Anomeric specificity of D-glucose metabolism in rat adipocytes

The anomeric specificity of D-glucose metabolism was investigated in rat adipocytes exposed for 60 min at 8 degrees C to pure alpha- or beta-D-glucose or to equilibrated D-glucose. The rate of D-[5-3H]glucose utilization was higher with alpha- than beta-D-glucose. However, as judged from the oxidation of D-[1-14C]glucose and D-[6-14C]glucose anomers, the fraction of D-glucose catabolism occurring via the pentose cycle was higher with beta- than alpha-D-glucose. In the presence of equilibrated D-glucose, the utilization of alpha-D-[5-3H]glucose and the oxidation of both alpha-D-[1-14C]glucose and alpha-D-[6-14C]glucose were higher, relative to the anomer concentration, than the corresponding values for beta-D-glucose. It is concluded that the anomeric specificity of D-glucose metabolism is operative in adipocytes, even when they are exposed to equilibrated D-glucose.     

Reciprocal influence of glucose anomers upon their respective phosphorylation by hexokinase

The phosphorylation of D-glucose (1.0mM) was measured in homogenates of tumoral islet cells incubated at 7 degrees C in the presence of labelled alpha- and/or beta-D-glucose, with or without exogenous glucose 6-phosphate. The close-to-maximal reaction velocity of hexokinase was higher with beta- than alpha-D-glucose. The latter anomer inhibited beta-D-glucose phosphorylation more than the beta-anomer decreased the phosphorylation of alpha-D-glucose. This behaviour was accounted for by the higher affinity of hexokinase for alpha- than for beta-D-glucose. These direct measurements of the relative contribution of each anomer to the overall rate of glucose phosphorylation in the presence of mixed populations of alpha- and beta-D-glucose validate the concept that the phosphorylation of D-glucose displays anomeric specificity even when the hexose is used at anomeric equilibrium. Glucose 6-phosphate inhibited the phosphorylation of the two anomers more severely when alpha-D-glucose rather than beta-D-glucose was the most abundant anomer.     

Metabolism of D-glucose anomers in rat pancreatic islets exposed to equilibrated D-glucose.

This study aims at establishing the contribution of alpha- and beta-D-glucose to the total generation of (3)HOH by rat pancreatic islets exposed to D-[2 - (3)H]glucose or D-[5 - (3)H] glucose at anomeric equilibrium. The islets were incubated for 60 min at 4 degrees C in the presence of equilibrated D-glucose (2.8 and 8.3 mM) mixed with tracer amounts of either alpha- or beta-D-glucose labelled with tritium on either the C (2) or C (5) of the hexose. Relative to their respective concentrations, (3)HOH generation from the anomers labelled with tritium on the C (2) or C (5) of the hexose provided beta/alpha ratios comparable to those previously found at both 2.8 and 8.3 mM, when the islets were exposed to each anomer separately. The relative contributions of each anomer to the total generation of (3)HOH was also close to the theoretical values derived from mathematical models for the catabolism of D-glucose at anomeric equilibrium in rat islets at both 2.8 and 8.3 mM and in the case of both D-[2 - (3)H]glucose and D-[5 - (3)H]glucose. Thus, even in islets exposed to D-glucose at anomeric equilibrium, the metabolic fate of alpha-D-glucose differs vastly from that of beta-D-glucose, the enzyme-to-enzyme channelling between hexokinase isoenzymes, especially glucokinase, and phosphoglucoisomerase being restricted to alpha-D-glucose 6-phosphate.     

