Calcium activates glucose-6-phosphatase in intact rat hepatic microsomes.

The effects of Ca2+ on the microsomal glucose-6-phosphatase activity were investigated. Evidence is provided that increases by Ca2+ in both the pyrophosphatase and the glucose-6-phosphate-hydrolysing activities are due to an increase in microsomal transport capacity of T2, the phosphate/pyrophosphate-transport protein.     

Calcium sequestration activity in rat liver microsomes. Evidence for a cooperation of calcium transport with glucose-6-phosphatase

Mechanisms regulating the energy-dependent calcium sequestering activity of liver microsomes were studied. The possibility for a physiologic mechanism capable of entrapping the transported Ca2+ was investigated. It was found that the addition of glucose 6-phosphate to the incubation system for MgATP-dependent microsomal calcium transport results in a marked stimulation of Ca2+ uptake. The uptake at 30 min is about 50% of that obtained with oxalate when the incubation is carried out at pH 6.8, which is the pH optimum for oxalate-stimulated calcium uptake. However, at physiological pH values (7.2-7.4), the glucose 6-phosphate-stimulated calcium uptake is maximal and equals that obtained with oxalate at pH 6.8. The Vmax of the glucose 6-phosphate-stimulated transport is 22.3 nmol of calcium/mg protein per min. The apparent Km for calcium calculated from total calcium concentrations is 31.9 microM. After the incubation of the system for MgATP-dependent microsomal calcium transport in the presence of glucose 6-phosphate, inorganic phosphorus and calcium are found in equal concentrations, on a molar base, in the recovered microsomal fraction. In the system for the glucose 6-phosphate-stimulated calcium uptake, glucose 6-phosphate is actively hydrolyzed by the glucose-6-phosphatase activity of liver microsomes. The latter activity is not influenced by concomitant calcium uptake. Calcium uptake is maximal when the concentration of glucose 6-phosphate in the system is 1-3 mM, which is much lower than that necessary to saturate glucose-6-phosphatase. These results are interpreted in the light of a possible cooperative activity between the energy-dependent calcium pump of liver microsomes and the glucose-6-phosphatase multicomponent system. The physiological implications of such a cooperation are discussed.     

The purification of a detergent-soluble glucose-6-phosphatase from rat liver.

A highly active and soluble glucose-6-phosphatase has been purified to near homogeneity from rat liver. Successful purification has been initiated by covalent labeling of the enzyme in native rat liver microsomes with pyridoxal 5'-phosphate and NaBH4, followed by solubilization of the microsomes with Triton X-100, chromatography on phenyl-Sepharose, hydroxyapatite, DEAE-Sephacel and a second chromatography step on hydroxyapatite. The final enzyme preparation obtained was approximately 700-fold purified over the activity of starting microsomes. As judged by SDS/PAGE the purified glucose-6-phosphatase is composed of a single protein with a molecular mass of 35 kDa. The present work demonstrates that the purified glucose-6-phosphatase must be arranged in the native microsomal membrane so that it is accessible to pyridoxal 5'-phosphate from the cytoplasmic side.     

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.     

Radiation inactivation analysis of rat liver microsomal glucose-6-phosphatase

Radiation inactivation analysis was utilized to estimate the sizes of the units catalyzing the various activities of hepatic microsomal glucose-6-phosphatase. This technique revealed that the target molecular weights for mannose-6-P phosphohydrolase, glucose-6-P phosphohydrolase, and carbamyl-P:glucose phosphotransferase activities were all about Mr 75,000. These results are consistent with the widely held view that all of these activities are catalyzed by the same protein or proteins. Certain observations indicate that the molecular organization of microsomal glucose-6-phosphatase is better described by the conformational hypothesis which envisions the enzyme as a single covalent structure rather than by the substrate transport model which requires the participation of several physically separate polypeptides. These include the findings: 1) that the target sizes for glucose-6-P phosphohydrolase and carbamyl-P:glucose phosphotransferase activities were not larger than that for mannose-6-P phosphohydrolase in intact microsomes and 2) that the target size for glucose-6-P phosphohydrolase in disrupted microsomes was not less than that observed in intact microsomes. These findings are most consistent with a model for glucose-6-phosphatase of a single polypeptide or a disulfide-linked dimer which spans the endoplasmic reticulum with the various activities of this multifunctional enzyme residing in distinct protein domains.     

