Pathways of glycogen synthesis in Novikoff ascites-hepatoma cells

Affinity of glucose, fructose and mannose for tumour hexokinase and their rates of phosphorylation at saturation concentration have been correlated with rates of glycogen synthesis by intact tumour cells at different concentrations of the three substrates. Competition experiments with one sugar labelled and the other sugar unlabelled indicate inhibition of glycogen synthesis by the sugar with a low K(m) for hexokinase. Glycogen synthesis from glucose 1-phosphate in aged cells and from nucleoside in freshly prepared cells is stimulated by fructose and inhibited by glucose. The decrease in glycogen formation from glucose 1-phosphate by oligomycin is partially overcome by increased fructose concentrations. These results are explained by an activation of alpha-glucan phosphorylase by fructose and an inhibition of this enzyme by glucose. It is suggested that differences in localization of glucose 6-phosphate, available to the intact cell in various ways, determine its transformation into glycogen by either the UDP-glucose-alpha-glucan glucosyltransferase reaction or by the alpha-glucan phosphorylase reaction.     

Brain Ligatin: A Membrane Lectin That Binds Acetylcholinesterase

Ligatin, a lectin that recognizes phosphorylated sugars, has been demonstrated in mammalian tissues to bind specific hydrolases to cell surfaces. Ligatin exists as a filament that can be released from membranes still complexed with its bound hydrolases by treatment of membrane preparations with CaCl₂ and/or pH 8.0. The ligatin-hydrolase complexes subsequently can be dissociated with ethyleneglycol-bis(β-amino-ethyl ether) N, N′-tetraacetic acid, resulting in a concurrent depolymerization of the ligatin filament. From membrane preparations of cerebrum, this procedure solubilized ligatin and a membrane-bound acetylcholinesterase (EC 3.1.1.7). Binding of the cosolubilized acetylcholinesterase to ligatin could be demonstrated in vitro by affinity chromatography using the immobilized lectin. Ligatin-hydrolase complexes have been shown to be dissociated by specific phosphorylated sugars (mannose 6-phosphate and glucose 1-phosphate). These sugars were also effective in eluting bound brain acetylcholinesterase from ligatin affinity columns. Analysis of labeled glycitols produced by tritiated borohydride reduction confirmed the presence of phosphorylated sugars on the ligatin-cosolubilized material from brain.     

Glucose permease of Escherichia coli. The effect of cysteine to serine mutations on the function, stability, and regulation of transport and phosphorylation

The glucose permease (IIGlc/IIIGlc complex) of the bacterial phosphotransferase system mediates sugar transport across the cytoplasmic membrane concomitant with sugar phosphorylation. It contains 3 cysteine residues, of which Cys-204 and Cys-326 are localized in the hydrophobic part and Cys-421 in the hydrophilic part of the IIGlc subunit. The cysteines were replaced, one at a time, by serines, and the effect of these mutations on stability, regulation, and catalytic properties of IIGlc was investigated in vivo and in vitro. Cys-204 and Cys-326 are not required for catalytic function and are not involved in the membrane potential-dependent regulation of IIGlc activity (Robillard, G. T., and Konings, W. N. (1982) Eur. J. Biochem. 127, 597-604). Replacement of these cysteines by serines results, however, in reduced stability of IIGlc in vivo (C204S) and in vitro (C204S and C326S), indicating that these substitutions in a hydrophobic environment can destabilize the protein structure. Cys-421 is absolutely required for transport and phosphorylation of glucose. C421S can neither be phosphorylated by phospho-IIIGlc nor catalyze the phosphoryl exchange between [14C] glucose and glucose 6-phosphate at equilibrium. C421S does not interfere with the activity of simultaneously expressed wild-type IIGlc. Unexpectedly C421S and wild-type IIGlc support growth on maltose of Escherichia coli ZSC112L (Curtis, S. J., and Epstein, W. (1975) J. Bacteriol. 122, 1189-1199), a strain which otherwise does not grow on this disaccharide as the only carbon source. C421S appears to facilitate the efflux of a growth inhibiting intermediate (glucose?) of maltose. Wild-type IIGlc catalyzes the intracellular phosphorylation of glucose derived from maltose. It is concluded that the cytoplasmic domain of IIGlc interacts with IIIGlc, the cytoplasmic subunit of the glucose permease, and also participates in phosphorylation of glucose, and that phosphorylation occurs independently of transport, although transport of glucose by wild-type IIGlc cannot occur without concomitant phosphorylation.     

