Abstract
Glycolysis is central to energy metabolism in most organisms, and is highly regulated to enable optimal growth. In the yeast Saccharomyces cerevisiae, feedback mechanisms that control flux through glycolysis span transcriptional control to metabolite levels in the cell. Using a cellobiose consumption pathway, we decoupled glucose sensing from carbon utilization, revealing new modular layers of control that induce ATP consumption to drive rapid carbon fermentation. Alterations of the beta subunit of phosphofructokinase (PFK2), H+-plasma membrane ATPase (PMA1), and glucose sensors (SNF3, RGT2) revealed the importance of coupling extracellular glucose sensing to manage ATP levels in the cell. Controlling the upper bound of cellular ATP levels may be a general mechanism used to regulate energy levels in cells, via a regulatory network that can be uncoupled from ATP concentrations under perceived starvation conditions.
Importance Living cells are fine-tuned through evolution to thrive in their native environments. Genome alterations to create organisms for specific biotechnological applications may result in unexpected and undesired phenotypes. We used a minimal synthetic biological system in the yeast Saccharomyces cerevisiae as a platform to reveal novel connections between carbon sensing, starvation conditions and energy homeostasis.
Introduction
Most microorganisms favor glucose as their primary carbon source, as reflected in their genetic programs hard-wired for this preference. Central to carbon metabolism is glycolysis, which is finely tuned to the dynamic state of the cell due to the fact that glycolysis first consumes ATP before generating additional ATP equivalents. To avoid catastrophic depletion of ATP, the yeast Saccharomyces cerevisiae has evolved a transient ATP hydrolysis futile cycle coupled to gluconeogenesis (1). Glycolysis in yeast is also tightly coupled to glucose transport into the cell, entailing three extracellular glucose sensing mechanisms and at least one intracellular glucose signaling pathway (2).
Synthetic biology and metabolic engineering of yeast holds promise to convert this microorganism into a “cell factory” to produce a wide range of chemicals derived from renewable resources or those unattainable through traditional chemical routes. However, many applications require tapping into metabolites involved in central carbon metabolism, a daunting challenge as living cells have numerous layers of feedback regulation that fine-tune growth to changing environments. Cellular regulation evolved intricate networks to maintain and ensure cell survival. For example, S. cerevisiae has evolved to rapidly consume high concentrations of glucose through fermentation, while repressing the expression of other carbon consumption pathways, an effect termed glucose repression. When perturbed genetically, regulatory networks such as those in glucose repression often generate undesirable or unexpected phenotypes.
For yeast to be useful in producing large volumes of renewable chemicals or biofuels, it will be important to expand its carbon utilization to include multiple sugars in the plant cell wall. One promising approach that helps overcome glucose repression and allows simultaneous utilization of different sugars is cellobiose consumption (3). Cellobiose is a disaccharide with two units of glucose linked by a ß-1,4 glycosidic bond. Cellobiose consumption using a minimal additional pathway in yeast—a cellodextrin transporter (CDT-1) and intracellular ß-glucosidase (4)–avoids glucose repression by importing carbon in the form of cellobiose instead of glucose. The cellodextrin transporter allows cellobiose to enter the cell where it is hydrolyzed to glucose and consumed via the native glycolytic consumption pathway. By moving glucose production into the cell, the Neurospora crassa-derived cellobiose consumption pathway is nearly the minimal synthetic biological module imaginable in S. cerevisiae, comprised of just two genes. Nevertheless, in S. cerevisiae the cellobiose consumption pathway is inferior to consumption of extracellular glucose in terms of rate and results in a prolonged lag phase (5). Previous efforts to understand the impact of cellobiose consumption on the physiology of S. cerevisiae using transcriptional profiling revealed that cellobiose improperly regulates mitochondrial activity and amino acid biosynthesis, both of which are tightly coupled to the transition from respiration to fermentation (5).
Since glycolytic enzymes are regulated mostly at the post-transcriptional level (6), we probed cellobiose consumption in S. cerevisiae at the metabolite level. We found that key metabolites in glycolysis are highly imbalanced, leading to low flux through glycolysis and slow fermentation. We also found that excess ATP levels drive the imbalance, and identified a new potential regulatory role of glucose sensors in cellular ATP homeostasis.
