Effect of dibutyryl cyclic AMP on glucose-6-phosphatase activity in human fetal liver explants

Glucose-6-phosphatase (EC 3.1.3.9) activity in human fetal liver remains constant at 8–28 nmoles/min per mg protein from the 8th week of gestation to at least week 28 and this value is approximately 25–35% of that found in the adult. This enzyme activity was well maintained for 2–3 days in organ culture of fetal liver explants. Incubation with dibutyryl cyclic AMP (0.1 mM) and theophylline (0.5 mM) increased glucose-6-phosphatase activity 4–8-fold within 24 h. Theophylline alone was ineffective, but markedly potentiated the effects of dibutyryl cyclic AMP. This increase in enzyme activity was completely abolished by simultaneous incubation with cycloheximide or actinomycin D. Insulin clearly decreased glucose-6-phosphatase activity in control tissues after 24 h incubation and tended to diminish the elevated glucose-6-phosphatase activity which resulted from pre-incubation with dibutyryl cyclic AMP.The smallest specimen obtained (36 mm crown-rump length = 6 weeks gestation) was capable of elevating glucose-6-phosphatase activity more than 3-fold in response to dibutyryl cyclic AMP incubation, suggesting that the human fetal liver has the competence to respond to hormonal agents at a very early stage of development.     

Effect of ischemia-reperfusion on the heterogeneous lobular distribution pattern of glycogen content and glucose-6-phosphatase activity in human liver allograft.

In order to examine glucose metabolism in liver grafts after cold ischemia and reperfusion, the heterogeneous lobular distribution pattern of glycogen content and glucose-6-phosphatase activity was studied using histochemical methods. The characteristic heterogeneous lobular distribution pattern of glycogen and glucose-6-phosphatase was maintained after preservation and reperfusion. However, it appeared that glycogen content decreased in both periportal and centrilobular hepatocytes after reperfusion. The glycogen decrease was higher in periportal hepatocytes. Glucose-6-phosphatase activity was maintained after reperfusion in most of the cases in periportal hepatocytes. In centrilobular hepatocytes, more cases showed a decrease in enzyme activity. It is suggested that ischemia-reperfusion mainly affects the glycogen content in both periportal and centrilobular hepatocytes and that centrilobular glucose-6-phosphatase activity is more sensitive to ischemia-reperfusion injury than periportal hepatocytes.     

The glucose-6-phosphatase enzyme in developing human trachea and oesophagus

Summary Glucose-6-phosphatase is an endoplasmic reticulum system which is found primarily in liver and kidney. Recently, it has become clear that it is also present in lower amounts in a variety of other tissues. Previous histochemical studies of glucose-6-phosphate hydrolysis in trachea have given equivocal results and only one study on adult oesophagus has shown glucose-6-phosphatase, enzymatic activity but without cellular localization. We have now shown, using microassay techniques, that microsomes isolated from human foetal trachea and oesophagus both contain low levels of specific glucose-6-phosphatase activity (mean= 0.9 and 1.5 nmol min⁻¹ mg⁻¹ microsomal protein, respectively) which are less than 10% of the levels in microsomes of human foetal liver of similar age. In the developing trachea, glucose-6-phosphatase immunoreactivity has been found, using a monospecific antibody to the catalytic subunit of the glucose-6-phosphatase enzyme, to be first present at 10–11 weeks' gestation, and thereafter in foetal life, predominantly present in ciliated cells, with smaller amounts in non-ciliated secretory cells, duct lining cells, and occasional basal cells. The foetal oesophageal epithelium is transiently ciliated from 10 to 11 weeks' gestation, but ciliated cells are gradually replaced by squamous cells from 14 to 16 weeks onwards. Glucose-6-phosphatase immunoreactivity in human foetal oesophagus is predominantly confined to ciliated cells, but non-ciliated luminal cells are also reactive, as are occasional basal cells. Mucus secretory cells in foetal trachea and oesophagus are immunonegative, as is the entire epithelium of both organs in the embryo (up to 56 postovulatory days).     

Cytoplasmic changes in level and distribution of glucose-6-phosphatase activities from rat liver during diethylnitrosamine-induced carcinogenesis.

