Abstract

   A metabolomic analysis using high resolution ^1H NMR spectroscopy
   coupled with multivariate statistical analysis was used to characterize
   the alterations in the endo- and exo-metabolome of S. cerevisiae BY4741
   during the exponential phase of growth in minimal medium supplemented
   with different ethanol concentrations (0, 2, 4 and 6% v/v). This study
   provides evidence that supports the notion that ethanol stress induces
   reductive stress in yeast cells, which, in turn, appears to be
   counteracted by the increase in the rate of NAD^+ regenerating
   bioreactions. Metabolomics data also shows increased intra- and
   extra-cellular accumulation of most amino acids and TCA cycle
   intermediates in yeast cells growing under ethanol stress suggesting a
   state of overflow metabolism in turn of the pyruvate branch-point.
   Given its previous implication in ethanol stress resistance in yeast,
   this study also focused on the effect of the expression of the
   aquaglyceroporin encoded by FPS1 in the yeast metabolome, in the
   absence or presence of ethanol stress. The metabolomics data collected
   herein shows that the deletion of the FPS1 gene in the absence of
   ethanol stress partially mimics the effect of ethanol stress in the
   parental strain. Moreover, the results obtained suggest that the
   reported action of Fps1 in mediating the passive diffusion of glycerol
   is a key factor in the maintenance of redox balance, an important
   feature for ethanol stress resistance, and may interfere with the
   ability of the yeast cell to accumulate trehalose. Overall, the
   obtained results corroborate the idea that metabolomic approaches may
   be crucial tools to understand the function and/or the effect of
   membrane transporters/porins, such as Fps1, and may be an important
   tool for the clear-cut design of improved process conditions and more
   robust yeast strains aiming to optimize industrial fermentation
   performance.

Introduction

   Saccharomyces cerevisiae is very important in winemaking and
   bio-ethanol production industries [31][1]. However, the accumulation of
   ethanol in the culture broth medium during alcoholic fermentation acts
   as a stress factor which limits the yield of bioethanol production
   [32][2], [33][3] and affects the quality of wines [34][4], [35][5],
   [36][6]. Therefore, understanding the toxic effects caused by ethanol
   and the molecular mechanisms triggered by yeast to cope with this
   stress is of fundamental importance for strain and process development.

   Cellular membranes are the primary target of ethanol [37][3], which,
   due to its lipophilicity, is incorporated in these structures changing
   their organization and affecting their function as a semi-permeable
   barrier and matrix for enzymes. By affecting the plasma membrane
   function, ethanol inhibits associated transport processes, the
   maintenance of the transmembrane electrochemical potential and the
   plasma membrane function as a selective barrier, leading to
   intracellular acidification [38][3], [39][7], [40][8]. Ethanol has also
   been shown to influence cell metabolism, particularly affecting the
   activity of crucial glycolytic enzymes [41][9], [42][10]. Although
   usually repressed in the presence of glucose, the first step in the
   metabolism of alcohol is the oxidation of ethanol to acetaldehyde
   catalyzed by alcohol dehydrogenase, containing the coenzyme NAD^+.
   Acetaldehyde is further oxidized to acetic acid and finally CO[2] and
   water through the citric acid cycle. In response to ethanol stress,
   yeast stimulates the activity of the plasma membrane H^+-ATPase to
   counteract intracellular acidification [43][11], [44][12], [45][13] and
   promotes the remodelling of plasma membrane composition by changing its
   levels of unsaturated fatty acids and ergosterol [46][11], [47][14],
   and of the cell wall composition and structure [48][15], [49][16].
   Interestingly, yeast tolerance to ethanol has recently been shown to
   depend on the expression of the ABC multidrug efflux pump Pdr18
   [50][17], involved in ergosterol incorporation in the yeast plasma
   membrane [51][18]. Despite the efforts made hitherto, the repercussion
   of ethanol stress in yeast cells is still not completely understood.

   In recent years, an increase in the exploitation of different global
   approaches has been observed, particularly transcriptomic and
   chemogenomic approaches, to gain greater insight into the yeast
   response and tolerance to ethanol stress, at a systems level. Several
   works have used transcriptomics to analyse the effect that short-term
   sub-lethal ethanol exposure has in S. cerevisiae [52][19], [53][20],
   [54][21]. These studies suggested the importance of biological
   processes associated to cell energetics, transport mechanisms, lipid
   metabolism, trehalose metabolism, glycolysis and tricarboxylic acid
   cycle (TCA cycle) in the context of yeast response to ethanol stress
   [55][22]. In parallel, many functional genomic screens were performed
   to identify determinants of resistance to ethanol stress [56][16],
   [57][23], [58][24], [59][25], [60][26], [61][27]. One of these screens,
   in which 254 yeast genes were identified as being required for maximal
   tolerance to ethanol, was performed in our laboratory [62][16]. Among
   these determinants of resistance, particular attention was given to the
   FPS1 gene, encoding a plasma membrane aquaglyceroporin [63][28], that
   was found to decrease intracellular accumulation of radiolabelled
   ethanol [64][16]. The activity of Fps1 is determined by the osmolarity
   of the environment. It was proposed that under hyperosmotic shock Fps1
   activity is reduced leading to glycerol accumulation, whereas upon
   shifting back to hypo-osmotic conditions the Fps1 channel opens to
   release glycerol and thus relieve turgor pressure [65][28], [66][29].
   Although Fps1 natural substrate seems to be glycerol, Fps1 appears to
   facilitate the diffusion of toxic compounds across the yeast plasma
   membrane, including the trivalent metalloids arsenite and antimonite
   [67][30], acetic acid [68][31] and boron [69][32]. On the other hand,
   Fps1 deletion has been shown to increase yeast susceptibility to
   numerous chemical stress inducers, including, according to the SGD
   compilation, tunicamycin, dithiotreitol, mercaptoethanol, telluride,
   cadmium chloride, 1-propanol, ethanol, sulfometuron methyl,
   cycloheximide, caffeine and rapamycin (Saccharomyces Genome Database –
   [70]www.yeastgenome.com). It does not seem likely, however, that Fps1
   plays a direct role in facilitating the diffusion of all these
   chemicals across the plasma membrane. Significantly, FPS1 deletion was
   shown to decrease ergosterol concentration in the yeast plasma membrane
   [71][33], an effect likely to interfere with all transmembrane
   transport systems. Given the role of this aquaglyceroporin in the
   control of the intracellular content of glycerol [72][29], we further
   hypothesized that Fps1 may have a broader effect in the yeast
   metabolome, which, in turn, may indirectly affect multiple chemical
   stress resistance.

