Mechanism of the stimulatory effect of a potassium-rich medium on the phosphorylation of glucose in isolated rat hepatocytes.

We have investigated the mechanism by which the replacement of a Na(+)-rich medium by a K(+)-rich medium causes an increase in the apparent affinity of glucokinase (hexokinase IV or D) for glucose in isolated hepatocytes [Bontemps, F., Hue, L. & Hers, H. G. (1978) Biochem. J. 174, 603-611]. The stimulatory effect of a K(+)-rich medium on the rate of glucose phosphorylation, as assessed by the release of tritium from [2-3H]glucose, was only partially additive with the effect of fructose, suggesting that it was also due to a decrease in the inhibition exerted on glucokinase by its regulatory protein. Measurements of metabolites indicated that the effect of the K(+)-rich medium was neither due to the formation of fructose 1-phosphate, nor to changes in the concentrations of fructose 6-phosphate or Pi, two other effectors of the regulatory protein. Replacement of Na+ by K+ in the medium resulted in a time-dependent and dose-dependent increase in cell volume that paralleled the changes in the rate of detritiation observed at 5 mM glucose. The water and chloride contents, estimated using radiolabelled compounds, were threefold and tenfold higher, respectively, in K+ cells than in Na+ cells, and the intracellular Cl- concentration about threefold higher (94 versus 29 meq/l). The effects of the K(+)-rich medium on cell volume, Cl- concentration and rate of detritiation were greatly reduced by including 80 mM trehalose or sucrose in the medium at the start of the incubation. Addition of trehalose to cells incubated for 45-50 min in the K(+)-rich medium caused an immediate decrease in cell volume whereas the rate of detritiation and the Cl- concentration underwent a transient increase followed by a decrease. Replacement of KCl by KBr, potassium acetate or potassium trichloroacetate in the K(+)-rich medium resulted in different relationships between cell volume and the rate of detritiation, in agreement with the differential effect of these salts on the activity of purified glucokinase assayed in the presence of regulatory protein. From these results we conclude that the increase in the activity of glucokinase induced by a KCl-rich medium is at least partly due to an increase in the concentration of Cl-, which relieves the inhibition exerted by the regulatory protein on purified glucokinase.     

Glucokinase overexpression restores glucose utilization and storage in cultured hepatocytes from male Zucker diabetic fatty rats.

Zucker diabetic fatty rats develop type 2 diabetes concomitantly with peripheral insulin resistance. Hepatocytes from these rats and their control lean counterparts have been cultured, and a number of key parameters of glucose metabolism have been determined. Glucokinase activity was 4.5-fold lower in hepatocytes from diabetic rats than in hepatocytes from healthy ones. In contrast, hexokinase activity was about 2-fold higher in hepatocytes from diabetic animals than in healthy ones. Glucose-6-phosphatase activity was not significantly different. Despite the altered ratios of glucokinase to hexokinase activity, intracellular glucose 6-phosphate concentrations were similar in the two types of cells when they where incubated with 1-25 mM glucose. However, glycogen levels and glycogen synthase activity ratio were lower in hepatocytes from diabetic animals. Total pyruvate kinase activity and its activity ratio as well as fructose 2,6-bisphosphate concentration and lactate production were also lower in cells from diabetic animals. All of these data indicate that glucose metabolism is clearly impaired in hepatocytes from Zucker diabetic fatty rats. Glucokinase overexpression using adenovirus restored glucose metabolism in diabetic hepatocytes. In glucokinase-overexpressing cells, glucose 6-phosphate levels increased. Moreover, glycogen deposition was greatly enhanced due to the activation of glycogen synthase. Pyruvate kinase was also activated, and fructose-2,6-bisphosphate concentration and lactate production were increased in glucokinase-overexpressing diabetic hepatocytes. Overexpression of hexokinase I did not increase glycogen deposition. In conclusion, hepatocytes from Zucker diabetic fatty rats showed depressed glycogen and glycolytic metabolism, but glucokinase overexpression improved their glucose utilization and storage.     

