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Selected Schizosaccharomyces pombe Strains Have Characteristics That Are Beneficial for Winemaking

  • Ángel Benito,

    Affiliation Department of Chemistry and Food Technology, Polytechnic University of Madrid, Madrid, Spain

  • Daniel Jeffares,

    Affiliation Research Department of Genetics, Evolution and Environment, University College London, London, United Kingdom

  • Felipe Palomero,

    Affiliation Department of Chemistry and Food Technology, Polytechnic University of Madrid, Madrid, Spain

  • Fernando Calderón,

    Affiliation Department of Chemistry and Food Technology, Polytechnic University of Madrid, Madrid, Spain

  • Feng-Yan Bai,

    Affiliation State Key Laboratory of Mycology, Institute of Microbiology, Chinese Academy of Sciences, Beijing, China

  • Jürg Bähler,

    Affiliation Research Department of Genetics, Evolution and Environment, University College London, London, United Kingdom

  • Santiago Benito

    santiago.benito@upm.es

    Affiliation Department of Chemistry and Food Technology, Polytechnic University of Madrid, Madrid, Spain

Abstract

At present, wine is generally produced using Saccharomyces yeast followed by Oenococus bacteria to complete malolactic fermentation. This method has some unsolved problems, such as the management of highly acidic musts and the production of potentially toxic products including biogenic amines and ethyl carbamate. Here we explore the potential of the fission yeast Schizosaccharomyces pombe to solve these problems. We characterise an extensive worldwide collection of S. pombe strains according to classic biochemical parameters of oenological interest. We identify three genetically different S. pombe strains that appear suitable for winemaking. These strains compare favourably to standard Saccharomyces cerevisiae winemaking strains, in that they perform effective malic acid deacidification and significantly reduce levels of biogenic amines and ethyl carbamate precursors without the need for any secondary bacterial malolactic fermentation. These findings indicate that the use of certain S. pombe strains could be advantageous for winemaking in regions where malic acid is problematic, and these strains also show superior performance with respect to food safety.

Introduction

Several research teams are studying the winemaking potential of non-Saccharomyces yeast strains [1]. For example, fission yeasts from the genus Schizosaccharomyces show more rapid malic acid deacidification, by converting malic acid to ethanol and CO2 [24]. Schizosaccharomyces pombe possesses several remarkable metabolic properties that may be useful in modern quality winemaking [2,56], including a malic dehydrogenase activity, high autolytic polysaccharides release [7], ability of gluconic acid reduction [811], urease activity [12,13], elevated production of pyruvic acid and colour improvement [14,15], as well as low production of biogenic amines and ethyl carbamate [6,16].

However, S. pombe type strains are not currently employed because of specific off-flavours commonly associated with their metabolism. Indeed, Schizosaccharomyces strains are commonly isolated from wines suffering from strong organoleptic and chemical deviations including the appearance of acetic acid, acetaldehyde, acetoin and ethyl acetate [1721]. These undesirable properties of the commonly-used strains have been assumed to be general properties of the species, and only one commercial strain of S. pombe is currently available on the market [22]. The exploration of the winemaking properties of other S. pombe strains has generally been overlooked. This omission partly reflects the absence of any specific processes to select strains that are appropriate for winemaking [5], and difficulties with isolating S. pombe from environmental samples [23]. Given this situation, it has been difficult to obtain a representative strain collection of this species. However, guided by a recent analysis of genetic and phenotypic diversity of 161 S. pombe strains [24], we can now conduct a more extensive survey of the utility of this species for winemaking.

The present study examines the winemaking potential of 75 S. pombe strains that are available from different microorganism type culture collections, or have been collected by us [5,25]. We apply classic selection parameters used in traditional fermentative Saccharomyces yeasts, along with more advanced and specific parameters for S. pombe. The results indicate that at least three S. pombe strains can potentially provide a viable and attractive alternative to the application of genetically modified Saccharomyces species [2629] whose use is restricted in food industry by European legislation [30].

