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.     

Identification of the human hepatic microsomal glucose-6-phosphatase enzyme

The glucose-6-phosphatase enzyme protein of the human hepatic microsomal glucose-6-phosphatase system was identified as a 36.5 kDa polypeptide. The 36.5 kDa glucose-6-phosphatase enzyme protein was shown to be absent in the microsomes isolated from a patient previously diagnosed as having a type 1a glycogen storage disease.     

Thermal stability of microsomal glucose-6-phosphatase

The thermal stability of glucose-6-phosphatase in rat liver microsomes was examined in untreated and cholate-treated microsomes. Activity of the enzyme was measured with both glucose-6-P and mannose-6-P as substrates. Heat treatment did not cause glucose-6-phosphatase activity to decline to zero with a single rate constant in untreated microsomes. Instead, heat treatment produced an enzyme with a small residual activity that was stable. The residual level of activity was not stimulated by addition of detergent. In untreated microsomes the energies of activation for the processes of decay were different for glucose-6-phosphatase and mannose-6-phosphatase activities, suggesting that the rate-limiting steps for the hydrolysis of these compounds were different. Treatment of microsomes with detergent increased the rate constants for the thermal decay of glucose-6-phosphatase by about 150 times, and, in contrast to untreated microsomes, glucose-6-phosphatase and mannose-6-phosphatase decayed to zero with a single rate constant in cholate-treated microsomes. Also, rate constants for thermal inactivation of glucose-6-phosphatase and mannose-6-phosphatase were the same in cholate-treated microsomes. Removal of cholate increased the stability of glucose-6-phosphatase but did not regenerate the form of the enzyme present in untreated microsomes. The data for the stability of glucose-6-phosphatase under different conditions provide evidence that the enzyme can exist in at least five different stable states that are enzymatically active.     

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.     

Kinetic properties of cat liver microsomal glucose-6-phosphatase

• 1.1. Cat liver microsomes contain the multifunctional enzyme glucose-6-phosphatase.
• 2.2. High specificity was shown for the phosphohydrolase as well as for the transferase activity.
• 3.3. Both activities have high V_max values determined in optimized conditions.
• 4.4. The phosphate transfer with carbamyl-phosphate as a phosphoryl donor and d-glucose as acceptor is consistent with a random mechanism in which the binding of one substrate decreases the enzyme's affinity for the second substrate.

     

Membrane effects on hepatic microsomal glucose-6-phosphatase.

1) Rat liver microsomes exhibit only a weak hydrolyzing activity towards galactose 6-phosphate. Disruption of the microsomal vesicles does not change the apparent Michaelis constant for this substrate but enhances the apparent maximum velocity. 2) The inhibition of microsomal glucose-6-phosphatase (EC 3.1.3.9) by galactose 6-phosphate is of the competitive type in intact and disrupted microsomal vesicles, suggesting that both substrates are hydrolyzed by the same enzyme. 3) The high degree of latency found for the hydrolysis of galactose 6-phosphate compared to glucose 6-phosphate indicates the presence of a carrier for glucose 6-phosphate in the microsomal membrane. 4) Since glucose as a product is not trapped inside the microsomal vesicles, this sugar probably is able to penetrate the microsomal membrane.     

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.     

The microsomal glucose-6-phosphatase enzyme of pancreatic islets.

Microsomal fractions isolated from pancreatic islet cells were shown to contain high specific glucose-6-phosphatase activity. The islet-cell glucose-6-phosphatase enzyme has the same Mr (36,500), similar immunological properties and kinetic characteristics to the hepatic microsomal glucose-6-phosphatase enzyme.     

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.     

Studies of microsomal glucose-6-phosphatase on liver of irradiated rats

The activity of microsomal glucose-6-phosphatase (EC 3.1.3.9) on male rat liver was measured 1-9 days after whole-body gamma-irradiation. A marked fall of activity, expressed per whole liver, was observed reaching a minimum on the 4th day following irradiation. The enzyme activity is partially and momentarily restored (on day 7), before a new decrease occurred. Furthermore, when the results are expressed per milligram of microsomal proteins, there was no change. Cysteamine, when injected in vivo, kept up the glucose-6-phosphatase of whole liver. On day 4, a histochemical demonstration of the enzyme in liver cells is in accordance with enzyme measures. These observations suggested that the enzyme quantity was altered during the acute radiation syndrome in the rat.     