Antagonistic regulation of the glucose/glucose 6-phosphate cycle by insulin and glucagon in cultured hepatocytes.

Flux through the glucose/glucose 6-phosphate cycle in cultured hepatocytes was measured with radiochemical techniques. Utilization of [2-3H]glucose was taken as a measure of glucokinase flux. Liberation of [14C]glucose from [U-14C]glycogen and from [U-14C]lactate, as well as the difference between the utilization of [2-3H]glucose and of [U-14C]glucose, were taken as measures of glucose-6-phosphatase flux. At constant 5 mM-glucose and 2 mM-lactate concentrations insulin increased glucokinase flux by 35%; it decreased glucose-6-phosphatase flux from glycogen by 50%, from lactate by 15% and reverse flux from external glucose by 65%, i.e. overall by 40%. Glucagon had essentially no effect on glucokinase flux; it enhanced glucose-6-phosphatase flux from glycogen by 700%, from lactate by 45% and reverse flux from external glucose by 20%, i.e. overall by 110%. At constant glucose concentrations cellular glucose 6-phosphate concentrations were essentially not altered by insulin, but were increased by glucagon by 230%. In conclusion, under basic conditions without added hormones the glucose/glucose 6-phosphate cycle showed only a minor net glucose uptake, of 0.03 mumol/min per g of hepatocytes; this flux was increased by insulin to a net glucose uptake of 0.21 mumol/min per g and reversed by glucagon to a net glucose release of 0.22 mumol/min per g. Since the glucose 6-phosphate concentrations after hormone treatment did not correlate with the glucose-6-phosphatase flux, it is suggested that the hormones influenced the enzyme activity directly.     

The control of hepatic glycogen metabolism in an in vitro model of sepsis

Culturing hepatocytes with a combination of LPS, TNF-α, IL-1β and IFN-γ resulted in an inhibition of glucose output from glycogen and prevented the repletion of glycogen in freshly cultured cells. The reduced glycogen mobilisation correlated with the lower cell glycogen content and reduced rate of glycogen synthesis from [U-¹⁴C]glucose rather than alterations in either total phosphorylase or phosphorylase a activity. There was no change in the percentage of glycogen exported as glucose nor the production of lactate plus pyruvate indicating that redistribution of the Gluc-6-P cannot explain the failure of the liver to export glucose. Although changes in glycogen mobilisation correlated with NO production, inhibition of NO synthase by inclusion of L-NMMA in the culture medium failed to prevent the inhibition of either glycogen accumulation or mobilisation by the proinflammatory cytokines, precluding the involvement of NO in this response. LPS plus cytokine treatment had no effect on total glycogen synthase activity although the activity ratio was lowered, indicative of increased phosphorylation. The inhibition of glycogen synthesis correlated with a fall in the intracellular concentrations of Gluc-6-P and UDP-glucose and in the absence of measured changes in kinase activity, it is suggested that the fall in Gluc-6-P reduces both substrate supply and glycogen synthase phosphatase activity. The fall in Gluc-6-P coincided with a reduction in total glucokinase and hexokinase activity within the cells, but no significant change in either the translocation of glucokinase or glucose-6-phosphatase activity. This demonstrates direct cytokine effects on glycogen metabolism independent of changes in glucoregulatory hormones.     

Mutations that confer resistance to 2-deoxyglucose reduce the specific activity of hexokinase from Myxococcus xanthus

The glucose analog 2-deoxyglucose (2dGlc) inhibits the growth and multicellular development of Myxococcus xanthus. Mutants of M. xanthus resistant to 2dGlc, designated hex mutants, arise at a low spontaneous frequency. Expression of the Escherichia coli glk (glucokinase) gene in M. xanthus hex mutants restores 2dGlc sensitivity, suggesting that these mutants arise upon the loss of a soluble hexokinase function that phosphorylates 2dGlc to form the toxic intermediate, 2-deoxyglucose-6-phosphate. Enzyme assays of M. xanthus extracts reveal a soluble hexokinase (ATP:D-hexose-6-phosphotransferase; EC 2.7.1.1) activity but no phosphotransferase system activities. The hex mutants have lower levels of hexokinase activities than the wild type, and the levels of hexokinase activity exhibited by the hex mutants are inversely correlated with the ability of 2dGlc to inhibit their growth and sporulation. Both 2dGlc and N-acetylglucosamine act as inhibitors of glucose turnover by the M. xanthus hexokinase in vitro, consistent with the finding that glucose and N-acetylglucosamine can antagonize the toxic effects of 2dGlc in vivo.     