   In this work, we performed a metabolomic analysis to unravel the
   alterations in the yeast metabolome due to ethanol stress, and to
   clarify the importance of Fps1 under these conditions. Two previous
   studies using GC-MS-based metabolomic approaches focused on the yeast
   response to ethanol-induced stress at the endo-metabolome level, when
   cultivated in YPD rich media [73][34], [74][35]. Although the final aim
   of metabolomics is to identify and quantify all the intra- and
   extra-cellular metabolites of an organism, the characteristics of the
   different metabolites make the output of any metabolic approach tightly
   dependent on the metabolomic strategy employed [75][36]. Indeed, each
   metabolic strategy only gives a part and complementary perspective of
   the full metabolome picture. We are, to the best of our knowledge, the
   first to explore a ^1H-NMR-based metabolomic approach coupled with a
   multivariate statistical analysis to study the alterations both in the
   exo- and endo-metabolome of yeast cells in the presence of increasing
   concentrations of ethanol (up to 6% v/v), revealing changes in the
   relative concentration of 35 metabolites, 40% of which had not been
   previously identified in this context. This study was undertaken in a
   controlled minimal growth medium, more suitable to analyse differences
   at the exo-metabolome level. This metabolomic analysis further examined
   the effect of the deletion of the FPS1 gene in the yeast metabolome
   both in the absence and presence of ethanol stress (2% v/v), thus
   shedding light on the pleiotropic effect of the expression of this
   aquaglyceroporin.

Materials and Methods

1. Strains, Growth Media and Growth Conditions

   Saccharomyces cerevisiae BY4741 (MATa his3Δ1 leu2Δ0 met15Δ0 ura3Δ0)
   parental strain and the mutant fps1Δ with the FPS1 gene deleted, were
   obtained from the Euroscarf collection. Cells were batch-cultured at
   30°C, with orbital agitation (250 rpm) in minimal growth medium MM4.
   This medium contained (per liter): 1.7 g yeast nitrogen base without
   amino acids or NH[4] ^+ (Difco), 20 g glucose (Merck), 2.65 g
   (NH[4])[2]SO[4] (Merck), 20 mg methionine (Merck), 20 mg histidine
   (Merck), 60 mg leucine (Sigma) and 20 mg uracil (Sigma). To examine the
   effect of ethanol, MM4 medium was supplemented with different ethanol
   concentrations (2, 4 and 6% v/v of ethanol). Growth curves were
   followed by measuring culture optical density (OD[600 nm]). Cells used
   to prepare the inoculum were cultivated in the absence of ethanol until
   mid-exponential phase at a standardized OD[600 nm] = 0.5±0.01. These
   cells were used to inoculate the different media to obtain an initial
   OD[600 nm] = 0.2±0.01.

2. Metabolome Profiling

2.1 Cell sampling, cold methanol quenching and metabolite extraction

   Saccharomyces cerevisiae BY4741 parental strain was cultivated in the
   absence or presence of different ethanol concentrations (2, 4 and 6%
   v/v) and harvested (120 mg of biomass) during the exponential growth
   phase when the culture OD[600 nm] reached values of 1.00±0.05. In the
   case of the deletion mutant fps1Δ, cell samples were collected at the
   same phase of growth (OD[600 nm] = 1.00±0.05) either in the absence or
   presence of 2% v/v of ethanol. Sample preparation for the
   endo-metabolome analysis was done as before [76][37]. In order to
   capture snapshots as accurate as possible of the endo-metabolome, cell
   metabolism was quenched using a previously described method [77][38].
   One volume of cell culture was immediately added in three volumes of
   methanol cold solution (60% v/v; T<<−50°C). Cells were pelleted in a
   centrifuge cooled to −20°C (2,500×g for 6 min). Pellets were washed
   three times. Eight ml of the methanol cold solution (T<<−50°C) were
   added to the pellets, vortexed, and pelleted again in a centrifuge
   cooled to −20°C (2,500×g for 3 min). After each centrifugation step,
   samples were checked for their temperature using a thermometer (−35°C
   to +50°C). During quenching and subsequent washing steps, the
   temperature of the mixture was always below −20°C. Metabolites were
   extracted based on the method described by Gonzalez et al. [78][39].
   Two ml of glass beads (0.4–0.6 mm diameter) and 4 ml of ethanol (75%
   v/v) were added to the cell pellets, the mixture was then vortexed for
   30 s, heated for 3 min to 80°C and vortexed again for 30 s. The
   supernatant was decanted and the extraction step repeated a second time
   with 2 ml of ethanol (75% v/v). The supernatants were mixed, cleared by
   centrifugation (−20°C; 16,000×g; 10 min) and dried under vacuum. For
   the exo-metabolome analysis, 2 ml of the cell cultures were collected,
   centrifuged (2,500×g for 3 min) and the supernatant kept in the freezer
   (−80°C) until NMR data acquisition.

2.2 NMR data acquisition, processing and resonance assignments

   For the endo-metabolome analysis, the dried extracts were dissolved in
   1 ml of buffer (0.1 M phosphate buffer pH 7.00, in D[2]O, containing
   0.1 mM of trimethylsilyl-2,2,3,3-tetradeuteropropionate (d4-TSP)) into
   5 mm diameter NMR tubes. The samples were analysed using a 500 MHz
   Avance III Bruker spectrometer, equipped with a 5 mm inverse probe at
   296 K. 1D proton spectra were acquired using a standard NOESY pulse
   sequence with pre-saturation for water suppression (spectrum width 12
   ppm, 32 K data points, relaxation delay 3 s, mixing time 150 ms and 512
   scans per FID). For the exo-metabolome analysis, one part of buffered
   D[2]O was added to three parts of sample (to a final concentration of
   0.1 M phosphate buffer pH 7.00 and 0.1 mM of
   trimethylsilyl-2,2,3,3-tetradeuteropropionate (d4-TSP)), and when
   necessary the pH was corrected. The proton spectra were collected as
   before and each spectrum is the result of 128 scans.

   All proton spectra were manually phased, baseline corrected and
   referenced to d4-TSP (δ 0.00 ppm) using Mnova 5.3 for NMR data
   processing. For metabolite identification purpose 2D J-resolved (128×8
   K data points, relaxation delay of 2 s, 128 transients per FID and a
   spectral width of 62.5 Hz in the 2^nd dimension), Total Correlation
   Spectroscopy (TOCSY; 512×2 K data points, relaxation delay of 2 s,
   mixing time of 60 ms and 64 transients per FID) and Heteronuclear
   Single Quantum Coherence (HSQC; 512×2 K data points, relaxation delay
   of 1.5 s, 64 transients per FID and a spectral width of 174 ppm in
   indirect dimension) spectra were collected for representative samples.

