A functional glycogen biosynthesis pathway in Lactobacillus acidophilus: expression and analysis of the glg operon

Glycogen metabolism contributes to energy storage and various physiological functions in some prokaryotes, including colonization persistence. A role for glycogen metabolism is proposed on the survival and fitness of Lactobacillus acidophilus, a probiotic microbe, in the human gastrointestinal environment. L. acidophilus NCFM possesses a glycogen metabolism (glg) operon consisting of glgBCDAP‐amy‐pgm genes. Expression of the glg operon and glycogen accumulation were carbon source‐ and growth phase‐dependent, and were repressed by glucose. The highest intracellular glycogen content was observed in early log‐phase cells grown on trehalose, which was followed by a drastic decrease of glycogen content prior to entering stationary phase. In raffinose‐grown cells, however, glycogen accumulation gradually declined following early log phase and was maintained at stable levels throughout stationary phase. Raffinose also induced an overall higher temporal glg expression throughout growth compared with trehalose. Isogenic ΔglgA (glycogen synthase) and ΔglgB (glycogen‐branching enzyme) mutants are glycogen‐deficient and exhibited growth defects on raffinose. The latter observation suggests a reciprocal relationship between glycogen synthesis and raffinose metabolism. Deletion of glgB or glgP (glycogen phosphorylase) resulted in defective growth and increased bile sensitivity. The data indicate that glycogen metabolism is involved in growth maintenance, bile tolerance and complex carbohydrate utilization in L. acidophilus.     

Analysis of the Escherichia coli glycogen gene cluster suggests that catabolic enzymes are encoded among the biosynthetic genes

The nucleotide sequences of the Escherichia coli genome between the glycogen biosynthetic genes glgB and glgC, and 1170 bp of DNA which follows glgA have been determined. The region between glgB and glgC contains an open reading frame (ORF) of 1521 bp which we call glgX. This ORF is capable of coding for an M_r 56 684 protein. The deduced amino acid (aa) sequence for the putative product shows significant similarity to the E. coli glycogen branching enzyme, and to several different glucan hydrolases and transferases. The regions of sequence similarity include residues which have been reported to be involved in substrate binding and catalysis by taka-amylase. This suggests that the proposed product may catalyze hydrolysis or glycosyltransferase reactions. The cloned region which follows glgA contains an incomplete ORF (1149 bp), glgY, which appears to encode 383 aa of the N terminus of glycogen phosphorylase, based upon sequence similarity with the enzyme from rabbit muscle (47% identical aa residues) and with maltodextrin phosphorylase from E. coli (37% identical aa residues). Results suggest that neither ORF is required for glycogen biosynthesis. The localization of glycogen biosynthetic and degradative genes together in a cluster may facilitate the regulation of these systems in vivo.     

The gap1 Operon of the Cyanobacterium SynechococcusPCC 7942 Carries a Gene Encoding Glycogen Phosphorylase and Is Induced under Anaerobic Conditions

The cloning and sequencing of the gap1 operon, which encodes the glycolytic NAD-specific glyceraldehyde-3-phosphate dehydrogenase in the cyanobacterium Synechococcus PCC 7942, showed that the gap1 gene is closely linked to the glgP gene encoding glycogen phosphorylase (an enzyme that catalyzes the first step of glycogen degradation). Northern blotting experiments showed that the gap1 and glgP genes are coexpressed and organized in a bicistronic operon, whose expression is enhanced under anaerobic conditions. The nucleotide sequence of the operon has been submitted to GenBank under accession number AF428099.     

Long term regulation of glycogen metabolizing enzymes by insulin in H4 hepatoma cells

Insulin alone at concentrations of less than 1 to 5 uU/ml increased the enzyme activities of glycogen synthase, synthase phosphatase, phosphorylase, and phosphorylase phosphatase in hepatoma H4 cells in culture in the presence and absence of serum. Increase in total and active forms of glycogen synthase and phosphorylase were observed. Cycloheximide blocked the action of insulin on glycogen synthase, glycogen synthase phosphatase and phosphorylase phosphatase. The enzymes with the exception of glycogen synthase phosphatase were expressed with greater hormonal sensitivity in the absence as compared to the presence of serum in terms of hormone concentration required and or time of onset.These results demonstrate that these glycogen metabolizing enzymes are under long term control by insulin, with glycogen synthase being the most sensitive of the enzymes studied to the action of the hormone.Supported by grants from NIH AM 14334 and AM 22125 (University of Virginia Diabetes Research and Training Center) and by a grant from Lilly Research Lab, and the March of Dimes     

Molecular cloning and nucleotide sequence of the glycogen branching enzyme gene (glgB) from Bacillus stearothermophilus and expression in Escherichia coli and Bacillus subtilis.

