Inhibition of phosphoenolpyruvate carboxykinase (PEPCK) gene expression by troglitazone: a peroxisome proliferator-activated receptor-gamma (PPARgamma)-independent, antioxidant-related mechanism.

Phosphoenolpyruvate carboxykinase (PEPCK) is the rate-limiting enzyme of gluconeogenesis. Enhanced expression of the PEPCK gene in liver is present in most models of diabetes, and is thought to contribute to the increased hepatic glucose output seen in this disease. Recently, we showed that troglitazone, the first thiazolidinedione (TZD) used clinically, inhibits expression of the PEPCK gene in isolated hepatocytes. We have pursued the molecular mechanism whereby troglitazone exerts this inhibition. TZDs are known to bind and activate peroxisome proliferator-activated receptor-gamma (PPARgamma), a nuclear receptor, which regulates expression of target genes. Initially, we examined the abilities of three other TZDs (rosiglitazone, englitazone, and ciglitazone) to inhibit expression of the PEPCK gene. Despite the fact that these agents are ligands for PPARgamma, they displayed little if any inhibitory activity on the expression of this gene. GW1929 [N-(2-benzoyl phenyl)-l-tyrosine], another potent PPARgamma ligand that is unrelated structurally to TZDs, had no inhibitory effect on PEPCK gene expression, while a natural PPARgamma ligand, the prostaglandin metabolite 15-PGJ2 (15-deoxy-Delta(12,14)-prostaglandin J2), displayed only modest inhibitory activity. Treatment of hepatocytes with ligands for other isoforms of PPAR also had no significant effect on PEPCK gene expression. Troglitazone has an alpha-tocopherol (vitamin E) moiety that is not present in other TZDs, and treatment of hepatocytes with vitamin E led to an inhibition of PEPCK gene expression. These observations support the conclusion that troglitazone inhibits the expression of the PEPCK gene by a PPARgamma-independent, antioxidant-related mechanism.

Reciprocal regulation of glycogen phosphorylase and glycogen synthase by insulin involving phosphatidylinositol-3 kinase and protein phosphatase-1 in HepG2 cells.

The effect of insulin on glycogen synthesis and key enzymes of glycogen metabolism, glycogen phosphorylase and glycogen synthase, was studied in HepG2 cells. Insulin stimulated glycogen synthesis 1.83-3.30 fold depending on insulin concentration in the medium. Insulin caused a maximum of 65% decrease in glycogen phosphorylase 'a' and 110% increase in glycogen synthase activities in 5 min. Although significant changes in enzyme activities were observed with as low as 0.5 nM insulin level, the maximum effects were observed with 100 nM insulin. There was a significant inverse correlation between activities of glycogen phosphorylase 'a' and glycogen synthase 'a' (R2= 0.66, p < 0.001). Addition of 30 mM glucose caused a decrease in phosphorylase 'a' activity in the absence of insulin and this effect was additive with insulin up to 10 nM concentration. The inactivation of phosphorylase 'a' by insulin was prevented by wortmannin and rapamycin but not by PD98059. The activation of glycogen synthase by insulin was prevented by wortmannin but not by PD98059 or rapamycin. In fact, PD98059 slightly stimulated glycogen synthase activation by insulin. Under these experimental conditions, insulin decreased glycogen synthase kinase-3beta activity by 30-50% and activated more than 4-fold particulate protein phosphatase- activity and 1.9-fold protein kinase B activity; changes in all of these enzyme activities were abolished by wortmannin. The inactivation of GSK-3beta and activation of PKB by insulin were associated with their phosphorylation and this was also reversed by wortmannin. The addition of protein phosphatase-1 inhibitors, okadaic acid and calyculin A, completely abolished the effects of insulin on both enzymes. These data suggest that stimulation of glycogen synthase by insulin in HepG2 cells is mediated through the PI-3 kinase pathway by activating PKB and PP-1G and inactivating GSK-3beta. On the other hand, inactivation of phosphorylase by insulin is mediated through the PI-3 kinase pathway involving a rapamycin-sensitive p70(s6k) and PP-1G. These experiments demonstrate that insulin regulates glycogen phosphorylase and glycogen synthase through (i) a common signaling pathway at least up to PI-3 kinase and bifurcates downstream and (ii) that PP-1 activity is essential for the effect of insulin.

Troglitazone inhibits expression of the phosphoenolpyruvate carboxykinase gene by an insulin-independent mechanism.