2.3 Multivariate data analysis

   For the endo-metabolome analysis, the spectra regions corresponding to
   residual water, methanol and ethanol were excluded. Since the total
   intensity of each spectrum varied markedly with the ethanol
   concentration present in the culture medium, normalization to the
   spectrum total intensity is not the best option for data normalization
   [79][40]. Therefore, the spectral data were normalized using multiple
   internal regions of the spectrum (5.000–5.185 ppm, 5.260–6.890 ppm,
   6.935–7.075 ppm, 7.165–7.180 ppm, 7.230–7.295 ppm, 7.480–7.895 ppm and
   7.985–9.650 ppm). The sum of these internal regions has the same
   average value (six biological replicates) in all conditions tested and
   within each condition its intensity is highly correlated with the
   spectrum total intensity. Unless stated otherwise, the relative
   abundances of the endo-metabolome data presented herein are always
   referred to the normalization procedure using these multiple internal
   regions of the spectrum. Each spectrum was integrated over a series of
   fixed width bins (0.005 ppm) using Mnova v5.3 features. All spectra
   were put in a data table form in an ASCI format file and imported into
   the software SIMCA-P12^+ for multivariate data analysis. In SIMCA-P12^+
   the data was pre-processed using Pareto scaling. For the exo-metabolome
   analysis, a more target analysis was used. The spectral data were
   normalized using the reference peak (TSP). Each metabolite
   characteristic region (bins with variable width) was integrated using
   Mnova v5.3 features. The relative abundances of the exo-metabolome data
   presented within this paper are always referred to the normalization
   procedure using the reference peak (TSP). All spectral data were put in
   a data table form in an ASCI format file and imported into the software
   SIMCA-P12^+ for multivariate data analysis. In SIMCA-P12^+ the data was
   pre-processed using UV scaling. Both the endo- and exo-metabolome data
   were analysed using Principal Component Analysis (PCA) and Orthogonal
   Projection on Latent Structures Discriminant Analysis (O-PLS-DA).
   Unsupervised methods like PCA give an overview of the data and cluster
   the observations, while supervised methods based on prior information
   are used to better discriminate between clusters. R^2 and Q^2 values
   were considered as measures of goodness of model and the model
   robustness, respectively. R^2 is the fraction of variance explained by
   a component, and cross validation of this component provides Q^2, which
   describes the fraction of the total variation predicted by a component.
   The value of Q^2 ranges from 0 to 1 and typically a Q^2 value greater
   than 0.4 is considered a good model, and those with Q^2 values over 0.7
   are robust. Interpretation of each supervised model was based on the
   score plot, the loading plot and the variable importance in the
   projection plot (VIP). Variables lying in the same region in the
   loading plot as to the observations in the score plot are enriched in
   those observations. A measure of the degree to which a particular
   variable explains cluster membership is obtained with the VIP plot
   (with confidence intervals derived from jack knifing routine). For a
   given variable a VIP value above 1 indicates that it is important for
   class membership.

2.4 Identification of metabolic pathways from metabolic data

   MetaboAnalyst [80][41] was used to identify metabolic pathways more
   likely associated with the metabolic alterations induced by ethanol
   stress. A file, in the appropriate format, containing a measure of the
   concentration (characteristic bin) of all identified metabolites in the
   endo-metabolome profiles was uploaded to the Pathway analysis
   ([81]http://www.metaboanalyst.ca/). The dataset used correspond to the
   data from S. cerevisiae BY4741 parental strain in the presence of
   consecutive concentrations ethanol and from the comparison between S.
   cerevisiae BY4741 parental strain and the derived fps1Δ deletion
   mutant, either in the absence and presence ethanol stress. All
   metabolites were scaled to UV. S. cerevisiae pathway library was
   selected, and the default options in the pathway analysis algorithms
   check box were selected, Global test for Pathway enrichment analysis
   and Relative-betweeness centrality for Pathway topology analysis.

Results

1. Effect of Ethanol on the Growth Curve of S. cerevisiae BY4741 and fps1Δ
Deletion Mutant

   The growth curves of Saccharomyces cerevisiae BY4741 parental strain in
   minimal medium supplemented with different ethanol concentrations (2, 4
   and 6% v/v) indicate a dose-dependent reduction of the maximum specific
   growth rate ([82]Figure 1). Compared to the parental strain, the fps1Δ
   mutant strain, with the FPS1 gene deleted, exhibited lower maximum
   specific growth rate even in the absence of ethanol supplementation of
   the growth medium. In the presence of a low concentration of ethanol
   (2% v/v), which induces only a slight inhibitory effect on the growth
   rate of the parental strain, the growth of the fps1Δ deletion mutant
   was drastically affected displaying an initial period of 3 h of growth
   latency and a reduced maximum specific growth rate ([83]Figure 1).

Figure 1. Growth curves of S. cerevisiae BY4741 parental strain and fps1Δ
deletion mutant under ethanol stress.

   [84]Figure 1
   [85]Open in a new tab

   (A) Comparison of the growth curves of S. cerevisiae BY4741 in the
   absence (▪) or presence of 2% v/v (□), 4% v/v (Δ) and 6% v/v (○) of
   ethanol. (B) Comparison of the growth curves of S. cerevisiae BY4741
   (▪, □) and the corresponding deletion mutant fps1Δ (♦, ◊) in the
   absence (closed symbols) or presence of 2% v/v of ethanol (open
   symbols).

2. Metabolic Characterization of S. cerevisiae BY4741 Cells in the
Exponential Phase of Growth with Increasing Ethanol Concentrations

   The ^1H NMR spectra from yeast cell extracts (endo-metabolome) and from
   the culture broth medium (exo-metabolome) ([86]Figure S1) obtained in
   the exponential phase of growth (OD[600 nm] of approximately 1.0),
   either in the presence (2, 4 and 6% v/v) or absence of exogenously
   added ethanol, enabled the detection of hundreds of resonances. Despite
   the fact that many of these resonances remain unassigned, some of which
   exhibiting marked changes, a wide range of classes of biomolecules were
   identified, including amino acids (L-alanine, L-arginine, L-aspartic
   and L-glutamic acids), cofactors (NADH, NAD^+ and NADP^+), osmolytes
   (glycerol and trehalose), organic acids (acetic, fumaric and pyruvic
   acids) and metabolites associated with energy metabolism (ATP, ADP and
   AMP). Metabolite identification was done by a careful analysis of the
   chemical shifts, intensities, J couplings and multiplicities of the
   metabolites peaks present in the 1D proton spectra, complemented with
   the information from J-resolved, TOCSY and HSQC spectra, and data
   gathered in different databases, as described before [87][37]. Indeed,
   it was possible to identify over 45 metabolites ([88]Figure S1;
   [89]Tables S1 and [90]S2). All the assigned metabolites, except
   acetaldehyde and orotidine, were confirmed by spiking with authentic
   standards.