Summary The structural gene for the Bacillus stearothermophilus glycogen branching enzyme (glgB) was cloned in Escherichia coli. Nucleotide sequence analysis revealed a 1917 nucleotide open reading frame (ORF) encoding a protein with an M_r of 74787 showing extensive similarity to other bacterial branching enzymes, but with a shorter N-terminal region. A second ORF of 951 nucleotides encoding a 36971 Da protein started upstream of the glgB gene. The N-terminus of the ORF2 gene product had similarity to the Alcaligenes eutrophus czcD gene, which is involved in cobalt-zinc-cadmium resistance. The B. stearothermophilus glgB gene was preceded by a sequence with extensive similarity to promoters recognized by Bacillus subtilis RNA polymerase containing sigma factor H (E - ^H). The glgB promoter was utilized in B. subtilis exclusively in the stationary phase, and only transcribed at low levels in B. subtilis spoOH, indicating that sigma factor H was essential for the expression of the glgB gene in B. subtilis. In an expression vector, the B. stearothermophilus glgB gene directed the synthesis of a thermostable branching enzyme in E. coli as well as in B. subtilis, with optimal branching activity at 53° C.     

Metabolic function of glycogen phosphorylase and trehalose phosphorylase in fruit-body formation ofFlammulina velutipes

Glycogen phosphorylase in the vegetative mycelium ofFlammulina velutipes converts glycogen to α-glucose 1-phosphate (G1P) in the colony during fruit-body development. Glycogen may contribute to the synthesis of trehalose as the starting material in the vegetative mycelium during the fruiting process of the colony, and the trehalose produced is translocated into the fruit-bodies as the main carbohydrate substrate for their development. Trehalose phosphorylase activity in the vegetative mycelium was at a relatively high level until fruit-body initiation, suggesting the turnover of this disaccharide during the vegetative stage of the colony development. Trehalose phosphorylase activity in the stipes showed a peak level at the early phase of fruit-body development, suggesting the continuing phosphorolysis of trehalose by this enzyme. The stipes also showed a high specific activity of phosphoglucomutase at a sufficient level to facilitate the conversion of G1P to α-glucose 6-phosphate (G6P). In the pilei a large amount of G1P remained until the growth of the fruit-bodies ceased. Trehalase activities in the stipes and pilei were at a very low level, and this enzyme may not contribute to the catabolism of trehalose in the fruit-body development.     

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.     

Changes in lipid and carbohydrate metabolism during starvation in adult Manduca sexta

Summary Adult Manduca sexta feed very irregularly in the laboratory, and many adult males never feed. Feeding adults live longer and feeding females lay many more eggs; however, in both feeding (sugar water) and starving adults a decrease of metabolic reserves is observed. Carbohydrates disappear from hemolymph and from fat body. Fat body lipid also decreases, while hemolymph lipid concentration increases strongly in starving adults. The activity of fat body glycogen phosphorylase increases strongly in starving adult M. sexta. The activity of glycogen phosphorylase is correlated inversely with hemolymph sugar concentration. Injected trehalose inactivates glycogen phosphorylase within 2 h, and lowers the hemolymph lipid level within 6 h. In starving adult M. sexta, neither the activation of glycogen phosphorylase nor the increase of hemolymph lipid concentration depends on adipokinetic hormone, since cardiacectomy does not prevent the activation of glycogen phosphorylase nor the increase of hemolymph lipid level.Abbreviations AKH adipokinetic hormone - EDTA ethylenediamine tetraacetate Present address: Department of Biochemistry and Center for Insect Science, The University of Arizona, Tucson, AZ 85721, USA     