In situ kinetic parameters of glucose-6-phosphatase in the rat liver lobulus.

Glucose-6-phosphatase activity has been determined in periportal and pericentral zones of the rat liver lobule using a quantitative histochemical method. The study was performed on unfixed cryostat sections of livers from fasted and fed female and male rats. Highest activity was found in periportal zones, and starvation caused a 2-3-fold increase of glucose-6-phosphatase activity in periportal and pericentral zones of both sexes. Unexpectedly, KM values were also significantly different in periportal and pericentral zones and were found to increase linearly with Vmax values, irrespective of sex and feeding condition. Because the cryofixation procedure was shown to permeabilize the biomembranes in the tissue sections, it can be concluded that the rise in KM and Vmax values has to be attributed to the catalytic unit of the glucose-6-phosphatase system. It is suggested that the enzyme exists in a high affinity configuration at low enzyme concentrations but that at high enzyme concentrations a hysteretic mechanism, as proposed by Berteloot et al. (Berteloot, A., Vidal, H., and Van de Werve, G. (1991) J. Biol. Chem. 266, 5497-5507), transforms the enzyme from a high to a low affinity configuration. The present study indicates that the concept of functional heterogeneity of liver parenchyma may be more complex than thus far assumed.     

Partial purification of rat liver microsomal glucose-6-phosphatase on hydroxylapatite

Glucose-6-phosphatase was effectively solubilized from rat liver-microsomal membrane by the nonionic detergent Renex 690 in the presence of 0.6M sodium chloride. Subsequent separation on hydroxylapatite proved to be a successful and rapid initial step towards the purification of this enzyme. Glucose-6-phosphatase appeared in the colourless void volume with a yield of about 40-50%. The specific activity in the pooled void volume was 3-4 U/mg protein representing an enrichment of 30- to 40-fold. The best final specific activity obtained in an enriched fraction was 6.7 U/mg protein. Analysis of the pooled glucose-6-phosphatase-enriched fraction by SDS electrophoresis revealed 2 dominant protein bands with the apparent molecular mass of 17 and 18.5 kDa and few weak protein bands in the range of 21 to 42 kDa.     

Studies on the interactions between phospholipids and membrane-bound enzymes in microsomes. Effects of phospholipases C on the glucose-6-phosphatase system of rat liver microsomes

The role of phospholipids in the glucose-6-phosphatase system, including glucose-6-P phosphohydrolase and glucose-6-P translocase, was studied in rat liver microsomes by using phospholipases C and detergents. In the time course experiments on detergent exposure, the maximal activation of glucose-6-P phosphohydrolase varied according to the nature of the detergent used. On treatment of microsomes with phospholipase C of C. perfringens, the activity of glucose-6-P phosphohydrolase without detergent (i.e. without rupture of translocase activity) was gradually decreased with the progressive hydrolysis of phosphatidylcholine and phosphatidylethanolamine on the microsomal membrane, and was restored by incubation of these microsomes with egg yolk phospholipids. The extent of decrease in this phosphohydrolase activity in the detergent-exposed microsomes (with rupture of translocase activity) also varied depending on the detergent used (Triton X-114 or taurocholate). When 66% of the phosphatidylinositol on the membrane was hydrolyzed by phosphatidylinositol-specific phospholipase C of B. thuringiensis, the inhibition of glucose-6-P phosphohydrolase activity without detergent was very small. Although the inhibition of enzyme activity with detergent was apparently greater than that without detergent, the enzyme activity was stimulated by the breakdown of phosphatidylinositol when the enzyme activity was measured at lower concentration (0.5 mM) of substrate, glucose-6-P. The latency of mannose-6-P phosphohydrolase, a plausible index of microsomal integrity, remained above 70% after the hydrolysis of phosphatidylcholine, phosphatidylethanolamine, or phosphatidylinositol. The results show that the glucose-6-phosphatase system requires microsomal phospholipids for its integrity, suggesting that there exists a close relation between phosphatidylinositol and glucose-6-P translocase.     

