Overexpression and characterization of a thermostable trehalose synthase from Meiothermus ruber

A thermostable trehalose synthase (TreS) gene from Meiothermus ruber CBS-01 was cloned and overexpressed in Escherichia coli. The purified recombinant TreS could utilize maltose to produce trehalose, and showed an optimum pH and temperature of 6.5 and 50°C, respectively. Kinetic analysis showed that the enzyme had a twofold higher catalytic efficiency (k _cat/K _m) for maltose than for trehalose, indicating maltose as the preferred substrate. The TreS also had a weak hydrolytic property with glucose as the byproduct, and glucose was a strong competitive inhibitor of the enzyme. The maximum production of trehalose by the enzyme reached 65% at 20°C. The most importantly the enzyme could maintain very high activity (above 90%) at pH 4.0–8.0 and 60°C 5 h. These results provided that the stable TreS was suitable for the industrial production of trehalose from maltose in a one-step reaction.     

Trehalose synthase of Mycobacterium smegmatis: purification, cloning, expression, and properties of the enzyme.

Trehalose synthase (TreS) catalyzes the reversible interconversion of trehalose (glucosyl-alpha,alpha-1,1-glucose) and maltose (glucosyl-alpha1-4-glucose). TreS was purified from the cytosol of Mycobacterium smegmatis to give a single protein band on SDS gels with a molecular mass of approximately 68 kDa. However, active enzyme exhibited a molecular mass of approximately 390 kDa by gel filtration suggesting that TreS is a hexamer of six identical subunits. Based on amino acid compositions of several peptides, the treS gene was identified in the M. smegmatis genome sequence, and was cloned and expressed in active form in Escherichia coli. The recombinant protein was synthesized with a (His)(6) tag at the amino terminus. The interconversion of trehalose and maltose by the purified TreS was studied at various concentrations of maltose or trehalose. At a maltose concentration of 0.5 mm, an equilibrium mixture containing equal amounts of trehalose and maltose (42-45% of each) was reached during an incubation of about 6 h, whereas at 2 mm maltose, it took about 22 h to reach the same equilibrium. However, when trehalose was the substrate at either 0.5 or 2 mm, only about 30% of the trehalose was converted to maltose in >or= 12 h, indicating that maltose is the preferred substrate. These incubations also produced up to 8-10% free glucose. The K(m) for maltose was approximately 10 mm, whereas for trehalose it was approximately 90 mm. While beta,beta-trehalose, isomaltose (alpha1,6-glucose disaccharide), kojibiose (alpha1,2) or cellobiose (beta1,4) were not substrates for TreS, nigerose (alpha1,3-glucose disaccharide) and alpha,beta-trehalose were utilized at 20 and 15%, respectively, as compared to maltose. The enzyme has a pH optimum of about 7 and is inhibited in a competitive manner by Tris buffer. [(3)H]Trehalose is converted to [(3)H]maltose even in the presence of a 100-fold or more excess of unlabeled maltose, and [(14)C]maltose produces [(14)C]trehalose in excess unlabeled trehalose, suggesting the possibility of separate binding sites for maltose and trehalose. The catalytic mechanism may involve scission of the incoming disaccharide and transfer of a glucose to an enzyme-bound glucose, as [(3)H]glucose incubated with TreS and either unlabeled maltose or trehalose results in formation of [(3)H]disaccharide. TreS also catalyzes production of a glucosamine disaccharide from maltose and glucosamine, suggesting that this enzyme may be valuable in carbohydrate synthetic chemistry.     

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.     

Isolation and Identification of a Thermophilic Strain Producing Trehalose Synthase from Geothermal Water in China

A slightly thermophilic strain, CBS-01, producing trehalose synthase (TreS), was isolated from geothermal water in this study. According to the phenotypic characteristics and phylogenetic analysis of the 16s rRNA gene sequence, it was identified as Meiothermus ruber. The trehalose synthase gene of Meiothermus ruber CBS-01 was cloned by polymerase chain reaction and sequenced. The TreS gene consisted of 2,895 nucleotides, which specified a 964-amino-acid protein. This novel TreS catalyzed reversible interconversion of maltose and trehalose.     