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     

Gene expression and molecular characterization of a thermostable trehalose phosphorylase fromThermoanaerobacter tengcongensis

A gene encoding the trehalose phosphorylase (TreP), which reversibly catalyzes trehalose degradation and synthesis from α-glucose-1-phosphate (α-Glc-1-P) and glucose, was cloned fromThermoanaerobacter tengcongensis and successfully expressed inEscherichia coli. The overexpressed TreP, with a molecular mass of approximately 90 kDa, was determined by SDS-PAGE. It catalyzes trehalose synthesis and degradation optimally at 70°C (for 30 min), with the optimum pHs at 6.0 and 7.0, respectively. It is highly thermostable, with a 77% residual activity after incubation at 50°C for 7 h. Under the optimum reaction conditions, 50 μg crude enzyme of the TreP is able to catalyze the synthesis of trehalose up to 11.6 mmol/L from 25 mmol/L α-Glc-1-P and 125 mmol/L glucose within 30 min, while only 1.5 mmol/L out of 250 mmol/L trehalose is degraded within the same time period. Dot blotting revealed that thetreP gene inT. tengcongensis was upregulated in response to salt stress but downregulated when trehalose was supplied. Both results indicate that the dominant function of theT. tengcongensis TreP is catalyzing trehalose synthesis but not degradation. Thus it might provide a novel route for industrial production of trehalose.     

Metabolic Engineering of Corynebacterium glutamicum for Trehalose Overproduction: Role of the TreYZ Trehalose Biosynthetic Pathway

Trehalose has many potential applications in biotechnology and the food industry due to its protective effect against environmental stress. Our work explores microbiological production methods based on the capacity of Corynebacterium glutamicum to excrete trehalose. We address here raising trehalose productivity through homologous overexpression of maltooligosyltrehalose synthase and the maltooligosyltrehalose trehalohydrolase genes. In addition, heterologous expression of the UDP-glucose pyrophosphorylase gene from Escherichia coli improved the supply of glycogen. Gene expression effects were tested on enzymatic activities and intracellular glycogen content, as well as on accumulated and excreted trehalose. Overexpression of the treY gene and the treY/treZ synthetic operon significantly increased maltooligosyltrehalose synthase activity, the rate-limiting step, and improved the specific productivity and the final titer of trehalose. Furthermore, a strong decrease was noted in glycogen accumulation. Expression of galU/treY and galU/treYZ synthetic operons showed a partial recovery in the intracellular glycogen levels and a significant improvement in both intra- and extracellular trehalose content.     

Role of glucose and insulin in regulating glycogen synthase and phosphorylase activities in rainbow trout hepatocytes

This study, using ¹³C nuclear magnetic resonance spectroscopy showed enrichment of glycogen carbon (C1) from ¹³C-labelled (C1) glucose indicating a direct pathway for glycogen synthesis from glucose in rainbow trout (Oncorhynchus mykiss) hepatocytes. There was a direct relationship between hepatocyte glycogen content and total glycogen synthase, total glycogen phosphorylase and glycogen phosphorylase a activities, whereas the relationship was inverse between glycogen content and % glycogen synthase a and glycogen synthase a/glycogen phosphorylase a ratio. Incubation of hepatocytes with glucose (3 or 10 mmol·1^-1) did not modify either glycogen synthase or glycogen phosphorylase activities. Insulin (porcine, 10^-8 mol·1^-1) in the medium significantly decreased total glycogen phosphorylase and glycogen phosphorylase a activities, but had no significant effect on glycogen synthase activities when compared to the controls (absence of insulin). In the presence of 10 mmol·1^-1 glucose, insulin increased % glycogen synthase a and decreased % glycogen phosphorylase a activities in trout hepatocytes. Also, the effect of insulin on the activities of % glycogen synthase a and glycogen synthase a/glycogen phosphorylase a ratio were more pronounced at low than at high hepatocyte glycogen content. The results indicate that in trout hepatocytes both the glycogen synthetic and breakdown pathways are active concurrently in vitro and any subtle alterations in the phosphorylase to synthase ratio may determine the hepatic glycogen content. Insulin plays an important role in the regulation of glycogen metabolism in rainbow trout hepatocytes. The effect of insulin on hepatocyte glycogen content may be under the control of several factors, including plasma glucose concentration and hepatocyte glycogen content.     