Materials and Methods

Microorganisms

The following yeasts were used for the experimental fermentations: 75 S. pombe strains, including the non-clonal 54 strains recently described [24], the three mating types of the standard laboratory strain: Leupold’s 972 (h), 975 (h+) and 968 (h90) (JB22, JB32 and JB50), strain V1 collected by us [5], and 17 strains collected from traditional Chinese breweries by Feng-Yan Bai (unpublished). The following S. cerevisiae strains were used as controls: 87 and 88 from the Spanish Type Culture collection, which have been used in previous studies. Data for all strains are provided in Table 1.

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Table 1. Schizosaccharomyces pombe yeast strains used in the experiments.

https://doi.org/10.1371/journal.pone.0151102.t001

First phase of S. pombe strain selection

Starter cultures were grown from 100 μL of each yeast suspension, cultivated in 5 mL volumes of YEPD at 25°C for 24 h. This procedure was performed in triplicate before the final inoculation of 1 mL in the fermentative medium. 1 mL (108 CFU/mL) of these starters cultures were then inoculated into tubes containing 9 ml of sterilised concentrated must (Dream Fruits S.A., Quero, Toledo, Spain), which was diluted to 212 g/L glucose + fructose and enriched with 4 g/L malic acid (Panreac, Barcelona, Spain) (final pH 3.1) to simulate acidic musts where the use of S. pombe is more recommended in order to increase wine quality [3,5]. After 21 days of fermentation, enzymatic analysis was performed for glucose + fructose, malic acid and acetic acid (S1 Table). This experiment was performed in triplicate for each studied strain.

Yeasts used in the second phase of S. pombe strain selection

The yeast strains used in the second selection phase included S. pombe IFI936/CECT12774 and IFI935/CECT1376 and S. cerevisiae IFI87/CECT12512 and IFI88/CECT12513 from the Spanish Type Culture collection. The S. pombe strains JB899/Y470, JB873/NCYC3422 and JB917/CBS1057 were selected during the first phase of the study. The strain V1 was selected in a previous study [5].

Second phase of S. pombe strain selection

Microfermentations were performed using 200 ml aliquots of concentrated must (Dream Fruits S.A., Quero, Toledo, Spain), which were diluted to glucose + fructose (G + F) concentrations of 211 g/L, enriched to 4.3 g/L malic acid (Panreac, Barcelona, Spain) (final pH 3.08), with 60 g/L of Actimax Natura (Agrovín S.A., Ciudad Real, Spain) added to provide nutrition. Each microfermentator was inoculated with 1 mL of liquid YEPD medium containing 107 CFU/mL (determined using a Thomas chamber) of one of the above-mentioned yeasts. All fermentations were performed in 250-ml flasks, which were sealed with a Muller valve and filled with 98% H2SO4 (Panreac, Barcelona, Spain) to allow the release of CO2 and to prevent microbial contamination [31]. The temperature was maintained at 25°C. The fermentations proceeded without aeration, oxygen injection or agitation. All fermentations were performed in triplicate.

The glucose + fructose, malic acid, acetic acid and pyruvic acid contents of the fermentations were monitored over a period of 14 days. The pH, urea, citric acid, glycerol, alcohol content, volatile compounds, amino acids and biogenic amine concentrations were determined at the end of the fermentation.

Measurements of biochemical compounds and pH

Glucose + fructose, malic acid, L-lactic acid, acetic acid, pyruvic acid, urea, glycerol and pyruvic acid analyses (Table 2) were conducted using a Y15 Autoanalyser (Biosystems, Barcelona, Spain). The kits to perform the analyses were obtained from Biosystems [32]. Alcohol content was determined by using the boiling method GAB Microebu [33]. The pH was measured with a Crison pH Meter Basic 20 (Crison, Barcelona, Spain).

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Table 2. Final analysis of fermentations performed by the studied strains.