Results
Metabolite profiling of cellobiose utilizing S. cerevisiae
S. cerevisiae cells engineered with the cellobiose consumption pathway exhibits a prolonged lag phase, with decreased growth and carbon consumption rates in comparison to when glucose is provided (Figure S1A) (5). We hypothesized that cellobiose consumption results in an ATP deficit in glycolysis relative to glucose, due to the fact that the cellodextrin transporter (CDT-1) in the cellobiose utilizing pathway is a proton symporter, requiring ATP hydrolysis for cellobiose uptake (7). Moreover, under anaerobic conditions, ATP production is limited to substrate-level phosphorylation, further restricting ATP availability. We measured the steady-state concentrations of ATP and other metabolites in central carbon metabolism in yeast fermenting cellobiose compared to glucose. Of the 48 compounds analyzed, the abundance of 25 compounds was significantly different between cellobiose and glucose-fed samples (Figure S1B). Surprisingly, ATP levels increased by 6-fold in the cellobiose grown cells (Figure 1A). The relative abundance of compounds in glycolysis—fructose 6-phosphate (F6P), glucose 6-phosphate (G6P), glucose and pyruvate—increased by 444-, 81-, 7- and 3-fold, respectively, while that of phosphoenolpyruvate (PEP) decreased by 2-fold (Figure 1A, B). These results suggest that the yeast cells underwent drastic physiological changes, reflected in metabolite levels, when cellobiose was provided in place of glucose.
Phosphofructokinase-1 inhibition by excess ATP
Given the dramatic buildup of glucose, G6P and F6P intermediates prior to the phosphofructokinase (PFK1) reaction in glycolysis (Figure 1B, 2A), we reasoned that Pfk1 might be a major bottleneck in cellobiose consumption. Pfk1 catalyzes the phosphorylation of F6P, using one ATP and yielding fructose 1,6-bisphosphate (F1,6BP) as a product. As the second committed step in glycolysis, Pfk1 is heavily regulated—with ATP acting as an allosteric inhibitor and AMP and fructose 2,6-bisphosphate serving as activators (8–10).
To test whether allosteric inhibition of Pfk1 by ATP limited cellobiose fermentation, a mutation in Pfk1 that makes the enzyme ATP-insensitive (P722L in the Pfk1 beta subunit, note the original publication referred to this mutation as P728L (11)) was introduced into the chromosomally encoded PFK1 gene (mutation here termed pfk1m) in the cellobiose utilizing strain. This mutation was previously shown to reduce ATP inhibition but also AMP and fructose 2,6-bisphosphate activation of Pfk1 in S. cerevisiae (11). We chose this mutation over an ATP-insensitive, AMP/F2,6BP-sensitive mutant phosphofructokinase (10) because the latter's phenotype has not been evaluated in S. cerevisiae. High initial cell densities were used hereafter, as the focus of this study is sugar consumption rather than growth.
Consistent with allosteric inhibition of Pfk1 by ATP, the cellobiose consumption efficiency (Ec) of the pfk1m strain increased by 33% in comparison to the strain with wild-type Pfk1 (Figure 2B). In these high cell densities, negligible changes in growth rate were observed (Figure 2C). The relative abundance of G6P and F1,6BP decreased by 47% and 34%, respectively, while that of ATP remained relatively unchanged (Figure 2D). The unchanged ATP level was expected as the ATP requirement for the cellobiose consumption pathway was likely offset by the ATP generated as part of carbon metabolism. These results indicate that the 6-fold increase in cellular ATP concentrations allosterically inhibited Pfk1, resulting in accumulation of glucose, G6P and F6P, which eventually slowed down cellobiose consumption.
Limited activity of plasma membrane ATPase
Although the pfk1m strain partially increased the rate of cellobiose fermentation, cellular ATP remained elevated relative to glucose fermentation. It is unlikely that ATP production was the cause of the difference, as fermentation is limited to substrate-level phosphorylation under anaerobic conditions regardless of carbon source. We therefore tested whether the activity of one of the major ATP sinks in yeast, the plasma membrane ATPase (Pma1) was responsible for the ATP buildup. Pma1 hydrolyzes 25-40% of cellular ATP in yeast (12) and is heavily regulated by glucose (13).