Glucose-6-phosphatase (EC 3.1.3.9) activities were determined in isolated microsomes, cytoplasmic smooth and rough membranes, ribosomes and free cytosol from rat liver undergoing carcinogenesis by diethylnitrosamine (DENA) and compared with cytoplasmic fractions isolated in parallel from healthy animals from the same age.With continuous administration of a low dose of DENA (2.6 mg/kg rat per day for 20 weeks in the drinking water) livers of carcinogen treated rats became heavier than the control livers but the body weight decreased. About 70% of total glucose-6-phosphatase activity could be detected in the microsomal fraction. While there was no significant difference in this activity in both animal groups up to the 4th week, glucose-6-phosphatase of cancerous liver showed a distinct decrease of activity compared with normal liver.During cancer induction this enzyme became more soluble, confirmed by the observation that it was detached from firmer structures of cytoplasm as rough membranes and polysomes and translocated to smooth membranes and the soluble cytoplasmic fraction successively. The corresponding increase in glucose-6-phosphatase activity in the 105 000 g supernatant appears to be due to the loss of enzyme activity in a distinct cytoplasmic membrane fraction. These data strongly suggest that in parallel with alteration of cytoplasmic membrane structures during carcinogen feeding glucose-6-phosphatase is detached from heavier components of the cytoplasm while total activity decreased. Possible mechanisms of these findings are discussed.     

Multiple thermal discontinuities in glucose-6-phosphatase activity.

The temperature dependence of glucose-6-phosphatase (D-glucose-6-phosphate phosphohydrolase EC 3.1.3.9) was studied in rat liver and kidney microsomal fractions. Arrhenius plots were non-linear and showed four distinct discontinuities in enzyme activity over the temperature range 2-41 degrees C. The discontinuities occurred at approx. 39, 30, 20 and 12 degrees C in the liver and were similar to this in the kidney. Changes in the energy of activation for the enzyme were noted at approx. 20 degrees C in both tissues. The multiple discontinuities in glucose-6-phosphatase activity are viewed as a reflection of complex reorganization and/or change in physical state of the membrane components, primarily lipid.     

Liver and kidney glucose-6-phosphatase levels in carbon tetrachloride- and DDT-administered mice.

Mouse liver and kidney glucose-6-phosphatase levels were found to be decreased 24 h after administration of various doses of carbon tetrachloride (CCl4) when compared to controls. Liver glucose-6-phosphatase levels were always decreased to a greater extent than the kidney enzyme in mice given the same amount of CCl4. Administration of p,p'-1,1,1,-trichloro-2,2-bis (p-chlorophenyl) ethane (p,p'-DDT) to mice did not significantly alter the glucose-6-phosphatase levels of liver or kidney.     

The kinetics of intact microsome glucose-6-phosphatase are sigmoid at physiologic glucose 6-phosphate concentrations

The kinetics of rat liver glucose-6-phosphatase (D-glucose-6-phosphate phosphohydrolase, EC 3.1.3.9) were studied with intact and detergent-disrupted microsomes from normal and diabetic rats. Glucose-6-P concentrations employed (12 microM to 1.0 mM) spanned the physiologic range. With the enzyme of intact microsomes from both groups, plots of v versus [glucose-6-P] were sigmoid. Hanes plots (i.e. [glucose-6-P]/v versus [glucose-6-P]) were biphasic (concave upwards). A Hill coefficient of 1.45 was determined with substrate concentrations between 12 and 133 microM. Disruption of microsomal integrity abolished these departures from classic kinetic behavior, indicating that sigmoidicity may result from cooperative interaction of glucose-6-P with the glucose-6-phosphatase system at the substrate translocase specific for glucose-6-P. With the enzyme from normal rats the [glucose-6-P] at which the enzyme was maximally sensitive to variations in [glucose-6-P] (which we term "Smax"), determined from plots of dv/d [glucose-6-P] versus [glucose-6-P], was in the physiologic range. The Smax of 0.13 mM corresponded well with the normal steady-state hepatic [glucose-6-P] of 0.16 mM, consistent with glucose-6-phosphatase's function as a regulatory enzyme. With the diabetic enzyme, in contrast, values were 0.30 and 0.07 mM for the Smax and steady-state level, respectively. We suggest that the decreasing sensitivity of glucose-6-phosphatase activity to progressively diminishing glucose-6-P concentration, inherent in its sigmoid kinetics, constitutes a mechanism for the preservation of a residual pool of glucose-6-P for other hepatic metabolic functions in the presence of elevated concentrations of glucose-6-phosphatase such as in diabetes.     

Glycogen metabloism in the developing chick glycogen body: functional significance of the direct oxidative pathway.

