New Insights into Trehalose Metabolism by Saccharomyces cerevisiae: NTH2 Encodes a Functional Cytosolic Trehalase, and Deletion of TPS1 Reveals Ath1p-Dependent Trehalose Mobilization

In the yeast Saccharomyces cerevisiae, the synthesis of endogenoustrehalose is catalyzed by a trehalose synthase complex, TPS,and its hydrolysis relies on a cytosolic/neutral trehalase encodedby NTH1. In this work, we showed that NTH2, a paralog of NTH1,encodes a functional trehalase that is implicated in trehalosemobilization. Yeast is also endowed with an acid trehalase encodedby ATH1 and an H⁺/trehalose transporter encoded by AGT1, whichcan together sustain assimilation of exogenous trehalose. Weshowed that a tps1 mutant defective in the TPS catalytic subunitcultivated on trehalose, or on a dual source of carbon madeof galactose and trehalose, accumulated high levels of intracellulartrehalose by its Agt1p-mediated transport. The accumulated disaccharidewas mobilized as soon as cells entered the stationary phaseby a process requiring a coupling between its export and immediateextracellular hydrolysis by Ath1p. Compared to what is seenfor classical growth conditions on glucose, this mobilizationwas rather unique, since it took place prior to that of glycogen,which was postponed until the late stationary phase. However,when the Ath1p-dependent mobilization of trehalose identifiedin this study was impaired, glycogen was mobilized earlier andfaster, indicating a fine-tuning control in carbon storage managementduring periods of carbon and energy restriction.

INTRODUCTION

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INTRODUCTION

Trehalose is a nonreducing disaccharide of ${alpha}$ (1,1)-linked glucosepresent in many organisms, including bacteria, fungi, insects,and plants (12). Fungal cells can accumulate this disaccharideto up to 15% of the cell dry mass depending on growth conditionsand environmental stress (for a review, see reference 15). Geneticand metabolic studies led to the proposal that trehalose playstwo distinct functions in living cells. On the one hand, itacts as a stress protectant of proteins and biological membranesagainst adverse conditions (39). On the other hand, it may playa role as a storage carbohydrate in the yeast Saccharomycescerevisiae. This latter function was suggested by the rapidmobilization of intracellular trehalose upon the resumptionof growth of starved cells on a fresh glucose medium and duringspore maturation and germination, as well as during oscillatoryevents in continuous or batch yeast cultures (22, 28). Trehaloseis also consumed very slowly when cells are maintained in nongrowingconditions, and this breakdown often follows that of glycogen,the major storage carbohydrate in yeast (26, 32), although themobilization pattern of one glucose store before the other canbe dependent on the growth conditions (17, 34, 37).

In the yeast S. cerevisiae, the intracellular level of trehaloseis the result of a well-regulated balance between enzymaticsynthesis and degradation. The synthesis of trehalose is catalyzedby an UDP-glucose-dependent trehalose synthase (TPS) proteincomplex encoded by four genes. TPS1 and TPS2 encode the trehalose-6-phosphatesynthase and trehalose-6-phosphate phosphatase, respectively,and TPS3 and TSL1 code for two regulatory subunits of the TPScomplex (for a review, see reference 15). The tps1 mutants notonly lack the ability to synthesize trehalose but also exhibitseveral pleiotropic defects including an inability to grow onglucose (3, 20), alterations in glycogen synthesis (6, 42) andin respiration (18), and a sporulation deficiency (9). Altogether,these phenotypic traits support the idea that Tps1p plays akey regulatory role in the control of yeast physiology (15,16, 41). Hydrolysis of trehalose can be carried out by two enzymaticsystems: a neutral trehalase encoded by NTH1 (24a) and an acidtrehalase encoded by ATH1 (10). A third gene, namely, NTH2,a paralog of NTH1 (77% identity at the protein level) existsin the yeast genome, but no trehalase activity has been associatedwith its product so far. Moreover, only Nth1p is known to catalyzethe intracellular mobilization of trehalose (31), and the apparentlack of Ath1p to carry out this function could be attributedto its exclusion from the cytosolic compartment (23).

Trehalose is also a potential carbon source for many yeast species(2) including the yeast S. cerevisiae. Recently, we demonstratedthat the assimilation of exogenous trehalose takes place bytwo different enzymatic pathways (23). The first one relieson Ath1p, whose major activity was measured extracellularlyand thereby hydrolyzes at the cell surface the disaccharideinto two glucose units, which are thereafter taken up by hexosetransporters. The second pathway consists of a coupling betweenthe Agt1p-mediated trehalose transport (36) and the Nth1p-dependenthydrolysis of the imported disaccharide (23). It is noteworthythat the expression of AGT1, which encodes a high-affinity H⁺-disaccharidesymporter and belongs to the major facilitator superfamily (fora review, see reference 8), is dependent on the MAL system (19).This feature explains why the Agt1-Nth1p pathway is defectivein mal-negative strains, as for instance in the BY background(4).

