Last Step in the Conversion of Trehalose to Glycogen: A MYCOBACTERIAL ENZYME THAT TRANSFERS MALTOSE FROM MALTOSE 1-PHOSPHATE TO GLYCOGEN

We show that Mycobacterium smegmatis has an enzyme catalyzing transfer of maltose from [¹⁴C]maltose 1-phosphate to glycogen. This enzyme was purified 90-fold from crude extracts and characterized. Maltose transfer required addition of an acceptor. Liver, oyster, or mycobacterial glycogens were the best acceptors, whereas amylopectin had good activity, but amylose was a poor acceptor. Maltosaccharides inhibited the transfer of maltose from [¹⁴C]maltose-1-P to glycogen because they were also acceptors of maltose, and they caused production of larger sized radioactive maltosaccharides. When maltotetraose was the acceptor, over 90% of the ¹⁴C-labeled product was maltohexaose, and no radioactivity was in maltopentaose, demonstrating that maltose was transferred intact. Stoichiometry showed that 0.89 μmol of inorganic phosphate was produced for each micromole of maltose transferred to glycogen, and 56% of the added maltose-1-P was transferred to glycogen. This enzyme has been named α1,4-glucan:maltose-1-P maltosyltransferase (GMPMT). Transfer of maltose to glycogen was inhibited by micromolar amounts of inorganic phosphate or arsenate but was only slightly inhibited by millimolar concentrations of glucose-1-P, glucose-6-P, or inorganic pyrophosphate. GMPMT was compared with glycogen phosphorylase (GP). GMPMT catalyzed transfer of [¹⁴C]maltose-1-P, but not [¹⁴C]glucose-1-P, to glycogen, whereas GP transferred radioactivity from glucose-1-P but not maltose-1-P. GMPMT and GP were both inhibited by 1,4-dideoxy-1,4-imino-d-arabinitol, but only GP was inhibited by isofagomine. Because mycobacteria that contain trehalose synthase accumulate large amounts of glycogen when grown in high concentrations of trehalose, we propose that trehalose synthase, maltokinase, and GMPMT represent a new pathway of glycogen synthesis using trehalose as the source of glucose.     

Production of trehalose phosphorylase by Catellatospora ferruginea

Abstract A range of microorganisms was screened for new and high producer strains of trehalose phosphorylase (EC 2.4.1.64). Trehalose phosphorylase activity was found in cells of actinomycetes of the genera Actinomadura, Amycolata, Catellatospora, Kineosporia , and Nocardia . Among them, Catellatospora ferruginea showed the highest enzyme activity. Trehalose phosphorylase from C. ferruginea was able to catalyse both the phosphorolysis of trehalose into β-glucose 1-phosphate and d-glucose and the synthesis of trehalose from β-glucose 1-phosphate and d-glucose.     

Transglucosylation potential of six sucrose phosphorylases toward different classes of acceptors

In this study, the transglucosylation potential of six sucrose phosphorylase (SP) enzymes has been compared using eighty putative acceptors from different structural classes. To increase the solubility of hydrophobic acceptors, the addition of various co-solvents was first evaluated. All enzymes were found to retain at least 50% of their activity in 25% dimethylsulfoxide, with the enzymes from Bifidobacterium adolescentis and Streptococcus mutans being the most stable. Screening of the enzymes’ specificity then revealed that the vast majority of acceptors are transglucosylated very slowly by SP, at a rate that is comparable to the contaminating hydrolytic reaction. The enzyme from S. mutans displayed the narrowest acceptor specificity and the one from Leuconostoc mesenteroides NRRL B1355 the broadest. However, high activity could only be detected on l-sorbose and l-arabinose, besides the native acceptors d-fructose and phosphate. Improving the affinity for alternative acceptors by means of enzyme engineering will, therefore, be a major challenge for the commercial exploitation of the transglucosylation potential of sucrose phosphorylase.     

