Trehalose synthase converts glycogen to trehalose

Trehalose (alpha,alpha-1,1-glucosyl-glucose) is essential for the growth of mycobacteria, and these organisms have three different pathways that can produce trehalose. One pathway involves the enzyme described in the present study, trehalose synthase (TreS), which interconverts trehalose and maltose. We show that TreS from Mycobacterium smegmatis, as well as recombinant TreS produced in Escherichia coli, has amylase activity in addition to the maltose <--> trehalose interconverting activity (referred to as MTase). Both activities were present in the enzyme purified to apparent homogeneity from extracts of Mycobacterium smegmatis, and also in the recombinant enzyme produced in E. coli from either the M. smegmatis or the Mycobacterium tuberculosis gene. Furthermore, when either purified or recombinant TreS was chromatographed on a Sephacryl S-200 column, both MTase and amylase activities were present in the same fractions across the peak, and the ratio of these two activities remained constant in these fractions. In addition, crystals of TreS also contained both amylase and MTase activities. TreS produced both radioactive maltose and radioactive trehalose when incubated with [(3)H]glycogen, and also converted maltooligosaccharides, such as maltoheptaose, to both maltose and trehalose. The amylase activity was stimulated by addition of Ca(2+), but this cation inhibited the MTase activity. In addition, MTase activity, but not amylase activity, was strongly inhibited, and in a competitive manner, by validoxylamine. On the other hand, amylase, but not MTase activity, was inhibited by the known transition-state amylase inhibitor, acarbose, suggesting the possibility of two different active sites. Our data suggest that TreS represents another pathway for the production of trehalose from glycogen, involving maltose as an intermediate. In addition, the wild-type organism or mutants blocked in other trehalose biosynthetic pathways, but still having active TreS, accumulate 10- to 20-fold more glycogen when grown in high concentrations (> or = 2% or more) of trehalose, but not in glucose or other sugars. Furthermore, trehalose mutants that are missing TreS do not accumulate glycogen in high concentrations of trehalose or other sugars. These data indicate that trehalose and TreS are both involved in the production of glycogen, and that the metabolism of trehalose and glycogen is interconnected.     

Effects of trehalose on stress tolerance and biocontrol efficacy of Cryptococcus laurentii

AIMS: To investigate the effects of internal trehalose on viability and biocontrol efficacy of antagonistic yeast Cryptococcus laurentii under stresses of low temperature (LT), controlled atmosphere (CA) and freeze drying. METHODS AND RESULTS: The content of trehalose in C. laurentii was increased by culturing the yeast in trehalose-containing medium. Compared with yeast cells with low trehalose level, the yeast cells with high level of internal trehalose not only obtained higher viability, but also showed higher population and better biocontrol efficacy against Penicillium expansum on apple fruit both at 1 degrees C and in CA condition (5% O(2), 5% CO(2), 1 degrees C). After freeze drying, survival of the yeast with high trehalose level was markedly increased when stored at 25 degrees C for 0, 15 and 30 days. Meanwhile, high integrity of plasma membrane was detected in the freeze-dried yeast with high trehalose level by propidium iodide staining. CONCLUSIONS: Induced accumulation of internal trehalose could improve viability and biocontrol efficacy of C. laurentii under stresses of LT and CA. Moreover, survival of the yeast was also increased as internal trehalose accumulation after freeze drying, and one of the reasons might be that trehalose gave an effective protection to plasma membrane. SIGNIFICANCE AND IMPACT OF THE STUDY: The results of this experiment show a promising way to improve the biocontrol performance of antagonistic yeasts under the commercial conditions.     