During our investigation of the physiological properties ofS. cerevisiae tps1 mutants cultivated on trehalose or on a dualcarbon source, i.e., galactose and trehalose, we observed thatthe Agt1p-dependent accumulation of intracellular trehalosewas followed by a rapid mobilization of this intracellular store.This mobilization occurred when the exogenous carbon sourcewas no longer available, and surprisingly, before that of glycogen.Our work led to the finding that the major degradation of endogenoustrehalose takes place in the absence of Nth1p and Nth2p. Wehere report that the mobilization of intracellular trehaloseinvolved its export and cleavage into glucose at the cell surfaceby Ath1p.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Media and culture conditions.
Yeast cells were routinely cultured in shake flasks (1-literErlenmeyer flasks with a working volume of 200 ml) at 30°Cin YN synthetic medium (1.7 g liter^–1 yeast nitrogen basewithout amino acids and without ammonium sulfate [Difco Laboratories])and 5 g liter ^–1 ammonium sulfate. The carbon source waseither 2% trehalose or 2% galactose plus 1% trehalose (wt/vol).YN medium was buffered at pH 4.8 by the addition of 14.3 g liter^–1succinic acid and 6 g liter^–1 NaOH (23). The growth wasfollowed by measuring the absorbance at 600 nm with an EasyspecIV spectrophotometer (Safas, Monaco, France). Optical densityat 600 nm (OD₆₀₀) values could be converted to cell dry massby use of a calibration curve that was previously establishedfor the CEN.PK113-7D strain under these growth conditions, i.e.,0.41 g liter^–1 of dry cell for one OD₆₀₀ unit. The maximalspecific growth rate (µ_max) of the cultures was calculatedby fitting an exponential regression over the experimental datapoints as described in reference 32. These points were selectedso that they led to a correlation coefficient (r²) higher than0.998.

All experiments reported in this work have been performed atleast three times, starting from independent precultures andindependent medium preparation. For the sake of clarity, thefigures report data from one representative experiment only.

Cell transfer and drug treatment.
For transfer of (pre)stationary-phase cells, yeast culture wasdivided into equal parts and centrifuged for 2 min at 4,000x g. The pellets were rinsed once with sterile water to discardextracellular trehalose traces. They were resuspended in eitherthe initial YN trehalose culture medium or a fresh YN mediumwithout a carbon source buffered at pH 5 or 7. By use of thesame procedure, yeast cells were also suspended in a trehalose-depletedYN medium which was obtained from stationary-phase Ath1⁺ cells.The inhibition of sugar uptake was carried out by the additionof NaF (final concentration, 50 mM) as described previously(23). Samples for the measurement of extracellular sugar andintracellular trehalose and glycogen levels were taken overa period of at least 200 h.

Strain and plasmid construction.
The prototrophic MAL constitutive CEN.PK113-7D strain (MATaMAL2-8^c SUC2 [45]) was used as the wild type and the host strainfor mutant constructions (Table 1). Constructions of tps1, nth1,nth2, ath1, nth1 nth2, and nth1 nth2 ath1 null mutants havebeen described in previous works (18, 23). The constructionof the atg1 mutant was carried out by homologous recombinationwith a PCR product that was obtained as follows. A 2.8-kb fragmentbearing the atg1::kanMX4 allele was amplified by PCR using genomicDNA from BY agt1::Kan^r from the Euroscarf mutant collection(http://web.uni-frankfurt.de/fb15/mikro/euroscarf/index.html)(4) and primers ATG1-600 (5'-TTCCCGTTAATCATCTTTTC-3') and ATG1+600(5'-CGGATCCTAATACCAATTCT-3'). Correct replacement of the genein the mutant strain was analyzed by PCR. Strains that combinedtps1, nth1, nth2, and atg1 mutations were obtained by use ofclassical genetics procedures, i.e., crosses, sporulation, andmarker-based selection (Table 1). The construction of the NTH2-overexpressingplasmid (pNTH2) used in this work has been previously described,and this plasmid was referred to as pGRSd-NTH2 (23).

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TABLE 1. Strains used in this study

Determination of intracellular trehalose and glycogen and extracellular sugars.
Cell samples corresponding to 15 to 30 OD₆₀₀ were quickly harvestedand centrifuged for 2 min at 4,000 x g in screw-cap microfugetubes, and the pellet was used for glycogen and trehalose leveldetermination (33). Trehalose in the culture medium was measuredby adding 0.6 ml of 0.2 M Na-acetate, pH 5.2, to 0.4 ml of supernatant,followed by digestion with trehalase as described before. Glucosein the medium was directly measured using a glucose oxidaseassay (kit 540; Sigma-Aldrich). The values for glycogen andtrehalose were given as equivalent glucose per OD₆₀₀ unit. OneOD₆₀₀ unit corresponds to 1.4 x 10⁶ cells or 0.4 mg cell drymass.