Performance of the continuous glucose isomerase reactor system for the production of fructose syrup

Glucose isomerase in the form of heat-treated whole-cell enzyme prepared from Streptomyces phaeochromogenus follows the reversible single-substrate reaction kinetics in isomerization of glucose to fructose. Based on the Kinetic constants determined and the mathematical model of the reactor system developed, the preformance of a plug-flow-type continuous-enzyme reactor system was studied experimentally and also simulated with the aid of a computer for the ultimate objective of optimization of the glucose isomerase reactor system. The enzyme decay function for both the enzyme storage and during the use in the continuous reactor, was found to follow the first-order decay kinetics. When the enzyme decay function is taken into consideration, the ideal homogeneous enzyme reactor kinetics provided a satisfactory working model without further complicatin of the mathematical model, and the results of computer simulation were found to be in good agreement with the experimental results. Under a given set of constraints the performance of the continuous glucose isomerase reactor system can be predicted by using the computer simulation method described in this paper. The important parameters studied for the optimization of reactor operation were enzyme loading, mean space time of the reactor, substrate feed concentration, enzyme decay constants, and the fractional conversion, in addition to the kinetic constants. All these parameters have significant effect on the productivity. Some unique properties of the glucose isomerization reaction and its effects on the performance of the continuous glucose isomerase reactor system have been studied and discussed. The reaction kinetics of glucose isomerase and the effects of both the enzyme loading and the changes in reaction rate within a continuous reactor on the productivity are all found to be of particular importance to this enzyme reactor system.     

Anomeric specificity of hexokinase and glucokinase activities in liver and insulin-producing cells.

Conflicting data have been reported concerning the anomeric specificity of glucokinase. In the present study, liver hexokinase (Km for D-glucose 0.4 mM) displayed a higher affinity for but lower Vmax. with alpha- than with beta-D-glucose. The velocity of the reaction catalysed by liver glucokinase was higher with with beta- than with alpha-D-glucose, whatever the glucose concentration. The apparent Km of glucokinase was somewhat lower, however, with alpha- than with beta-D-glucose. Comparable results were obtained for the high-Km glucokinase-like enzymic activity present in normal pancreatic islets or insulin-producing tumoral cells. These results suggest that the anomeric specificity of glucokinase cannot account for the higher rate of glycolysis found in islets exposed to alpha- as distinct from beta-D-glucose.     

Discrimination of glucose anomers by glucokinase from liver and transplantable insulinoma

Phosphorylation of alpha- and beta-D-glucose by glucokinase from rat liver or a radiation-induced, transplantable insulinoma was investigated. Glucokinase partially purified by ion exchange chromatography on DEAE-Cibacron blue F3GA agarose was incubated for brief periods (1 or 3 min) with glucose anomers. Glucokinase from both liver and insulinoma tissue had a higher affinity for alpha-D-glucose (S0.5 = 6-7 mM) than beta-D-glucose (S0.5 = 12-14 mM). The maximum velocity was 15-20% lower for alpha-D-glucose than beta-D-glucose. Cooperative rate dependence with respect to glucose concentration was observed with both anomers (nH = 1.4). These kinetic data imply that both anomers of glucose are phosphorylated by glucokinase, however, at the physiological range of glucose concentrations below 15 mM, the higher affinity of alpha-D-glucose results in higher rates than with beta-D-glucose. At clearly pathological glucose concentrations exceeding 20 mM, the observed velocities are slightly higher with beta- than alpha-D-glucose. Glucokinase is thought to be the glucose sensor of pancreatic beta cells. The present data indicating a preferential phosphorylation of alpha-D-glucose compared to beta-D-glucose by glucokinase, supports the glucokinase-glucose sensor hypothesis, because it parallels the well established greater potency of alpha-D-glucose as a stimulant of insulin release.     

Generalized linearization of kinetics of glucose isomerization to fructose by immobilized glucose isomerase

The kinetic parameters of both glucose isomerization to fructose and immobilized glucose isomerase (GI) inactivation calculated under different conditions are compared and discussed. Utilizing these figures, the possibility of generalizing a linear model, previously proposed for the kinetics of glucose isomerization by immobilized glucose isomerase, is investigated, so as to apply them to whole ranges of temperature and concentrations of actual interest in industrial processes. The proposed model is a satisfactory approximation of the more involved Briggs-Haldane approach and substantially simplifies the problem of optimizing an industrial fixed-bed column for high-fructose corn syrup (HFCS) production.     