Identification and Characterization of a Novel Trehalose Synthase Gene Derived from Saline-Alkali Soil Metagenomes

A novel trehalose synthase (TreS) gene was identified from a metagenomic library of saline-alkali soil by a simple activity-based screening system. Sequence analysis revealed that TreS encodes a protein of 552 amino acids, with a deduced molecular weight of 63.3 kDa. After being overexpressed in Escherichia coli and purified, the enzymatic properties of TreS were investigated. The recombinant TreS displayed its optimal activity at pH 9.0 and 45 °C, and the addition of most common metal ions (1 or 30 mM) had no inhibition effect on the enzymatic activity evidently, except for the divalent metal ions Zn²⁺ and Hg²⁺. Kinetic analysis showed that the recombinant TreS had a 4.1-fold higher catalytic efficientcy (Kcat/K _m) for maltose than for trehalose. The maximum conversion rate of maltose into trehalose by the TreS was reached more than 78% at a relatively high maltose concentration (30%), making it a good candidate in the large-scale production of trehalsoe after further study. In addition, five amino acid residues, His172, Asp201, Glu251, His318 and Asp319, were shown to be conserved in the TreS, which were also important for glycosyl hydrolase family 13 enzyme catalysis.     

Saturation mutagenesis and self-inducible expression of trehalose synthase in Bacillus subtilis

Trehalose is a nonreducing disaccharide synthesized by trehalose synthase (TreS), which catalyzes the reversible interconversion of maltose and trehalose. We aimed to enhance the catalytic conversion of maltose to trehalose by saturation mutagenesis, and constructed a self-inducible TreS expression system by generating a robust Bacillus subtilis recombinant. We found that the conversion yield and enzymatic activity of TreS was enhanced by saturation mutations, especially by the combination of V407M and K490L mutations. At the same time, these saturation mutations were contributing to reducing by-products in the reaction. Compared to WT TreS, the conversion yield of maltose to trehalose was increased by 11.9%, and the k_cat/K_m toward trehalose was 1.33 times higher in the reaction catalyzed by treS^V407M-K490L. treS^V407M-K490L expression was further observed in the recombinant B. subtilis W800N(Δσ^F) under the influence of P_srfA, P_cry3Aa, and P_srfA-cry3Aa promoters without an inducer. It was shown that P_srfA-cry3Aa was evidently a stronger promoter for treS^V407M-K490L expression, with the intracellular enzymatic activity of recombinant treS^V407M-K490L being over 5,800 U/g at 35 hr in TB medium. These results suggested the combination of two mutations, V407M and K490L, was conducive for the production of trehalose. In addition, the self-inducible TreS^V407M/K490L mutant in the B. subtilis host provides a low-cost choice for the industrial production of endotoxin-free trehalose with high yields.     

Three trehalose synthetic pathways in the acarbose-producing Actinoplanes sp. SN223/29 and evidence for the TreY role in biosynthesis of component C

In this study, three trehalose gene clusters, treX-Y-Z, tpS1, and treS, of the acarbose-producing strain, Actinoplanes sp. SN223/29, have been identified. In particular, five trehalose synthetic genes were sequenced and characterized in detail. They were cloned and expressed in Escherichia coli BL21(DE3)pLysS using the His-tag vector pET19b. The recombinant proteins were purified by Ni²⁺-nitrilotriacetic acid agarose affinity chromatography, and their functions were characterized biochemically. Both the maltooligosyltrehalose synthase (TreY–TreZ) pathway and the trehalose synthase (TreS) pathway have maximum activity at 40°C and at pH 7.5 and 7.0, respectively, in 100-mM phosphate buffer. Meanwhile, the trehalose-6-phosphate synthase (TpS1) showed maximum activity at 35°C and at pH 7.5 in 100 mM Tris–HCl. As a cofactor candidate, Mg²⁺ enhanced the activities of all three trehalose synthetic reactions significantly. TreY produced component C from acarbose by its proposed isomerase activity, but TreS did not. This study suggests that the mutation of treY can improve acarbose production by repressing component C production. Based on the data obtained in this study, a model for component C production in Actinoplanes sp. SN 223/29 is proposed.     