Preparation of extracts and enzyme assays.
Yeast cells (equivalent dry mass, 30 mg) were harvested by centrifugation(3,000 x g, 5 min, 4°C) and resuspended in 0.5 ml of extractionbuffer (20 mM HEPES, pH 7.1, 1 mM EDTA, 100 mM KCl, completedjust before use with 1 mM dithiothreitol and 1 mM phenylmethylsulfonylfluoride). The cell suspension was vigorously disrupted by vortexingin the presence of 1 g of glass beads for four 30-s periodsat 4°C. After centrifugation (16,000 x g for 10 min), thesupernatant was used as a crude extract for enzyme assays. Acidtrehalase activity was measured as previously described (23)in a total volume of 0.5 ml containing 315 mM sodium citrate,pH 4.5, 1.4 mM EDTA, and 55 mM trehalose. Unless otherwise stated,the neutral trehalase was assayed as previously described (29)in a total volume of 0.5 ml containing 20 mM HEPES (pH 7.1),2.5 mM CaCl₂, and 50 mM trehalose. One unit is defined as theamount of enzyme that catalyzes the hydrolysis of 1 µmolof trehalose per minute under the conditions of the assay.

RESULTS

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RESULTS

Rapid mobilization of intracellular trehalose store in tps1 mutants cultivated on trehalose.
In recent work, we showed that the growth of S. cerevisiae ontrehalose as the sole carbon source was strictly respiratory,with a maximal growth rate of about 0.07 h^–1 (22, 23).Under this condition, wild-type cells accumulated intracellulartrehalose to up to 10% of the dry mass (Fig. 1A). The disaccharidewas then partially mobilized (a drop from 10 to $~$ 6% of dry mass)during a transition phase preceding the entrance of cells intostationary phase. It then remained at this level for about 150to 200 h and was further degraded very slowly without beingcompletely exhausted even after 700 h of culture. Glycogen alsoaccumulated with the growth and reached a maximum of 12% ofdry mass at the end of the growth phase on trehalose (Fig. 1A).It remained at this high level for about 100 h in the stationaryphase, which was followed by a very slow mobilization to dropby only 30% over the next 200 h of the culture.

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FIG. 1. The loss of TPS1 triggered the breakdown of intracellular trehalose independently of neutral trehalases. Cultures were performed on YN medium set at pH 4.8 with 2% (wt/vol) trehalose. Wild-type (WT) CEN.PK113-7D strain (A) and its derivative tps1 (B), tps1 nth2 (C), and tps1 nth1 nth2 (D) mutants are shown. Symbols: , OD; ${blacktriangleup}$ , extracellular trehalose; ${triangleup}$ , intracellular trehalose; ${circ}$ , glycogen. For the sake of clarity, the time scales were arbitrary arranged so that all the strains enter the stationary phase simultaneously, at the time when exogenous trehalose has been completely consumed (vertical dashed line).

The loss of TPS1 function did not modify the specific growthrate on trehalose, although the biomass yield was about 10%lower than that for the wild type (Fig. 1B). Also, this geneticdefect did not prevent the accumulation of intracellular trehalose,which reached a maximal level comparable to that in the wild-typecells at the end of the exponential phase of growth. This resultfavored the idea that in wild-type cells, the accumulation oftrehalose arose mainly from the active uptake of exogenous trehaloseby the AGT1-encoded transporter (36). In contrast to what wasseen for the wild-type cells, however, the mobilization of trehalosewas faster in tps1 cells. Most of the disaccharide was consumedduring the short transition phase that preceded the entranceinto the stationary phase, while the remaining part was slowlymobilized and fully depleted in less than 300 h (Fig. 1B). Thedeletion of TPS1 also significantly modified the pattern ofglycogen degradation, which started earlier than in the wild-typestrain and was almost complete after 300 h of growth in thestationary phase (Fig. 2B). Taken together, these results revealeda notable impact of TPS1 deletion that promoted a rapid trehalosemobilization and reversed the usual observation that trehalosedegradation follows that of glycogen during the stationary phaseof growth (14, 26, 32).

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FIG. 2. Ath1p is indispensable for the complete mobilization of intracellular trehalose in a tps1 mutant. Cells were cultivated in YN medium set at pH 4.8 containing 2% (wt/vol) galactose and 1% (wt/vol) trehalose. Symbols are as in Fig. 1.