Glucose-6-phosphate dehydrogenase, 6-phosphogluconate dehydrogenase, and glucose-6-phosphatase were quantitatively determined for the first time in glycogen body tissue from late embryonic and neonatal chicks. For comparative purposes, the activities of these enzymes were examined also in liver and skeletal muscle from pre- and post-hatched chicks. The present data show that both the embryonic and neonatal glycogen body lack glucose-6-phosphatase, but contain relatively high levels of glucose-6-phosphate dehydrogenase. The activity of each dehydrogenase in either embryonic or neonatal glycogen body tissue is two- to five-fold greater than that found in muscle or liver from pre- or post-hatched chicks. The relatively high activities observed for both dehydrogenases in the glycogen body, together with the absence of glucose-6-phosphatase activity in that tissue, suggest that the direct oxidative pathway (pentose phosphate cycle) of glucose metabolism is a functionally significant route for glycogen utilization in the glycogen body. It is hypothesized that the glycogen body is metabolically linked to lipid synthesis and myelin formation in the central nervous system of the avian embryo.     

Protease inhibitors but not proteases inhibit the glucose-6-phosphatase of native rat liver microsomes.

Controlled proteolytic digestion by trypsin or bacterial proteases limited to the cytosolic side of the native microsomal membrane is not efficient to inhibit glucose-6-phosphate hydrolysis. Modification of the microsomes with deoxycholate prior to protease treatment is prerequisite to allow accessibility of the integral protein and inhibition of enzyme activity. Glucose-6-phosphatase of native microsomes, however, is rapidly inactivated by micromolar concentrations of TPCK as well as TLCK. In deoxycholate-modified microsomes both reagents do not affect glucose-6-phosphate hydrolysis. These results indicate that in the native, intact microsomal membrane glucose-6-phosphatase is not accessible to proteolytic attack from the cytoplasmic surface. The putative inhibitory effect of some trypsin or bacterial protease preparations on glucose-6-phosphatase of native microsomes observed most possibly is a result of contaminating agents as TPCK or TLCK.     

Glucose-6-phosphatase Activity in Copper-Deficient Rats

Copper deficiency has been reported to cause glucose intolerance in rats by interfering with normal glucose utilization. Accordingly, copper deficiency was produced in rats to study its effects on glucose-6-P phosphohydrolase and carbamyl-P: glucose phosphotransferase activities of hepatic glucose-6-phosphatase (EC 3.1.3.9), a major enzyme involved in maintaining glucose homeostasis. When measured in homogenates treated with deoxycholate, total glucose-6-P phosphohydrolase was 23% lower and total carbamyl-P:glucose phosphotransferase was 17% lower in copper-deficient rats compared to controls. Latency, or that portion of total activity that is not manifest unless the intact membranous components are disrupted with deoxycholate also was lower in copper-deficient rats. Glucose-6-P phosphohydrolase was 5% latent in copper-deficient rats compared to 24% in controls and carbamyl-P : glucose phosphotransferase was 55% latent in copper-deficient rats compared to 65% in controls. The decrease in latency appears to compensate for the lower total enzyme activities in such a manner as to allow the net expression of these activities in the intact membranous components of the homogenate to remain unaltered by copper deficiency. It thus appears unlikely that copper deficiency affects glucose homeostasis in vivo by altering the net rate of glucose-6-P hydrolysis or synthesis by glucose-6-phosphatase. These observations are interpreted on the basis of a multicomponent glucose-6-phosphatase system in which the total enzyme activity expressed in intact membranous preparation is limited by substrate specific translocases that transport substrate to the membrane-bound catalytic unit. A decrease in latency can then be interpreted as a functional increase in translocase activity and may constitute a compensating mechanism for maintaining constant glucose homeostasis when glucose-6-phosphatase catalytic activity is depressed as it is in copper deficiency.     

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.     

Role of polyfunctional glucose-6-phosphatase in the liver carbohydrate metabolism of the developing chick embryo

Glucose-6-phosphatase was shown to be polyfunctional in the liver of the developing chick embryo. Changes in the activity of glucose-6-phosphate phosphohydrolase did not correlate with the rate of gluconeogenesis. The activity of this enzyme increased from the 16th to the 20th day of embryogenesis. The activities of pyrophosphate-glucose phosphotransferase, carbamyl-phosphate-glucose phosphotransferase did not change during embryogenesis. The ratio of the activities of phosphohydrolase and phosphotransferases was characterized by the predominance of the phosphohydrolase activity. The values of latency of phosphohydrolase and phosphotransferases did not correlate with the rate of gluconeogenesis. Glucose-6-phosphate phosphohydrolase was found not only in the microsomal, but in the nuclear fraction as well. KM(G6P) of the enzyme of the nuclear fraction differed from KM of the microsomal enzyme.     