Cloning, expression and functional characterization of a novel trehalose synthase from marine Pseudomonas sp. P8005

Trehalose synthase (TreS) catalyzes the reversible interconversion of maltose and trehalose. A novel treS gene with a length of 3,369 bp, encoding a protein of 1,122 amino acid residues with a predicted molecular mass of 126 kDa, was cloned from a marine Pseudomonas sp. P8005 (CCTCC: M2010298) and expressed in Escherichia coli. The amino acid sequence identities between this novel TreS and other reported TreS is relatively low. The purified recombinant TreS showed an optimum pH and temperature of 7.2 and 37 °C, respectively. The enzyme displayed a high conversion rate (70 %) of maltose to trehalose during equilibrium and had a higher catalytic efficiency (k _cat/K _m) for maltose than for trehalose, suggesting its application in the production of trehalose. In addition to maltose and trehalose, this enzyme can also act on sucrose, although this activity is relatively low. Mutagenesis studies demonstrated that enzymatic activity was reduced dramatically by individually substitution with alanine for D78, Y81, H121, D219, E261, H331 or D332, which implied that these residues might be important in P8005-TreS. Experiments using isotope-labeled substrates showed that [²H₂]trehalose combined with unlabeled trehalose was converted to [²H₂]maltose and maltose, but without any production of [²H]maltose or [²H]trehalose and with no incorporation of exogenous [²H₇]glucose into the disaccharides during the conversion catalyzed by this enzyme. This finding indicated the involvement of an intramolecular mechanism in P8005-TreS catalyzing the reversible interconversion of maltose and trehalose.     

Cloning, Expression and Characterization of a Trehalose Synthase Gene From Rhodococcus opacus

Trehalose is a unique disaccharide capable of protecting proteins against environmental stress. A novel trehalose synthase (TreS) gene from Rhodococcus opacus was cloned and expressed in Escherichia coli Top10 and BL21 (DE3) pLysS, respectively. The recombinant TreS showed a molecular mass of 79 kDa. Thin layer chromatography (TLC) result suggested that this enzyme had the ability to catalyze the mutual conversion of maltose and trehalose. Moreover, high-performance liquid chromatography (HPLC) result suggested that glucose appeared as a byproduct with a conversion rate of 12 %. The purified recombinant enzyme had an optimum temperature of 25 °C and pH optimum around 7.0. Kinetic analysis revealed that the K _m for trehalose was around 98 mM, which was a little higher than that of maltose. The preferred substrate of TreS was maltose according to the analysis of k _cat/K _m. Both 1 and 10 mM of Hg²⁺, Cu²⁺ and Al³⁺ could inhibit the TreS activity, while only 1 mM of Ca²⁺ and Mn²⁺ could increase its activity. Five amino acid residues, Asp²⁴⁴, Glu²⁸⁶, Asp³⁵⁴, His¹⁴⁷ and His³⁵³, were shown to be conserved in R. opacus TreS, which were also important for α-amylase family enzyme catalysis.     

Mechanistic analysis of trehalose synthase from Mycobacterium smegmatis

Trehalose synthase (TreS) catalyzes the reversible interconversion of maltose and trehalose and has been shown recently to function primarily in the mobilization of trehalose as a glycogen precursor. Consequently, the mechanism of this intriguing isomerase is of both academic and potential pharmacological interest. TreS catalyzes the hydrolytic cleavage of α-aryl glucosides as well as α-glucosyl fluoride, thereby allowing facile, continuous assays. Reaction of TreS with 5-fluoroglycosyl fluorides results in the trapping of a covalent glycosyl-enzyme intermediate consistent with TreS being a member of the retaining glycoside hydrolase family 13 enzyme family, thus likely following a two-step, double displacement mechanism. This trapped intermediate was subjected to protease digestion followed by LC-MS/MS analysis, and Asp(230) was thereby identified as the catalytic nucleophile. The isomerization reaction was shown to be an intramolecular process by demonstration of the inability of TreS to incorporate isotope-labeled exogenous glucose into maltose or trehalose consistent with previous studies on other TreS enzymes. The absence of a secondary deuterium kinetic isotope effect and the general independence of k(cat) upon leaving group ability both point to a rate-determining conformational change, likely the opening and closing of the enzyme active site.     

