 0.954 U/mL at 28 °C, and 0.765 and 0.722 U/mL at 15 °C, respectively). A. pullulans is a yeast-like euascomycete fungus, meaning that despite having yeast phases of growth, it is multicellular and, as such, an excellent producer of lytic enzymes. Given the trophic and ecological roles of these fungi, degradation of organic matter, they release enzymes for primary degradation to the environment, and during later stages they provide yeasts responsible for completing the degradation. Based on the present results and according to a previous report (3), A. pullulans demonstrated the best activity profiles of oenological importance. This yeast-like fungus is very common in the phyllosphere and carposphere of fruit and vegetable crops and has a potential action against phytopathogenic fungi (41). According to Onetto et al. (42), the genus Aureobasidium is a central component of the microbial community of grape must, and their studies revealed the potential of the species to affect the composition of grape must through the production of polymers and extracellular enzymes, as well as through modulation of the fermentation kinetics by competition for trace elements.

Continuing with the screening of carbohydrolase-secreting microorganisms, and in agreement with Merín and Morata de Ambrosini (3), basidiomycetes were the second most abundant isolates, especially those belonging to the genera Cryptococcus and Rhodotorula. Only C. saitoi produced enzymes with increased activity and a complete enzyme pool considering the assayed activities. Strain C. saitoi Crs-GM-4 reached a pectinolytic activity of 0.634 U/mL at 15 °C and 0.974 U/mL at 28 °C, while R. dairenensis Rd-GM-15 showed a different enzyme composition: no xylanase or β-glucosidase activity, little pectinase activity and cellulase as the main carbohydrase activity at 15 and 28 °C (0.197 and 0.394 U/mL, respectively). F. capsuligenum Fc-B-13 produced a polysaccharidase enzyme pool with high pectinolytic activity (0.715 U/mL at 15 °C and 0.901 U/mL at 28 °C). Previously, Merín et al. (20) studied F. capsuligenum strains and they found good pectinase activity at 12 and 28 °C (0.77 and 1.15 U/mL, respectively). Their report mentioned for the first time the ability of this species to produce pectinases.

Subsequently, the oxidative and weakly fermentative hemiascomycete yeasts belonging to the genera Candida, Debaromyces, Hanseniaspora, Metschnikowia and Pichia had a less complete enzyme pool, with lower levels of enzyme activities. Previously, production of polysaccharidase activities such as pectinases, cellulases, amylases and proteases in other fruits or fermentation processes by the genera Debaryomyces (43), Metschnikowia (1), Hanseniaspora, Candida and Pichia (44) had been reported. The findings for strain D. vanrijiae Dv-m87-3 were particularly interesting, as it showed significant levels of pectinase (0.656 and 0.841 U/mL at 15 and 28 °C, respectively), xylanase (0.167 and 0.390 U/mL at 15 and 28 °C, respectively), cellulase (0.058 and 0.228 U/mL at 15 and 28 °C, respectively) and β-glucosidase (0.062 U/mL at 28 °C) activities, with a spectrum similar to that of basidiomycete yeasts. There are reports on pectinolytic activity by Debaromyces hansenii and Debaromyces polymorphus strains present in tropical fruits, whereas xylanolytic activity was only observed in D. hansenii and D. vanrijiae strains from oenological origin (45). Cellulolytic activity is not abundant in wine yeasts, although this activity has been reported in D. hansenii isolated from decayed wood (46).

Likewise, the apiculated yeast H. uvarum/K. apiculata seems to be the most common grape berry species worldwide, which is consistent with its predominance at the beginning of spontaneous must fermentations (38). It should be mentioned that Hanseniaspora sp. H-m27-2 had a particular enzyme profile, almost exclusively consisting of pectinolytic activity, and reached significantly high levels (0.677 and 0.840 U/mL at 15 and 28 °C, respectively).

Finally, two strongly fermentative hemiascomycete yeasts, S. cerevisiae and T. delbrueckii, were also observed in the present isolation and selection study. These strains produce lytic enzymes, which are of great interest because they are able to produce plant cell wall-degrading enzymes, while carrying out alcohol fermentation. However, these results differ from a previous study by Merín et al. (4), who did not detect pectinolytic activity among ascomycetous yeasts isolated from grapes and during fermentation.