Monkey liver microsomal glucose-6-phosphatase]

Kinetic studies indicate that glucose-6-phosphatase is a multifunctional enzyme. a) Phosphohydrolase activities. The mannose-6-phosphatase activity is low (Km = 8 mM, VM = 90 nmoles. min-1mg-1). The enzyme shows a strong affinity for glucose-6-phosphate (Km = 2.5 mM, VM = 220 nmoles.min-1mg-1). beta-glycerophosphate (K1 = 30 mM), D-glucose (Ki = 120 mM) are mixed type inhibitors; pyrophosphate (Ki = 2 mM) is a non competitive one. b) Phosphotransferase activities. Di and triphosphate adenylic nucleosides or phosphoenol pyruvate are not substrates. Carbamylphosphate serves as a phosphoryl donor with D-glucose as acceptor. The phosphate transfer is consisstent with a random mechanism in which the binding of one substrate increases the enzymes affinity for the second substrate. Apparent Km values for carbamyl-phosphate range from 5.2 mM (D-glucose concentration leads to infinity) to 8 mM (D-glucose concentration leads to 0). The corresponding apparent Km values for D-glucose are 59 mM (carbamyl-phosphate concentration leads to infinity) to 119 mM (carbamyl-phosphate concentration leads to 0). Maximal reaction velocity with infinite levels of both substrates is 270 nmoles.min-1.mg-1. Pyrophosphate is a poor phosphoryl donnor (Km = 55 mM with D-glucose concentration 250 mM). In addition we do not find any latency; detergents, namely sodium deoxycholate, Triton X 100 do not affect or inhibit glucose-6-phosphatase activity.     

Evidence for glucose-6-phosphate transport in rat liver microsomes

The existence of glucose-6-phosphate transport across the liver microsomal membrane is still controversial. In this paper, we show that S3483, a chlorogenic acid derivative known to inhibit glucose-6-phosphatase in intact microsomes, caused the intravesicular accumulation of glucose-6-phosphate when the latter was produced by glucose-6-phosphatase from glucose and carbamoyl-phosphate. S3483 also inhibited the conversion of glucose-6-phosphate to 6-phosphogluconate occurring inside microsomes in the presence of electron acceptors (NADP or metyrapone). These data indicate that liver microsomal membranes contain a reversible glucose-6-phosphate transporter, which furnishes substrate not only to glucose-6-phosphatase, but also to hexose-6-phosphate dehydrogenase.     

Evidence for changes in the conformational status of rat liver microsomal glucose-6-phosphate:phosphohydrolase during detergent-dependent membrane modification. Effect of p-mercuribenzoate and organomercurial agarose gel on glucose-6-phosphatase of native and detergent-modified microsomes

Comparative studies investigating influences of temperature and time of preincubation on the interactions of an organomercurial agarose gel and p-mercuribenzoate with glucose-6-phosphatase of native and Triton X-114-modified rat liver microsomes were carried out. The effect of p-mercuribenzoate on glucose 6-phosphate hydrolysis is a result of two processes, a moderate membrane perturbation connected with release of some latency and temperature- and time-dependent inhibition of the catalytic activity. Short-term preincubation with both organic mercurials at 37 degrees C is a necessary condition for the entire inhibition of the enzyme activity of native as well as of Triton X-114-modified microsomes. A binding site of the phosphohydrolase itself is accessible to p-mercuribenzoate and the phenyl mercury residue of the affinity gel from the cytoplasmic surface even in native microsomes. Kinetic analyses reveal a formally competitive mechanism of inhibition using native microsomes, but the kinetic picture changes to a noncompetitive pattern of Lineweaver-Burk plots when the inhibitor-loaded microsomes are modified optimally by Triton X-114. This behavior can be evaluated as the first convincing evidence for drastic changes of the conformational status of the phosphohydrolase during the membrane modification process. A combined conformational flexibility-substrate transport model characterizing the microsomal glucose-6-phosphatase as an integral channel-protein embedded within the hydrophobic interior of the membrane is proposed.     