A constitutively active mutant form of PMA1 (pma1-Δ916, here abbreviated pt) (14) was introduced into the endogenous PMA1 locus in the cellobiose utilizing strain. This mutation results in high Pma1 ATPase activity even in carbon starvation conditions (14). The Ec of the pt strain was 4 times that of the control (Figure 2B), whereas the growth rate of pt strain was only slightly faster than the Pma1 WT strain (Figure 2C). As expected, we observed a 66% decrease in cellular ATP levels in the pt strain in comparison to the wild-type control (WT, i.e. cellobiose pathway only) (Figure 2D). In addition, the concentrations of G6P and F1,6BP decreased by 58% and 93%, respectively, relative to strains expressing wild-type PMA1. Notably, these concentrations dropped more than when the ATP-insensitive PFK1 mutant was introduced (Figure 2D). These results suggest that increased Pma1 ATPase activity improved cellobiose fermentation. We hypothesize that the drastic decrease in F1,6BP level and the fast growth rate were the result of rapid glycolytic flux, as the cells experience low cellular ATP levels in the pt strain.
Next, we observed the phenotypes of pfk1m-pt double mutant strain. The cellobiose consumption profile of a pfk1m-pt double mutant was identical to that of the pt strain (Figure 2A). However, the growth rate and relative abundance of G6P, F1,6BP and ATP of the pfk1m-pt differed from the pt strain (Figure 2C,D). In fact, their levels were similar to those in the pfk1m strain. These results imply that while the ATP might be hydrolyzed rapidly due to the pt effect, the removal of ATP inhibition on pfk1 allowed enough ATP to be regenerated downstream that no growth burst was observed. The underlying explanation of the mixed phenotypes will require future experiments to dissect how Pfk1 exerts allosteric control on glycolysis and ATP levels.
Carbon starvation-like state of the plasma membrane ATPase
Although cellobiose theoretically provides the same energy and carbon availability to cells as glucose, its releases glucose only after intracellular hydrolysis by β-glucosidase. Thus the cellobiose consumption system used here does not generate extracellular glucose, which acts as a crucial signaling molecule for yeast carbon metabolism. Taken together with the observation that increased ATPase activity in the pt strain increased cellobiose consumption efficiency, we wondered whether the limited Pma1 activity in cellobiose-fed cells is due to the absence of extracellular glucose in the media. Transcriptionally, the presence of glucose increases PMA1 mRNA levels by 2-4 times via the regulation of Rap1, Gcr1 and Sir2 (15–17). Consistent with the requirement for extracellular glucose sensing, previous RNA sequencing experiments revealed a 40% decrease in PMA1 transcript levels when cellobiose was provided in place of glucose (5). However, although transcriptional regulation of PMA1 is important, it is slower than post-transcriptional regulation and results in smaller changes (13, 18).
In the presence of glucose, phosphorylation of Ser-899 decreases Pma1's Km and Ser-911/Thr-912 increases Pma1's Vmax for ATP, respectively (13, 19, 20). Given the 6-fold excess amount of ATP observed in cellobiose utilizing conditions (Figure 1A), the effective velocity of the Pma1 reaction is likely approaching Vmax regardless of the phosphorylation status at Ser-899 (21). The Km of ATP hydrolysis by Pma1 has been reported to increase approximately 3-fold from 1.2 mM in glucose-fermenting cells to 4.0 mM in glucose-starved cells, while a 10-fold decrease in Vmax was reported in the same study (22). We reasoned that the 6-fold increase of ATP in cellobiose-fed cells should result in ATP concentrations in excess of the Km for Pma1, resulting in Pma1 activity being limited by its Vmax. Thus, in this study, we did not investigate the phosphorylation of Ser-899 and chose to investigate whether Vmax-determining phosphorylation states of Ser-911 and Thr-912 might play a major role in establishing the efficiency of cellobiose fermentation (Figure 3A).