Isolation and identification of a thermophilic strain producing trehalose synthase from geothermal water in China

A slightly thermophilic strain, CBS-01, producing trehalose synthase (TreS), was isolated from geothermal water in this study. According to the phenotypic characteristics and phylogenetic analysis of the 16s rRNA gene sequence, it was identified as Meiothermus ruber. The trehalose synthase gene of Meiothermus ruber CBS-01 was cloned by polymerase chain reaction and sequenced. The TreS gene consisted of 2,895 nucleotides, which specified a 964-amino-acid protein. This novel TreS catalyzed reversible interconversion of maltose and trehalose.     

Insights on the evolution of trehalose biosynthesis

Background  

The compatible solute trehalose is a non-reducing disaccharide, which accumulates upon heat, cold or osmotic stress. It was commonly accepted that trehalose is only present in extremophiles or cryptobiotic organisms. However, in recent years it has been shown that although higher plants do not accumulate trehalose at significant levels they have actively transcribed genes encoding the corresponding biosynthetic enzymes.     

Characterization and expression patterns of a membrane-bound trehalase from <Emphasis Type="Italic">Spodoptera exigua</Emphasis>

Background  

The chitin biosynthesis pathway starts with trehalose in insects and the main functions of trehalases are hydrolysis of trehalose to glucose. Although insects possess two types, soluble trehalase (Tre-1) and membrane-bound trehalase (Tre-2), very little is known about Tre-2 and the difference in function between Tre-1 and Tre-2.     

Homology modeling and function of trehalose synthase from Pseudomonas putida P06

Trehalose is a non-reducing disaccharide that has wide applications in the food industry and pharmaceutical manufacturing. Trehalose synthase (TreS) from Pseudomonas putida P06 catalyzes the reversible interconversion of maltose and trehalose and may have applications in the food industry. However, the catalytic mechanism of TreS is not well understood. Here, we investigated the structural characteristics of this enzyme by homology modeling. The highly conserved Asp294 residue was identified to be critical for catalytic activity. In addition, flexible docking studies of the enzyme–substrate system were performed to predict the interactions between TreS and its substrate, maltose. Amino acids that interact extensively with the substrate and stabilize the substrate in an orientation suitable for enzyme catalysis were identified. The importance of these residues for catalytic activity was confirmed by the biochemical characterization of the relevant mutants generated by site-directed mutagenesis.     

A unique combination of genetic systems for the synthesis of trehalose in Rubrobacter xylanophilus: properties of a rare actinobacterial TreT

Trehalose is the primary organic solute in Rubrobacter xylanophilus under all conditions tested, including those for optimal growth. We detected genes of four different pathways for trehalose synthesis in the genome of this organism, namely, the trehalose-6-phosphate synthase (Tps)/trehalose-6-phosphate phosphatase (Tpp), TreS, TreY/TreZ, and TreT pathways. Moreover, R. xylanophilus is the only known member of the phylum Actinobacteria to harbor TreT. The Tps sequence is typically bacterial, but the Tpp sequence is closely related to eukaryotic counterparts. Both the Tps/Tpp and the TreT pathways were active in vivo, while the TreS and the TreY/TreZ pathways were not active under the growth conditions tested and appear not to contribute to the levels of trehalose observed. The genes from the active pathways were functionally expressed in Escherichia coli, and Tps was found to be highly specific for GDP-glucose, a rare feature among these enzymes. The trehalose-6-phosphate formed was specifically dephosphorylated to trehalose by Tpp. The recombinant TreT synthesized trehalose from different nucleoside diphosphate-glucose donors and glucose, but the activity in R. xylanophilus cell extracts was specific for ADP-glucose. The TreT could also catalyze trehalose hydrolysis in the presence of ADP, but with a very high K_m. Here, we functionally characterize two systems for the synthesis of trehalose in R. xylanophilus, a representative of an ancient lineage of the actinobacteria, and discuss a possible scenario for the exceptional occurrence of treT in this extremophilic bacterium.     