The tps1-promoted intracellular trehalose mobilization is independent of neutral trehalases.
To know whether NTH1 and/or NTH2 was implicated in this rapidmobilization of intracellular trehalose, we carried out similarexperiments with tps1 mutants from which either one or bothof the NTH1 and NTH2 genes were further deleted. The growthof the tps1 nth1 mutant on this carbon source was twofold lowerthan that for the wild type or the tps1 mutant (0.03 versus0.07 h^–1), due to the absence of the Agt1p-Nth1p-dependentpathway (23). In spite of this growth rate reduction, the deletionof NTH1 did not modify the pattern of trehalose accumulationand breakdown (data not shown). The deletion of NTH2 in thetps1 strain had no notable effect on growth rate and trehaloseaccumulation. We nevertheless repeatedly found that the mobilizationof the accumulated trehalose was lower than that in the tps1cells during the transition period and extended beyond the onsetof the stationary phase (Fig. 1C). The nth1 nth2 tps1 mutantexhibited the combined phenotypes mentioned for nth1 and nth2mutants (Fig. 1D), which indicated that rapid and sustainedtrehalose mobilization in a tps1 mutant was largely independentof both Nth1p and Nth2p.

The mobilization of cytosolic trehalose is dependent on Ath1p.
The finding of intracellular trehalose mobilization in a tps1mutant lacking both NTH1 and NTH2 prompted us to investigatewhether this phenotype could be attributed to the trehalaseencoded by ATH1. Since Ath1p is essential for growth on trehalosein the absence of the Agt1p-Nth1p pathway (23), it was not possibleto investigate this question using a tps1 nth1 nth2 mutant thatwas further defective in Ath1p. We circumvented this difficultyby cultivating the quadruple tps1 nth1 nth2 ath1 mutant in agalactose medium containing trehalose, since this medium ispermissive for the growth of tps1 mutants and enables trehaloseaccumulation by Agt1p-mediated transport (35). Under this condition,the culture of the tps1 strain followed a biphasic growth (Fig.2A), i.e., a first phase corresponding to the growth on galactosefollowed by a second purely oxidative growth phase on the remainingtrehalose and on the ethanol produced from galactose catabolism.At the time when the latter two carbon sources were depleted,cells entered the stationary phase, and trehalose that had accumulatedduring the growth to $~$ 25 µg eq Glc/OD₆₀₀ (6% of dry mass)was readily degraded. As already observed in Fig. 1, the mobilizationof the disaccharide occurred prior to that of glycogen. Thedeletion of NTH1 in the tps1 mutant did not alter the growthkinetic but resulted in a twofold increase of trehalose contentin the postdiauxic phase of growth (Fig. 2B). Quite interestingly,the tps1 nth1 nth2 mutant accumulated even more trehalose thanthe tps1 nth1 mutant (Fig. 2C). Altogether, these results providedadditional genetic evidence that NTH2 may encode a functionaltrehalase.

This experimental setup described above then allowed study ofthe role of acid trehalase by deletion of ATH1 from a tps1 nth1nth2 strain. As can be seen in Fig. 2D, this mobilization wasactually dependent on Ath1p, since the deletion of ATH1 completelyprevented this degradation. In this mutant, the trehalose levelremained at about 17% of the dry mass in the stationary phase,and it was even higher in the tps1 ath1 nth1 nth2 mutant defectivein all three trehalases, reaching the exceptional level of 25%of the cell dry mass (data not shown). It can also be seen fromthis figure that glycogen was mobilized in ath1 mutants earlierthan in the Ath1⁺ cells and as soon as cells entered the stationaryphase. It is thus possible that this degradation of glycogencompensated for the lack of trehalose mobilization to supplythe cells with carbon and energy during stationary phase.

The mobilization of intracellular trehalose by Ath1p requires the export of the disaccharide.
Recently, we showed that a significant part of Ath1p activitywas measured extracellularly (23). We therefore assumed thatthe remaining intracellular, most probably vacuolar, trehalaseactivity (1, 24) could be responsible for trehalose catabolism,similarly to the vacuolar glucoamylase-dependent degradationof glycogen during the late stationary phase (46, 47). Sincethis later process is dependent on ATG1, which encodes a serine/threonineprotein kinase required for autophagy (27, 40), we evaluatedwhether trehalose degradation followed the same fate as glycogenby disrupting ATG1 in both tps1 nth2 and tps1 nth1 nth2 mutants.Contrary to expectation, these mutants were still able to mobilizetrehalose with the same kinetic observed for their isogeniccontrol strains (data not shown), while glycogen mobilizationwas altered as previously reported (46). Altogether, these datashowed that macroautophagy did not bring intracellular trehaloseto the vacuole for subsequent cleavage, even though this pathwaywas functional under our growth conditions and actively participatedin glycogen catabolism.