Structure of a Micrococcus lysodeikticus cell wall fragment containing phosphorylated sugars.

A polysaccharide-peptidoglycan complex containing different phosphorylated sugars from Micrococcus lysodeikticus cell wall has been isolated and purified. The peptidoglycan contained muramic acid 6-phosphate and N-acetylglucosamine 6-phosphate as phosphorylated sugars in addition to other sugar residues. Mild acid hydrolysis of the peptidoglycan and subsequent reduction of the released polysaccharide showed therein the presence of glucose and N-acetyl-glucosamine in the linkage of the external polysaccharide residues to the peptidoglycan through phosphodiester linkage. These data suggest the presence of polysaccharide chains linked to a peptidoglycan core through two phosphorylated sugars via two different terminal carbohydrate residues of the external polysaccharide chains in a same polymer.     

Regulation of protein synthesis in rabbit reticulocyte lysate. Glucose 6-phosphate is required to maintain the activity of eukaryotic initiation factor (eIF)-2B by a mechanism that is independent of the phosphorylation of eIF-2 alpha

Previous studies from other laboratories, using rabbit reticulocyte lysate filtered through Sephadex G-25 or G-50, have demonstrated that glucose 6-phosphate is required to maintain active rates of translation, but its mechanism of action is currently unsettled. We have tested whether glucose 6-phosphate is required to prevent activation of the hemin-controlled translational repressor and the phosphorylation of the smallest or alpha subunit of eukaryotic initiation factor 2 (eIF-2). We have found that antibody to the hemin-controlled translational repressor can completely restore protein synthesis in reticulocyte lysate, filtered through Sephadex G-25, that is incubated in the absence of hemin and presence of glucose 6-phosphate, but cannot restore protein synthesis in such lysate incubated in the presence of hemin and absence of glucose 6-phosphate. We have also found, using a modification of the method of Matts and London [1984) J. Biol. Chem. 259, 6708-6711) to measure the ability of gel-filtered lysate to dissociate and exchange GDP from eIF-2.GDP, that this endogenous eIF-2B activity is reduced to the same low level in the presence of hemin and absence of glucose 6-phosphate as it is in the absence of hemin and presence of glucose 6-phosphate. Although there is a low level of phosphorylation of eIF-2 alpha in gel-filtered lysate given hemin but no glucose 6-phosphate, it cannot account for the loss of eIF-2B activity, since this phosphorylation is removed by antibody to the hemin-controlled translational repressor or isocitrate, which do not restore protein synthesis or eIF-2B activity, and not by fructose 1,6-diphosphate, which does partially restore protein synthesis and eIF-2B activity. These findings suggest that sugar phosphates may exert a direct effect on eIF-2B and may be required for its proper function. Additional support for this conclusion is our finding that protein synthesis and eIF-2B activity in partially hemin-deficient lysate can be restored by high levels of glucose 6-phosphate or fructose 1,6-diphosphate without a reduction in the level of phosphorylated eIF-2 alpha, suggesting that such levels of sugar phosphate may permit restoration of normal function with a limiting amount of eIF-2B.     

Competitive inhibitors of yeast phosphoglucose isomerase: synthesis and evaluation of new types of phosphorylated sugars from the synthon D-arabinolactone-5-phosphate

Designed as competitive inhibitors of the isomerization reaction catalyzed by the potential chemotherapeutic target phosphoglucose isomerases (PGI), D-arabinonamide-5-phosphate and D-arabinohydrazine-5-phosphate were synthesized and fully characterized. These new types of phosphorylated sugar derivatives were easily and efficiently obtained in a one-step procedure from the promising synthon D-arabinono-1,4-lactone 5-phosphate. These two compounds proved to be new good competitive inhibitors of yeast PGI with the substrate D-fructose-6-phosphate, though not as strong as D-arabinohydroxamic acid-5-phosphate. Overall, our results are in accord with the postulated 1,2-cis-enediolate species as a probable high-energy intermediate of the PGI-catalyzed reaction.     

Kinetic study of a phosphoryl exchange reaction between fructose and fructose 1-phosphate catalyzed by the membrane-bound enzyme II of the phosphoenolpyruvate-fructose 1-phosphotransferase system of Bacillus subtilis.