Enhancing the stability of trehalose synthase via SpyTag/SpyCatcher cyclization to improve its performance in industrial biocatalysts

SpyTag and SpyCatcher can spontaneously and rapidly conjugate to form an irreversible and stable covalent bond. The trehalose synthase (TreS) from Thermomonospora curvata was successfully cyclized after the fusion of a SpyTag to its C-terminus and SpyCatcher to the N-terminus. Cyclized TreS retained more than 85% of its activity at temperatures ranging from 40 to 50°C and more than 95% at a pH range of 8 to 10, while the wild type kept only 60 and 80% of its activity under the same conditions. These results demonstrated that cyclized TreS had better resistance to high temperature and alkali than the wild type. Furthermore, structural analysis revealed that cyclized TreS had better conformational stability and was able to fold correctly at a higher temperature than the wild type. Our findings indicate that the use of SpyTag and SpyCatcher to cyclize enzymes is a promising strategy to increase their stability.     

Effects of the N-terminal and C-terminal domains of <Emphasis Type="Italic">Meiothermus ruber</Emphasis> CBS-01 trehalose synthase on thermostability and activity

Numerous trehalose synthases (TreS) from thermophilic microorganisms have extra C-terminal domains. To determine the function of the N- and C-terminal domains of TreS from the thermophilic bacterium Meiothermus ruber CBS-01, the two domains were expressed. From the findings, the N-terminal domain from M. ruber was not active when compared with that from Thermus thermophilus, which had been studied previously. The circular dichroism spectrum showed that the secondary structure of N-terminal domain from M. ruber underwent a greater change than that of C terminus. In addition, the N-terminal domain from T. thermophilus and C terminus from M. ruber were fused. The fusion protein TSTtMr was more efficient and thermostable than the TreS from M. ruber. The N-terminal domain from M. ruber and C terminus from T. thermophilus were fused. The optimum temperature and thermostability of fusion protein TSMrTt were similar to the TreS from M. ruber. It was presumed that aside from the C-terminal domain, the N-terminal domain of TreS from thermophilic bacteria could influence thermostability. For the TreS from M. ruber, the mutant protein R392F led to a complete loss in activity, and R392A showed a sharp decrease in activity.     

Gene cloning,expression, and characterization of a novel trehalose synthase from <Emphasis Type="Italic">Arthrobacter aurescens</Emphasis>

Trehalose synthase (TreS) is an intramolecular transglycosylase. It specially catalyzes the conversion of maltose and trehalose. In this study, a novel treS gene, which had a length of 1,797 bp and encoded 598 amino acids, was cloned from Arthrobacter aurescens CGMCC 1.1892 and expressed in Escherichia coli. Thin layer chromatography results indicated that it could catalyze the conversion between maltose and trehalose in one step. However, the ion chromatography results showed that, as a byproduct, about 13% glucose was also produced. The purified recombinant enzyme had a molecular weight of 68 kDa and showed its optimal activity at 35 °C and pH 6.5. This enzyme was not thermostable, and its activity was increased by 1 mM Mg²⁺, Mn²⁺, and Ca²⁺ while strongly inhibited by 5 mM Cu²⁺ and SDS.     

Regulation of expression of trehalose-6-phosphate synthase during cold shock in Arthrobacter strain A3

Trehalose is a chemical chaperone known to protect a variety of organisms against cold stress. Members of the genus Arthrobacter, which belongs to the Actinomycetales group, exhibit strong resistance to stress conditions, but exactly how trehalose synthesis is regulated in conditions of cold stress is still unknown. Here, we report that Arthrobacter strain A3, which was isolated from the alpine permafrost, has only two trehalose synthesis pathways (OtsA/B and TreS), while other Arthrobacter spp. have three. Mutants and immunoblot analyses indicate that trehalose is mainly synthesized via OtsA at low temperatures in Arthrobacter strain A3. Therefore, we have focused on the regulation of OtsA expression during cold shock. The results indicated that both low temperature and accumulation of trehalose can inhibit OtsA expression. The elongation factor Tu, which binds to OtsA, stabilizes the expression of OtsA in the cold.