Selected strains are JB899/Y470, JB917/CBS1057, JB873/NCYC3422 and V1, non-selected S. pombe strains from the Spanish culture collection (IFI936/CECT12774 and IFI935/CECT1376) and selected S. cerevisiae strains (IFI87/CECT12512 and IFI88/CECT12513).

https://doi.org/10.1371/journal.pone.0151102.t002

Quantification of volatile compounds

Volatile compounds (Table 3) were quantified by headspace gas chromatography–mass spectrometry (HS-GC-MS). Analyses were carried out using a Perkin-Elmer Clarus 500 gas chromatograph with a flame ionization detector, coupled to a mass spectrometer single quadrupole Clarus 560 S, all coupled to an automatic headspace sampler Turbomatrix 110 Trap (Perkin-Elmer, Massachusetts, USA). The headspace sampler conditions were: temperature of thermostating: 80°C, time of thermostating: 45 min, type of trap: Tenax TA, cycles of purge and trap: 4, temperature of trap capture: 45°C, desorption temperature of the trap: 290°C, time of dry trap purge: 10 min, desorption time of trap: 2 min, trap cleaning time: 5 min, needle temperature: 110°C, temperature of HS-GC transfer line: 150°C, vial pressure: 30 psi and constant pressure column: 28 psi. A FFAP capillary column (60 m × 0.25 mm DI x 0.25 μm film thickness) was used. Helium (Air Liquide, España) was used as carrier gas. Gradient analysis was run using the following temperature program: 40°C (3 min); 40–80°C (2°C/min); 80–180°C (3°C/min); and 210°C (5 min). Identification of individual compounds was based on a comparison of the obtained mass spectra of the individual chromatographic peaks with those valid for the standards and available from the National Institute of Standards and Technology (Gaithersburg, MD) software library. We also compared the retention times valid for individual peaks from the wine samples with those of the known volatile components use as standard patterns. To this effect, we used Gas chromatography quality compounds as the sets of the volatile standards (Fluka, Sigma–Aldrich Corp., Buchs SG, Switzerland).

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Table 3. Final analysis of volatile compounds performed by the studied strains during fermentations.

Selected S. pombe strains (JB899/Y470, JB917/CBS1057, JB873/NCYC3422 and V1), non-selected S. pombe strains from the Spanish culture collection (936/CECT12774 and IFI 935/CECT1376) and selected S. cerevisiae strains (IFI 87/CECT12512 and IFI 88/CECT12513) from the Spanish culture collection.

https://doi.org/10.1371/journal.pone.0151102.t003

Quantification of biogenic amines

The studied biogenic amines (Table 4) were analysed using a Jasco (Tokyo, Japan) UHPLC chromatograph series X-LCTM, equipped with a Fluorescence detector 3120-FP. Gradients of solvent A (methanol/acetonitrile, 50:50, v/v) and B (sodium acetate /tetrahydrofuran, 99:1, v/v) were used in a C18 (HALO, USA) column (100 mm × 2.1 mm; particle size 2.7 μm) as follows: 60% B (0.25 ml/min) from 0 to 5 min, 60–50% B linear (0.25 ml/min) from 5 to 8 min, 50% B from 8 to 9 min, 50–20% B linear (0.2 ml/min) from 9 to 12 min, 20% B (0.2 ml/min) from 12 to 13 min, 20–60% B linear (0.2 ml/min) from 13 to 14.5 min, and re-equilibration of the column from 14.5 to 17 min. Detection was performed by scanning in the 340–420 nm range. Quantification was performed by comparison against external standards of the studied amines. The different amines were identified by their retention times.

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Table 4. Final analysis of biogenic amines.

Fermentations by selected S. pombe strains (JB899/Y470, JB917/CBS1057, JB873/NCYC3422 and V1), non-selected S. pombe strains from the Spanish culture collection (936/CECT12774 and IFI 935/CECT1376) and selected S. cerevisiae strains (IFI 87/CECT12512 and IFI 88/CECT12513).