PTP1B deficiency increases glucose uptake in neonatal hepatocytes: involvement of IRA/GLUT2 complexes

The contribution of the liver to glucose utilization is essential to maintain glucose homeostasis. Previous data from protein tyrosine phosphatase (PTP) 1B-deficient mice demonstrated that the liver is a major site for PTP1B action in the periphery. In this study, we have investigated the consequences of PTP1B deficiency in glucose uptake in hepatocytes from neonatal and adult mice. The lack of PTP1B increased basal glucose uptake in hepatocytes from neonatal (3-5 days old) but not adult (10-12 wk old) mice. This occurs without changes in hexokinase, glucokinase, and glucose 6-phosphatase enzymatic activities. By contrast, the glucose transporter GLUT2 was upregulated at the protein level in neonatal hepatocytes and livers from PTP1B-deficient neonates. These results were accompanied by a significant increase in the net free intrahepatic glucose levels in the livers of PTP1B(-/-) neonates. The association between GLUT2 and insulin receptor (IR) A isoform was increased in PTP1B(-/-) neonatal hepatocytes compared with the wild-type. Indeed, PTP1B deficiency in neonatal hepatocytes shifted the ratio of isoforms A and B of the IR by increasing the amount of IRA and decreasing IRB. Moreover, overexpression of IRA in PTP1B(-/-) neonatal hepatocytes increased the amount of IRA/GLUT2 complexes. Conversely, hepatocytes from adult mice only expressed IRB. Since IRA plays a direct role in the regulation of glucose uptake in neonatal hepatocytes through its specific association with GLUT2, we propose the increase in IRA/GLUT2 complexes due to PTP1B deficiency as the molecular mechanism of the increased glucose uptake in the neonatal stage.     

Inhibition of glucokinase translocation by AMP-activated protein kinase is associated with phosphorylation of both GKRP and 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase

The rate of glucose phosphorylation in hepatocytes is determined by the subcellular location of glucokinase and by its association with its regulatory protein (GKRP) in the nucleus. Elevated glucose concentrations and precursors of fructose 1-phosphate (e.g., sorbitol) cause dissociation of glucokinase from GKRP and translocation to the cytoplasm. In this study, we investigated the counter-regulation of substrate-induced translocation by AICAR (5-aminoimidazole-4-carboxamide-1-beta-D-ribofuranoside), which is metabolized by hepatocytes to an AMP analog, and causes activation of AMP-activated protein kinase (AMPK) and depletion of ATP. During incubation of hepatocytes with 25 mM glucose, AICAR concentrations below 200 microM activated AMPK without depleting ATP and inhibited glucose phosphorylation and glucokinase translocation with half-maximal effect at 100-140 microM. Glucose phosphorylation and glucokinase translocation correlated inversely with AMPK activity. AICAR also counteracted translocation induced by a glucokinase activator and partially counteracted translocation by sorbitol. However, AICAR did not block the reversal of translocation (from cytoplasm to nucleus) after substrate withdrawal. Inhibition of glucose-induced translocation by AICAR was greater than inhibition by glucagon and was associated with phosphorylation of both GKRP and the cytoplasmic glucokinase binding protein, 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase (PFK2) on ser-32. Expression of a kinase-active PFK2 variant lacking ser-32 partially reversed the inhibition of translocation by AICAR. Phosphorylation of GKRP by AMPK partially counteracted its inhibitory effect on glucokinase activity, suggesting altered interaction of glucokinase and GKRP. In summary, mechanisms downstream of AMPK activation, involving phosphorylation of 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase and GKRP are involved in the ATP-independent inhibition of glucose-induced glucokinase translocation by AICAR in hepatocytes.     