Improving the freeze tolerance of bakers' yeast by loading with trehalose

We examined the freeze tolerance of bakers' yeast loaded with exogenous trehalose. Freeze-tolerant and freeze-sensitive compressed bakers' yeast samples were soaked at several temperatures in 0.5 M and 1 M trehalose and analyzed. The intracellular trehalose contents in both types of bakers' yeast increased with increasing soaking period. The initial trehalose-accumulation rate increased with increasing exogenous trehalose concentration and soaking temperature. The maximum trehalose content was almost identical (200-250 mg/g of dry cells) irrespective of the soaking temperature and the type of bakers' yeast, but depended on the exogenous trehalose concentration. The leavening ability of both types of bakers' yeast loaded with trehalose was almost identical to that of the respective original cells, irrespective of the soaking conditions. The freeze-tolerant ratio (FTR) of both types of bakers' yeast increased with increasing intracellular trehalose content. However, FTR decreased during over-soaking after the maximum amount of trehalose had accumulated. FTR of the freeze-sensitive bakers' yeast was more efficiently improved than that of the freeze-tolerant type.     

13C nuclear magnetic resonance study of trehalose mobilization in yeast spores.

Using high-resolution 13C nuclear magnetic resonance, we examined the mobilization of endogenous trehalose in suspensions of yeast asci. Sporulation of yeast cells in [1-13C]acetate resulted in incorporation of label into the C-3 and C-4 positions of trehalose within the asci. During germination of these asci with [1-13C]glucose, the consumption of both endogenous trehalose and exogenous glucose were followed simultaneously by 13C nuclear magnetic resonance, as was the formation of glycerol and ethanol, their glycolytic and products. Time courses for carbohydrate consumption indicated that trehalose, although it decreased to 25% of its initial value upon germination, was not preferentially catabolized and did not provide the primary energy supply for germination with glucose. The ratio of trehalose to glucose catabolized was 0.09. Exogenous glucose levels appeared to regulate trehalose mobilization since trehalose was only consumed when sufficiently high levels (more than 2 mM) of glucose were present. Upon glucose depletion newly synthesized [1-13C]trehalose was observed. Nuclear magnetic resonance spectra of extracts confirmed the trehalose peak assignments and showed products of [1-13C]glucose catabolism. In addition by quantitating trehalose consumption and 2-deoxyglucose incorporation in dormant yeast asci, we found that 3.8 +/- 0.l4 molecules of 2-deoxyglucose were incorporated for each trehalose molecule consumed. Trehalose can therefore function as a carbohydrate source for ATP formation during dormancy.     

The cryoprotectant trehalose destabilises the bilayer organisation of Escherichia coli-derived membrane systems at elevated temperatures as determined by H and P-NMR

In this study, ²H and ³¹P-NMR techniques were used to study the effects of trehalose and glycerol on phase transitions and lipid acyl chain order of membrane systems derived from cells of E. coli unsaturated fatty acid auxotroph strain K1059, which was grown in the presence of [11,11-²H₂]-oleic acid or [11,11-²H₂]-elaidic acid. From an analysis of the temperature dependence of the quadrupolar splitting it could be concluded that neither 1 M trehalose or glycerol generally had any significant effect on the temperature of the lamellar gel to liquid-crystalline phase transition. In the case of the oleate-containing hydrated total lipid extract, glycerol but not trehalose caused a 5°C increase of this transition temperature. In general, both cryoprotectants induced an ordering of the acyl chains in the liquid-crystalline state. Trehalose and glycerol both decrease the bilayer to non-bilayer transition temperature of the hydrated lipid extract of oleate-grown cells by about 5°C, but only trehalose in addition induces an isotropic to hexagonal (H_II) phase transition. In the biological membranes, trehalose and not glycerol destabilised the lipid bilayer, and in the case of the E. coli spheroplasts, part of the induced non-bilayer structures is ascribed to a hexagonal (H_II) phase in analogy with the total lipids. Interestingly, 1 mM Mg²⁺ was a prerequisite for the destabilisation of the lipid bilayer. In the hydrated total lipid extract of E. coli grown on the more ordered elaidic acid, both transition temperatures were shifted about 20°C upwards compared with the oleate-containing lipid, but the effect of trehalose on the lipid phase behaviour was similar. The bilayer destabilising ability of trehalose might have implications for the possible protection of biological systems by (cryo-)protectants during dehydration, in that protection is unlikely to be caused by preventing the occurrence of polymorphic phase transitions.     