A putative second messenger of insulin action regulates hepatic microsomal glucose-6-phosphatase

Physiological concentrations of insulin suppressed rat liver microsomal glucose-6-phosphatase activity in vitro. To attest a hypothesis that a putative second messenger of insulin action (insulin mediator) mediated this process, we isolated the low molecular factor from insulin-treated plasma membranes of rat liver, which was acid- and heat-stable substance of a peptide nature. The insulin mediator which was proved to activate the mitochondria pyruvate dehydrogenase suppressed microsomal glucose-6-phosphatase. The insulin mediator was linked to suppression of the gluconeogenic enzyme through the control of non-specific phosphohydroxylase.     

Hysteretic behavior of the hepatic microsomal glucose-6-phosphatase system.

Carbamyl-P:glucose and PPi:glucose phosphotransferase, but not inorganic pyrophosphatase, activities of the hepatic microsomal glucose-6-phosphatase system demonstrate a time-dependent lag in product production with 1 mM phosphate substrate. Glucose-6-P phosphohydrolase shows a similar behavior with [glucose-6-P] less than or equal to 0.10 mM, but inorganic pyrophosphatase activity does not even at the 0.05 or 0.02 mM level. The hysteretic behavior is abolished when the structural integrity of the microsomes is destroyed by detergent treatment. Calculations indicate that an intramicrosomal glucose-6-P concentration of between 20 and 40 microM must be achieved, whether in response to exogenously added glucose-6-P or via intramicrosomal synthesis by carbamyl-P:glucose or PPi:glucose phosphotransferase activity, before the maximally active form of the enzyme system is achieved. It is suggested that translocase T1, the transport component of the glucose-6-phosphatase system specific for glucose-6-P, is the target for activation by these critical intramicrosomal concentrations of glucose-6-P.     

The effect of p-hydroxymercuribenzoate and congeners on microsomal glucose-6-phosphatase

Summary Iodoacetamide, N-ethylmaleimide, p-hydroxy-mercuribenzoate (p-MB) and HgCl₂ were tested as inhibitors of microsomal glucose-6-phosphatase. Iodoacetamide had no effect at 2mm. N-ethylmaleimide inhibited only crude, but not purified microsomal preparations (M₂) or crude microsomes exposed to deoxycholate.¹⁴C-labelled N-ethylmaleimide was not bound by the M₂ protein fraction. p-MB inhibited all types of preparations and the inhibition was not counteracted by detergent. A more detailed study was carried out with the purified M₂ fraction (specific activity: 2–4µmoles P_i/min/mg protein). Glucose-6-phosphate hydrolysis was inhibited 50% by 5 × 10^–5 m p-MB. The inhibition was completely reversible by dithiothreitol except when the enzyme was pre-incubated with p-MB in the absence of substrate. Then p-MB accelerated the temperature-dependent inactivation of glucose-6-phosphatase. Binding studies showed that around 3µmoles¹⁴C-p-MB were incorporated into 100 mg M₂ protein regardless of the concentration of mercurial in the incubation mixture. That is, over a 25 fold range of p-MB concentration, causing up to 80% inhibition of enzyme activity, no difference was seen in the amount of labelled p-MB which was irreversibly bound to M₂ protein. Kinetically p-MB behaved like a reversible inhibitor and this was confirmed by dilution experiments. Several compounds, including some amino acids, antagonized the inhibition by p-MB. The order of effectiveness was EDTA > barbital > tryptophan > histidine > lysine > other amino acids. Glycine, Tris and urea were ineffective competitors of p-MB inhibition. Double reciprocal plots showed that the K_m for glucose-6-phosphate was increased and the V_max reduced in the presence of p-MB. HgCl₂ was a more effective inhibitor than p-MB with a K_i of 6 × 10^–6 m. We conclude that a reaction of p-MB with M₂ sulfhydryls does not play a part in the inhibition of enzyme activity. It is suggested that p-MB may interact with one or more amino acid side chains in such a way that enzyme conformation is altered.Supported by U.S. Public Health Service Grant No. AM11448-08 and General Research Support Grant No. RR05486-12.     

The mechanism of histone activation of the hepatic microsomal glucose-6-phosphatase system: a novel method to assay glucose-6-phosphatase activity

The mechanism of activation of hepatic microsomal glucose-6-phosphatase (EC 3.1.3.9) by histone 2A has been investigated in both intact and disrupted microsomes. Histone 2A increased the Vmax and decreased the Km of glucose-6-phosphatase in intact microsomes but had no effect on glucose-6-phosphatase activity in disrupted microsomes. Histone 2A was shown to activate glucose-6-phosphatase in intact microsomes by disrupting the membrane vesicles and thereby allowing the direct measurement of the activity of the latent glucose-6-phosphatase enzyme. The study demonstrated that disrupting microsomes with histone 2A is an excellent method for directly assaying glucose-6-phosphatase activity as it poses none of the problems encountered with all of the previously used methods.