Combinatorial mutations of Ser-911/Thr-912 to alanine and aspartic acid were introduced into the endogenous PMA1 gene to prevent or mimic phosphorylation, respectively. We were unable to obtain strains with pma1-S911A/T912A and pma1- S911A/T912D, potentially because the combinations were lethal. All mutant strains whose Pma1 S911 position was mutated to aspartic acid consumed cellobiose more efficiently in comparison to when the S911 position remained unchanged (Figure 3B). By contrast, mutating Pma1 T912 to aspartic acid did not show a correlation with the cellobiose consumption phenotype. These results suggest that phosphorylation of Pma1 at S911 was lacking when cellobiose was provided as a sole carbon source.
Positive effects of extracellular glucose sensor deletions
According to the above mutational analysis, the Pma1 phosphorylation state of cellobiose-fed cells was similar to that in carbon starvation conditions (Figure 3A) (20). In the previously published experiments (20), carbon-starved cells were prepared by incubating mid-exponential phase cells in media without glucose. In such conditions, neither extracellular nor intracellular glucose is present. For the cellobiose-fed cells, based on the relatively high level of intracellular glucose we detected (Figure 1A), it is unlikely that the intracellular glucose induced Pma1 carbon starvation. Additionally, since intracellular glucose metabolism is expected in cellobiose-fed cells, its effect on Pma1 carbon starvation was also ruled out (23). We therefore tested the role of extracellular glucose in regulating Pma1 activity. In cellobiose-fed cells, glucose is not provided as part of the media, and thus the extracellular glucose is absent. We hypothesize that the extracellular glucose is likely essential for full activation of Pma1 through S911 phosphorylation.
Snf3, Rgt2 and Gpr1 are the three known sensors of extracellular glucose in S. cerevisiae. Snf3 and Rgt2 mainly regulate glucose transport while Gpr1 controls cell physiology via an interaction with Gpa2 to activate protein kinase A and cAMP synthesis (23). To mimic the presence of extracellular glucose, constitutively active mutations (snf3 R229K, rgt2 R231K and gpa2 R273A) were introduced into the endogenous loci to probe the role of each glucose-sensing pathway (24, 25). Surprisingly, the cellobiose consumption efficiency of all the three mutant strains decreased by ∼25% (Figure S2A). We then inverted the genetic modifications by deleting SNF3, RGT2 and/or GPA2. Notably, the triple glucose-sensing deletion strain (snf3Δrgt2Δgpa2Δ, or srgΔ) showed a 275% increase in Ec (Figure 4A).
Combinatorial deletions revealed that the Gpr1 pathway did not contribute to improved cellobiose fermentation, but combining the SNF3 and RGT2 deletions (srΔ) was necessary and sufficient to replicate the Ec of the triple deletion strain (Figure 4A, Figure S2B, C). Consistent with the observed Ec values, the intracellular ATP levels of srgΔ and srΔ decreased by 41% and 18% respectively, while those in the individual-deletion strains snf3Δ and rgt2Δ remained unchanged (Figure 4A). These results reveal a negative correlation between Ec and cellular ATP levels (Figure 4B) and that Snf3 and Rgt2 acted together to regulate cellular ATP levels, in addition to regulating glucose transport.
Although the additional deletion of GPA2 (gpa2Δ) in the srΔ strain did not further improve Ec (Fig 4A), it reduced the relative abundance of ATP by 28%, implying that the Gpr1 pathway has a separate mechanism to control cellular ATP levels that does not directly affect carbon metabolism. Consistently, gpa2Δ had a negative or neutral impact on cellobiose consumption (Figure S2). The decrease in ATP level may be a result of altered cellular activities, controlled by Gpr1 via the Tor and cAMP-PKA-Ras pathways (23). The relationship between Gpr1-regulated ATP levels and carbon metabolism remains to be discovered. Since gpa2Δ did not have a direct effect on Ec, it was not investigated further in this study.