https://doi.org/10.1371/journal.pone.0151102.t004

Analytical determinations of amino acids

Selected amino acids (Table 5) were analysed using a Jasco (Tokyo, Japan) UHPLC chromatograph series X-LCTM, equipped with a Fluorescence detector 3120-FP. Gradients of solvent A (methanol/acetonitrile, 50:50, v/v) and B (sodium acetate /tetrahydrofuran, 99:1, v/v) were used in a C18 (HALO, USA) column (100 mm × 2.1 mm; particle size 2.7 μm) as follows: 90% B (0.25 mL/min) from 0 to 6 min, 90–78% B linear (0.2 mL/min) from 6 to 7.5 min, 78% B from 7.5 to 8 min, 78–74% B linear (0.2 mL/min) from 8 to 8.5 min, 74% B (0.2 mL/min) from 8.5 to 11 min, 74–50% B linear (0.2 mL/min) from 11 to 15 min, 50% B (0.2 mL/min) from 15 to 17 min, 50–20% B linear (0.2 mL/min) from 17 to 21 min, 20–90% B linear (0.2 mL/min) from 21 to 25 min, and re-equilibration of the column from 25 to 26 min. Detection was performed by scanning in the 340–455 nm range. Quantification was performed by comparison against external standards of the studied amino acids. The different amino acids were identified by their retention times.

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Table 5. Final analysis of amino acids.

Fermentations by selected S. pombe strains (JB899/Y470, JB917/CBS1057, JB873/NCYC3422 and V1), non-selected S. pombe strains from the Spanish culture collection (936/CECT12774 and IFI 935/CECT1376) and selected S. cerevisiae strains (IFI 87/CECT12512 and IFI 88/CECT12513) from the Spanish culture collection.

https://doi.org/10.1371/journal.pone.0151102.t005

Fermentation in stress conditions

Study of fermentation in stress caused by ethanol, sulphur dioxide and the osmotic stress caused by salts (NaCl and KCl), were performed based on methods described previously for S.cerevisiae [34]. 15 ml sealed test tubes contatining 10 ml of sterilized grape must were inoculated with the studied strains. The grape must final sugar concentration was 206 g/L diluted from a concentrated grape must (Dream Fruits S.A., Quero, Toledo, Spain) that was corrected to the respective stressful conditions before yeast inoculation: Ethanol (6%; 10%; 12% and 14%), KCl (0.75 M), NaCl (1.5 M) (both osmotic stress) and KHSO3 (150 and 300 mg/L) (sulphur dioxide). Ethanol, KCl, NaCl products were from Panreac (Panreac, Barcelona, Spain) and KHSO3 was from Agrovín S.A. (Alcázar de San Juan, Spain). The testing tubes were inoculated to a cellular density of 5x106 cells/mL with the studied strains: S. pombe strains (JB899/Y470, JB917/CBS1057, JB873/NCYC3422, JB4/ NCYC683, JB837/ NOTT1 and V1), non-selected S. pombe strains from the Spanish culture collection (936/CECT12774 and IFI 935/CECT1376) and selected S. cerevisiae strains (IFI 87/CECT12512 and IFI 88/CECT12513) from the Spanish culture collection. Final optical density was determined at 640 nm after 24 h of incubation at 25°C by an Y15 spectrophotometer (Biosystems, Barcelona, Spain). The maximal ethanol production was estimated through the fermenting power method [35,36]. In this case the original concentrated grape must (Dream Fruits S.A., Quero, Toledo, Spain) was diluted to a sugar concentration of 300 g/L, the sealed flasks with Müller trapflasks (Alamo, Madrid, Spain) were incubated at 25°C. All the tests were performed in triplicate.

Sensory analysis

For a sensory analysis, fermentations triplicate with S. pombe strains (JB899/Y470, JB873/NCYC3422, JB917/CBS1057, JB4/NCYC683, JB837/ NOTT1, 936/CECT12774, IFI935/CECT1376 and V1) and S. cerevisiae strains (IFI 87/CECT12512 and IFI88/CECT12513) were performed with microvinifications with similar methodology to previously described [13, 15]. Sealed 1 L flasks with a Müller trapflasks (Alamo, Madrid, Spain) containing 800 ml of sterilised (115°, 15 min) concentrated must (Dream Fruits S.A., Quero, Toledo, Spain), which was diluted to 202 g/L glucose + fructose and enriched with 4 g/L malic acid (Panreac, Barcelona, Spain) (final pH 3.11). The flasks were inoculated with the studied strains to initial population of 106 CFU/mL. The completion of the fermentation process was verified by weight loss and confirmation that final enzymatic analysis of glucose + fructose was below 3 g/L after fermenting at 25°C. After fermentation, wines were racked and stored for 7 days at 4°C in 750 mL wine bottles. The final product was bottled in 350 mL wine bottles, sealed bottles and stored horizontally in a climate chamber at 4°C for two weeks until sensory evaluation.