2.1 Alterations in the endo- and exo-metabolome of S. cerevisiae BY4741 in
the presence of increasing ethanol concentrations

   The modelling of the endo-metabolome data using Principal Component
   Analysis (PCA) generated a model with four principal components (PCs)
   (R^2X = 0.955 and Q^2 = 0.928). [91]Figure 2 A shows that the different
   biological replicates are grouped in four distinct clusters,
   corresponding to the four different growth conditions (absence and
   presence of 2, 4 or 6% v/v of ethanol). The analysis of the
   intracellular metabolic profiles using Orthogonal-Partial Least
   Squares-Discriminant Analysis (O-PLS-DA) ([92]Table S5), and in
   accordance with the PCA modelling, clearly distinguished the different
   conditions under study. The PCA modelling of S. cerevisiae BY4741
   exo-metabolome data (R^2X = 0.689 and Q^2 = 0.432), collected during
   the exponential phase of growth in the presence of increasing ethanol
   concentrations, also allows to clearly distinguish the four growth
   conditions under study ([93]Figure 3 A and B). The analysis of the
   loading plots ([94]Figures 2 B and 3 B) indicates which metabolites
   were found to contribute more for cluster separation. The metabolites
   trehalose, L-alanine, L-methionine, L-leucine and L-glutamic were found
   to be major contributors for endo-metabolome cluster separation
   ([95]Figure 2 B).

Figure 2. Endo-metabolome analysis of S. cerevisiae BY4741 parental strain
under ethanol stress.

   [96]Figure 2
   [97]Open in a new tab

   Yeast cells were harvested during the exponential phase of growth
   (OD[600 nm] = 1.0) in the same basal medium and supplemented with
   different ethanol concentrations (% v/v). (A) 2D score plot displaying
   the space formed by the two first principal components (R^2X for PC1
   equal to 0.792 and R^2X for PC2 equal to 0.129), (B) 2D loading plot
   displaying the space formed by the two first principal components and
   presenting the characteristic bins for a set of metabolites and (C)
   Relative abundance of different metabolites in the endo-metabolome of
   S. cerevisiae BY4741 cells harvested during the exponential phase of
   growth (OD[600 nm] = 1.0) in the presence of different ethanol
   concentrations (0, 2, 4 and 6% v/v). Each plot displays the variation
   in the relative abundance of a representative bin in the spectrum for
   each amino acid. Experimental values are means of six independent
   experiments with standard deviation error bars. Key: 1 Glycerol, 2
   L-arginine, 3 NAD^+, 4 NADP^+, 5 L-tyrosine, 6 L-histidine, 7
   Trehalose, 8 NADH, 9 Fumaric acid, 10 L-proline, 11 L-phenylalanine, 12
   L-asparagine, 13 Citric acid, 14 L-serine, 15 Succininic acid, 16
   L-aspartic acid, 17 Malic acid, 18 L-glutamine, 19 L-alanine, 20
   L-lysine, 21 L-glycine, 22 L-threonine, 23 L-valine, 24 L-methionine,
   25 L-leucine, 26 L-glutamic acid and 27 L-ornithine.

Figure 3. Exo-metabolome analysis of S. cerevisiae BY4741 parental strain
under ethanol stress.

   [98]Figure 3
   [99]Open in a new tab

   Samples were collected during the exponential phase of growth (OD[600
   nm] = 1.0) in the same basal medium supplemented with different ethanol
   concentrations (% v/v). (A) 2D score plot displaying the space formed
   by the two first principal components (R^2X for PC1 equal to 0.522 and
   R^2X for PC2 equal to 0.166), (B) 2D loading plot displaying the space
   formed by the two first principal components and presenting the
   characteristic bins for a set of metabolites and (C) relative abundance
   of different metabolites in the exo-metabolome of S. cerevisiae BY4741
   cells during the exponential phase of growth (OD[600 nm] = 1.0) in the
   presence of different ethanol concentrations (0, 2, 4 and 6% v/v).
   Experimental values are means of four independent experiments with
   standard deviation error bars. Key: 1 Orotic acid, 2 Succininc acid, 3
   2-Oxoglutaric acid, 4 L-leucine, 5 L-methionine, 6 Glucose, 7
   L-histidine, 8 Glycerol, 9 Formic acid, 10 Uracil, 11 Acetic acid, 12
   Pyruvic acid, 13 Acetoin, 14 Acetaldehyde, 15 Lactic acid, 16 L-alanine
   and 17 Fumaric acid.

   Using Pathway analysis from MetaboAnalyst (see Materials and methods
   2.2.4), we obtained an indication of the metabolic pathways that may be
   more relevant in the context of ethanol stress. Although this tool is
   extremely valuable to do an overall analysis of metabolic data, it
   should be stressed that this analysis is biased to the metabolic
   pathways containing metabolites covered by the selected metabolomic
   strategy. Based on the endo-metabolome data of S. cerevisiae BY4741 in
   the absence or presence of 2, 4, and 6% v/v of ethanol, we searched for
   metabolic pathways with highest scores from the Pathway topology
   analysis (impact value) and Pathway enrichment analysis (-log p).
   Alanine, aspartate and glutamate metabolism (13.328), Glutathione
   metabolism (13.933), Glycine, serine and threonine metabolism (13.087),
   Arginine and proline metabolism (16.211), Starch and sucrose metabolism
   (14.089), Glycerolipid metabolism (9.7168), Nitrogen metabolism
   (13.514), Glyoxylate and dicarboxylate metabolism (13.542), and Citrate
   cycle (TCA cycle) (13.361) are some of the metabolic pathways, ordered
   by impact factor with each -log p in brackets, pointed out by this
   analysis.