Structural rationale for the short branched substrate specificity of the glycogen debranching enzyme GlgX

Glycogen serves as major energy storage in most living organisms. GlgX, with its gene in the glycogen degradation operon, functions in glycogen catabolism by selectively catalyzing the debranching of polysaccharide outer chains in bacterial glycosynthesis. GlgX hydrolyzes α‐1,6‐glycosidic linkages of phosphorylase‐limit dextrin containing only three or four glucose subunits produced by glycogen phosphorylase. To understand its mechanism and unique substrate specificity toward short branched α‐polyglucans, we determined the structure of GlgX from Escherichia Coli K12 at 2.25 Å resolution. The structure reveals a monomer consisting of three major domains with high structural similarity to the subunit of TreX, the oligomeric bifunctional glycogen debranching enzyme (GDE) from Sulfolobus. In the overlapping substrate binding groove, conserved residues Leu270, Asp271, and Pro208 block the cleft, yielding a shorter narrow GlgX cleft compared to that of TreX. Residues 207–213 form a unique helical conformation that is observed in both GlgX and TreX, possibly distinguishing GDEs from isoamylases and pullulanases. The structural feature observed at the substrate binding groove provides a molecular explanation for the unique substrate specificity of GlgX for G4 phosphorylase‐limit dextrin and the discriminative activity of TreX and GlgX toward substrates of varying lengths. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Regulation of energy metabolism in yeast

Summary The recessive, nuclear gene mutation glc1, which causes glycogen deficiency in Saccharomyces cerevisiae, is highly plciotropic. Studies of the inheritance of glc1 revealed two classes of phenotypic characteristics: I. Traits invariably associated with the mutant gene and II. Traits whose expressions require the presence of glc1 and one or more additional genes. Class I traits include glycogen deficiency and the loss of capacity to accumulate trehalose in nonproliferating conditions. Traits in the second class include a decreased rate of growth on ethanol medium, a deficiency in cytochrome a.a ₃ and an enhanced accumulation of pigment, probably a metalloporphyrin. Constructed strains containing both glc1 and the constitutive maltose fermentation gene MAL4 ⁰ can accumulate trehalose but not glycogen during growth on glucose. However, accumulated trehalose is degraded when cells are exposed to nonproliferating conditions. It is proposed that the glc1 mutation affects a regulatory system, probably involving a protein kinase and/or protein phosphatase, which regulates glycogen synthase and trehalase. Independent regulation of trehalose synthesis by a system controlled by MAL4 ⁰ is indicated.     

Comparative Genomic and Phylogenetic Analyses of Gammaproteobacterial glg Genes Traced the Origin of the Escherichia coli Glycogen glgBXCAP Operon to the Last Common Ancestor of the Sister Orders Enterobacteriales and Pasteurellales

Production of branched α-glucan, glycogen-like polymers is widely spread in the Bacteria domain. The glycogen pathway of synthesis and degradation has been fairly well characterized in the model enterobacterial species Escherichia coli (order Enterobacteriales, class Gammaproteobacteria), in which the cognate genes (branching enzyme glgB, debranching enzyme glgX, ADP-glucose pyrophosphorylase glgC, glycogen synthase glgA, and glycogen phosphorylase glgP) are clustered in a glgBXCAP operon arrangement. However, the evolutionary origin of this particular arrangement and of its constituent genes is unknown. Here, by using 265 complete gammaproteobacterial genomes we have carried out a comparative analysis of the presence, copy number and arrangement of glg genes in all lineages of the Gammaproteobacteria. These analyses revealed large variations in glg gene presence, copy number and arrangements among different gammaproteobacterial lineages. However, the glgBXCAP arrangement was remarkably conserved in all glg-possessing species of the orders Enterobacteriales and Pasteurellales (the E/P group). Subsequent phylogenetic analyses of glg genes present in the Gammaproteobacteria and in other main bacterial groups indicated that glg genes have undergone a complex evolutionary history in which horizontal gene transfer may have played an important role. These analyses also revealed that the E/P glgBXCAP genes (a) share a common evolutionary origin, (b) were vertically transmitted within the E/P group, and (c) are closely related to glg genes of some phylogenetically distant betaproteobacterial species. The overall data allowed tracing the origin of the E. coli glgBXCAP operon to the last common ancestor of the E/P group, and also to uncover a likely glgBXCAP transfer event from the E/P group to particular lineages of the Betaproteobacteria.     