Final wines were assessed (in a blind test) by a panel of 10 experienced wine tasters, all members of the staff of the Food Technology Department of the Technical University of Madrid, Spain. Assessments took place in standard sensory analysis chambers with separate booths. Following the generation of a consistent terminology by consensus, one visual descriptor, four aromas and four taste attributes were chosen to describe the wines. Formal assessment consisted of two sessions held on different days where wine tasters tasted all fermented triplicates. The panellists used a 10-cm unstructured scale, from 0 (no character) to 10 (very strong character), to rate the intensity of the 10 attributes.

Statistical analyses

All statistical analyses were performed using PC Statgraphics v. 5 software (Graphics Software Systems, Rockville, MD, USA). The significance was set to p <0.05 for the ANOVA matrix F value. The multiple range test was used to compare the means.

Results and Discussion

First phase of S. pombe strain selection

A specific advantage of Schizosaccharomyces yeast in winemaking is that it degrades malic acid. To examine this with our strains, we initiated fermentation of grape must supplemented with malic acid (4 g/L). After fermenting the 75 S. pombe strains in test tubes for 21 days, we measured malic acid. We also measured two basic parameters, residual glucose + fructose and acetic acid production, which are typically used in the selection of fermentative yeasts of the genus Saccharomyces, the main yeast genus used in winemaking. The final concentrations of glucose + fructose after fermentation were close to 0 g/L (Fig 1a). This finding is in agreement with data reported by other authors, and is indicative of strong fermentative power [37,3]. This property allows the production of dry wines that are most popular in the world market.

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Fig 1. (a) Glucose + fructose concentrations (g/L); (b) malic acid degradation (%); (c) acetic acid concentration (g/L).

Scatterplots and box-and-whisker plots for the mean values of the final fermentations for the 75 studied S. pombe strains after 21. The red points indicate the values of the standard laboratory reference strain (Leupolds, 972, 975, 978), green line indicates values of strains with low levels of acetic acid (<0.4 g/L).

https://doi.org/10.1371/journal.pone.0151102.g001

The degradation of malic acid, which currently represents the primary industrial application of Schizosaccharomyces yeasts, was nearly 100% in all the studied strains (Fig 1b). These data are comparable to those from other authors, who reported malic acid degradation rates ranging between 75 and 100% [38].

Out of the 75 initial S. pombe strains tested, however, only five strains (JB4/NCYC683, JB837/UWOPS92.229.4, JB873/NCYC3422, JB899/Y470 and JB917/CBS1057) showed moderate final concentrations of acetic acid (<0.4 g/L) (Fig 1c). According to these results, just 6.5% of the S. pombe strains could be used for producing quality wine. In a previous study, a similarly low rate of 5% was reported [5]. Three of these strains (JB837, JB873 and JB899) showed acetic acid concentration lower than 0.3 g/L. These data demonstrate that it is possible to identify S. pombe strains that can produce quality wines (Fig 1c).

Comparison between pre-selected S. pombe strains and other culture collection strains

After identifying the three S. pombe strains that show low acetic acid production, we studied additional features in detail. Microvinifications (200 mL) were performed to verify the acetic acid data and to confirm the proper fermentative ability of the pre-selected strains. In this portion of the study, the pre-selected S. pombe strains (JB837, JB873 and JB899) were compared with two S. cerevisiae strains (87/CECT12512 and 88/CECT12513) and with three other S. pombe strains (V1, 935/CECT1376 and 936/CECT12774) that had been tested previously [5].

Acetic acid.

The maximal final concentrations of acetic acid were approximately 0.3 g/L (Fig 2.a.1; Table 2) for all selected strains, while the S. pombe strains from the Spanish Type Culture Collection produced acetic acid concentrations of up to 1 g/L (Fig 2.b.1; Table 2). Therefore, when used as a single strain during fermentation, the latter strains are not suitable for the production of quality wines [14,5].