Cloning and characterization of a gene encoding trehalose phosphorylase (TP) from Pleurotus sajor-caju

Complementary DNA for a gene encoding trehalose phosphorylase (TP) that reversibly catalyzes trehalose synthesis and degradation from alpha-glucose-1-phosphate (alpha-Glc-1-P) and glucose was cloned from Pleurotus sajor-caju. The cDNA of P. sajor-caju TP (designated PsTP, GenBank Accession No. AF149777) encodes a polypeptide of 751 amino acids with a deduced molecular mass of 83.7 kDa. The PsTP gene is expressed in mycelia, pilei, and stipes of fruiting bodies. Trehalose phosphorylase PsTP was purified from PsTP-transformed Escherichia coli. The enzyme catalyzes both the phosphorolysis of trehalose to produce alpha-Glc-1-P and glucose, and the synthesis of trehalose. The apparent K(m) values for trehalose and Pi in phosphorolytic reaction at pH 7.0 were 74.8 and 5.4 mM, respectively. The PsTP gene complemented Saccharomyces cerevisiae Deltatps1, Deltatps2 double-mutant cells, allowing their growth on glucose medium. Furthermore, yeast transformed with PsTP produced 2-2.5-fold more trehalose than non-transformants or cells transformed with empty vector only.     

Factors affecting the survival of Bradyrhizobium applied in liquid cultures to soya bean [Glycine max (L.) Merr.] seeds

AIMS: To determine the impact of medium composition, bacterial strain, trehalose accumulation, and relative humidity during seed storage on the survival of Bradyrhizobium japonicum on soya bean [Glycine max (L.) Merr.] seeds. METHODS AND RESULTS: Bacteria in liquid cultures were applied to seeds, and the number of survivors was quantified after 2, 24, 48, or 96 h. Addition of yeast extract to a defined medium increased on-seed survival 50- to 80-fold. Addition of 40 mmol l(-1) of NaCl to the medium doubled or tripled the accumulation of trehalose in cells and increased survival several fold, and the addition of both salt and trehalose had an additive effect. There was a threefold difference among strains in survival, and survival of the various strains was significantly correlated with differences in the accumulation of trehalose. The correlation between trehalose accumulation by bacteria and survival was also highly significant in other experiments. Studies in controlled humidity environments showed 100-fold or more differences in survival. CONCLUSIONS: The consistently significant correlation of trehalose content of cells with survival on seed suggests that trehalose is an important component of the survival mechanisms. When some of the factors (salt and trehalose in the medium plus humidity control) were studied in combination, several 100-fold increases in survival of bacteria on seeds were recorded. SIGNIFICANCE AND IMPACT OF THE STUDY: It is possible by manipulation of several parameters--strain selection, salt and trehalose content of the medium, control of relative humidity--to achieve substantial improvements in survival of Bradyrhizobium on soya bean seeds.     

Purification and Characterization of Trehalose Phosphorylase from Micrococcus varians

Trehalose phosphorylase (EC 2.4.1.64), which catalyzes the reversible reaction of phosphorolysis and synthesis of trehalose, was purified to homogeneity from a cell-free extract of Micrococcus varians strain No. 39. The enzyme was shown to have a molecular weight of 570,000 to 580,000 by gel filtration, and to have a subunit of molecular weight of 105,000 by SDS–polyacrylamide gel electrophoresis. The stoichiometry of the reaction between trehalose, Pi, glucose, and β-glucose 1-phosphate was 1: 1: 1: 1 (molar ratio). The enzyme had high specificity for trehalose, glucose, and β-glucose 1-phosphate. The K_ms for trehalose, Pi, glucose, and β-glucose 1-phosphate were 10, 3.1, 23, and 38mM, respectively. The k_cats were 200s^?1 for trehalose phosphorolysis and 660s^?1 for trehalose synthesis. The enzyme was inhibited by validamycin A, validoxylamine A, 1-deoxynojirimycin, and Cu^{2 +} during trehalose phosphorolysis, and by Cu^{2 +}, Zn^{2 +}, and Ni^{2 +} during trehalose synthesis. Inhibition competitive against trehalose was noted with validamycin A, validoxylamide A, and 1-deoxynojirimycin. Initial velocity, product inhibition, and dead-end inhibition studies suggested that both trehalose phosphorolysis and trehalose synthesis proceeded through an ordered Bi Bi mechanism.     