Sucrose phosphorylase: a powerful transglucosylation catalyst for synthesis of α-D-glucosides as industrial fine chemicals

Abstract

Sucrose phosphorylase is a bacterial transglucosidase that catalyzes conversion of sucrose and phosphate into α-D-glucose-1-phosphate and D-fructose. The enzyme utilizes a glycoside hydrolase-like double displacement mechanism that involves a catalytically competent β-glucosyl enzyme intermediate. In addition to reaction with phosphate, glucosylated sucrose phosphorylase can undergo hydrolysis to yield α-D-glucose or it can decompose via glucosyl transfer to a hydroxy group in suitable acceptor molecules, giving new α-D-glucosidic products. The glucosyl acceptor specificity of sucrose phosphorylase is reviewed, focusing on applications of the enzyme in glucoside synthesis. Polyhydroxylated compounds such as sugars and sugar alcohols are often glucosylated efficiently. Aryl alcohols and different carboxylic acids also serve as acceptors for enzymatic transglucosylation. The natural osmolyte 2-O-(α-D-glucopyranosyl)-sn-glycerol (GG) was prepared by regioselective glucosylation of glycerol from sucrose using the phosphorylase from Leuconostoc mesenteroides. An industrial process for production of GG as active ingredient of cosmetic formulations has been recently developed. General advantages of sucrose phosphorylase as a transglucosylation catalyst lie in the use of sucrose as a high-energy glucosyl donor and the usually weak hydrolase activity of the enzyme towards substrate and product.     

Engineering trehalose synthesis in Lactococcus lactis for improved stress tolerance

Trehalose accumulation is a common cell defense strategy against a variety of stressful conditions. In particular, our team detected high levels of trehalose in Propionibacterium freudenreichii in response to acid stress, a result that led to the idea that endowing Lactococcus lactis with the capacity to synthesize trehalose could improve the acid tolerance of this organism. To this end, we took advantage of the endogenous genes involved in the trehalose catabolic pathway of L. lactis, i.e., trePP and pgmB, encoding trehalose 6-phosphate phosphorylase and β-phosphoglucomutase, respectively, which enabled the synthesis of trehalose 6-phosphate. Given that L. lactis lacks trehalose 6-phosphate phosphatase, the respective gene, otsB, from the food-grade organism P. freudenreichii was used to provide the required activity. The trehalose yield was approximately 15% in resting cells and in mid-exponential-phase cells grown without pH control. The intracellular concentration of trehalose reached maximal values of approximately 170 mM, but at least 67% of the trehalose produced was found in the growth medium. The viability of mutant and control strains was examined after exposure to heat, cold or acid shock, and freeze-drying. The trehalose-producing strains showed improved tolerance (5- to 10-fold-higher survivability) to acid (pH 3) and cold shock (4°C); there was also a strong improvement in cell survival in response to heat shock (45°C), and no protection was rendered against dehydration. The insight provided by this work may help the design of food-grade strains optimized for the dairy industry as well as for oral drug delivery.     

Transglucosylation Catalyzed by Sucrose Phosphorylase from Leuconostoc mesenteroides and Production of Glucosyl-xylitol

The synthesis of glucooligosaccharides from α-D-glucose-1-phosphate by transglucosylation with sucrose phosphorylase from Leuconostoc mesenteroides was studied using the purified enzyme and high performance liquid chromatography. The enzyme had a rather broad acceptor specificity and transferred glucosyl residues to various acceptors such as sugars and sugar alcohols. Especially, 5-carbon sugar alcohols (pentitols), D- and L-arabitol were acceptors equal to D-fructose, which was known as a good acceptor. The transfer product of xylitol formed by the enzyme was investigated. The structure of the product was found to be 4-O-α-D-glucopyranosyl-xylitol (G-X) by acid hydrolysis and ¹³C-nuclear magnetic resonance analysis. G-X is a probable candidate for a preventive for dental caries because it reduced the synthesis of water-insoluble glucan by Streptococcus mutans and kept a neutral pH in the cell suspension.     