   Analysing the data in more detail, an increase in amino acid content in
   yeast cells growing exponentially in the presence of increasing
   concentrations of ethanol was registered, both for the more abundant
   (e.g. L-glutamic acid, L-leucine and L-alanine) and in the less
   abundant (e.g. L-tyrosine, L-proline and L-phenylalanine) amino acids
   ([100]Figure 2 C; [101]Tables S3 and [102]S4). Exceptions to this
   general trait are the profiles of L-ornithine, L-lysine and L-arginine
   ([103]Tables S3 and [104]S4). Significantly, the exometabolome data
   show that the abundance of L-leucine and L-methionine in the culture
   broth medium decreases in the same conditions ([105]Figure 3 C;
   [106]Tables S6 and [107]S7). Alterations in the content of other
   metabolites were also observed ([108]Figure 2 C; [109]Tables S3 and
   [110]S4). The content of NAD^+ decreases while the content of NADH
   increases with increasing ethanol concentrations ([111]Figure 2 C).
   Similarly to the observed for NAD^+, the NADP^+ content decreases with
   increasing ethanol concentrations ([112]Figure 2 C). A slight
   alteration in the oxidized/reduced glutathione ratio was also observed,
   with the content of the oxidized glutathione slightly decreasing and of
   the reduced glutathione slightly increasing with increasing ethanol
   concentrations ([113]Figure 2 C). Of all alterations identified, the
   most striking occurred in the content of the osmolyte trehalose that
   increases markedly with increasing ethanol concentrations ([114]Figure
   2 C). On the other hand, the glycerol content was higher in the
   presence of 2 and 4% v/v of ethanol than in absence or presence of 6%
   v/v of ethanol ([115]Figure 2 C). The TCA cycle associated metabolites
   succinic, malic, citric and fumaric acids also exhibit a dose-dependent
   increase in yeast cells growing under ethanol stress ([116]Figure 2 C).
   A metabolite-to-metabolite correlation analysis of the endo-metabolome
   data ([117]Figure S2) suggested a link between amino acid and
   TCA-associated metabolite concentration changes under ethanol stress.
   Simultaneously, a lower accumulation of 2-oxoglutaric acid and a higher
   accumulation of acetic and pyruvic acids, acetaldehyde and acetoin were
   registered in the culture broth of yeast cells growing exponential
   under ethanol stress ([118]Figure 3 C).

2.2 Effect of FPS1 expression in the endo- and exo-metabolome of yeast cells
in the presence or absence of ethanol stress

   The intracellular metabolic profiles from the fps1Δ mutant strain and
   the parental strain cells harvested in the exponential phase of growth
   (OD[600 nm] of approximately 1.0) either in the presence (2% v/v) or
   absence of exogenously added ethanol were compared using a multivariate
   statistical analysis. The PCA model (two PCs, R^2X = 0.846 and
   Q^2 = 0.819) clearly distinguishes between both the growth conditions
   and the yeast strains ([119]Figure 4). The analysis of the score plot
   ([120]Figure 4 A) indicates a more pronounced difference between the
   two strains in the absence than in the presence of ethanol stress. The
   O-PLS-DA modelling ([121]Table S8) pointed the metabolites glycerol,
   L-leucine and L-methionine, and glycerol, L-glutamic acid and L-alanine
   as major contributors for strain differentiation, either in the absence
   or presence of ethanol stress (2% v/v), respectively. The analysis of
   the exo-metabolome data, collected during the exponential phase of
   growth (OD[600 nm] of approximately 1.0) either in the presence (2%
   v/v) or absence of exogenously added ethanol, gave clustering results
   similar to the endo-metabolome analysis. The PCA model (five PCs,
   R^2X = 0.929 and Q^2 = 0.467) clearly distinguishes between both the
   growth conditions and the two yeast strains ([122]Figure 5 A and B). In
   particular, the growth conditions are distinguishable across the PC1
   ([123]Figure 5 A). The metabolic differences between yeast strains are
   more pronounced in the absence than in the presence of ethanol
   ([124]Figure 5 B). Several metabolites contribute for strain
   differentiation ([125]Figure 5 C; [126]Tables S6, [127]S10, [128]S11
   and [129]S12).

Figure 4. Comparison between the endo-metabolome of BY4741 parental strain
and of fps1Δ deletion mutant.

   [130]Figure 4
   [131]Open in a new tab

   Yeast cells were harvested during the exponential phase of growth
   (OD[600 nm] = 1.0) in the same basal medium supplemented with 0 or 2%
   v/v of ethanol. (A) 2D score plot displaying the space formed by the
   two first principal components (R^2X for PC1 equal to 0.525 and R^2X
   for PC2 equal to 0.321), (B) 2D loading plot displaying the space
   formed by the two first principal components (with characteristic bins
   for a set of metabolites) and (C) relative abundances of different
   metabolites in the endo-metabolome of the parental strain and the fps1Δ
   deletion strain during the exponential growth phase (OD[600 nm] = 1.0)
   in the presence of different ethanol concentrations (0 and 2% v/v).
   Experimental values are means of six independent experiments with
   standard deviation error bars. Key: 1 NAD^+, 2 NADP^+, 3 L-tyrosine, 4
   Fumaric acid, 5 L-phenylalanine, 6 Citric acid, 7 Succininic acid, 8
   Glycerol, 9 L-glutamic acid, 10 L-leucine, 11 L-methionine, 12
   L-alanine, 13 L-ornithine, 14 L-threonine, 15 L-valine,16 L-glutamine,
   17 L-aspartic acid, 18 L-malic acid, 19 L-histidine, 20 L-serine, 21
   L-asparagine, 22 L-lysine, 23 Thiamine, 24 NADH and 25 L-proline.

Figure 5. Comparison between the exo-metabolome of BY4741 parental strain and
of fps1Δ deletion mutant.

   Figure 5
   [132]Open in a new tab

   Samples were collected during the exponential phase of growth (OD[600
   nm] = 1.0) in the same basal medium supplemented with 0 or 2% v/v of
   ethanol. (A) 2D score plot displaying the space formed by the two first
   principal components (R^2X for PC1 equal to 0.375 and R^2X for PC2
   equal to 0.284), (B) dendrogram based on the PCA scores (ward
   clustering distance measure) considering all principal components of
   the model and (C) relative abundances of different metabolites in the
   exo-metabolome of the parental strain and the fps1Δ deletion mutant
   during the exponential growth phase (OD[600 nm] = 1.0) in the presence
   of different ethanol concentrations (0 and 2% v/v). Experimental values
   are means of four independent experiments with standard deviation error
   bars.

   Pathway analysis pointed out the metabolic pathways Starch and sucrose
   metabolism, Glycerolipid metabolism, Nicotinate and nicotinamide
   metabolism, Nitrogen metabolism, Citrate cycle (TCA cycle), and
   Phenylalanine, tyrosine and tryptophan biosynthesis as being possibly
   linked to the effect of FPS1 expression in the endo-metabolome of yeast
   cells in the presence or absence of ethanol stress.