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Fig 2. Fermentation kinetics of acetic acid (1), malic acid (2) and glucose + fructose (3) for (a) selected S. pombe strains (JB899/Y470, JB917/CBS1057, JB873/NCYC3422 and V1); (b) non-selected S. pombe strains from the collection (935 and 936); (c) selected S. cerevisiae strains (87 and 88).

https://doi.org/10.1371/journal.pone.0151102.g002

Malic acid.

The malic acid degradation was almost complete for most of the studied S. pombe strains (Fig 2.a.2 and 2.b.2; Table 2), although the degradation kinetics differed. The two S. cerevisiae strains degraded 11–24% of the initial malic acid content in the must (Fig 2.c.2; Table 2). Several authors have proposed similarly high malic acid degradation for yeast belonging to other genera than Schizosaccharomyces [5, 3943]. The malic acid reduction influenced the final pH of the wine (Table 2), as S. pombe fermentations showed up to 0.34 higher pH values than S. cerevisiae fermentations.

Sugar consumption kinetics.

The consumption kinetics of glucose + fructose was more rapid in the S. cerevisiae strains than in most studied S. pombe strains (Fig 2.a.3, 2.b.3 and 2.c.3; Table 2). Similar results have been described before [6]. Nevertheless, differences in degradation kinetics of glucose + fructose between the studied S. pombe strains were evident (Fig 2.a.3 and 2.b.3).

Pyruvic acid.

All studied S. pombe strains produced more pyruvic acid than the S. cerevisiae yeasts (Fig 3). Strain JB873 yielded a maximum pyruvic acid concentration of 487 mg/L after 48 h of fermentation, which is a slightly higher concentration than those obtained in previous studies [5,6]. The other S. pombe strains provided a maximum pyruvic acid content that varied from 254 to 276 mg/L, except for the case of S. pombe JB899 that reached a pyruvic acid content of 374 mg/L (Fig 3). Previous pyruvic acid studies with S. cerevisiae and non-Saccharomyces species other than Schizosaccharomyces showed maximum values of about 150 mg/L during the first stages of fermentation [43]. These values are substantially lower than those obtained for the studied S. pombe strains. There is a strong correlation between the amount of pyruvic acid released by yeasts and the formation of vitisin A [3,5,15]; vitisin A is a stable pigment that influences wine colour quality. Thus, the selected strains with high pyruvate production rates such as JB873 and JB899 may be of interest in red wine production.

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Fig 3. Fermentation kinetics of pyruvic acid for selected S. pombe strains (JB899/Y470, JB917/CBS1057, JB873/NCYC3422 and V1), non-selected S. pombe strains from the collection (935 and 936) and selected S. cerevisiae strains (87 and 88).

https://doi.org/10.1371/journal.pone.0151102.g003

Glycerol.

Schizosaccharomyces species have previously been reported to produce more glycerol than Saccharomyces species [15]. In this study, final levels of glycerol varied from 8.02 g/L to 8.91 g/L (Table 2). Even though two S. pombe strains showed the highest levels (V1 and JB917), several differences were observed between the studied strains, and not in every case were the values higher than those obtained for the two S. cerevisiae strains. Increased glycerol content has been described as one of the main contributors of non-Saccharomyces strains on wine quality [1,44].

Ethanol.

Among all strains tested, the final ethanol levels varied from 12.04 to 12.44 (% vol/vol) (Table 2). The fermentations involving S. pombe produced very similar ethanol levels to the S. cerevisiae strains we examined (Table 2). Among the S. pombe strains, only slight differences in final ethanol levels of less than 0.24 (% vol/vol) were evident. In contrast other authors have shown that some non-Saccharomyces types of yeast produce lower ethanol yields than Saccharomyces [4547]. The sugar metabolism can also be used to produce compounds other than ethanol, such as glycerol or pyruvic acid, or to increase the yeast biomass [48,49]. Previous studies with S. pombe showed similar results to those obtained here [13]. Other authors observed lower final ethanol levels using other non-Saccharomyces species under specific high aeration conditions [50,51].

Urea.