Biochemical compartmentation of fish tissues. Distribution of gluconeogenic enzymes in the brain

1. Specific glucose-6-phosphatase and fructose-1,6-diphosphatase activity were found to be biochemically compartmentalized in four parts of the brain in nine nutritionally important fishes. 2. Glucose-6-phosphatase and fructose-1,6-diphosphatase activity were highest in the cerebrum and lowest in the cerebellum. 3. Piscivorous fishes had the highest gluconeogenic enzyme content, followed by catfishes and major carps. 4. After the liver and muscles, the various parts of the brain play an important role in carbohydrate metabolism. 5. A direct relationship between the stage of evolution and elevation of gluconeogenic enzyme levels was observed. 6. It is evident from the results and the discussion that evolution modifies the biochemical organization of fishes in general and of their brain in particular.     

Hexose metabolism in pancreatic islets: The glucose-6-phosphatase riddle

Summary Glucose-6-phosphatase activity was measured in rat liver or pancreatic islet crude homogenates and microsomes. The data recorded in the liver were comparable to those reported in prior studies. However, in the islets, the hydrolysis of D-glucose 6-phosphate by disrupted microsomes represented, when expressed relative to the protein content, less than 2% of the value recorded in liver microsomes. Moreover, no phosphotransferase activity was detected in the islets. These findings impose reservation on both the presence of glucose-6-phosphatase in rat islets and its participation to stimulus-secretion coupling.     

The molecular basis of the type 1 glycogen storage diseases.

Microsomal glucose-6-phosphatase catalyses the last step in liver glucose production. Glucose-6-phosphatase deficiency, now termed type 1 glycogen storage disease, was first described almost 40 years ago but until recently very little was known about the molecular basis of the various type 1 glycogen storage diseases. Recently we have shown that at least six different proteins are needed for normal glucose-6-phosphatase activity in liver. Four of the proteins have been purified and three cloned. Study of the type 1 glycogen storage diseases has stimulated investigations of the mechanisms of small molecule transport across the endoplasmic reticulum membrane and demonstrated the existence of novel endoplasmic reticulum transport proteins for glucose and phosphate.     

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.     

Preliminary observations on a glucose-6-phosphate-hydrolyzing enzyme in secretory cells: a light microscopic study

Synopsis A glucose-6-phosphate-hydrolyzing enzyme was localized histochemically in a variety of secretory cells of the rat. Cells exhibiting enzyme activity include thyroid and parafollicular cells, parathyroid and secretory epithelium of the trachea, bronchi and bronchioles. Clusters of ganglion cells underlying these organs are also heavily reactive. In its cytoplasmic staining pattern and its ability to hydrolyze glucose-6-phosphate, the enzyme activity localized in these secretory cells appears similar to glucose-6-phosphatase found in liver and kidney.     

A protein in crude cytosol regulates glucose-6-phosphatase activity in crude microsomes to regulate group size in Dictyostelium

Dictyostelium discoideum form groups of approximately 2 x 10(4) cells. The group size is regulated in part by a negative feedback pathway mediated by a secreted multipolypeptide complex called counting factor (CF). The CF signal transduction pathway involves CF-repressing internal glucose levels by increasing the K(m) of glucose-6-phosphatase. Little is known about how this enzyme is regulated. Glucose-6-phosphatase is associated with microsomes in both Dictyostelium and mammals. We find that the activity of glucose-6-phosphatase in crude microsomes from cells with high, normal, or low CF activity had a negative correlation with the amount of CF present in these cell lines. In crude cytosols (supernatants from ultracentrifugation of cell lysates), the glucose-6-phosphatase activity had a positive correlation with CF accumulation. The crude cytosols were further fractionated into a fraction containing molecules greater than 10 kDa (S>10K) and molecules less than 10 KDa (S<10K). S>10K from wild-type cells strongly repressed the activity of glucose-6-phosphatase in wild-type microsomes, whereas S>10K from countin(-) cells (cells with low CF activity) significantly increased the activity of glucose-6-phosphatase in wild-type microsomes by decreasing K(m). The regulatory activities in the wild-type and countin(-) S>10Ks are heat-labile and protease-sensitive, suggesting that they are proteins. S<10K from both wild-type and countin(-) cells did not significantly change glucose-6-phosphatase activity. Together, the data suggest that, as a part of a pathway modulating multicellular group size, CF regulates one or more proteins greater than 10 KDa in crude cytosol that affect microsome-associated glucose-6-phosphatase activity.     

Lack of coordination between glucose-6-phosphatase and gamma glutamyltranspeptidase activities in rat hepatocytes maintained in primary culture

Glucose-6-phosphatase activity decreases whereas gamma glutamyltranspeptidase activity increases during hepatocarcinogenesis and the maintenance of hepatocytes in primary culture. This report describes the effect of culture conditions that are known to preserve hepatic glucose-6-phosphatase activity on gamma glutamyltranspeptidase activity. The results indicate that the regulation of glucose-6-phosphatase and gamma glutamyltranspeptidase activities is not coordinated in primary cultures of hepatocytes.