The reduction of CrVI to CrIII by the alpha and beta anomers of D-glucose in dimethyl sulfoxide. A comparative kinetic and mechanistic study

The reduction of CrVI by alpha-D-glucose and beta-D-glucose was studied in dimethyl sulfoxide in the presence of pyridinium p-toluensulfonate, a medium where mutarotation is slower than the redox reaction. The two anomers reduce CrVI by formation of an intermediate CrVI ester precursor of the slow redox step. The equilibrium constant for the formation of the intermediate chromic ester and the rate of the redox steps are different for each anomer. alpha-D-Glucose forms the CrVI-Glc ester with a higher equilibrium constant than beta-D-glucose, but the electron transfer within this complex is slower than for the beta anomer. The difference is attributed to the better chelating ability of the 1,2-cis-diolate moiety of the alpha anomer. The CrV species, generated in the reaction mixture, reacts with the two anomers at a rate comparable with that of CrVI. The EPR spectra show that the alpha anomer forms several linkage isomers of the five-coordinate CrV bis-chelate, while beta-D-glucose affords a mixture of six-coordinate CrV monochelate and five-coordinate CrV bis-chelate. The conversion of the CrV mono- to bis-chelate is discussed in terms of the ability of the 1,2-cis- versus 1,2-trans-diolate moieties of the glucose anomers to bind CrV.     

D-Glucose Isomerization using an Immobilized Glucose Isomerase preparation from Streptomyces Thermovulgaris Strain 127

The kinetics of D-glucose isomerization to D-fructose by an original whole-cell immobilized biocatalyst preparation based on Streptomyces thermovulgaris (strain 127) have been studied under various process conditions, substrate concentration, particle size. Two versions of different activity were applied. For the biocatalyst of moderate activity the kinetic constants in the MICHAELIS -MENTEN equation for reversible reaction were determined. Effectiveness factors for both preparations were calculated and compared with other reported data.     

Kinetics of glucose isomerization to fructose by immobilized glucose isomerase in the presence of substrate protection

The activity of immobilized glucose isomerase of Streptomyces murinus has been tested batchwise under different conditions in order to gather the related kinetic parameters necessary to optimize an immobilized enzyme column for the continuous production of high fructose corn syrup (HFCS). To this purpose, the Briggs-Haldane model incorporating an apparent first-order inactivation constant has been used with success. A comparison of the equilibrium constants and of the maximum theoretical conversion yields calculated at different temperatures with those estimated for the native enzyme demonstrates that the immobilization favours the transformation of glucose to fructose only at T?>?70?°C, as a possible consequence of a combined effect of catalysis and equilibrium thermodynamics enhancement. Enzyme inactivation has also been tested at different temperatures and sugar concentrations to evaluate the related kinetic parameters under different conditions of substrate protection.     

A simple method for the rapid and economical immobilization of glucose isomerase

The immobilization of glucose isomerase by adsorption on a macroreticular polystyrene sulphonate cation exchanger equilibrated with Ti⁴⁺, Zr⁴⁺, V⁵⁺ ions, followed by alkaline glutaraldehyde-induced crosslinking, is described. Experimental conditions are fixed for a selective and optimal retention of glucose isomerase and for its minimal leaching during subsequent use as a continuous compact glucose isomerase bed reactor, the performance of which is assessed on a laboratory scale for glucose isomerization. Factors influencing the glucose isomerase activity on solid supports, such as ratios of enzyme load - carrier - metal ion concentration, substrate feed concentration, residence period, loss of enzymic activity during storage and use, etc. are studied. The merits and drawbacks of the newly developed glucose isomerase reactor are discussed.     

Increased yield of fructose from glucose employing thermophilic xylose isomerase in water-ethanol mixtures

Summary The isomerization of D-glucose in mixed ethanol-water was studied at various reaction temperatures (40–70 °C), employing glucose isomerase fromStreptomyces phaeochromogenes andClostridium thermohydrosulfuricum, respectively. The thermophilicClostridium enzyme was considerably, more stable towards the combination of organic cosolvent and increased temperature and with this enzyme a 55% yield of fructose from glucose was obtained at relatively low concentration of ethanol (40 %).     