The urea content of the finished wines was lower in the fermentations involving S. pombe, with values less than 0.5 mg/L (Table 2). This result can be attributed to the special ability of the Schizosaccharomyces genus to produce urease [12,52]. This enzymatic activity also could reduce the initial level of precursors for ethyl carbamate (one of the most toxic compounds reported in wine) [3,15]. This factor is becoming increasingly important as ethyl carbamate is a known carcinogen that is present in a variety of fermented foods [53].

Citric acid and lactic acid.

No differences were evident with respect to citric and lactic acid (Table 2), as no wine performed malolactic fermentation [6] or Lachancea thermotolerans species were used [54]. Note that after a traditional malolactic fermentation process by lactic bacteria, all citric acid could be converted into acetic acid; this collateral effect increases the final acetic acid content [6] and consequently slightly reduces wine quality.

Volatile aromas.

Higher alcohols were produced in higher total concentrations by S. cerevisiae fermentations (Table 3). Some differences were observed between the studied S. pombe strains (Table 3). Other authors described non-Saccharomyces yeasts as lower producers of higher alcohols than S. cerevisiae [42,43,5457], and much strain variability has been reported [58,59]. This finding could be of interest in facilitating the making of wines with typicity for specific grape varieties or to increase wine complexity [60]. Similarly, the tested S. pombe strains produced less esters than the S. cerevisiae strains. No differences between the S. pombe and S. cerevisiae strains were observed with respect to compounds considered negative, such as ethyl acetate and diacetyl. However, those compounds could increase after a malolactic fermentation process performed by lactic bacteria [15]. Significant differences in compounds such as acetaldehyde and ethyl acetate were evident between the different S. pombe strains.

Biogenic amines.

During the past years, harmful effects of biogenic amines [6164] have been demonstrated, which now constitutes a serious matter in food safety that must be taken into account. A histamine value of 2 mg/L is considered the maximum level [65] in some countries. All studied strains reported values below that threshold (Table 4). The study shows that S. pombe does not produce higher levels of biogenic amines than S. cerevisiae. Subtle statistical differences were observed in the case of cadaverine (Table 4), but this biogenic amine is not produced by yeasts, and the slight differences could reflect that some strains remove biogenic amines during the fermentation process; similar processes have been described before [66]. However, most biogenic amines are produced during wine ageing and malolactic fermentation [67], as they are compounds produced primarily by lactic acid bacteria [68,69]. Thus, the wines that still contain malic acid (Fermentations by S. cerevisiae) could increase their biogenic amine contents later on [6,16].

Amino acids.

S. pombe fermentations showed higher final levels in most amino acids (Table 5). Similar results were obtained before, as it has been described as demanding less nitrogen [14] and releasing more nitrogen [7] than S. cerevisiae. However some differences were observed among the studied strains (Table 5). S. cerevisiae fermentations produced a higher final level in ornithine. The observed differences in threonine, valine, isoleucine and leucine explain the differences measured for higher alcohols (Table 5), because they are precursors of 1-propanol, isobutanol, 2-methylbutanol and 3-methylbutanol, respectively (Table 5) [43]. The statistical differences reported for histidine, tyrosine and lysine show that S. pombe fermentations increase the content of some biogenic amine precursors [65,67]. Nevertheless, the transformation of some of those precursors to biogenic amines takes place during the malolactic fermentation, therefore the wines fermented by S. pombe did not run a serious risk of increasing the levels of histamine or tyramine since they do not need any longer a malolactic fermentation [16].

Fermentations in stress conditions

Several authors have reported how important is to study yeast performance under stress conditions [70,71]. After performing the stress tests conditions for the selected strains (Table 6) for some parameters described before in literature [34]. We observed that different phenotypic cases were detected for the studied strains in the studied parameters. Other authors have reported before the importance of phenotypic performance in yeasts [72,73]. According to these results strain S.pombe 936/CECT12774 would develop better than the others S.pombe under circumstances similar to KCl test and strain JB837/NOTT1 would not be able to perform properly. In the NaCl test strains JB873/NCYC3422, JB4/NCYC683, 935/CECT1376 and 936/CECT12774 performed slightly better than the others S.pombe. For the ethanol resistance tests, strains JB873/NCYC3422, 935/CECT1376 and 936/CECT12774 could perform better than the others. In the case of KHSO3 test, strains JB873/NCYC3422, JB4/NCYC683, 935/CECT1376 and 936/CECT12774 showed to be more resistant. The highest fermenting powers were obtained by strains JB873/NCYC3422, JB4/NCYC683, 935/CECT1376 and 936/CECT12774 among the S.pombe strains. Even though the values were better for the S.cerevisiae controls, these differences could be related to the slower developing kinetic describe for S.pombe than S.cerevisiae that was observed in the previous trials and reported by other authors [6]. In fact S.pombe has been described before as highly resistant to some stress conditions [23].