   The intracellular content of glycerol was the most striking change
   registered both in the absence or presence of ethanol stress, being
   much higher in the fps1Δ mutant strain than in the parental strain
   ([133]Figure 4 C). This is consistent with the observed decrease in
   glycerol accumulation in the extracellular medium, registered for fps1Δ
   cells ([134]Figure 5 C). Overall metabolite abundances suggest that the
   deletion of FPS1 in the absence of ethanol stress has, although in a
   different magnitude, a similar effect to ethanol stress exposure in the
   parental strain ([135]Figure 4 C; [136]Tables S4 and [137]S9). In
   particular, the fps1Δ mutant strain has a lower content of NAD^+ than
   the parental strain, both in the presence or absence of ethanol stress.
   In the absence of ethanol supplementation, the content of succininc,
   citric and fumaric acids is higher in the fps1Δ mutant strain than in
   the parental strain. The intracellular and extracellular content of
   fumaric acid is also higher in the fps1Δ mutant strain than in the
   parental strain in the presence of ethanol stress ([138]Figures 4 C and
   5 C). Similarly, the content of L-phenylalanine and L-tyrosine is
   higher in the fps1Δ mutant strain than in the parental strain both in
   the absence and presence of ethanol supplementation ([139]Figure 4 C).
   Differences were also observed in the content of other amino acids
   (e.g. L-alanine, L-glutamic acid and L-glutamine) either in the absence
   or presence of exogenously added ethanol ([140]Figure 4 C).
   Furthermore, the content of intracellular orotidine ([141]Figure 4 C)
   and extracellular orotic acid ([142]Figure 5 C) was also found to be
   higher in the fps1Δ mutant strain than in the parental strain in both
   conditions tested. On the other hand, the content of trehalose was
   found to be higher in the parental strain than in the fps1Δ mutant
   strain both in the absence and presence of ethanol stress ([143]Figure
   4 C), although in this last case, due to the variability registered in
   the parental strain, it did not pass the statistical test (P-value
   1.05×10^−1).

   Finally, the fps1Δ deletion mutant was found to excrete lower amounts
   of acetaldehyde and acetoin in the culture broth medium than the
   parental strain in both conditions tested ([144]Figure 5 C), while, in
   the absence of exogenously added ethanol, the fps1Δ strain
   exo-metabolome exhibits 23% and 34% higher levels of ethanol and acetic
   acid ([145]Figure 5 C) than that of the parental strain, respectively.

Discussion

   In this study the changes occurring in the endo- and exo-metabolome of
   yeast cells that allow them to grow exponentially in the presence of
   inhibitory concentrations of ethanol were characterized by high
   resolution ^1H NMR spectroscopy. Previously, Ding et al. and Li et al.
   [146][34], [147][35] used GC-MS-based metabolomic approaches to study
   the yeast response to ethanol-induced stress at the endo-metabolome
   level. Based on the metabolites that were reported to be,
   simultaneously, detected and identified in those studies, the work
   herein have significantly increased the metabolic coverage at the
   endo-metabolome level (30% increase), emphasizing the importance of
   complementary strategies in metabolomics. The simultaneous analysis of
   the exo-metabolome further increased our understanding, allowing the
   quantification of metabolites whose presence was only detected in the
   extracellular environment, and providing clues on whether the changes
   observed in the endo-metabolome may be due to different
   catabolic/anabolic rates or to altered partition across the plasma
   membrane.

   The changes induced by ethanol stress at endo- and exo-metabolome level
   identified in this work are summarized in [148]Figure 6. A number of
   metabolic effects from alcohol appear to be directly linked to the
   production of an excess of both NADH and acetaldehyde. Since ethanol
   exposure leads to this sort of reductive stress, the latter might
   trigger the induction of pathways aimed at the elimination of NADH
   excess (e.g. the conversion of pyruvic acid to lactic acid, the
   synthesis of glycerol or fatty acids, or the mitochondrial electron
   transport chain) and thus in the down-regulation of other metabolic
   pathways needed for optimal growth. NAD(P)^+ and NAD(P)H, besides their
   role in determining the cell redox status [149][42], are critical
   determinants of in vivo reaction kinetics, being involved in over 200
   reactions throughout yeast metabolism [150][43], [151][44]. It is
   therefore reasonable to hypothesize that the huge differences in the
   yeast metabolome in the presence of increasing ethanol concentrations
   are, at least partially, linked with the perturbation of the cell redox
   status. In fermentative or respiro-fermentative growth conditions, the
   NADH formed during glycolysis is reoxidized through the reduction of
   acetaldehyde to ethanol, maintaining in this way the intracellular
   redox balance [152][45]. However, Martini et al. [153][46] showed that
   the metabolic yield of ethanol production in S. cerevisiae decreases
   with increasing concentrations of exogenously added ethanol, in
   agreement with the known toxic effects of ethanol, namely, decreased
   fermentation productivity and ethanol yield [154][11], [155][47],
   [156][48], [157][49]. Therefore, and since the formation of glycolytic
   NADH beyond the cellular capacity for its reoxidation will lead to
   reduced conditions, an inhibition in the yeast fermentative capability,
   particularly at the level of the final alcohol dehydrogenase reaction,
   may be causing an imbalance in the cell redox status. Another possible
   cause for such an apparent decreased ability to regenerate NAD^+ may be
   the inhibitory effect of ethanol at the level of the mitochondrial
   respiratory chain, whose function depends deeply on membrane integrity.
   Strongly linked with the intracellular redox status is the type and
   amount of by-products formed during yeast metabolism [158][44],
   [159][45], [160][50], [161][51], [162][52], [163][53]. Indeed, the
   exo-metabolome analysis carried out herein showed a higher accumulation
   in the broth medium of acetate, pyruvate, acetoin and acetaldehyde when
   ethanol is exogenously added, in a dose dependent way. The results
   obtained are also consistent with the previous observation, based on
   transcriptomic analysis, that ethanol challenge leads to a strong
   induction of the expression of TDH1, encoding a
   glyceraldehyde-3-phosphate dehydrogenase that utilises NAD^+ as a
   cofactor, suggesting that ethanol stressed-cells may experience
   reductive stress [164][2], [165][22]. Also in agreement with this
   notion, the ratio of reduced to oxidized glutathione was observed, in
   this study, to increase in a dose-dependent manner in yeast cells
   growing exponentially in the presence of inhibitory ethanol
   concentrations.

Figure 6. Integrative overview of the metabolic changes occurring under
ethanol stress or upon FPS1 deletion.