Beta-glucose 1-phosphate-interconverting enzymes in maltose- and trehalose-fermenting lactic acid bacteria

Maltose and trehalose catabolic pathways are linked through their common enzyme, beta-phosphoglucomutase, and metabolite, beta-glucose 1-phosphate, in Lactococcus lactis. Maltose is degraded by the concerted action of maltose phosphorylase and beta-phosphoglucomutase, whereas trehalose is assimilated by a novel pathway, including the recently discovered enzyme, trehalose 6-phosphate phosphorylase, and beta-phosphoglucomutase. In the present study, 40 strains of lactic acid bacteria were investigated for utilization of metabolic reactions involving beta-glucose 1-phosphate. All genera of the low G+C content lactic acid bacteria belonging to the clostridial subbranch of Gram-positive bacteria were represented in the study. The strains, which fermented maltose or trehalose, were investigated for beta-phosphoglucomutase, maltose phosphorylase and trehalose 6-phosphate phosphorylase activity, as indications of maltose and trehalose catabolic pathways involving beta-glucose 1-phosphate interconversions. Eighty per cent of all strains fermented maltose and, of these strains, 63% were shown to use a maltose phosphorylase/beta- phosphoglucomutase pathway. One-third of the strains fermenting trehalose were found to harbour trehalose 6-phosphate phosphorylase activity, and these were also shown to possess beta-phosphoglucomutase activity. Mainly L. lactis and Enterococcus faecalis strains were found to harbour the novel trehalose 6-phosphate phosphorylase/beta-phosphoglucomutase pathway. As lower beta-glucose 1-phosphate interconverting enzyme activities were observed in the majority of glucose-cultivated lactic acid bacteria, glucose was suggested to repress the synthesis of these enzymes in most strains. Thus, metabolic reactions involving the beta-anomer of glucose 1-phosphate are frequently found in both maltose- and trehalose-utilizing lactic acid bacteria.     

Acceptor specificity of 4-alpha-glucanotransferases of mammalian glycogen debranching enzymes

Glycogen debranching enzyme (GDE) has two distinct active sites for its 4-alpha-glucanotransferase and amylo-alpha-1,6-glucosidase activities. The GDE 4-alpha-glucanotransferases of mammals show stringent donor specificity; only alpha-glucans with an alpha-1,6-linked maltotetraosyl or maltotriosyl branch function as donors of a maltotriosyl or maltosyl residue. In this study, we investigated the acceptor specificity of the 4-alpha-glucanotransferases using methyl alpha-maltooligosides, p-nitrophenyl alpha-maltooligosides, and pyridylaminated maltooligosaccharides of various sizes as the acceptor substrates, and phosphorylase limit dextrin as the donor substrate. High-performance liquid chromatography analysis of the transfer products indicated that maltotriosyl and maltosyl residues were specifically transferred from phosphorylase limit dextrin to acceptors with a maltopentaosyl residue comprising a nonreducing-end. These results suggest that the acceptor binding sites in the active sites of mammalian GDE 4-alpha-glucanotransferases are composed of tandem subsites that are geometrically complementary to five glucose residues.     

The molecular basis for the broad substrate specificity of human sulfotransferase 1A1

Cytosolic sulfotransferases (SULTs) are mammalian enzymes that detoxify a wide variety of chemicals through the addition of a sulfate group. Despite extensive research, the molecular basis for the broad specificity of SULTs is still not understood. Here, structural, protein engineering and kinetic approaches were employed to obtain deep understanding of the molecular basis for the broad specificity, catalytic activity and substrate inhibition of SULT1A1. We have determined five new structures of SULT1A1 in complex with different acceptors, and utilized a directed evolution approach to generate SULT1A1 mutants with enhanced thermostability and increased catalytic activity. We found that active site plasticity enables binding of different acceptors and identified dramatic structural changes in the SULT1A1 active site leading to the binding of a second acceptor molecule in a conserved yet non-productive manner. Our combined approach highlights the dominant role of SULT1A1 structural flexibility in controlling the specificity and activity of this enzyme.     