Synthesis of bicyclic biaryls as glucose-6-phosphatase inhibitors

Biaryls, 7-naphthyl-5-s-amino-2,3-dihydrobenzo[b]thiophene-4-carbonitriles (3a-e), 8-(1-naphthyl)-6-s-amino-isothiochroman-5-carbonitriles (6a-d), 4-(1-naphthyl)-2-s-aminobezocycloalkene-1-carbonitriles (6e-j), 8-naphthyl-6-s-amino-2-ethyl-1,2,3,4-tetrahydro-isoquinoline-5-carbonitrle (6k-n), 1-naphthyl-3-s-amino-10H-9-thia-phenantherene-4-carbonitriles (8a-e) and 1-(1-naphthyl)-3-s-amino-9,10-dihydrophenantherene-4-carbonitriles (8f-i) have been prepared through carbanion induced ring transformation reactions of 6-naphthyl-3-cyano-4-s-amino-2H-pyran-2-ones (1) from respective ketones (2, 5, and 7). These compounds have been evaluated for their glucose-6-phosphatase inhibitory activity and only 6a, c, j, m, c, d, h displayed significant inhibition of the glucose-6-phosphatase.     

A Limulus glucose-6-phosphatase with phosphotransferase activity characteristic of vertebrate liver microsomes. Its possible evolutionary significance.

1. Limulus hepatopancreas, coxal glands and intestine contain a particulate enzyme which can synthesize glucose 6-phosphate from glucose and inorganic pyrophosphate or carbamyl phosphate as well as hydrolyze glucose 6-phosphate. This has been clearly differentiated from hydrolysis by lysosomal or soluble phosphatases. 2. The enzyme resembles vertebrate glucose-6-phosphatase in its specific anatomical distribution, pH optimum, kinetic properties, donor specificity and phospholipid dependence, as indicated by its satency and lability to detergent treatment. 3. A variety of other invertebrates tested exhibited little or no PPi-glucose phosphotransferase activity with these properties. A similar phosphotransferase activity of lobster hepatopancreas had somewhat different kinetic properties and pH optimum. 4. The hypothesis that a specific glucose-6-phosphatase is to be found only in those animals which utilize free glucose as an important circulating form of energy is presented and discussed. It appears that a variety of transport compounds, such as trehalose and glucose, was tried at the evolutionary level of the Arthropods.     

The characteristics of liver glucose-6-phosphatase in the envelope of isolated nuclei and microsomes are identical

We have compared the characteristics of glucose-6-phosphatase (EC 3.1.3.9) in the envelope of purified nuclei and microsomes from rat liver. The latency of mannose-6-P hydrolysis, permeability to EDTA, and susceptibility of the enzyme to protease-mediated inactivation all indicated that the permeability barrier defined by the envelope in situ is significantly disrupted in isolated nuclei (i.e. in vitro). Latency of mannose-6-P hydrolysis was demonstrated to provide a quantitative measure of the degree of nuclear membrane disruption. Electron micrographs confirmed the existence of substantial regions of the envelope in vitro where the permeability barrier to EDTA was intact (i.e. an "intact component"). The kinetics of glucose-6-phosphatase catalyzed by the intact component was obtained by subtracting the contribution of enzyme in disrupted regions from the total enzymic activity of untreated nuclei. The characteristics of glucose-6-phosphatase in intact and fully disrupted membranes of nuclei were indistinguishable from microsomes with respect to (a) the kinetics of glucose-6-P hydrolysis, (b) the effects of incubations with mannose-6-P, N-ethylmaleimide, and protease from Bacillus amyloliquefaciens, (c) the extremely high latency of carbamyl phosphate:glucose phosphotransferase activity, and (d) both the patterns of response of activity and the change in latency of glucose-6-phosphatase induced by fasting, experimental diabetes, and cortisol injection. Our results show clearly that apparent differences in the glucose-6-phosphatase activity of untreated preparations of nuclei and microsomes are simply expressions of significant differences in the degree of intactness of their respective permeability barriers. Since flattened cisternae, characteristic of the rough endoplasmic reticulum in situ, are preserved in intact regions of the envelope of isolated nuclei, the present findings constitute the most direct and definitive evidence to date that the properties of glucose-6-phosphatase in the endoplasmic reticulum in situ are faithfully reproduced with intact microsomes.