A phosphoryl exchange reaction between fructose 1-phosphate and fructose was found to be catalyzed by a membrane preparation isolated from Bacillus subtilis. The regulation of the biosynthesis of the activity in the wild type as well as in the regulation mutants fruB closely correlates with that of the membrane-bound enzyme II of the phosphoenolpyruvate fructose 1-phosphotransferase system which is known to mediate the transmembrane vectorial phosphorylation of fructose. The computed analysis of the kinetic data shows that the mechanism of the enzyme II is ping-pong, i.e. that a phosphoryl-enzyme intermediate occurs in the reaction. The apparent dissociation constants of the enzyme II/fructose 1-phosphate complex and of the phosphoryl enzyme II/fructose complex are estimated. The value of the standard free energy of the hydrolysis of the bond between the phosphoryl moiety and the enzyme suggests a covalent bonding. This intermediate is assumed to occur in the physiological functioning of the enzyme which utilizes the phosphocarrier protein HPr as phosphoryl donor. The exchange reaction is competitively inhibited by high fructose concentrations: this indicates that the same site of the enzyme binds fructose and fructose 1-phosphate, this site being accessible to fructose on the external side of the membrane when the enzyme is phosphorylated.     

Phosphorylation of 3-O-methyl-D-glucose and catabolite repression in yeast

The glucose analog, 3-O-methyl-D-glucose, inhibited growth of yeast on non-fermentable carbon sources. The sugar was phosphorylated by the yeast and also in vitro by a commercial preparation of yeast hexokinase. The chromatographic behaviour of the phosphorylated product was identical in both cases. This suggests that 3-O-methyl-D-glucose is phosphorylated to form 3-O-methyl-D-glucose 6-phosphate. The inhibition of the growth appears to be due to interference with the derepression of several enzymes necessary to grow on non-fermentable carbon sources. Spontaneous mutants whose growth was unaffected by 3-O-methyl-D-glucose were isolated. In these mutants there was no significant accumulation of the phosphorylated ester and the derepression of the enzymes tested was not affected by the glucose analog.     

Phosphorylation of D-glucosamine by rat liver glucokinase.

D-Glucosamine was found to be phosphorylated by a rat liver extract in the presence of a high concentration of glucose, which was formerly believed to be a strong competitive inhibitor of this reaction. Results suggested that glucosamine may be phosphorylated by high Km hexokinase, i.e. glucokinase [EC 2.7.1.2]. The enzyme involved was separated from specific N-acetyl-D-glucosamine kinase [EC 2.7.1.59]. The phosphorylation was not inhibited by a physiological level of glucose or glucose 6-phosphate, which strongly inhibited low Km hexokinase. The apparent Km of glucokinase for glucosamine was estimated as 8 mM, which is ten times that of low Km hexokinase.     

Biochemical characterization of avirulent exoC mutants of Agrobacterium tumefaciens.

The synthesis of periplasmic beta(1-2)glucan is required for crown gall tumor formation by Agrobacterium tumefaciens and for effective nodulation of alfalfa by Rhizobium meliloti. The exoC (pscA) gene is required for this synthesis by both bacteria as well as for the synthesis of capsular polysaccharide and normal lipopolysaccharide. We tested the possibility that the pleiotropic ExoC phenotype is due to a defect in the synthesis of an intermediate common to several polysaccharide biosynthetic pathways. Cytoplasmic extracts from wild-type A. tumefaciens and from exoC mutants of A. tumefaciens containing a cloned wild-type exoC gene synthesized in vitro UDP-glucose from glucose, glucose 1-phosphate, and glucose 6-phosphate. Extracts from exoC mutants synthesized UDP-glucose from glucose 1-phosphate but not from glucose or glucose 6-phosphate. Membranes from exoC mutant cells synthesized beta(1-2)glucan in vitro when exogenous UDP-glucose was added and contained the 235-kilodalton protein, which has been shown to carry out this synthesis in wild-type cells. We conclude that the inability of exoC mutants to synthesize beta(1-2)glucan is due to a deficiency in the activity of the enzyme phosphoglucomutase (EC 2.7.5.1), which in wild-type bacteria converts glucose 6-phosphate to glucose 1-phosphate, an intermediate in the synthesis of UDP-glucose. This interpretation can account for all of the deficiencies in polysaccharide synthesis which have been observed in these mutants.     