α-Glucose-1-phosphate formation by a novel trehalose phosphorylase from Flammulina velutipes

A novel type of trehalose phosphorylase was found in a basidiomycete. Flammulina velutipes . The enzyme catalyzes both the reversible phosphorolysis of trehalose to form α-glucose 1-phosphate and glucose and also the synthesis of trehalose. Comparison of the specific activity of trehalose phosphorylase with that of trehalase suggested that the function of the former enzyme was more important in the fruit-bodies of this fungus.     

Construction of cellobiose phosphorylase variants with broadened acceptor specificity towards anomerically substituted glucosides

The general application of glycoside phosphorylases such as cellobiose phosphorylase (CP) for glycoside synthesis is hindered by their relatively narrow substrate specificity. We have previously reported on the creation of Cellulomonas uda CP enzyme variants with either modified donor or acceptor specificity. Remarkably, in this study it was found that the donor mutant also displays broadened acceptor specificity towards several β‐glucosides. Triple mutants containing donor (T508I/N667A) as well as acceptor mutations (E649C or E649G) also display a broader acceptor specificity than any of the parent enzymes. Moreover, further broadening of the acceptor specificity has been achieved by site‐saturation mutagenesis of residues near the active site entrance. The best enzyme variant contains the additional N156D and N163D mutations and is active towards various alkyl β‐glucosides, methyl α‐glucoside and cellobiose. In comparison with the wild‐type C. uda CP enzyme, which cannot accept anomerically substituted glucosides at all, the obtained increase in substrate specificity is significant. The described CP enzyme variants should be useful for the synthesis of cellobiosides and other glycosides with prebiotic and pharmaceutical properties. Biotechnol. Bioeng. 2010;107: 413–420. © 2010 Wiley Periodicals, Inc.     

Trehalose phosphorylase from Pichia fermentans and its role in the metabolism of trehalose

During a screening for novel microbial trehalose phosphorylase three Pichia strains were identified as producers of this particular enzyme that have not yet been described. To our knowledge, this is the first time that this enzyme activity has been shown in yeasts. Pichia fermentans formed trehalose phosphorylase when cultivated on a growth medium containing easily metabolizable sugers such as glucose. Addition of NaCl (0.4 M) to the medium increased the synthesis of the enzyme significantly. Production of trehalose phosphorylase was found to be growth-associated with a maximum of activity formed at the transition of the exponential to the stationary phase of growth. Trehalose phosphorylase catalyzes the phosphorolytic cleavage of trehalose, yielding glucose 1-phosphate (glucose-1-P) and glucose as products. In vitro the enzyme readily catalyzes the reverse reaction, the synthesis of trehalose from glucose and glucose-1-P. For this reaction, the enzyme of P. fermentans was found to utilize -glucose-1-P preferentially. A partially purified enzyme preparation showed a pH optimum of 6.3 for the synthesis of trehalose. The enzyme was found to be rather unstable; it was easily inactivated by dilution unless Ca²⁺ or Mn²⁺ were added. This instability is presumably caused by dissociation of the enzyme. In contrast to other yeasts, P. fermentans rapidly degraded intracellularly accumulated trehalose when the carbon source in the medium was depleted. Trehalose phosphorylase seems to be a key enzyme in the degradative pathway of trehalose in P. fermentans. Additional enzymes in this catabolic pathway of trehalose include phosphoglucomutase, glucose-6-phosphate dehydrogenase, and gluconolactonase.This contribution is part of the Ph.D. thesis of Ingrid Schick     

Enzymatic Synthesis of α-Anomer-Selective D-Glucosides Using Maltose Phosphorylase

A maltose phosphorylase (EC 2.4.1.8; MPase) showed novel acceptor specificity and transferred the glucosyl moiety of maltose not only to sugars but also to various acceptors having alcoholic OH groups. Salicyl alcohol acted as acceptor for MPase from Enterococcus hirae, and the product, salicyl-O-α-D-glucopyranoside (α-SalGlc) was identified. The yield based on supplied salicyl alcohol was 86% (mol/mol).     