   [166]Figure 6
   [167]Open in a new tab

   Changes found to occur (as indicated by the black or white arrows) or
   not (□,▪) in yeast cells growing in the presence of inhibitory
   concentrations of ethanol (closed symbols), or upon FPS1 deletion (open
   symbols) are shown. The metabolic scheme was based on information
   gathered in the KEGG PATHWAY Database
   ([168]http://www.genome.jp/kegg/pathway.html) and in Yeast Biochemical
   Pathway Database ([169]http://pathway.yeastgenome.org/).

   Li et al. [170][34], [171][35] suggested that in the presence of
   ethanol stress there is an inhibition of glycolysis. The increased
   amount of intracellular and/or excreted glycolytic and TCA cycle
   intermediate metabolites, including pyruvate, citrate, malate, fumarate
   and succinate suggests an increase in overflow metabolism in turn of
   the pyruvate branch-point. The higher accumulation of pyruvate in the
   broth medium in the presence of ethanol stress is probably a
   consequence of an increase in difference between the fluxes upstream
   and downstream of pyruvate, which may be linked with the demand of
   energy supply for stress responsive processes. The referred overflow
   metabolism in turn of the pyruvate branch-point may underlie the
   changes registered in the intracellular content of some amino acids
   [172][37], [173][54]. Indeed, the current endo-metabolome analysis
   identified an overall increase in the intracellular content of most
   amino acids, which corroborates the observations made in previous
   metabolomic studies focused on the ethanol stress response [174][34],
   [175][35]. One general explanation that could account to an increase in
   the intracellular concentration of each amino acid could be an
   inhibition in protein synthesis in the presence of ethanol stress.
   However, this explanation apparently cannot account for the fact that
   not all the amino acids that were monitored increased their content
   with increasing ethanol concentrations as it is the case for
   L-arginine, L-lysine and L-ornithine. Moreover, the increase fold
   changes were found to vary significantly between the different amino
   acids monitored. In particular, the intracellular content of L-alanine
   and L-valine, two pyruvate-related amino acids, showed a dramatic
   accumulation in the exponential growth phase with increasing
   concentrations of ethanol, reinforcing the idea of overflow metabolism
   in turn of the pyruvate branch-point, as previously suggested to occur
   under other stress challenges, as was reported for very high gravity
   fermentation and in propionic acid stressed cells [176][37], [177][54].
   The increased intracellular content of L-aspartate, L-asparagine and
   L-threonine was also shown to occur in yeast cells grown in the
   presence of increasing ethanol concentrations. These aminoacids are
   derived from oxaloacetate, an intermediate of tricarboxylic acid (TCA)
   pathway that occurs in the matrix of mitochondria. Similar trends were
   observed in the contents of the TCA pathway intermediates succinate,
   malate, citrate and fumarate. These observations are consistent with
   previous indications, suggesting that, even in the presence of
   glucose-repressing conditions, mitochondrial function is important for
   yeast tolerance against ethanol stress [178][16]. During alcoholic
   fermentation, the TCA pathway operates as two branches, a reductive and
   an oxidative branch [179][55], aiming the supply of C4 and C5 compounds
   (oxaloacetate and 2-oxoglutarate), the precursors of L-aspartate and
   L-glutamate, respectively [180][56]. Interestingly, the interconversion
   of L-glutamate and L-glutamine, whose concentrations were found to
   increase in yeast cells thriving in the presence of ethanol stress, has
   been implicated in the balance of the cell redox status [181][57],
   [182][58], [183][59], [184][60]. Since L-glutamate is formed from the
   condensation of ammonium and 2-oxoglutarate, the accumulation of lower
   amounts of 2-oxoglutarate in the broth medium in the presence of
   ethanol stress is consistent with the changes registered in the
   intracellular content of L-glutamate. Aromatic amino acid
   concentrations were also found to increase in the presence of
   increasing ethanol concentrations, which may correlate with the
   identification of aromatic amino acids biosynthetic enzymes as being
   required for maximal ethanol resistance [185][26]. Although with
   different magnitudes, we also observed the intracellular accumulation
   of the amino acids that were supplemented in the growth medium due to
   the yeast strain auxotrophies (L-leucine, L-methionine and L-histidine)
   in a dose dependent way. The accumulation of L-leucine and L-methionine
   may rely on the fact that they may be degraded into fusel alcohols,
   such as isoamyl alcohol or methionol, in a NAD^+ regenerating reactions
   [186][50]. Interestingly, changes observed in the L-leucine content are
   consistent with a recent study suggesting that an enhanced uptake
   and/or utilization of L-leucine may be responsible for improved growth
   in the presence of ethanol [187][61]. Furthermore, these observations
   may also indicate the diffusion of externally supplied hydrophobic
   amino acids across the plasma membrane, which may occur as a
   consequence of membrane permeabilization by ethanol.

   The increased accumulation of several metabolites known for their
   function as cellular stress protectants was also identified in yeast
   cells growing under ethanol stress. This was the case of L-proline and
   trehalose, whose accumulation in yeast cells [188][62], [189][63],
   together with the increased expression of the corresponding
   biosynthetic genes [190][16], [191][24], [192][26] had been previously
   implicated in cell protection against ethanol stress. Both L-proline
   and trehalose have been shown to enhance the stability of membranes,
   and to contribute to protect proteins from denaturation and aggregation
   (reviewed in [193][64]), two important features for cells growing in
   the presence of ethanol stress, which induces low water activity
   stress. In this work we show that L-proline and trehalose accumulation
   occurs in an ethanol-dose dependent manner in yeast cells growing
   exponentially in the presence of this stress.

   This study also focused on the effect of FPS1 expression in the yeast
   metabolome, as summarized in [194]Fig. 6. Consistent with the decreased
   exponential growth rate registered upon FPS1 deletion under control
   conditions, it was interesting to observe that, even in the absence of
   ethanol stress, there are significant differences at the metabolome
   level between the fps1Δ deletion mutant and the corresponding parental
   strain. The major change registered was the 13-fold increase in the
   intracellular accumulation of glycerol in the absence of Fps1,
   accompanied by a decrease in extracellular glycerol concentration,
   which is in agreement with the proposed role for this aquaglyceroporin
   in facilitating the diffusion of glycerol across the plasma membrane
   [195][28], [196][65]. Simultaneously, a decrease in NAD^+ content was
   also observed in yeast cells devoid of FPS1, which may imply that
   glycerol-3-phosphate dehydrogenase activity, that catalyses a step
   required for NAD^+ regeneration and leads to glycerol formation, is
   inhibited by the over-accumulation of glycerol. Indeed, FPS1 deletion
   was previously shown to decrease not only glycerol transport, but also
   total glycerol production [197][65]. This result suggests that the
   fps1Δ deletion mutant may experience a permanent state of redox
   imbalance, similar to the one observed in this work to affect wild-type
   cells growing under ethanol stress. Consistent with the hypothesis
   raised herein that fps1Δ cells may experience reductive stress, Fps1
   was previously identified as conferring resistance to the reductive
   stress inducers dithiothreitol and mercaptoethanol [198][66]. Given the
   obtained results, fps1Δ cells may exhibit an increased susceptibility
   to ethanol stress due to their intrinsic redox imbalance, which may be
   further exacerbated under ethanol stress. The higher ethanol tolerance
   exhibited by cells expressing FPS1 [199][16] is hypothesized to be due
   to their increased ability to regenerate NAD^+, through the production
   and release of glycerol [200][28], and to the increased trehalose
   levels produced, assuming that a link between trehalose and glycerol
   synthesis may exist to fine-tune the concentration of these two
   molecules with partially overlapping functions as osmoprotectants.
   Consistent with this hypothesis is the increased glycerol content found
   in wild-type cells growing exponentially in the presence of ethanol
   stress, except for those exposed to 6% ethanol, which instead exhibit a
   very high increase in trehalose levels.