Sugar cane bagasse as a possible source of fermentable carbohydrates. II. Optimization of the xylose isomerase reaction for isomerization of xylose as well as sugar cane bagasse hydrolyzate to xylulose in laboratory-scale units

Both the forward and backward reactions of xylose isomerase (Sweetzyme Q) with xylose and glucose as substrates have been studied in terms of kinetics and thermodynamics. The relationship between the two reactions can thus be determined. Much attention has been given to the reaction with xylose as substrate. The optimal conditions of the xylose reaction in terms of pH, buffer, metal ions, substrate concentration, temperature, and ionic strength have been determined. These findings did not differ much from those reported for the glucose reaction. Equilibrium constants for the aldose to ketose conversion were more favorable in the case of glucose. The results obtained with continuous isomerization of xylose in columns packed with either Sweetzyme Q or Taka-Sweet were very similar to those obtained from batch isomerization processes. Particle size had a definite effect on reaction rate, which indicates that diffusion limitations do occur with the immobilized enzyme particles. Heat stability of Sweetzyme Q was good with t(1/2) of 118, 248, and 1200 h at 70, 55, and 40 degrees C, respectively. A novel method for the separation of xylose-xylulose mixtures with water as eluant on a specially prepared Dowex 1 x 8 column was developed. This technique has the capability of producing pure xylulose for industrial or research applications. A writ for a patent regarding this technique is at present prepared.     

Enzyme-to-enzyme channelling in the early steps of glycolysis in rat pancreatic islets

The metabolism of D-glucose displays anomeric specificity in rat pancreatic islets. The aim of the present report is to investigate whether such a situation implies enzyme-to-enzyme tunnelling of metabolites in the early steps of glycolysis. For such a purpose, the modelling of alpha- and beta-D-glucose catabolism, itself based on available information concerning both the utilisation of these two anomers and the intrinsic properties of phosphoglucoisomerase, was first examined. According to a theoretical model with enzyme-to-enzyme channelling, the generation of 3HOH from D-[2-3H]glucose should be higher in islets exposed to beta-D-glucose rather than alpha-D-glucose, whilst the opposite situation should prevail in the case of D-[5-3H]glucose conversion to 3HOH. Experimental data collected in rat islets incubated for 60 min at 4 degrees C in the presence of either alpha- or beta-D-glucose mixed with tracer amounts of either alpha- or beta-D-[2- 3H]glucose and alpha- or beta-D-[5-3H]glucose indicate that the beta/alpha ratio for D-[2-3H]glucose conversion to 3HOH is indeed higher than the beta/alpha ratio for D-[5-3H]glucose conversion to 3HOH. These findings are consistent with the postulated enzyme-to-enzyme tunnelling of glycolytic intermediates between hexokinase isoenzyme(s), phosphoglucoisomerase and, possibly, phosphofructokinase.     

Effect of metal ions on the glucose isomerase activity of Streptomyces robeus S-606

The intracellular glucose isomerase produced by Str. robeus S-606 refers to the group of isomerases activated most effectively by Mg2+. Besides, an activating effect of Fe3+, Co2+ and Mn2+ is observed. The optimal Mg2+ concentration for the D-glucose isomerization to D-fructose is 10(-2) M, and that of Co2+ is 100 times as low. Addition of Ca2+ (above 10% of the Mg2+ content) to the reaction mixture with the optimal Mg concentration inhibits the enzyme. At the same time Co2+ increases thermostability of glucose isomerase to a greater extent than Mg2+.     

Anomeric specificity and kinetics of glucokinase: theoretical unsuitability of the Hill equation

The kinetics of the low-Km hexokinase isoenzymes, which obey the Michaelis-Menten equation, can be established from the Km (Michaelis constant) and Vmax (maximal velocity) values for either equilibrated D-glucose or its alpha- and beta-anomers. In the case of the high-Km glucokinase isoenzyme, however, the sigmoidal substrate dependency and the competition between the two anomers of D-glucose do not allow, theoretically, to assign any meaningful value to either the Km, Vmax or n (Hill number) constants for equilibrated D-glucose. Thus, with equilibrated D-glucose, the concentration dependency fails to display a rectilinear relationship in the Hill plot. These observations illustrate the shortcomings of current biochemical studies in which the anomeric heterogeneity of D-glucose is ignored.     