The species S. cerevisiae is rarely isolated from grapes using traditional sampling techniques (47). Most S. cerevisiae strains normally used in winemaking do not show the ability to degrade pectin substrates. Only a few wild strains have been reported to possess the ability to degrade pectin during wine fermentation (48). In the present study, two S. cerevisiae strains, one isolated from the grape surface (Sc-m79-1) and one from winery equipment (Sc-B-17) (20), were able to secrete pectinases, reaching enzyme activities of 0.264 and 0.321 U/mL at 15 °C, and 0.476 and 0.543 U/mL at 28 °C, respectively. These findings could be related to the fact that some grapes used for isolation had an advanced state of maturity.

Regarding T. delbrueckii, strain Td-m7-2 showed significantly higher pectinolytic activity at both assay temperatures (0.682 and 0.723 U/mL at 15 and 28 °C, respectively), and xylanase (0.195 and 0.241 U/mL), cellulase (0.212 and 0.250 U/mL) and β-glucosidase (0.113 and 0.185 U/mL) activities were also excellent. This species is characterized by its decent oenological characteristics such as low acetic acid production, higher glycerol concentration and a better composition of volatile aromatic compounds in wines (49). Recent reports indicate its ability to promote malolactic fermentation in wines with a high polyphenol content (50). However, the ability of this species to produce extracellular enzymes has been studied little (2,51). T. delbrueckii Td-m30-1 showed a different behaviour, as it only presented pectinase activity, but less than strain Td-m7-2, and it was negative for the other determined activities, suggesting that production of polysaccharidases is strain-dependent.

On the other hand, amylase production was observed in all basidiomycetes and all A. pullulans strains assayed, while it was negative in hemiascomycetes, with the exception of S. cerevisiae Sc-B-17.

Technological effects of extracellular enzyme extracts on short macerations of grape must

Table 3 shows the effects of microbial enzyme extracts on different technological parameters evaluated after short macerations of Malbec must at 15 and 28 °C. Musts treated with enzymes showed differences in the extraction of total polyphenols during the maceration. All enzymatically treated musts had total polyphenol index (TPI) values that were higher than that of the control treatment without enzymes (C1) at both assay temperatures. A. pullulans Ap-m11-2 had the highest TPI values (59.1±0.4 and 58.6±0.0 at 15 and 28 °C, respectively). However, the other A. pullulans extracts had similar values, which were the highest in macerations carried out at 15 °C. Similarly, the T. delbrueckii Td-m7-2 extract produced a TPI value during maceration which was higher at 15 than at 28 °C, and also higher than with the three Metschnikowia pulcherrima extracts. The remaining extracts produced slightly lower TPI values, probably as a result of the effect of lower molecular mobility due to the low temperature. Our results are in agreement with those observed by Belda et al. (1) for the same parameter. In particular, this study indicates the potential of M. pulcherrima in co-culture with S. cerevisiae on a semi-industrial scale to improve the colour properties in red wine owing to its pectinolytic activities at 12 and 28 °C. Likewise, the TPC was the highest in the must treated with Ap-m11-2 extract at both maceration temperatures (750.5±0.6 and 746.8±1.2 at 15 and 28 °C, respectively). Moreover, the TPC in all M. pulcherrima extracts and in those of A. pullulans Ap-R-22, T. delbrueckii Td-m7-2, D. vanrijiae Dv-m87-3 and R. dairenensis Rd-GM-15 was significantly higher at 15 than at 28 °C.

Quantification of the antioxidant activity (AA) by means of DPPH˙ radical scavenging is based on the capacity of the sample to reduce free radicals, which is proportional to the antioxidant content. In our case, the AA values of all enzymatically treated musts were higher at 15 than at 28 °C. All A. pullulans enzyme extracts had a high antioxidant capacity, particularly Ap-R-22 and Ap-m11-2, which showed a significantly higher activity at 15 °C than the other strains (553.3 and 548.0 mg/L, respectively). Other prominent enzyme extracts regarding their high antioxidant activity at low temperatures were (in mg/L): Td-m7-2 (528.3), Fc-B-13 (506.1) and the two M. pulcherrima extracts: Mp-ts-2 and Mp-ts-1 (514.1 and 505.3, respectively).

Therefore, macerations with highest TPI, TPC and antioxidant capacity values corresponded to the most extensive multi-enzyme systems. The antioxidant capacity is related to the content of anthocyanins and total polyphenols. Each phenolic compound contributes proportionately and differently to this activity. Di Carlo et al. (52) observed a strong linear correlation between the antioxidant activity and TPI values.