We therefore examined the possibility that the mobilizationof intracellular trehalose relied on the extracellular poolof Ath1p (23). As a first step to evaluate this mechanism, wetook advantage of the pH sensitivity of Ath1p, since we previouslyshowed that Ath1p-dependent trehalose assimilation was optimalat pH 5.0 and was severely impaired at neutral pH (23). Thus,the tps1 nth1 nth2 mutant was cultivated on a trehalose mediumat pH 4.8 until it had accumulated enough disaccharide (onsetof stationary phase) (Fig. 1D). These trehalose-loaded tps1nth1 nth2 cells were then transferred to a carbon-free minimalmedium set at pH 5 or 7. As shown in Fig. 3, the mobilizationof intracellular trehalose was faster in yeast cells resuspendedin a pH 5.0 medium, whereas the converse was found for glycogendegradation. This result is an additional evidence of a closeinteraction between these two glucose stores in the managementof carbon and energy during poor growth conditions. More importantly,we detected the presence of trehalose in the resuspension culturemedium, indicating that the disaccharide was exported out ofthe cells. In both culture media, a transient burst of trehalosethat was about five times higher in the culture medium at pH7.0 than at pH 5.0 was observed, in agreement with a higherAth1p activity at this latter pH (23). After the peak, trehalosedeclined and remained at very low but detectable levels of approximately0.05 mM. Altogether, these results favored the idea that themobilization of an intracellular trehalose store in a tps1 mutantcultivated on trehalose requires the export of the disaccharideand its hydrolysis at the cell surface by Ath1p.

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FIG. 3. Intracellular trehalose mobilization and its export into the medium. Trehalose-loaded tps1 nth1 nth2 cells cultivated on YN trehalose were centrifuged, washed once with water, resuspended in a fresh medium free of any carbon source, and set at pH 5.0 (empty symbols) or 7.0 (full symbols). (Top) Mobilization of intracellular trehalose ( ${triangleup}$ , ${blacktriangleup}$ ) and glycogen ( ${circ}$ , •). (Bottom) Trehalose exported from intracellular stores and measured in the culture medium ( ${diamond}$ , ${blacklozenge}$ ).

The trehalase Ath1p exerts a pull effect on the export of intracellular trehalose.
To further demonstrate the occurrence of a trehalose export,we transferred trehalose-loaded tps1 nth1 nth2 ath1 mutant cellsin a carbon-free medium set at pH 5.0. Following this transfer,the disaccharide was immediately expulsed from the medium andaccumulated to 100 mg/liter after 200 h of incubation, withouta significant decrease of the intracellular store (Fig. 4).This result indicated that the equilibrium between trehaloseexport and Agt1p-mediated import was in favor of the intracellularlocation of the disaccharide. The export of trehalose and thepartition between intracellular and extracellular disaccharidewere not modified when yeast cells were transferred in a mediumset at pH 7.0 (data not shown), indicating that the effect ofincreasing the pH (Fig. 3) merely affected the activity of Ath1p.Very interestingly, the presence of extracellular Ath1p shiftedthis equilibrium and resulted in a net mobilization of the intracellulartrehalose. This was shown by transferring trehalose-loaded tps1nth1 nth2 ath1 (Ath1^–) cells in a filtered, carbon-depletedgrowth medium obtained from a culture of the tps1 nth1 nth2(Ath1⁺) strain grown to stationary phase. According to our previousdata (23), free secreted Ath1p (approximately 5% of the totalactivity) can be found in the supernatant of stationary-phaseculture on trehalose. As indicated in Fig. 4, the presence ofthis "exogenous" Ath1p activity in the resuspension medium partiallyprevented the accumulation of trehalose in the medium whilepromoting the complete intracellular depletion of the disaccharide(not shown). Altogether, these results indicated that extracellulartrehalose cleavage into glucose by Ath1p is necessary for theefficient export of the disaccharide.

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FIG. 4. Lack of Ath1p results in a weak trehalose accumulation in the medium. Trehalose-loaded tps1 nth1 nth2 ath1 mutant cells cultivated on YN containing galactose-trehalose were transferred into carbon-free medium (vertical dashed line). Intracellular trehalose ( ${triangleup}$ , control; ${blacktriangleup}$ , after transfer) and trehalose exported in the culture medium after the transfer ( ${blacklozenge}$ ) in fresh medium set at pH 5.0 with no carbon source (continuous line) or in a filtered, trehalose-exhausted medium from Ath1⁺ strain cultivated to the stationary phase (dashed line).