The involvement of hexokinases in trehalose synthesis.

Yeast cells harboring a MAL2-8c gene accumulate trehalose during the transition phase of growth on glucose due to the presence of the ADPG-dependent trehalose 6-phosphate synthase. Under these conditions, glucokinase appeared not to provide G-6-P for trehalose synthesis and the two hexokinases seemed to act synergistically. After incubation in d-xylose, trehalose levels in these cells dropped almost in 90%, confirming the involvement of both hexokinases in the accumulation of this carbohydrate. Nevertheless, G-6-P levels appeared to be similar in all strains. Some explanations for this paradox are discussed. In stationary phase, neither of the three isoenzymes were involved in trehalose synthesis. Possibly, gluconeogenesis provides the substrate for trehalose synthesis at that stage.     

Stimulation of trehalose efflux from cockroach (Periplaneta americana) fat body by hypertrehalosemic hormone is dependent on protein kinase C and calmodulin

Protein kinase C and calmodulin play key roles in cockroach fat body during activation of phosphorylase and trehalose efflux by HTH-II. The data support the view that an increase in cytosolic Ca2+ is prerequisite for enhanced activity of protein kinase C and calmodulin. Chelation of Ca2+ (i) with BAPTA blocks HTH-II-induced trehalose efflux from the fat body whereas thapsigargin, which raises [Ca2+]i to the same level as HTH-II, produces only a small, yet significant increase in trehalose efflux. Sphingosine, an inhibitor of protein kinase C, inhibits HTH-II-induced trehalose efflux in a concentration-dependent manner. Trehalose efflux is not activated by the protein kinase C activators OAG or PMA alone but in the presence of thapsigargin both agents increase trehalose efflux to a level comparable to that obtained with HTH-II. Thapsigargin has only a moderate activating effect on phosphorylase but in combination with OAG produces an activation indistinguishable from that provoked by HTH-II. Each of the structurally different calmodulin inhibitors, trifluoperazine, W-7, and calmidazolium, blocks completely the action of HTH-II on trehalose efflux, thus confirming the importance of calmodulin in HTH-II initiated trehalose efflux.     

Interaction between trehalose and alkaline-earth metal ions

We investigated the interaction between trehalose and alkaline-earth metal ions. The nuclear relaxation times of carbon atoms of trehalose were shortened by addition of the alkaline-earth chloride salts, MgCl2, CaCl2, and SrCl2, indicating that trehalose formed metal-complexes with the alkaline-earth metal chlorides. From the data of the 1H-1H coupling constants of trehalose in the presence of the alkaline-earth chlorides, it appeared that trehalose formed complexes with MgCl2, and CaCl2 at the various complexing sites: Mg2+ was coordinated to O-4 and O-4' of trehalose, and Ca2+ to O-2 and O-3. We succeeded in the preparation of two types of crystals of the trehalose/CaCl2. One was a crystal consisting of trehalose, CaCl2, and water in a ratio of 1:1:1. The other was an anhydrous crystal containing trehalose and CaCl2 in a ratio of 1:2. Several applications of the complexing between trehalose and the metal ions for food processing are proposed.     