The colour of a sample is defined by the colour intensity (CI) and the hue. The latter parameter represents the relative importance of yellow over red. According to the results shown inTable 3, a significant decrease in the hue was observed after all macerations with enzymes, even with the commercial enzyme (C2), compared to the control (C1). There were no statistically significant differences in CI between Ap-R-22 and Ap-m11-2 extracts, but there were in the hue, which would indicate that the Ap-m11-2 sample extracted more red pigments. Ap-m86-1 had a lower CI than the other extracts at 15 and 28 °C, but the hue was also lower. In the case of Crs-GM-4, there were no significant differences in the CI between both temperatures, but the hue was significantly lower at 15 than at 28 °C. This is a favourable effect of the low temperature on the colour composition. Additionally, the microbial extracts with the most extensive enzyme systems produced the highest values of the CIELAB parameters and highest ΔE.

Filterability and clarification of the macerated musts were also assessed at 15 and 28 °C (Table 4). At both temperatures and for all assayed enzyme extracts, filtration time was shorter than that of control without the enzyme. Furthermore, for all enzyme extracts, the filtration time at 15 °C was shorter than that recorded at 28 °C. In particular, macerations with Td-m7-2 and Ap-R-22 extracts required the shortest filtration times at 15 °C (249.2 and 250.4 s/mL, respectively), followed by those with Ap-m11-2 and Dv-m87-3 (256.3 and 255.0 s/mL, respectively). Regarding clarification, the formation of pectin flocs facilitates the production of a clear supernatant through elimination of the colloidal particles of the must. Hence, musts treated with Td-m7-2 and Ap-m86-2 were the most efficient, with an increase in transmittance of more than 4 times at both maceration temperatures. Other extracts with good clarification performance at low temperature were those of D. vanrijiae Dv-m87-3, A. pullulans Ap-R-22 and Hanseniaspora sp. H-m27-2. These results demonstrate that filtration and clarification are positively correlated with strains with very wide hydrolytic enzyme activity profiles for the degradation of plant cell wall polymers.

Principal component and cluster analyses

In order to select strains with multiple enzyme activities of great oenological importance based on the effects observed with macerations carried out with Malbec must, principal component analysis (PCA) was applied. At 28 °C (Fig. 2a), the first two dimensions explain 80.4% of the variability, with component one (PC1) representing 71.4% and component two (PC2) 9.0%. At 15 °C, PC1 represents 73.4% and PC2 8.6% of the variability (Fig. 2b). At both temperatures, PC1 positively correlated with the following parameters: clarification, TPI, TPC, CI, a*, ΔE and AA. All A. pullulans enzyme extracts together with Td-m7-2, Dv-m87-3 and Mp-ts-2 showed a similar behaviour regarding their relationship with the variables mentioned in component one. In turn, enzyme extracts presenting negative values for PC1 show an inverse correlation with these parameters. In this case, they correspond to the strains with low enzyme activity and with enzyme systems comprising only one or two of the assayed activities. Therefore, extracts that have multiple enzymes with a broad range of activities are represented by positive PC1 values, while those that show lower levels and types of enzyme activity are negative, and the intersection of the components is occupied by extracts with intermediate enzyme activities.

Fig. 2 Biplot graphs of the first two principal components using PCA and Factor Map for the effects of microbial enzyme extracts on technological parameters assayed for short maceration of Malbec must at: a) 28 °C and b) 15 °C

PC2 was represented with significant weight by the following parameters: filterability, hue, clarity (L*) and component b*. The hue, L* and b* are variables that are negatively related to the colour of red wine, and hence Pg-m28-1, H-m82, Cs-m89-1, Tp-m29 and Td-m30 extracts had a negative impact on the colour of the must during maceration. Filterability in the negative quadrant indicates a low efficiency of this parameter, resulting in longer filtration times.

Cluster analysis (Fig. 3) demonstrates that all A. pullulans extracts (Ap-R-22, Ap-m11-2, Ap-m86-1 and Ap-m86-2) as well as those of T. delbrueckii Td-m7-2, D. vanrijiae Dv-m87-3 and M. pulcherrima Mp-ts-2 generated the same cluster at 28 °C. At 15 °C, however, only the Ap-R-22, Ap-m11-2, Ap-m86-2 and Td-m7-2 extracts generated a cluster which was different from all the others, showing the ability to improve technological parameters assessed at the two assay temperatures. Consequently, these strains would produce the best blend of enzymes to improve the chromatic characteristics, clarification and filterability as well as the extraction of bioactive compounds during maceration of the grape must.

Fig. 3 Cluster analysis of microbial enzyme extracts after their technological effects on maceration of Malbec grape must at: a) 28 °C and b) 15 °C