Analysis of the cooperativity of human beta-cell glucokinase through the stimulatory effect of glucose on fructose phosphorylation

Using overexpressed Escherichia coli sorbitol-6-phosphate dehydrogenase to monitor fructose 6-phosphate formation, we found that the stimulation of fructose phosphorylation by glucose was reduced in two human beta-cell glucokinase mutants with a low Hill coefficient or when the activity of wild type glucokinase was decreased by replacing ATP with poorer nucleotide substrates. Mutation of two other residues, neighboring glucose-binding residues in the catalytic site, also reduced the affinity for glucose as a stimulator of fructose phosphorylation. Among a series of glucose analogs, only 3, all substrates of glucokinase, stimulated fructose phosphorylation; other analogs were either inactive or inhibited glucokinase. Glucose increased the apparent affinity for inhibitors that are glucose analogs but not for the glucokinase regulatory protein or palmitoyl-CoA. These data indicate that the stimulatory effect of glucose on fructose phosphorylation reflects the positive cooperativity for glucose and is mediated by binding of glucose to the catalytic site. They support models involving the existence of two slowly interconverting conformations of glucokinase that differ through their affinity for glucose and for glucose analogs. We show by computer simulation that such a model can account for the kinetic properties of glucokinase, including the differential ability of mannoheptulose and N-acetylglucosamine to suppress cooperativity (Agius, L., and Stubbs, M. (2000) Biochem. J. 346, 413-421).     

Regulation of hepatic glucose metabolism by translocation of glucokinase between the nucleus and the cytoplasm in hepatocytes.

We studied the role of glucokinase translocation between the nucleus and the cytoplasm in hepatocytes. In cultured hepatocytes, both the translocation of glucokinase from the nucleus to the cytoplasm and the rate of glucose phosphorylation were increased when cells were incubated with high concentrations of glucose. The addition of low concentrations of fructose, which is known to stimulate glucose phosphorylation, stimulated both glucokinase translocation and glucose phosphorylation. There was a good correlation between the increase in cytoplasmic glucokinase induced by fructose and that in the glucose phosphorylation rate induced by fructose. Furthermore, we observed a linear relationship between cytoplasmic glucokinase activity and rate of glucose phosphorylation over various glucose concentrations in the absence or presence of fructose. These results indicate that glucose phosphorylation in hepatocytes depended on glucokinase in the cytoplasmic compartment--that is, the increase in the rate of glucose phosphorylation was due to the increase in translocation of glucokinase out of the nucleus. Also, oral administration of glucose, fructose, or glucose plus fructose to 24-h fasted rats induced translocation of glucokinase in the liver. All of these results indicate that hepatic glucose metabolism is regulated by the translocation of glucokinase.     

Free fatty acids increase basal hepatic glucose production and induce hepatic insulin resistance at different sites

To investigate the sites of the free fatty acid (FFA) effects to increase basal hepatic glucose production and to impair hepatic insulin action, we performed 2-h and 7-h Intralipid + heparin (IH) and saline infusions in the basal fasting state and during hyperinsulinemic clamps in overnight-fasted rats. We measured endogenous glucose production (EGP), total glucose output (TGO, the flux through glucose-6-phosphatase), glucose cycling (GC, index of flux through glucokinase = TGO - EGP), hepatic glucose 6-phosphate (G-6-P) content, and hepatic glucose-6-phosphatase and glucokinase activities. Plasma FFA levels were elevated about threefold by IH. In the basal state, IH increased TGO, in vivo glucose-6-phosphatase activity (TGO/G-6-P), and EGP (P < 0.001). During the clamp compared with the basal experiments, 2-h insulin infusion increased GC and in vivo glucokinase activity (GC/TGO; P < 0.05) and suppressed EGP (P < 0.05) but failed to significantly affect TGO and in vivo glucose-6-phosphatase activity. IH decreased the ability of insulin to increase GC and in vivo glucokinase activity (P < 0.01), and at 7 h, it also decreased the ability of insulin to suppress EGP (P < 0.001). G-6-P content was comparable in all groups. In vivo glucose-6-phosphatase and glucokinase activities did not correspond to their in vitro activities as determined in liver tissue, suggesting that stable changes in enzyme activity were not responsible for the FFA effects. The data suggest that, in overnight-fasted rats, FFA increased basal EGP and induced hepatic insulin resistance at different sites. 1) FFA increased basal EGP through an increase in TGO and in vivo glucose-6-phosphatase activity, presumably due to a stimulatory allosteric effect of fatty acyl-CoA on glucose-6-phosphatase. 2) FFA induced hepatic insulin resistance (decreased the ability of insulin to suppress EGP) through an impairment of insulin's ability to increase GC and in vivo glucokinase activity, presumably due to an inhibitory allosteric effect of fatty acyl-CoA on glucokinase and/or an impairment in glucokinase translocation.     