Snf3/Rgt2 regulation of cellular ATP levels
To examine whether Snf3/Rgt2 regulated the cellular ATP level in cellobiose fermentations via Pma1, an snf3Δ rgt2Δ pma1-Δ916 strain (srΔ-pt) was constructed. Notably, the Ec of the srΔ-pt strain increased more than 4 times in comparison to the wild-type control (Figure 4A, Figure 5A). The improvement was additive, within the range of the ΔEc summation of srΔ and pma1-Δ916 strains relative to wild-type (Figure 5A). Although ATP levels decreased in a nearly linear fashion as a function of Ec (Figure 4B), it is not presently possible to ascertain whether the srΔ and pma1-Δ916 mutations act entirely independently due to limitations in measurement accuracy (Figure 5A).
To further determine the relationship between Snf3/Rgt2 and Pma1, the vanadate-specific ATPase activity of Pma1 (26) from different strains consuming cellobiose was analyzed (Figure 5B). Consistent with the constitutively active nature of the pt mutation, the activities of Pma1 in the pt and srΔ-pt strains were higher than those observed in the WT or srΔ strains, respectively. Addition of srΔ decreased the Pma1 ATPase activities by 25% and 32% in WT and pt strains, respectively. In other words, the absence of Snf3 and Rgt2 led to a partial decrease in Pma1 ATPase activity, which implied that Snf3/Rgt2 partially activated Pma1 ATPase activity in the absence of glucose.
Discussion
To identify the effects of a minimal alteration to carbon metabolism in yeast, we chose a cellobiose-consumption pathway composed of two genes and analyzed its cellular metabolite profiles in comparison to cells provided with glucose, yeast's preferred carbon source (Figure 6). Here we focus on the cellobiose consumption efficiency (Ec), as Ec linearly correlated with ethanol production rate, while ethanol yield remained mostly unchanged (Figure S3).
More than half of the metabolites significantly changed in abundance when cellobiose was provided in place of glucose. The buildup of G6P, F6P and ATP in S. cerevisiae fermenting cellobiose suggested that Pfk1 was one of the bottlenecks in the process. Pfk1 is subjected to complex allosteric regulation, including inhibition by ATP and activation by AMP and fructose 2,6-bisphosphate (F2,6BP) (8–10). The Pfk1 bottleneck was partially relieved in cells expressing an ATP/AMP/F2,6BP-insensitive PFK1 allele, while the ATP level remained elevated. These results contrast with previous studies that identified ATP depletion and the buildup of fructose-1,6-bisphosphate–the metabolite immediately downstream of Pfk1–as a weak link in glycolysis (1). Although we did not investigate the effect of AMP and F2,6BP activation since their changes between glucose and cellobiose conditions were less than 2 fold and they did not meet the significance threshold of a p-value less than 0.01, it is possible that they could influence cellobiose consumption efficiency.
ATP is central to a cell's energy currency, but too much ATP is not necessary beneficial (27, 28). In fact, we observed a negative correlation between cellular ATP levels and cellobiose consumption efficiency (Figure 4B). A similar correlation has been reported for glucose as a carbon source, suggesting metabolic uncoupling of energy homeostasis in yeast cells (29). We propose that intracellular glucose concentrations– generated by cellobiose hydrolysis in our experiments–and glucose metabolism (23) are insufficient to trigger glucose activation of key metabolic pathways and enzyme activity. For example, we found that the ATP-dependent proton pump Pma1 existed in a carbon-starvation like state during cellobiose fermentation, and was partially responsible for the aberrant accumulation of ATP. These results suggest that neither intracellular glucose nor glucose metabolism are sufficient to fully activate Pma1. A previous study showed the lack of phosphorylation of S899 and S911/T912 in Pma1, in a hexokinase/glucokinase deletion strain (hxk1Δ hxk2Δ glk1Δ) provided with glucose, suggesting that phosphorylation of these residues requires glucose metabolism (30). Together with our results, we propose that the activation of Pma1 through S911 phosphorylation requires both extracellular glucose and glucose metabolism. Our results reveal that the cellobiose utilization system allows uncoupling of glucose metabolism and intracellular glucose from extracellular glucose signaling. Future experiments will be required to reveal why ATP was not consumed by other cellular processes triggered under starvation (31).