Glucose permease of Escherichia coli. Purification of the IIGlc subunit and functional characterization of its oligomeric forms

The membrane subunit (IIGlc) of the glucose permease has been purified from overproducing Escherichia coli. About 2 mg of pure protein was obtained from 10 g (wet weight) of cells. IIGlc of E. coli and Salmonella typhimurium are functionally indistinguishable. A small difference was revealed, however, by a monoclonal antibody which neutralizes glucose phosphorylation activity of IIGlc from S. typhimurium, but does not cross-react with IIGlc of E. coli. A dimeric form of purified IIGlc can be detected by chemical cross-linking and by zonal sedimentation at 4 degrees C. Upon mild oxidation a disulfide bond is formed between the subunits of the dimer. Oxidized IIGlc is more stable than the reduced form but is inactive because it cannot be phosphorylated by the cytoplasmic subunit (IIIGlc) of the glucose permease. Cys-421 could be identified as the oxidation-sensitive residue, using a novel assay to detect IIIGlc-dependent phosphorylation of nitrocellulose-bound IIGlc that has been purified by gel electrophoresis. No dimeric form of phosphorylated IIGlc could be detected. Because phosphorylated IIGlc is a catalytic intermediate it is concluded that catalytically active IIGlc is a monomer and that the dimeric form is an artefact observed only with purified resting IIGlc. That IIGlc is active as a monomer is further supported by the observation that monomeric IIGlc catalyzes phosphoryl exchange between glucose and glucose 6-phosphate at equilibrium and that an excess of inactive IIGlc with a serine replacing Cys-421 does not interfere with the activity of wild-type IIGlc as would be expected if interaction between the subunits in a dimer were essential for activity.     

Factors affecting hepatic glycolysis and some changes that occur during development

1. Glycolysis by the supernatant fraction of homogenates of liver from guinea pigs and rats at various stages of development (foetal, newborn and adult) has been examined in a suitably fortified medium by measurement of inorganic phosphate uptake and production of lactate and glycerol 1-phosphate. 2. Starting with glucose as substrate, two rate-determining steps in glycolysis occur at the stages of glucose phosphorylation and the phosphofructokinase reaction in liver tissue from animals of all ages. Effects of the post-natal development of glucokinase are recorded. 3. The appearance of microsomal glucose 6-phosphatase activity around birth has an effect on glycolysis owing to competition for glucose 6-phosphate. 4. A stimulating effect of the nuclear fraction, especially from foetal liver, on glycolysis by the supernatant fraction is interpreted as being due to stimulation by adenosine-triphosphatase activity at the 3-phosphoglycerate-kinase stage.     

Lactose metabolism in Streptococcus lactis: phosphorylation of galactose and glucose moieties in vivo.

Starved cells of Streptococcus lactis ML3 grown previously on lactose, galactose, or maltose were devoid of adenosine 5'-triphosphate contained only three glycolytic intermediates: 3-phosphoglycerate, 2-phosphoglycerate, and phosphoenolpyruvate (PEP). The three metabolites (total concentration, ca 40 mM) served as the intracellular PEP potential for sugar transport via PEP-dependent phosphotransferase systems. When accumulation of [14C]lactose by iodoacetate-inhibited starved cells was abolished within 1 s of commencement of transport, a phosphorylated disaccharide was identified by autoradiography. The compound was isolated by ion-exchange (borate) chromatography, and enzymatic analysis showed that the derivative was 6-phosphoryl-O-beta-D-galactopyranosyl (1 leads to 4')-alpha-D-glucopyranose (lactose 6-phosphate). After maximum lactose uptake (ca. 15 mM in 15 s) the cells were collected by membrane filtration and extracted with trichloroacetic acid. Neither free nor phosphorylated lactose was detected in cell extracts, but enzymatic analysis revealed high levels of galactose 6-phosphate and glucose 6-phosphate. The starved organisms rapidly accumulated glucose, 2-deoxy-D-glucose, methyl-beta-D-thiogalactopyranoside, and o-nitrophenyl-beta-D-galactopyranoside in phosphorylated form to intracellular concentrations of 32, 32, 42, and 38.5 mM, respectively. In contrast, maximum accumulation of lactose (ca. 15 mM) was only 40 to 50% that of the monosaccharides. From the stoichiometry of PEP-dependent lactose transport and the results of enzymatic analysis, it was concluded that (i) ca. 60% of the PEP potential was utilized via the lactose phosphotransferase system for phosphorylation of the galactosyl moiety of the disaccharide, and (ii) the residual potential (ca. 40%) was consumed during phosphorylation of the glucose moiety.     