Distribution of hexokinase isoenzymes depending on a carbon source in Saccharomyces cerevisiae.

DEAE cellulose chromatography and agar gel electrophoresis of glucose-phosphorylating enzymes in Saccharomyces cerevisiae showed the existence of glucokinase and two hexokinase isoenzymes ( designated as hexokinase I and II ). The distribution of hexokinase isoenzymes was dependent on a carbon source in the medium, while that of glucokinase was not dependent. The cells grown on 3 % ethanol as carbon source showed the isoenzyme pattern with predominant hexokinase I and a little hexokinase II. The isoenzyme pattern of the cells grown on 6 % glucose, which was differnt from that of the cells grown on ethanol, showed that hexokinase I and II were minor and major parts respectively. When the cells grown on 3 % ethanol were incubated on the medium containing 6 % glucose, hexokinase I was repressed and hexokinase II inducted. These facts suggest that two hexokinase isoenzymes, but not glucokinase, are adaptive enzyme.     

Low temperature directly activates the initial glycerol antifreeze response in isolated rainbow smelt (Osmerus mordax) liver cells

Rainbow smelt (Osmerus mordax) accumulate high levels of glycerol in winter that serve as an antifreeze. Liver glycogen is a source of glycerol during the early stages of glycerol accumulation, whereas dietary glucose and amino acids are essential to maintain rates of glycerol synthesis. We presently report rates of glycerol and glucose production by isolated hepatocytes. Cells from fish held at 0.4 to -1.5 degrees C and incubated at 0.4 degrees C were metabolically quiescent with negligible rates of glycerol or glucose production. Hepatocytes isolated from fish maintained at 8 degrees C and incubated at 8 degrees C produced glucose but not glycerol. Glycerol production was activated in cells isolated from 8 degrees C fish and incubated at 0.4 degrees C without substrate or when glucose, aspartate, or pyruvate was available in the medium. Incubation at 0.4 degrees C without substrate resulted in similar molar rates of glucose and glycerol production in concert with glycogen mobilization. Glycogenolysis and glycerol production were associated with increases in total in vitro activities of glycogen phosphorylase and glycerol-3-phosphate dehydrogenase. Maximal in vitro activities of hexokinase and glucokinase were not influenced by temperature, but high activities of a low-K(m) hexokinase may serve to redirect glycogen-derived glucose to glycolysis as opposed to releasing it from the cells. Rates of glycerol production were not enhanced in cells from fish held at 8 degrees C and incubated at 0.4 degrees C with adrenergic or glucocorticoid stimulation. As such, low temperature alone is sufficient to activate the glycerol production mechanism and results in a shift from glucose to a mix of glucose and glycerol production.     