Extracellular trehalose utilization by Saccharomyces cerevisiae

Two haploid strains of Saccharomyces cerevisiae viz. MATalpha and MATa were grown in glucose and trehalose medium and growth patterns were compared. Both strains show similar growth, except for an extended lag phase in trehalose grown cells. In both trehalose grown strains increase in activities of both extracellular trehalase activities and simultaneous decrease in extracellular trehalose level was seen. This coincided with a sharp increase in extracellular glucose level and beginning of log phase of growth. Alcohol production was also observed. Secreted trehalase activity was detected, in addition to periplasmic activity. It appeared that extracellular trehalose was hydrolyzed into glucose by extracellular trehalase activity. This glucose was utilized by the cells for growth. The alcohol formation was due to the fermentation of glucose. Addition of extracellular trehalase caused reduction in the lag phase when grown in trehalose medium, supporting our hypothesis of extracellular utilization of trehalose.     

The hatching of common carp (Cyprinus carpio L.) embryos in response to exposure to different concentrations of cryoprotectant at low temperatures

The hatching performance of embryos of the common carp (Cyprinus carpio L.) was examined after 1, 7, 14, 21, or 28 days of storage at -8, -6, -4, -2, 0, 2, or 4 degrees C with different concentrations of methanol (0.5-7.0 M in 0.5 M steps) or varying concentrations of methanol in 0.1 M sucrose or trehalose. Preserved embryos failed to hatch after storage at -8 and -6 degrees C, regardless of the duration of storage or the concentrations tested. Likewise, there was no hatching out above 5.0 M concentration of methanol, even with the addition of sucrose or trehalose. After storage at 2 or 4 degrees C, the hatching rate was higher with mixtures of methanol (1.5 M) and trehalose (0.1 M) than with methanol plus sucrose or methanol alone. At 4 degrees C, the solution containing 1.5 M methanol supplemented with trehalose gave the highest hatching response of embryos stored for 14 days. Comparison of hatching after 24h of storage at the effective temperatures (-4, -2, 0, 2, and 4 degrees C) revealed that low concentrations of methanol were effective at high temperatures and high concentrations at sub-zero temperatures. The combination of 0.1 M trehalose with 1.5 M methanol gave the highest percentage hatching out both at 4 and 2 degrees C. At 0 degrees C, the highest percentage hatching occurred with 0.1 M trehalose plus 2.5 M methanol and at -2 and 4 degrees C, the best results were with 0.1 M trehalose plus 3.0 M methanol.     

Partial purification and properties of a highly specific trehalose phosphate phosphatase from Mycobacterium smegmatis

A specific trehalose phosphate phosphatase was purified approximately 50-fold from Mycobacterium smegmatis. The enzyme had a pH optimum of about 7.0 and was stimulated by Mg(2+). The optimum concentration of Mg(2+) was about 1.5 x 10(-3)m. Of other divalent cations tested, only Co(2+) showed some activity. The K(m) for trehalose phosphate was found to be about 1.5 x 10(-3)m. The enzyme showed slight activity toward mannose-6-P and fructose-6-P but was inactive on a large number of other phosphorylated compounds. Citrate was a competitive inhibitor of the enzyme both with respect to trehalose phosphate concentration and Mg(2+) concentration. This inhibition appears to be due to chelation of Mg(2+) by this compound. Ethylenediaminetetraacetic acid and NaF were also inhibitors of the enzyme, but these inhibitions were noncompetitive.     