Cytosolic pH is also a key regulator of carbon utilization (32), and is likely to be impacted by the use of the proton symporter CDT-1 for cellobiose import and the resulting low activity of Pma1. High cytosolic pH is necessary and sufficient to activate Tor-Ras-PKA activities, which are downstream of Gpr1 glucose sensing pathway (32). By contrast, the proton symporter CDT-1 and low activity of Pma1 may result in a low cytosolic pH. However, cytosolic pH alone is unlikely to determine the cellobiose consumption efficiency (Ec) as the strain with an ATP/AMP/F2,6BP-insensitive PFK1 allele showed improved Ec but unaltered cellular ATP levels. Furthermore, the inactivation of the Gpr1 pathway resulted in decreased cellular ATP but unaltered Ec. Glucose storage, i.e. in the form of trehalose, may be interconnected through the Gpr1 pathway because Ras-cAMP activates trehalase required to break down trehalose—a phenomenon observed when gluconeogenesis is switched to glycolysis (33). Trehalose cycling has been shown to lead to an imbalanced state of glycolysis (1). The relationship between carbon storage and Ec will require future studies to examine this relationship.
We also found that the well-studied extracellular glucose sensors Snf3/Rgt2 exhibited a novel role in cellular ATP homeostasis partially through the major plasma membrane ATPase Pma1. Deletion of extracellular glucose sensors (Snf3/Rgt2) increased cellobiose consumption efficiency and partially restored ATP levels. Interestingly, the absence of the Snf3/Rgt2 decreased Pma1 ATPase activities, an effect that should have led to an increase in ATP level. The restored low ATP level observed in the srΔ strain implied that Snf3/Rgt2 regulated cellular ATP level with additional mechanism(s) other than through Pma1. It is known that deletion of SNF3 and RGT2 slows down glucose consumption (34), due to the inability of these strains to degrade Mth1/Std1, which block the promoter regions of hexose transporters required for optimal glucose import (35–38). Unlike glucose, cellobiose does not signal Mth1 degradation even with intact Snf3/Rgt2 (38). Thus, genes downstream of Mth1 regulation, including hexose transporters, are not expected to be responsible for the improved Ec and decreased cellular ATP levels observed in srΔ. Consistent with this model, no growth defect is observed in a mth1Δ strain growing on glucose, suggesting that Snf3/Rgt2 has additional regulatory nodes other than Mth1 (34). Future transcriptional profiling and ribosome profiling experiments will be required to reveal the additional Snf3/Rgt2 roles in cellular ATP homeostasis.
The present systems-level study of a minimal synthetic biology pathway for cellobiose consumption revealed the dramatic impact of decoupling extracellular and intracellular glucose sensing, resulting in an overabundance of ATP in cells. The inability of S. cerevisiae to catabolize ATP for cellular processes in the presence of intracellular glucose and glucose metabolism but in the absence of extracellular glucose resulted in slow fermentation. Thus, ATP levels must be kept in a relatively narrow range for optimal fermentation and to allow robust startup of glycolysis, yet yeast seems to lack a direct mechanism to monitor ATP concentrations. For example, a dynamic model showed that a small concentration difference of inorganic phosphate, a product of ATP hydrolysis, could alter cell fate from a stable glycolytic steady state to an imbalanced dead-end state (1). Here, we found that the extracellular glucose sensing by Snf3/Rgt2 required for optimal glucose fermentation (2) can be uncoupled from the role of these receptors in regulating ATP homeostasis under carbon starvation conditions. It will be important in the future to map the fully regulatory pathways of ATP homeostasis leading from Snf3/Rgt2 and, independently, terminating in Pma1.
Materials & Methods
Yeast strains, media and anaerobic fermentation
The S. cerevisiae background strain used in this study was S288C ura3::PPGK1-cdt-1 N209S/F262Y-TADH1lyp1::PTDH3-gh1-1 (codon optimized)-TCYC1 derived by chromosomal DNA library selection (39). The strain was subjected to further modifications using the CRISPRm system (39). The list of strains constructed, CRISPRm guides and primers used are included in Table S1.