Anomeric preference of glucose utilization in human erythrocytes loaded with glucokinase

Human erythrocytes were loaded with homogeneous rat liver glucokinase by an encapsulation method based on hypotonic hemolysis and isotonic resealing. As assayed at 10 mM glucose, glucokinase and hexokinase activities in glucokinase-loaded erythrocytes were 218 and 384 nmol/min/gHb, respectively; whereas hexokinase activity in both intact and unloaded red cells, which contain no glucokinase activity, was about 400 nmol/min/gHb. No difference in the rate of lactate production from glucose anomers between intact and unloaded erythrocytes suggested that the encapsulation procedure itself did not affect glucose utilization in red cells. Alpha-anomeric preference in lactate production from glucose was observed in glucokinase-loaded erythrocytes, whereas the beta anomer of glucose was more rapidly utilized than the alpha anomer in intact and unloaded erythrocytes. The results indicate that the step of glucose phosphorylation determines the anomeric preference in glucose utilization by human erythrocytes, since glucokinase and hexokinase are alpha- and beta-preferential, respectively, in glucose phosphorylation.     

The identification of extrahepatic "glucokinase" as N-acetylglucosamine kinase

Several research groups have reported the presence of a high Km glucokinase (ATP:D-glucose 6-phosphotransferase, EC 2.7.1.2) in tissues other than adult liver. As shown in this report, protein fractions catalyzing glucose phosphorylation only at high substrate concentrations (100 mM) are indeed found in bovine spleen, rat kidney, human placenta, and newborn rat liver. However, the study of substrate specificities and Michaelis constant values showed that those fractions could be better described as N-acetylglucosamine kinase (ATP:acetamide-2-deoxy-D-glucose-6-phosphotransferase, EC 2.7.1.9) which, in addition to N-acetylglucosamine (Km = 0.066 mM), can also phosphorylate glucose although with very high Km values (370 mM). Furthermore, a homogeneous preparation from bovine spleen was able to phosphorylate both N-acetylglucosamine and glucose. An immune serum against bovine spleen N-acetylglucosamine kinase did not cross-react with purified hexokinases or with glucokinase from rat. However, it was able to remove the putative "glucokinases" from extracts of rat kidney, newborn rat liver, and one of two electrophoretic bands of liver "glucokinase." It is proposed that any report of extrahepatic glucokinase should explicity rule out N-acetylglucosamine kinase as the enzyme being described.     

Multifunctional glucose-6-phosphatase: cellular biology.

Glucose-6-phosphatase is a multifunctional enzyme, displaying potent ability to synthesize as well as hydrolyze Glc-6-P. These multifunctional characteristics have been exploited in studies of the extended distribution of the enzyme, and their physiological significance has been examined. The enzyme is considerably more widely distributed than previously suspected. It has been found in pancreas, adrenals, lung, testes, spleen, and brain as well as in liver, kidney, and mucosa of small intestine. Approximately 15–20% of total hepatic glucose-6-phosphatase-phosphotransferase is present in nuclear membrane, 75–80% is found in endoplasmic reticulum, and small amounts have been detected also in plasma membrane and repeatedly-washed mitochondria. Both hydrolytic and synthetic functions, in constant proportions, have been found in livers of 21 species of birds, amphibia, reptiles, crustacea, fishes, and mammals (including man) studied. With 5 mM phosphoryl donor and 100 mM D-glucose as substrates, carbamyl-P:glucose phosphotransferase activity of glucose-6-phosphatase exceeded that of glucokinase by 5–50 fold. While latencies of activities of isolated microsomal preparations are extensive, those of nuclear membranes are not. Latencies of activities of intact endoplasmic reticulum of permeable hepatocytes are 28% for Glc-6-P phosphohydrolase and 56% for carbamyl-P:glucose phosphotransferase. Studies with isolated perfused livers from fasted rats suggest rather convincingly that such phosphotransferase activities may function as an hepatic glucose-phosphorylating system supplemental to glucokinase and hexokinase. This conclusion is based both on comparisons of rates of glucose uptake with hepatic enzyme levels (glucokinase, hexokinase, phosphotransferase), and on observed inhibitibility of glucose uptake by ornithine and 3-0-methyl-D-glucose. The question of availability of adequate concentrations of suitable phosphoryl donor(s) in cytosol of the liver cell constitutes a principal focus for continuing studies regarding physiological functions of this enzyme.     