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Table 6. Final analysis of phenotypic classes for different stressful parameters.

Fermentations by selected S. pombe strains (JB899/Y470, JB917/CBS1057, JB873/NCYC3422, JB4/ NCYC683, JB837/NOTT1 and V1), non-selected S. pombe strains from the Spanish culture collection (936/CECT12774 and IFI 935/CECT1376) and selected S. cerevisiae strains (IFI 87/CECT12512 and IFI 88/CECT12513). Number of strains belonging to different phenotypic classes, regarding values of optical density after developing in corrected must with studied stressful parameter (Class 0: A640 = 0.1; Class 1: 0.2<A640>0.4; Class 2: 0.5<A640>1.0; Class 3: A640>1.0).

https://doi.org/10.1371/journal.pone.0151102.t006

Sensory evaluation

A sensory evaluation was performed to verify that the selected strains had the potential to produce wines that were pleasant to drink. Fig 4 shows a spider web diagram of the average scores of some olfactory and taste attributes. Large differences in the perception of acidity were recorded; this result agrees with acidity parameters explained above in the previous fermentations. Slight differences were reported regarding to sweetness even though all fermentations depleted successfully all the sugars, this can be explained by differences in acid-sweet balance. Serious faults were reported for non-selected S. pombe strains IFI935/CECT1376 and 936/CECT12774 regarding to high acetic acid and reduction characters. Fermentations by selected S. pombe strains JB899/Y470 and JB873/NCYC3422 received the best scores from all tasters while non-selected IFI935/CECT1376 and 936/CECT12774 received the lowest scores, S. cerevisiae strains IFI87/CECT12512 and IFI88/CECT12513 received moderate scores in overall impression scores related to excessive high acidity for the tasters. These results show that S. pombe can perform better than S.cerevisiae under very acidic conditions. The above data show that all fermentations with S. pombe achieved the main goals related to malic acid deacidification from a very acidic must.

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Fig 4. Results of the sensory analysis on fermentation products of selected S. pombe strains: JB899/Y470, JB873/NCYC3422, JB917/CBS1057, JB4/NCYC683, JB837/NOTT1 and V1; Non selected S.pombe strains: 936/CECT12774 and IFI935/CECT1376; Selected S. cerevisiae strains: IFI87/CECT12512 and IFI88/CECT12513.

https://doi.org/10.1371/journal.pone.0151102.g004

Conclusions

Among 75 S. pombe strains tested, we have discovered three strains with highly promising winemaking properties. These strains could be used to produce wines with low levels of malic acid, acetic acid, ethyl carbamate and biogenic amines, and with an appropriate volatile aroma profile. Because these S. pombe strains produced similar ethanol as the budding yeast strains we examined, this species may well have untapped potential for the producing of ethanol as a fuel (‘bioethanol’).

Supporting Information

Acknowledgments

The authors are grateful to the accredited Estación Enológica de Haro laboratory, where the biogenic amines, amino acids and volatile aroma analysis were performed, especially to Montserrat Iñiguez and Elena Melendez. Jürg Bähler and Daniel Jeffares were supported by a Wellcome Trust Senior Investigator Award to J.B. (grant 095598/Z/11/Z).

Author Contributions

Conceived and designed the experiments: SB DJ AB FC FP JB FB. Performed the experiments: AB DJ FC FP JB FB SB. Analyzed the data: AB DJ FC FP JB SB. Contributed reagents/materials/analysis tools: SB JB DJ FB. Wrote the paper: AB DJ FC FP JB FB SB.

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