Seed cultures for cellobiose fermentation experiments were grown in 20 g/L glucose modified optimal minimal media (oMM) (5) and harvested at mid-log phase. All cellobiose fermentation experiments were conducted under strict anaerobic conditions, in 80 g/L cellobiose oMM media at an initial OD600 of 20, using 10 mL serum flasks containing 5 mL fermentation in 2-5 biological replicates. The flasks were incubated at 30°C, 220 rpm. The cellobiose consumption efficiency (Ec) was defined as the inverse of the area under the curve of extracellular cellobiose concentration over time.
Analytical analysis of yeast metabolites
Extracellular cellobiose concentrations were determined by high performance liquid chromatography on a Prominence HPLC (Shimadzu, Kyoto, Japan) equipped with Rezex RFQ-FastAcid H 10 × 7.8 mm column. The column was eluted with 0.01 N of H2SO4 at a flow rate of 1 mL/min, 55°C.
For the metabolite profiling comparison between glucose and cellobiose (modified from (40)), equal amounts of yeast cells at mid-exponential phase of anaerobic sugar consumption (10 g/L cellobiose or glucose) were harvested (final pellet OD600 equivalent to 5). The samples were quenched in 180 µL of 40:40:20 acetonitrile:methanol:water. Following the addition of 10 nmols of d3 serine (as an internal standard), the mixtures were vortexed and centrifuged at 13,000 rpm for 10 minutes. The supernatants were injected onto an Agilent 6460 QQQ LC-MS/MS and the chromatography was achieved by normal phase separation with a Luna NH2 column (Phenomenex) starting with 100% acetonitrile with a gradient to 100% 95:5 water acetonitrile. 0.1% formic acid or 0.2% ammonium hydroxide with 50 mM ammonium acetate was added to assist with ionization in positive and negative ionization mode, respectively. Five biological replicates were used for each sample analyzed.
For targeted intracellular metabolite comparisons, yeast cells equivalent to 20 OD600 units were harvested and filtered through a 0.8 µm nylon membrane, prewashed with 3mL water, followed by another 3 mL water wash after cell filtration. The membranes were placed in 1.5mL extraction solution (0.1 M formic acid, 15.3 M acetonitrile) flash-frozen in liquid nitrogen, and stored at −80°C. Before analysis, the extracts were vortexed for 15 minutes and centrifuged to collect the supernatants at 4°C. Glucose 6-phosphate and fructose 1,6-bisphosphate were separated and identified using a 1200 Series liquid chromatography instrument (Agilent Technologies, Santa Clara, CA). 1 µL of each sample was injected onto an Agilent Eclipse XDB-C18 (2.1 mm i.d., 150 mm length, 3.5 µm particle size) column with a Zorbax SB-C8 (2.1 mm i.d., 12.5 mm length, 5 µm particle size) guard column and eluted at 25 °C and a flow rate of 0.2 mL/min with the following gradient (modification from (41)): 15 min isocratic 100% buffer A (10 mM tributylamine/15 mM acetic acid), then in 15 min with a linear gradient to 60% buffer B (methanol), 2 min isocratic 60% B, then 10 min equilibration with 100% buffer A. The eluent from the column was introduced into a mass spectrometer for 25 minutes after the first 10 minutes. Mass spectrometry (MS) was performed on an LTQ XL ion trap instrument (Thermo Fisher Scientific, San Jose, CA) with an ESI source operated in negative ion mode. The MS settings were capillary temperature 350 °C, ion spray voltage 4.5 kV, sheath gas flow: 60 (arbitrary units), auxiliary gas flow 10 (arbitrary units), sweep gas flow 5 (arbitrary units). For the MS/MS product ion scan, the scan range was m/z 80 to m/z 300. The compounds G6P at m/z 259.1 and F16BP at m/z 339.1 were isolated with an m/z 2 isolation width and fragmented with a normalized collision-induced dissociation energy setting of 35% and with an activation time of 30ms and an activation Q of 0.250.
The significance threshold between cells provided with cellobiose and cells provided with glucose was set at a p-value of 0.01. Five biological replicates were used in each sample group. Only the metabolites with higher than a 2 fold-change between each sample group were included in the analysis.