Production of trehalose synthase from a basidiomycete, Grifola frondosa, in Escherichia coli

The genomic DNA and cDNA for a gene encoding a novel trehalose synthase (TSase) catalyzing trehalose synthesis from α-d-glucose 1-phosphate and d-glucose were cloned from a basidiomycete, Grifola frondosa. Nucleotide sequencing showed that the 732-amino-acid TSase-encoding region was separated by eight introns. Consistent with the novelty of TSase, there were no homologous proteins registered in the databases. Recombinant TSase with a histidine tag at the NH₂-terminal end, produced in Escherichia coli, showed enzyme activity similar to that purified from the original G. frondosa strain. Incubation of α-d-glucose 1-phosphate and d-glucose in the presence of recombinant TSase generated trehalose, in agreement with the enzymatic property of TSase that the equilibrium lay far in the direction of trehalose synthesis. Received: 12 January 1998 / Received revision: 20 February 1998 / Accepted: 20 March 1998     

Purification and properties of α-glucose 1-phosphate-forming trehalose phosphorylase from a basidiomycete,Pleurotus ostreatus

Pleurotus ostreatus produced a high activity of α-glucose 1-phosphate (α-Glc 1-P) forming trehalose phosphorylase in vegetative mycelia and fruit-bodies. The enzyme was purified to homogeneity from the fruit-bodies by a procedure involving ammonium sulfate fractionation, DEAE-cellulose column chromatographies and cellulose phosphate column chromatographies. The enzyme catalyzes both the phosphorolysis of trehalose to produce α-Glc 1-P and glucose, and the synthesis of trehalose. It was not active toward other α- or β-glucosyl disaccharides and polysaccharides. The optimum pH was 7.0 for phosphorolysis and 6.4 for synthesis of trehalose. The Km values for trehalose and Pi in phospholytic reaction were 75 mM and 4.2 mM, respectively. Those for glucose and α-Glc 1-P in synthetic reaction were 505 mM and 38 mM, respectively. The estimated molecular mass by the sedimentation equilibrium method using an ultracentrifuge was 120 kDa. The molecular mass of the subunit (61 kDa) by SDS-polyacrylamide gel electrophoresis suggested that the enzyme was a dimer of two identical subunits. The addition of glycerol higher than 25% into the enzyme solution stabilized its activity. The removal of phosphorus ions from the enzyme solution, by means of dialysis or electrophoresis, caused inactivation of the enzyme, probably by dissociation of the holoenzyme into the subunit proteins.     

Impact of Heterologous Expression of Escherichia coli UDP-Glucose Pyrophosphorylase on Trehalose and Glycogen Synthesis in Corynebacterium glutamicum

Trehalose is a disaccharide with a wide range of applications in the food industry. We recently proposed a strategy for trehalose production based on improved strains of the gram-positive bacterium Corynebacterium glutamicum. This microorganism synthesizes trehalose through two major pathways, OtsBA and TreYZ, by using UDP-glucose and ADP-glucose, respectively, as the glucosyl donors. In this paper we describe improvement of the UDP-glucose supply through heterologous expression in C. glutamicum of the UDP-glucose pyrophosphorylase gene from Escherichia coli, either expressed alone or coexpressed with the E. coli ots genes (galU otsBA synthetic operon). The impact of such expression on trehalose accumulation and excretion, glycogen accumulation, and the growth pattern of new recombinant strains is described. Expression of the galU otsBA synthetic operon resulted in a sixfold increase in the accumulated and excreted trehalose relative to that in a wild-type strain. Surprisingly, single expression of galU also resulted in an increase in the accumulated trehalose. This increase in trehalose synthesis was abolished upon deletion of the TreYZ pathway. These results proved that UDP-glucose has an important role not only in the OtsBA pathway but also in the TreYZ pathway.