Platelet cryopreservation using a trehalose and phosphate formulation

Long-term storage of platelets is infeasible due to platelet activation at low temperatures. In an effort to address this problem, we evaluated the effectiveness of a formulation combining trehalose and phosphate in protecting platelet structure and function following cryopreservation. An annexin V binding assay was used to quantify the efficacy of the trehalose and phosphate formulation in suppressing platelet activation during cryopreservation. Of the platelets cryopreserved with the trehalose plus phosphate formulation, 23% +/- 1.2% were nonactivated, compared with 9.8% +/- 0.26% nonactivated following cryopreservation with only trehalose. The presence of both trehalose and phosphate in the cryopreservation medium is critical for cell survival and preincubation in trehalose plus phosphate solutions further enhances viability. The effectiveness of trehalose plus phosphate in preserving platelets in a nonactivated state is comparable to 6% dimethyl sulfoxide (Me(2)SO). Measurements of platelet metabolic activity using an alamarBlue assay also established that trehalose plus phosphate is superior to trehalose alone. Finally, platelets protected by the trehalose plus phosphate formulation exhibit similar aggregation response upon thrombin addition as fresh platelets, but an increase of cytosolic calcium concentration upon thrombin addition was not observed in the cryopreserved platelets. These results suggest that trehalose and phosphate protect several aspects of platelet structure and function during cryopreservation, including an intact plasma membrane, metabolic activity, and aggregation in response to thrombin, but not intracellular calcium release in response to thrombin.     

Protection against thermal denaturation by trehalose on the plasma membrane H+-ATPase from yeast. Synergetic effect between trehalose and phospholipid environment.

Yeast cells have had to develop mechanisms in order to protect themselves from chemical and physical agents of the environment to which they are exposed. One of these physical agents is thermal variation. Some yeast cells are known to accumulate high concentrations of trehalose when submitted to heat shock. In this work, we have studied the effect of trehalose on the protection against thermal inactivation of purified plasma membrane H+-ATPase from Schizosaccharomyces pombe, in the solubilized and in the reconstituted state. We observed that after 1 min of incubation at 51 degrees C in the presence of 1 M trehalose, about 50% of soluble enzyme remains active. In the same conditions, but in the absence of trehalose, the activity was completely abolished. The t0.5 for the enzyme inactivation increased from 10 to 50 s after reconstitution into asolectin liposomes. Curiously, in the presence of 1 M trehalose, the t0.5 for inactivation of the reconstituted enzyme was further increased to higher than 300 s, regardless of whether trehalose was added inside or outside the liposome. Additionally, the concentration that confers 50% for the protection by trehalose (K0.5) decreased from 0.5 M, in the solubilized state, to 0.04 M in the reconstituted state, suggesting a synergetic effect between sugar and lipids. Gel electrophoresis revealed that the pattern of H+-ATPase cleavage by trypsin changed when 1 M trehalose was present in the buffer. It is suggested that both in a soluble and in a phospholipid environment, accumulation of trehalose leads to a more heat-stable conformation of the enzyme, probably an E2-like form.     

Recrystallization of Ice Crystals in Trehalose Solution at Isothermal Condition

An isothermal ice recrystallization behavior in trehalose solution was investigated. The isothermal recrystallization rate constants of ice crystals in trehalose solution were obtained at ?5 °C, ?7 °C, and ?10 °C. Then the results were compared to those of a sucrose solution used as a control sample. Simultaneous estimation of water mobility in the freeze-concentrated matrix was conducted by ¹H spin–spin relaxation time T₂ to investigate mechanisms causing the different ice crystal recrystallization behaviors of sucrose and trehalose. At lower temperatures, lower recrystallization rates were obtained for both trehalose and sucrose solutions. The ice crystallization rate constants in trahalose solution tended to be smaller than those in sucrose solution at the same temperature. Although different ice contents (less than 3.6%) were observed between trehalose and sucrose solutions at the same temperature, the recrystallization behaviors of ice crystals were not markedly different. The ¹H spin–spin relaxation time T₂ of water components in a freeze-concentrated matrix for trehalose solution was shorter than in a sucrose solution at the same temperature. Results show that the water mobility of trehalose solutions in freeze-concentrated matrix was less than that of sucrose solutions, which was suggested as the reason for retarded ice crystal growth in a trehalose solution. Results of this study suggest that the replacement of sucrose with trehalose will not negatively affect deterioration caused by ice crystal recrystallization in frozen foods and cryobiological materials.