To further validate the fact that the trehalose was expulsedand cleaved at the cell surface by Ath1p, we repeated the experimentin the presence of NaF, as this drug is reported to inhibitcarbon metabolism and hence indirectly block the consumptionof extracellular glucose (23, 38). As expected, the exposureof tps1 nth1 nth2 (Ath1⁺) cells to 50 mM NaF before the onsetof stationary phase suddenly stopped the assimilation of extracellulartrehalose and caused growth cessation (Fig. 5). Moreover, thisdrug treatment enhanced the mobilization of intracellular trehalose,with a complete depletion after 100 h of incubation. Concomitantly,glucose increased in the culture medium to up to 6 g/liter asa result of the Ath1p-dependent hydrolysis of both the residualtrehalose from the medium ( $~$ 4 g/liter at the time when NaF wasadded) and the exported intracellular trehalose store. As acontrol, we carried out the same experiment with tps1 nth1 nth2(Ath1⁺) cells cultivated in galactose as the sole carbon sourceso it could not accumulate any intracellular trehalose. Theaddition of NaF to these cells did not cause any release ofglucose into the culture medium. This result confirmed thatthe production of glucose in trehalose-loaded tps1 nth1 nth2cells after NaF treatment was strictly dependent on the disappearanceof its intracellular trehalose store.

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FIG. 5. Addition of NaF to Ath1⁺ cells provoked a complete depletion of intracellular trehalose, which was recovered in the culture medium as free glucose. Trehalose-loaded cells of the tps1 nth1 nth2 strain cultivated on galactose-trehalose (empty symbols) were treated with 50 mM NaF (vertical dashed line; full symbols). Symbols: , OD; ${triangleup}$ and ${blacktriangleup}$ , intracellular trehalose; ${circ}$ and •, glycogen; ${diamond}$ , exogenous trehalose as the substrate. Free glucose in the medium ( ${blacksquare}$ ) as measured by glucose oxidase assay after NaF treatment. This glucose arose from Ath1p-dependent hydrolysis of both the residual exogenous trehalose ( ${blacklozenge}$ ) and the exported intracellular trehalose store. The total carbon after NaF treatment as given in glucose equivalents ( ${square}$ ) includes free glucose in the medium (see above) plus glucose resulting from in vitro trehalase treatment of the culture medium.

The export of trehalose also takes place in Tps1⁺cells.
The experiments presented above relied on the finding that yeastcells can accumulate a large amount of trehalose through theAgt1p transporter when this sugar is present in the medium.Under this condition, we found that a tps1 mutant exhibiteda rapid mobilization of its intracellular store, which seemedto occur by the export of trehalose and its extracellular cleavageby Ath1p. The question was therefore whether this singular eventwas truly specific to the lack of TPS1. When we studied nth1nth2 ATH1 cells cultivated on glucose or galactose as the solecarbon source, we found that trehalose accumulated through denovo synthesis. It is shown in Fig. 6 that the treatment ofthese yeast cells with NaF caused a sudden depletion of thetrehalose store concomitantly with the accumulation of freeglucose in the culture medium. In addition, when this strainwas cultivated in glucose or galactose medium supplemented with10 g·liter^–1 trehalose as previously done for thetps1 mutant, the glucose that was released in the medium arosefrom the cleavage of trehalose that remained in the growth mediumand the one that was exported from the cells (data not shown).Altogether, these results indicate that the export of trehalosein the medium was neither triggered by the loss of TPS1 functionnor induced by the presence of extracellular trehalose.

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FIG. 6. Addition of NaF to Tps1⁺ cells provoked a depletion of intracellular trehalose store, which was recovered in the culture medium as free glucose. The nth1 nth2 (Tps1⁺ Ath1⁺) strain was grown on galactose as the sole carbon source. Details and symbols are as for Fig. 5.

The fact that an export of trehalose could be seen for Tps1⁺cells allowed us to verify whether the export of the disaccharidewas dependent upon the H⁺/trehalose transporter encoded by AGT1.To this end, the wild type and an agt1 mutant were cultivatedon galactose until the stationary phase and were then treatedwith 50 mM NaF as described above. In both cases, glucose appearedin the medium (data not shown), indicating that the export oftrehalose was not due to the reversal of its uptake by Agt1p.