Phosphorylation by liver glucokinase of D-glucose anomers at anomeric equilibrium

The relative contribution of each anomer of D-glucose to the overall phosphorylation rate of the hexose tested at anomeric equilibrium was examined in rat liver postmicrosomal supernatants under conditions aimed at characterizing the activity of glucokinase, with negligible interference of either hexokinase, N-acetyl-D-glucosamine kinase or glucose-6-phosphatase (acting as a phosphotransferase). Both at 10 degrees and 30 degrees C, the relative contribution of each anomer was unaffected by the concentration of D-glucose. At both temperatures, the alpha/beta ratio for the contribution of each anomer was slightly, but significantly, lower than the alpha/beta ratio of anomer concentrations. These findings, which are consistent with the anomeric specificity of glucokinase in terms of affinity, cooperativity and maximal velocity, reveal that the preferred alpha-anomeric substrate for both glycogen synthesis and glycolysis is generated by glucokinase at a lower rate than is beta-D-glucose-6-phosphate.     

Noradrenaline and glycogen content and the activity of several enzymes of carbohydrate metabolism in normal, embryonic, and partly denervated livers and in hepatomas of the rat]

The noradrenaline and glycogen contents as well as hexokinase, glucokinase and glucose-6-phosphatase activities were determined in normal, embryonic and partially denervated (bilateral dissection of the Nervus splanchnicus or Nervus vagus) rat liver and in two transplantable hepatomas. In embryonic liver and hepatomas a strong decrease or complete loss of noradrenaline and glycogen levels and glucokinase and glucose-6-phosphatase activities is demonstrable as compared to the livers of adult animals, while the hexokinase activity is enhanced. Following bilateral splanchnicotomy the glycogen content and hexokinase activity are enhanced; the glucose-6-phosphatase activity is reduced, and the liver does not contain any noradrenaline. Bilateral vagotomy causes decrease of the glycogen content, of the hexokinase and glucokinase activities and an enhancement of glucose-6-phosphatase activity. The results lend support to the idea of antagonistic action of the sympathetic and parasympathetic nervous systems upon several partial reactions of carbohydrate metabolism of liver. In addition, it can be assumed that the alterations of the carbohydrate metabolism demonstrable in hepatomas as compared to normal liver are not solely attributable to disturbance or breakdown of the nervous regulation.     

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.     

Stability of hexokinases A, B and C and N-acetylglucosamine kinase in liver cells isolated from rats submitted to diabetes and several dietary conditions.

The effect of dietary and hormonal variations on the specific activities of hexokinase isoenzymes, N-acetylglucosamine kinase and pyruvate kinase isoenzymes in parenchymal and non-parenchymal liver cells was studied. Hexokinase D was markedly decreased in hepatocytes from animals fasted or fed on the carbohydrate-free diet as well as from diabetic rats, attaining a constant low level of about 17% of normal values. Pyruvate kinase L was also diminished in hepatocytes under the same experimental conditions. In contrast, the three high-affinity hexokinase isoenzymes A, B and C remained without variation in total amount or in their relative proportions in hepatocytes and non-parenchymal liver cells isolated from animals under the various conditions studied. N-Acetylglucosamine kinase activities also did not change either in parenchymal or in non-parenchymal liver cells under all conditions. The results are discussed in relation to the significance of N-acetylglucosamine kinase and the various hexokinase isoenzymes for the phosphorylation of glucose after dietary and hormonal manipulations.     

Hexose metabolism in pancreatic islets: regulation of mitochondrial hexokinase binding

A major fraction of hexokinase was found to be bound, presumably to mitochondria, in both normal and tumoral rat pancreatic islet cells examined after either mechanical disruption or digitonin treatment. Spermidine enhanced the binding and glucose 6-phosphate caused the release of hexokinase to and from islet mitochondria, in a manner comparable to that seen in parotid or brain homogenates. In hepatocytes, some hexokinase, but no glucokinase, was found in the bound form. In islet cells, however, the pattern of glucokinase binding was similar to that of hexokinase. It is speculated that the preferential location of both hexokinase and glucokinase on mitochondria may favor the maintenance of a high cytosolic ATP content in islet cells.