Formation and reorientation of glucose 1,6-bisphosphate in the PMM/PGM reaction: transient-state kinetic studies

The interconversion of glucose 1-phosphate and glucose 6-phosphate, catalyzed by Pseudomonas aeruginosa phosphomannomutase/phosphoglucomutase, has been studied by transient-state kinetic techniques. Glucose 1,6-bisphosphate is formed as an intermediate in the reaction, but an obligatory step in the catalytic cycle appears to be the formation of an enzyme-glucose 1,6-bisphosphate complex that is not competent to form either glucose 1-phosphate or glucose 6-phosphate directly. We suggest that during the lifetime of this complex the glucose 1,6-bisphosphate intermediate undergoes the 180 degrees reorientation that is required for completion of the catalytic cycle. The formation of glucose 1,6-bisphosphate from glucose 1-phosphate is in rapid equilibrium relative to the rest of the reaction, where K(eq) = 0.14. In the opposite direction, glucose 1,6-bisphosphate is formed from glucose 6-phosphate with a rate constant of 12 s(-)(1), and the reverse step occurs with a rate constant of 255 s(-)(1). The interconversion of the productive and nonproductive glucose 1,6-bisphosphate complexes occurs with a rate constant of 64 s(-)(1) in one direction and 48 s(-)(1) in the other direction. Glucose 1,6-bisphosphate remains associated with the enzyme during reorientation. Isotope trapping studies indicate that it partitions to form glucose 1-phosphate or glucose 6-phosphate 14.3 times more frequently than it dissociates from the enzyme.     

The formation of reactive intermediate(s) of glucose 6-phosphate and lysine capable of rapidly reacting with DNA

Glucose has been shown to react nonenzymatically in vitro with DNA, to form products with spectral properties similar to those observed with the nonenzymatic glycosylation of proteins in vivo. The incubation in vitro of glucose or glucose 6-phosphate with f1 phage DNA results in a time- and concentration-dependent loss of transfection efficiency. It has also been shown that incubation in vitro of pBR322 DNA with glucose 6-phosphate prompts a loss in transformation capability as well as gross DNA alterations. In the present communication, we have investigated a model reaction of glucose 6-phosphate with the amino groups of lysine to form reactive intermediates which are capable of forming covalent adducts with DNA. The preincubation of glucose 6-phosphate and [3H]lysine leads to a time- and concentration-dependent formation of reactive intermediates. These intermediates, which accumulate with time, can subsequently react with single- or double-stranded DNA to form acid-stable complexes. Studies done with synthetic polynucleotides suggest low reactivity of the intermediate with thymidine. The formation of the reactive intermediates is saturated by the addition of excess unlabeled lysine. Once formed the intermediates are insensitive to the addition of aminoguanidine and to reduction by sodium borohydride. The chemical reactions between sugars and lysine reported here and the reactivity of that product with DNA provide a model for exploring the classes of DNA damage that may contribute to the loss of DNA function during aging.     

Kinetics and subunit interaction of the mannitol-specific enzyme II of the Escherichia coli phosphoenolpyruvate-dependent phosphotransferase system

Purified mannitol-specific enzyme II (EIImtl), in the presence of the detergent Lubrol, catalyzes the phosphorylation of mannitol from P-HPr via a classical ping-pong mechanism involving the participation of a phosphorylated EIImtl intermediate. This intermediate has been demonstrated by using radioactive phosphoenolpyruvate. Upon addition of mannitol, at least 80% of the enzyme-bound phosphoryl groups can be converted to mannitol 1-phosphate. The EIImtl concentration dependence of the exchange reaction indicates that self-association is a prerequisite for catalytic activity. The self-association can be achieved by increasing the EIImtl concentration or at low concentrations of EIImtl by adding HPr or bovine serum albumin. The equilibrium is shifted toward the dissociated form by mannitol 1-phosphate, resulting in a mannitol 1-phosphate induced inhibition. Mannitol does not affect the association state of the enzyme. Both mannitol and mannitol 1-phosphate also act as classical substrate inhibitors. The apparent Ki of each compound, however, is approximately equal to its apparent Km, suggesting that mannitol and mannitol 1-phosphate bind at the same site on EIImtl. Due to strong inhibition provided by mannitol and mannitol 1-phosphate in the exchange reaction, the kinetics of this reaction cannot be used to determine whether the reaction proceeds via a ping-pong or an ordered reaction mechanism.     