NTH2 encodes a functional trehalase.
Data in Fig. 1 and 2 suggested that NTH2, the paralog of NTH1,may encode a functional trehalase. To gain additional evidencefor a role for NTH2 in trehalose metabolism, we tested if theoverexpression of NTH2 could rescue the growth defect of anath1nth1 mutant on trehalose. This experiment was unsuccessful,suggesting that NTH2 encodes a weakly active or nonfunctionaltrehalase. We therefore carried out enzymatic measurement usingvarious trehalase mutants. As indicated in Table 2, the deletionof NTH1 in either the wild type or the tps1 or ath1 mutant ledto a 75% decrease in neutral trehalase activity measured atpH 7.0. The residual 25% activity could be attributed to theproduct of NTH2, since it was abolished by the deletion of thisgene in nth1, ath1 nth1, or tps1 nth1 mutants. In contrast,the overexpression of NTH2 in an nth1 mutant resulted in anapproximately 10-fold increase of trehalose-hydrolyzing activity.From data in Table 2, it can be proposed that the NTH2-dependenttrehalase activity is dependent on the growth medium, sincethe "residual neutral trehalase activity" nth1 was about fivefoldhigher in cells cultivated on trehalose than in stationary-phasecells on glucose. Moreover, this activity is undetectable duringgrowth on glucose and began to be detected at the onset of thediauxic shift to reach a maximum of about 10 milliunits/mg protein(or 0.2 units/g cell dry mass) in the stationary phase. Whilefurther biochemical and genetic analyses are currently underway, we verified that Nth2p was optimally active at a neutralpH (Table 2) and at a temperature of 30 to 35°C and displayedan apparent K_m of about 10 mM for trehalose (data not shown).

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TABLE 2. Assay of extracellular (acid) and cytosolic (neutral) trehalases with different mutants and growth conditions

DISCUSSION

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DISCUSSION

Despite the fact that trehalose has been the focus of many studiesover decades, several issues remained ambiguous with respectto the enzymatic machinery devoted to this disaccharide. Inthis work, we provided two major results that clarify some ofthese long-standing enquiries. First, we showed that NTH2, aparalog of NTH1, encodes a functional neutral trehalase. Second,we demonstrated that the extracellular acid trehalase encodedby ATH1 can be implicated in the mobilization of endogenoustrehalose, and we showed that this process required an exportof the disaccharide. On top of these findings, we reinforcedprevious findings (6, 15, 26) on the existence of an interconnectionbetween trehalose and glycogen in yeast cell carbon storagemanagement.

No trehalase activity has ever been attributed to Nth2p, inspite of a strong sequence similarity with Nth1p, which ledsome authors to suggest that this protein might be a regulatorof Nth1p (30). In this work, we provided genetic and biochemicalevidence that NTH2 encodes a functional cytosolic/neutral trehalasewith a measurable activity in the stationary phase on glucoseor during growth on trehalose. This result is in accordancewith the expression level of NTH2, which is low during the exponentialphase of growth on glucose, increases in the late exponentialphase, and peaks at the onset of the stationary phase (31).Curiously, a similar pattern of expression has been also foundfor NTH1 (32), although the enzymatic activity of Nth1p followedan opposite trend (13). This opposite profile is explained bya posttranscriptional control of Nth1p by a cyclic AMP-dependentprotein kinase phosphorylation that takes place during growthon glucose and causes its activation (30). Whether Nth2p isalso regulated by this type of mechanism is an open question.Moreover, while a weak intervention of Nth2p in trehalose mobilizationhas been uncovered in the experimental context of this work,it still remains to identify other situations that may supportits physiological function in yeast.

In a recent work, we demonstrated that the bulk of acid trehalaseactivity encoded by ATH1 was localized at the cell surface andthat this localization accounted for the growth of yeast ontrehalose (23). However, we did not exclude the possibilitythat the residual fraction of Ath1p could be located in thevacuoles (1), thus enabling an autophagy-dependent trehalosemobilization. Autophagy is indeed a self-eating, starvation-inducedprocess, in which various cytoplasmic components such as organellesand cytoplasm are delivered into the vacuole for degradation.The outcome of this process is probably to allow basic buildingblocks to be regenerated. Such turnover of a large amount ofcytoplasm is essential for survival under nutrient-depletedconditions, a condition that de facto matched with the timingand putative role of trehalose consumption observed at the endof growth on trehalose medium. We explored this hypothesis byuse of tps1 mutants with deletion of ATG1. This mutation blocksearly steps of double-membrane vesicle formation, not only inmacroautophagy (autophagosomes) but also in the cytoplasm-to-vacuoletargeting biosynthetic pathway. Since the latter appears toexclude bulk cytoplasm and occurs during vegetative conditionsto deliver hydrolases into the vacuole, the atg1 mutant wasexpected in our study to prevent cytosolic trehalose sequestrationinto the autophagosomes. Contrary to expectation, this mutationdid not alter the intracellular trehalose pattern, althougha clear effect of the atg1 mutation on glycogen mobilizationwas observed in total, in agreement with results from Roach'sgroup (46, 47). We concluded that this pathway did not contributeto trehalose catabolism. Other forms of autophagy processes,such as microautophagy that involves the direct engulfment ofcytoplasm at the surface of the vacuole (11, 25) or a yet unknownsugar transport system from cytoplasm to vacuole, could notbe totally excluded. However, our experimental data stronglysupport the notion that the intracellular degradation of trehaloseinvolved its export and cleavage into glucose at the cell surface.In favor of this mechanism, the deletion of ATH1 in the tps1mutant resulted in a moderate accumulation of trehalose in themedium. In addition, the efficiency of trehalose export waspromoted by the activity of Ath1p, which indicated a pull effectof this enzyme on the export of the disaccharide.