   The intra-cellular concentration of a number of amino acids, including
   L-tyrosine, L-phenylalanine, L-alanine, and L-glutamine, and
   TCA-related metabolites, including succinate, fumarate and citrate was
   found to be increased in the fps1Δ deletion mutant, when compared to
   the parental strain, mimicking ethanol stress repercussions exerted
   upon the parental strain. Particularly interesting is the observation
   that fps1Δ cells display a decreased concentration of trehalose both in
   control conditions and under ethanol stress. Given the importance of
   this metabolite for ethanol tolerance [201][64], the decreased ability
   of the fps1Δ deletion mutant to produce trehalose may also underlie its
   increased susceptibility towards ethanol stress.

Concluding Remarks

   Altogether, this study provides evidence that support the notion that
   ethanol stress induces reductive stress in yeast cells, which appears
   to be dealt with by the increase in the rate of NAD^+ regenerating
   bioreactions. The action of Fps1 in mediating the passive diffusion of
   glycerol is highlighted as a key factor in the maintenance of redox
   balance, an important feature for ethanol stress resistance. The
   obtained results further reinforce the idea that metabolomic approaches
   may be crucial tools to understand the function of membrane
   transporters/porins, such as Fps1, particularly by providing clues on
   their physiological substrates and/or the effect of their expression at
   the global metabolism level. By providing a systems level view of the
   metabolome changes contributing to ethanol stress tolerance in yeast,
   this metabolic analysis appears as an important approach to guide the
   design of process conditions and of more robust yeast strains optimized
   to improve industrial fermentation performance.

Supporting Information

   Figure S1

   Representative endo- and exo-metabolome profiles. High-resolution ^1H
   NMR spectra from the endo- and the exo-metabolome profiles of S.
   cerevisiae BY4741 and the fps1Δ deletion mutant cells harvested during
   the exponential phase of growth (OD[600nm] = 1.0) in the presence of
   different ethanol concentrations (% v/v). Spectra are representative of
   all the replicates obtained for each growth condition and were
   normalized to the reference TSP (δ = 0 ppm).

   (TIF)
   [202]Click here for additional data file.^ (850.6KB, tif)
   Figure S2

   Metabolite-metabolite correlations map. Metabolite to metabolite
   correlations based from the BY4741 parental strain endo-metabolome in
   the presence of different ethanol concentrations (0, 2, 4 and 6% v/v).
   For each metabolite, a characteristic bin in the NMR spectrum was used.
   Metabolites were grouped based on the PCA loadings considering all
   principal components of the PCA model (dendrogram using ward clustering
   distance measure). Each square represents the correlation between the
   metabolite heading the column and the metabolite heading the row. Each
   square indicates a given R^2 value (coefficient of determination)
   resulting from a Pearson correlation analysis in a false color scale
   (see color key at the bottom).

   (TIF)
   [203]Click here for additional data file.^ (215.7KB, tif)
   Table S1

   Metabolites identified in the endo-metabolome data.

   (XLSX)
   [204]Click here for additional data file.^ (11.1KB, xlsx)
   Table S2

   Metabolites identified in the exo-metabolome data.

   (XLSX)
   [205]Click here for additional data file.^ (9KB, xlsx)
   Table S3

   Endo-metabolome data.

   (XLSX)
   [206]Click here for additional data file.^ (18.2KB, xlsx)
   Table S4

   Metabolite analysis of the endo-metabolome of BY4741 parental strain.

   (XLSX)
   [207]Click here for additional data file.^ (19.2KB, xlsx)
   Table S5

   O-PLS-DA modelling of the endo-metabolome of BY4741 parental strain in
   the presence of different ethanol concentrations.

   (XLSX)
   [208]Click here for additional data file.^ (9.5KB, xlsx)
   Table S6

   Exo-metabolome data.

   (XLSX)
   [209]Click here for additional data file.^ (13.7KB, xlsx)
   Table S7

   Metabolite analysis of the exo-metabolome of BY4741 parental strain.

   (XLSX)
   [210]Click here for additional data file.^ (13.3KB, xlsx)
   Table S8

   O-PLS-DA modelling of the endo-metabolome of the BY4741 parental strain
   and Dfps1 deletion mutant in the presence of different ethanol
   concentrations.

   (XLSX)
   [211]Click here for additional data file.^ (9.4KB, xlsx)
   Table S9

   Metabolite analysis of the endo-metabolome of fps1Δ deletion mutant
   strain.

   (XLSX)
   [212]Click here for additional data file.^ (12.1KB, xlsx)
   Table S10

   Metabolite analysis of the endo-metabolome of the parental strain and
   of the fps1Δ deletion mutant.

   (XLSX)
   [213]Click here for additional data file.^ (13KB, xlsx)
   Table S11

   Metabolite analysis of the exo-metabolome of fps1Δ deletion mutant
   strain.

   (XLSX)
   [214]Click here for additional data file.^ (10.3KB, xlsx)
   Table S12

   Metabolite analysis of the exo-metabolome of the parental strain and of
   the fps1Δ deletion mutant.

   (XLSX)
   [215]Click here for additional data file.^ (11.7KB, xlsx)

Funding Statement

   This research was supported by FEDER, Fundacão para a Ciência e a
   Tecnologia (FCT) (ERA-IB/0002/2010 and PhD grants to ABL and FCR). The
   Portuguese National NMR Network is acknowledged for providing the
   authors with the NMR facility. The funders had no role in study design,
   data collection and analysis, decision to publish, or preparation of
   the manuscript.

References