Comparative kinetics of D-xylose and D-glucose isomerase activities of the D-xylose isomerase from Thermus aquaticus HB8

The D-xylose isomerase from T. aquaticus accepts, besides D-xylose, also D-glucose, and, with lower efficiency, D-ribose, and D-arabinose as alternative substrates. The activity of the enzyme is strictly dependent on divalent cations. Mn2+ is most effective in the D-xylose isomerase reaction and Co2+ in the D-glucose isomerization. Mg2+ is active in both reactions, Zn2+ only in the further one. The enzyme is strongly inhibited by Cu2+, and weakly by Ni2+, Fe2+, and Ca2+. A hyperbolic dependence of the reaction velocity of the D-xylose isomerase on the concentration of D-xylose xylose and of D-glucose was found, while biphasic saturation curves were obtained by variation of the metal ion concentrations. The D-glucose isomerization reaction shows normal behaviour with respect to the metal ions. A kinetic model was derived on the basis of the assumption of two binding sites for divalent cations, one cofactor site with higher affinity and a second, low affinity site, which modulates the activity of the enzyme.     

Anomeric specificity of D-glucose phosphorylation by rat liver glucose-6-phosphatase.

The anomeric specificity of D-glucose phosphorylation by hepatic glucose-6-phosphatase was examined in rat liver microsomes incubated in the presence of carbamoyl phosphate. At 10 degrees C, the Km for the equilibrated hexose and phosphate donor was close to 56 mM and 11 mM, respectively. The enzymic activity, which was increased in diabetic rats, was about 40% lower in untreated than in sonicated microsomes. No anomeric difference in affinity was found in sonicated microsomes. In untreated microsomes, however, the Km for beta-D-glucose was slightly lower than that for alpha-D-glucose. The maximal velocity was higher with beta- than alpha-D-glucose in both untreated and sonicated microsomes. These data indicate that the phosphotransferase activity of glucose-6-phosphatase cannot account for the higher rate of glycolysis and glycogen synthesis found in hepatocytes exposed to alpha- rather than beta-D-glucose.     

Anomeric specificity of D-[U-14C]glucose incorporation into glycogen in rat hemidiaphragms

The anomeric specificity of D-[U-14C]glucose incorporation into glycogen in rat hemidiaphragms was investigated. For this purpose, the hemidiaphragms were preincubated for 30 min at 37 degrees C and then incubated for 5 min at the same temperature in the presence of alpha- or beta-D-[U-14C]glucose. The concentrations of D-glucose (5.6 or 8.8 mM) and insulin (0 or 10 mU/ml) were identical during the preincubation and incubation periods. The incubation medium was prepared in D2O/H2O (3:1, v/v) in order to delay the interconversion of the D-glucose anomers. In addition to glycogen labelling, the output of radioactive acidic metabolites was also measured. Insulin caused a preferential stimulation of glycogen labelling relative to glycolysis. Such was not the case in response to a rise in D-glucose concentration. At 5.6 mM D-glucose and whether in the presence or absence of insulin, both glycogen labelling and glycolysis were lower with alpha-D-glucose than with beta-D-glucose suggesting a higher rate of beta-D-glucose than alpha-D-glucose transport across the plasma membrane. A mirror image was found at 8.8 mM D-glucose, especially in the absence of insulin. At this close-to-physiological hexose concentration, insulin lowered the alpha/beta ratio for glycogen labelling. On the contrary, the rise in D-glucose concentration increased such a ratio. Since such a rise is probably little affected by any possible anomeric difference in D-glucose transport across the plasma membrane, the present results strongly suggest that the intracellular factors regulating net glycogen synthesis, as well as glycolytic flux, display obvious preference for alpha-D-glucose.