Very little is known about sugar exporters in the yeast S. cerevisiae,despite a growing number of characterized hexose transportersin this microorganism (43). The physiological significance ofmost of the 20 hexose transporter proteins has not been elucidatedso far, and some of them could be important under atypical growthconditions. As an example, an in vivo expulsion of internalglucose was observed when yeast cells growing in maltose-limitingcontinuous conditions were exposed to an excess of exogenousmaltose (21). This expulsion was explained as a means to preventa massive entry of glucose into glycolysis and the dissipationof metabolic energy. With respect to trehalose, an export ofthis disaccharide has been already reported for germinatingyeast cells (7). In a previous work, we showed that the Agt1-H⁺/trehalosesymporter also called Mal11p allows the import of trehaloseinto yeast cells (36). Whether this transporter can also catalyzethe reverse reaction, i.e., the export of trehalose, remainsan open question, but the possibility is attractive. Using isolatedplasma membrane vesicles, it was indeed shown that nonconcentrativemaltose transport is possible in the absence of an electrochemicalgradient and that maltose transport is in principle reversible(5, 44). Here, we found that this Agt1p/Mal11p transporter cannotmediate the export of trehalose in vivo under the experimentalconditions described herein.

Expression studies with wild-type cells showed that ATH1 isregulated by the carbon source: Ath1p activity is low in thepresence of fermentable sugars, including galactose, and highduring the stationary phase of growth on glucose or during growthon respiratory substrates (24, 38). Our finding that trehalosewas readily mobilized during stationary phase in tps1 mutantswas originally considered as a singular trait associated withthe loss of TPS1. Taking into account the expression data presentedabove, this active mobilization was apparently quite logical.However, the export system was shown to be active whatever thecarbon source and TPS1 allele, raising the question of why suchmobilization did not occur in wild-type Tps1⁺ cells during thestationary phase. A hypothesis to account for this preservationof the trehalose store in wild-type cells is the existence ofa "sugar in-out cycling" due to the concomitant and compartmentalizedactivities of Ath1p and of the trehalose synthase complex, respectively.Accordingly, as for ATH1, genes encoding the TPS complex arederepressed and Tps1p activity is also increased when cellsenter stationary phase (3, 15), allowing de novo synthesis ofthe disaccharide. The absence of Tps1p may break down this cycling,revealing a potent degradation of trehalose in this tps1 mutantcontext. Based on our study, Ath1p likely plays the leadingrole in this cycling, favoring outward migration of the disaccharidewith the immediate, extracellular cleavage of trehalose intoglucose moieties that can be assimilated by the cells.

Finally, these experiments revealed that tps1 mutants presentincreased energy demand as soon as they face starvation conditions.We also showed in this work that this mutant cultivated on amedium that contains trehalose delayed its glycogen mobilizationto after that of trehalose. In this context, earlier and fasterglycogen degradation was triggered when trehalose mobilizationwas prevented. At this stage, our data do not allow for a molecularmechanism that explains the compensatory mechanism between thetwo glucose stores to be proposed. From a physiological viewpoint,these results definitively pose trehalose as an important energystore in yeast and reveal a fine-tuning control in carbon storagemanagement under starvation conditions.

ACKNOWLEDGMENTS

This work was supported in part by the ACI program "Microbiologyand Pathogenicity" of the French Ministry of Education. G.B.was supported by a 1-year Marie Curie Young Training Fellowship(no. HPMT-EC-2000-00135) as part of her Ph.D. thesis in J.F.'slaboratory. M.J. was supported by a doctoral grant from theFrench Ministry of Education and Research.

FOOTNOTES

* Corresponding author. Mailing address: UMR 5504 & UMR 792 d'Ingénierie des Systèmes Biologiques et des Procédés, Institut national des Sciences Appliquées, 135 Avenue de Rangueil, 31077 Toulouse cedex 04, France. Phone: 33 5 61 559492. Fax: 33 5 61 559400. E-mail: fran_jm{at}insa-toulouse.fr

Published ahead of print on 7 December 2007.

This paper is dedicated to Carlos and Juana Maria Gancedo, friendsand colleagues, for their outstanding contributions to the fieldof yeast biochemistry.

These two authors contributed equally to this work.

Present address: Unit Genomics of Microbial Pathogens, InstitutPasteur, Paris, France.

^¶ Present address: Department of Cellular and Molecular Biology,Goeteborg, Sweden.

REFERENCES

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