Formation of sorbitol 6-phosphate by bovine and human lens aldose reductase, sorbitol dehydrogenase and sorbitol kinase

Formation of sorbitol 6-phosphate by bovine and human lens aldose reductase and sorbitol dehydrogenase by the reduction of glucose 6-phosphate and fructose 6-phosphate, respectively, has been demonstrated. The reaction product has been identified by Dowex-formate column chromatography, gas chromatography and mass spectrometry. Sorbitol 6-phosphate can also be formed by the phosphorylation of sorbitol by lens sorbitol kinase in the presence of ATP.     

Novel phosphoenolpyruvate-dependent futile cycle in Streptococcus lactis: 2-deoxy-D-glucose uncouples energy production from growth.

The addition of 2-deoxy-D-glucose to cultures of Streptococcus lactis 133 that were growing exponentially on sucrose or lactose reduced the growth rate by ca. 95%. Inhibition did not occur with glucose or mannose as the growth sugar. The reduction in growth rate was concomitant with rapid accumulation of the analog in phosphorylated form (2-deoxy-D-glucose 6-phosphate) via the phosphoenolpyruvate-dependent mannose:phosphotransferase system. Within 5 min the intracellular 2-deoxy-D-glucose 6-phosphate concentration reached a steady-state level of greater than 100 mM. After maximum accumulation of the sugar phosphate, the rate of sucrose metabolism (glycolysis) decreased by only 30%, but the cells were depleted of fructose-1,6-diphosphate. The addition of glucose to 2-deoxy-D-glucose 6-phosphate preloaded cells caused expulsion of 2-deoxy-D-glucose and a resumption of normal growth. S. lactis 133 contained an intracellular Mg2+-dependent, fluoride-sensitive phosphatase which hydrolyzed 2-deoxy-D-glucose 6-phosphate (and glucose 6-phosphate) to free sugar and inorganic phosphate. Because of continued dephosphorylation and efflux of the non-metabolizable analog, the maintenance of the intracellular 2-deoxy-D-glucose 6-phosphate pool during growth stasis was dependent upon continued glycolysis. This steady-state condition represented a dynamic equilibrium of: (i) phosphoenolpyruvate-dependent accumulation of 2-deoxy-D-glucose 6-phosphate, (ii) intracellular dephosphorylation, and (iii) efflux of free 2-deoxy-D-glucose. This sequence of events constitutes a futile cycle which promotes the dissipation of phosphoenolpyruvate. We conclude that 2-deoxy-D-glucose functions as an uncoupler by dissociating energy production from growth in S. lactis 133.     

The effect of sugars on the activity of sorbitol dehydrogenase from the cytoplasm of bovine liver cells

The effect of sugar and its phosphate derivatives on sorbitoldehydrogenase from bovine liver has been studied. The presence of 100 mM glucose, mannose, and arabinose did not influence that activity of the studied reaction, whereas fructose, sorbose, and xylose, inhibit the reaction by 20-25%. This can be explained in terms of inhibition by the final reaction products. Inhibition by glucose-6-phosphate (24%), glucose-1-phosphate (21%), and fructose-6-phosphate (42%) is of particular interest since these compounds may play a regulatory role.     

Mechanism-based inactivation of rabbit muscle phosphoglucomutase by nojirimycin 6-phosphate

Nojirimycin 6-phosphate (N6P) was tested as a substrate and inhibitor for phosphoglucomutase (PGM). In the absence of glucose 1,6-bisphosphate (GBP), the incubation of PGM and N6P resulted in the complete inactivation of all enzyme activity. When equimolar amounts of N6P and GBP were incubated together with PGM, the GBP was quantitatively converted to glucose 6-phosphate (G6P) and phosphate. At higher ratios of GBP and N6P (greater than 100) the final concentration of G6P produced was found to be 19 times the initial N6P concentration. These results have been interpreted to suggest that the phosphorylated form of PGM catalyzes the phosphorylation of N6P at C-1. This intermediate rapidly eliminates phosphate to form an imine and the dephosphorylated enzyme. The dephosphorylated enzyme is rapidly rephosphorylated by GBP and forms G6P. The imine is nonenzymatically hydrated back to N6P. Occasionally (5%) the imine isomerizes to a compound that is not processed by PGM.