Development and application of a screening assay for glycoside phosphorylases

Glycoside phosphorylases (GPs) are interesting enzymes for the glycosylation of chemical molecules. They require only a glycosyl phosphate as sugar donor and an acceptor molecule with a free hydroxyl group. Their narrow substrate specificity, however, limits the application of GPs for general glycoside synthesis. Although an enzyme’s substrate specificity can be altered and broadened by protein engineering and directed evolution, this requires a suitable screening assay. Such a screening assay has not yet been described for GPs. Here we report a screening procedure for GPs based on the measurement of released inorganic phosphate in the direction of glycoside synthesis. It appeared necessary to inhibit endogenous phosphatase activity in crude Escherichia coli cell extracts with molybdate, and inorganic phosphate was measured with a modified phosphomolybdate method. The screening system is general and can be used to screen GP enzyme libraries for novel donor and acceptor specificities. It was successfully applied to screen a residue E649 saturation mutagenesis library of Cellulomonas uda cellobiose phosphorylase (CP) for novel acceptor specificity. An E649C enzyme variant was found with novel acceptor specificity toward alkyl β-glucosides and phenyl β-glucoside. This is the first report of a CP enzyme variant with modified acceptor specificity.     

Increasing the transglycosylation activity of alpha-galactosidase from Bifidobacterium adolescentis DSM 20083 by site-directed mutagenesis

The alpha-galactosidase (AGA) from Bifidobacterium adolescentis DSM 20083 has a high transglycosylation activity. The optimal conditions for this activity are pH 8, and 37 degrees C. At high melibiose concentration (600 mM), approximately 64% of the enzyme-substrate encounters resulted in transglycosylation. Examination of the acceptor specificity showed that AGA required a hydroxyl group at C-6 for transglycosylation. Pentoses, hexuronic acids, deoxyhexoses, and alditols did not serve as acceptor molecules. Disaccharides were found to be good acceptors. A putative 3D-structure of the catalytic site of AGA was obtained by homology modeling. Based on this structure and amino acid sequence alignments, site-directed mutagenesis was performed to increase the transglycosylation efficiency of the enzyme, which resulted in four positive mutants. The positive single mutations were combined, resulting in six double mutants. The mutant H497M had an increase in transglycosylation of 16%, whereas most of the single mutations showed an increase of 2%-5% compared to the wild-type AGA. The double mutants G382C-Y500L, and H497M-Y500L had an increase in transglycosylation activity of 10%-16%, compared to the wild-type enzyme, whereas the increase for the other double mutants was low (4%-7%). The results show that with a single mutation (H497M) the transglycosylation efficiency can be increased from 64% to 75% of all enzyme-substrate encounters. Combining successful single mutants in double mutations did not necessarily result in an extra increase in transglycosylation efficiency. The donor and acceptor specificity did not change in the mutants, whereas the thermostability of the mutants with G382C decreased drastically.     

Engineering the acceptor specificity of trehalose phosphorylase for the production of trehalose analogs

Trehalose (α‐D ‐glucopyranosyl‐(1,1)‐α‐D ‐glucopyranoside) is widely used in the food industry, thanks to its protective effect against freezing and dehydration. Analogs of trehalose have the additional benefit that they are not digested and thus do not contribute to our caloric intake. Such trehalose analogs can be produced with the enzyme trehalose phosphorylase, when it is applied in the reverse, synthetic mode. Despite the enzyme's broad acceptor specificity, its catalytic efficiency for alternative monosaccharides is much lower than for glucose. For galactose, this difference is shown here to be caused by a lower K_m whereas the k_cat for both substrates is equal. Consequently, increasing the affinity was attempted by enzyme engineering of the trehalose phosphorylase from Thermoanaerobacter brockii, using both semirational and random mutagenesis. While a semirational approach proved unsuccessful, high‐throughput screening of an error‐prone PCR library resulted in the discovery of three beneficial mutations that lowered K_m two‐ to three‐fold. In addition, it was found that mutation of these positions also leads to an improved catalytic efficiency for mannose and fructose, suggesting their involvement in acceptor promiscuity. Combining the beneficial mutations did not further improve the affinity, and even resulted in a decreased catalytic activity and thermostability. Therefore, enzyme variant R448S is proposed as new biocatalyst for the industrial production of lactotrehalose (α‐D ‐glucopyranosyl‐(1,1)‐α‐D ‐galactopyranoside). © 2012 American Institute of Chemical Engineers Biotechnol. Prog., 2012     