Plasma membrane isolation
Strains were subjected to cellobiose fermentation under anaerobic conditions. Yeast cells with an OD600 equivalent to 40 were harvested at mid-log phase and flash frozen in liquid nitrogen. Membrane fractions were extracted based on the protocol published in (42).
Pma1 ATPase activity assay
The ATPase assay described in (26) was modified as follows. 30 µg of the isolated membrane fraction was incubated in assay buffer (50 mM MES pH 5.7, 10 mM MgSO4, 50 mM KCl, 5 mM NaN3, 50 mM KNO3) with and without 3 mM orthovanadate for 25 minutes at 30 °C. 1.8 mM ATP was added to start the 100 uL reactions. The reactions were incubated at 30 °C for 15 minutes, then the membranes were isolated from the reactions by centrifugation at 13,000x g for 10 minutes at 4°C. The released inorganic phosphate was measured in the supernatant using the ATPase/GTPase Activity Assay Kit (Sigma-Aldrich) based on the manufacturer's protocol. The specific Pma1 ATPase activities were calculated by subtracting the concentration of released inorganic phosphate in reactions provided with orthovanadate from those without.
Yeast cell-based cellobiose uptake assay
The cell-based cellobiose uptake assay was modified from (43). Yeast strains were grown to mid-exponential phase in 2% oMM glucose, washed with assay buffer (5 mM MES, 100 mM NaCl, pH 6.0) three times and resuspended to a final OD600 of 10. Equal volumes of the cell suspension and 200 µM cellobiose were mixed to start the reactions, which were incubated at 30°C with continuous shaking for 15 minutes. The reactions were stopped by adding 150 µL of supernatants to 150 µL 0.1 M NaOH. The concentrations of the remaining cellobiose were measured using an ICS-3000 Ion Chromatography System (Dionex, Sunnyvale, CA, USA) equipped with a CarboPac® PA200 carbohydrate column. The column was eluted with a NaOAc gradient in 100 mM NaOH at a flow rate of 0.4 mL/min, 30°C.
Conflict of Interest
The authors declare that they have no conflict of interest.
Author contributions
All authors contributed to the design of the experiments. KC and DIB carried out the experiments. DKN and JHDC aided in interpretation of the systems-level experiments. KC wrote the manuscript, with editing from DIB, DKN, and JDHC.
Supplementary Figure legends
Figure S1. Metabolite profile of cells provided with glucose or cellobiose. (A) cell density and sugar consumption profiles of the strains used for metabolite profiling experiments. (B) Heatmap representation of steady state intracellular metabolite abundance of cells provided with glucose or cellobiose under anaerobic conditions. Shown are the results of 5 biological replicates. Asterisks (*) mark identified compounds that were significantly different between glucose and cellobiose conditions at a significance threshold of a p-value < 0.01.
Figure S2. Cellobiose consumption profiles and efficiency of Snf3, Rgt2 and Gpa2 mutants. (A) Cellobiose consumption profiles of strains with consitutively active Snf3 (R229K), Rgt2 (R231K) and Gpa2 (R273A). (B) Cellobiose consumption profiles of SNF3, RGT2, and GPA2 double deletion combinations. (C) Cellobiose consumption profiles of SNF3 and RGT2 single deletion in comparison to the srΔ, srgΔ and srΔ-pt strains. (D) Cellobiose consumption profiles of GPA2 deletion (gΔ) in comparison to the WT strain. In panels A, B, C, and D, the results of 3 biological replicates are shown.
Figure S3. Relationship of ethanol productivity parameters and cellobiose consumption efficiency (Ec). Ethanol production rate and the final concentration of ethanol are plotted against Ec.
Table S1: List of strains constructed, CRISPRm guides and primers.
Acknowledgements
The authors thank Raissa Estrela, Dr. Xin Li, Dr. Ligia Acosta-Sampson, Dr. Yuping Lin and Dr. Matt Shurtleff for helpful discussions. This work was supported by funding from Energy Biosciences Institute to JHDC and from National Institutes of Health (R01CA172667) to DKN.
Footnotes
KC: kchomv{at}gmail.com
DIB: dbenjami{at}stanford.edu
DKN: dnomura{at}berkeley.edu
JHDC: jcate{at}lbl.gov