Enzymatic synthesis of alpha-anomer-selective D-glucosides using maltose phosphorylase

A maltose phosphorylase (EC 2.4.1.8; MPase) showed novel acceptor specificity and transferred the glucosyl moiety of maltose not only to sugars but also to various acceptors having alcoholic OH groups. Salicyl alcohol acted as acceptor for MPase from Enterococcus hirae, and the product, salicyl-O-alpha-D-glucopyranoside (alpha-SalGlc) was identified. The yield based on supplied salicyl alcohol was 86% (mol/mol).     

Dextransucrase: Acceptor substrate reactions

Studies were carried out on the acceptor specificity of dextransucrase which had been isolated from Streptococcus sanguis 10558. Radioactive acceptors were employed in reactions with cold sucrose and the counts incorporated were taken as a measure of “acceptor activity.” An order of relative activity was found to be polysaccharide > oligosaccharide > glycoside > monosaccharide. An evaluation of the time course of the reaction with α-methyl glucoside, or maltose, showed that a homologous series of oligosaccharides were formed from each. This suggested that the individual members of the series were related as precursors and products. The kinetics of the reaction with different acceptors was studied. All acceptors studied caused an activation of the enzyme and changes in the K_m for sucrose. The kinetic constants obtained were also used to compare the various acceptors.     

Structural characterization of enzymatically synthesized dextran and oligosaccharides from Leuconostoc mesenteroides NRRL B-1426 dextransucrase

Leuconostoc mesenteroides NRRL B-1426 dextransucrase synthesized a high molecular mass dextran (>2 × 10⁶ Da) with ～85.5% α-(1→6) linear and ～14.5% α-(1→3) branched linkages. This high molecular mass dextran containing branched α-(1→3) linkages can be readily hydrolyzed for the production of enzyme-resistant isomalto-oligosaccharides. The acceptor specificity of dextransucrase for the transglycosylation reaction was studied using sixteen different acceptors. Among the sixteen acceptors used, isomaltose was found to be the best, having 89% efficiency followed by gentiobiose (64%), glucose (30%), cellobiose (25%), lactose (22.5%), melibiose (17%), and trehalose (2.3%) with reference to maltose, a known best acceptor. The β-linked disaccharide, gentiobiose, showed significant efficiency for oligosaccharide production that can be used as a potential prebiotic.     

Carbohydrate metabolism in starved fifth instar larvae of Manduca sexta

The influence of starvation on carbohydrate metabolism in fifth instar larvae of Manduca sexta was studied. The percentage of active fat body glycogen phosphorylase increased from 10% to approximately 50% within 3 h of starvation; afterward the enzyme was slowly inactivated. The increase of phosphorylase activity might have been caused by a peptide(s) from the CC. The amount of fat body glycogen in starved animals decreased over 24 h by approximately 20 mg. The released glucose molecules seem to be converted mainly to trehalose because the hemolymph trehalose concentration in starved animals was always slightly higher than in the fed controls, and the glucose concentration decreased even when phosphorylase was activated. The chitosan content in starved larvae increased during the first 9 h of treatment to the same extent as in fed controls. It is suggested that fat body glycogen phosphorylase was activated during starvation to provide substrates for chitin synthesis and energy metabolism.