Troglitazone is an oral insulin-sensitizing drug used to treat patients with type 2 diabetes. A major feature of this hyperglycemic state is the presence of increased rates of hepatic gluconeogenesis, which troglitazone is able to ameliorate. In this study, we examined the molecular basis for this property of troglitazone by exploring the effects of this compound on the expression of the two genes encoding the major regulatory enzymes of gluconeogenesis, phosphoenolpyruvate carboxykinase (PEPCK) and glucose-6-phosphatase (G6Pase) in primary cultures of rat hepatocytes. Insulin is able to inhibit expression of both of these genes, which was verified in our model system. Troglitazone significantly reduced mRNA levels of PEPCK and G6Pase in rat hepatocytes isolated from normal and Zucker-diabetic rats, but to a lesser extent than that observed with insulin. Interestingly, troglitazone was unable to reduce cAMP-induced levels of PEPCK mRNA, suggesting that the molecular mechanism whereby troglitazone exerted its effects on gene expression differed from that of insulin. This was further supported by the observation that troglitazone was able to reduce PEPCK mRNA levels in the presence of the insulin signaling pathway inhibitors wortmannin, rapamycin, and PD98059. These results indicate that troglitazone can regulate the expression of specific genes in an insulin-independent manner, and that genes encoding gluconeogenic enzymes are targets for the inhibitory effects of this drug.

Troglitazone induces expression of PPARgamma in liver.

Troglitazone is an insulin sensitizer which affects a number of target tissues. It is believed to exert these effects primarily by binding to and activating the y-isoform of peroxisome proliferator-activated receptor (PPARgamma), which in turn regulates the expression of specific genes. However, in a number of target organs, such as liver, the levels of PPARgamma are low and other isoforms predominate. In the present study, we examined whether troglitazone induces the expression of PPARgamma, thereby sensitizing cells for the action of this drug. Treatment of isolated rat hepatocytes with troglitazone induced both the mRNA and protein levels of PPARgamma in a dose-dependent fashion, with maximal levels of induction being three- to fourfold. This induction was also observed using the 15-deoxy-delta12,14-prostaglandin J2, a known natural ligand for PPARgamma, whereas ligands specific for PPARalpha were without effect. The induction of PPARgamma expression by troglitazone was also observed in livers from rats fed a diet containing troglitazone. Troglitazone had no effect on the expression of the alpha- or beta-isoforms of PPAR, the more predominant liver isoforms. These results indicate that troglitazone produces a reprogramming of PPAR isoform content in liver, which may in part underlie the mechanism whereby troglitazone sensitizes the liver to the action of insulin and/or ameliorates hyperglycemia.

Insulin action on protein phosphatase-1 activation is enhanced by the antidiabetic agent pioglitazone in cultured diabetic hepatocytes.

Effect of the antidiabetic agent pioglitazone on the insulin-mediated activation of protein phosphatase-1 was examined in diabetic hepatocytes. Streptozotocin-induced diabetes in Sprague Dawley rats caused a significant decrease in the activation of glycogen synthase in hepatocytes isolated from these animals. There was an inverse correlation between the in vivo hyperglycemic condition and the in vitro activation of glycogen synthase in liver cells (r = 0.93, p < 0.001). Long term incubation of diabetic hepatocytes with insulin and dexamethasone caused significant (p < 0.001) improvement in the activation of glycogen synthase activation. When incubated along with hormones, pioglitazone enhanced their action (p < 0.05-0.01). Diabetic hepatocytes were also characterized by 50% decrease in the activity of protein phosphatase-1, the enzyme which dephosphorylates and activates glycogen synthase. Pioglitazone potentiated the acute stimulatory effect of insulin on protein phosphatase-1 in normal hepatocytes but not in diabetic hepatocytes. Long term incubation of diabetic hepatocytes with insulin ameliorated the decrease in the protein phosphatase-1 activity in these cells. This stimulatory long-term effect of insulin was significantly (p < 0.05) enhanced by the antidiabetic agent pioglitazone.

Protein phosphorylation in rat cardiac microsomes: effects of inhibitors of protein kinase A and of phosphatases.

The phosphorylation of rat cardiac microsomal proteins was investigated with special attention to the effects of okadaic acid (an inhibitor of protein phosphatases), inhibitor 2 of protein phosphatase 1 and inhibitor of cyclic AMP-dependent protein kinase (protein kinase A). The results showed that okadaic acid (5 microM) modestly but reproducibly augmented the protein kinase A-catalyzed phospholamban (PLN) phosphorylation, although exerted little effect on the calcium/calmodulin kinase-catalyzed PLN phosphorylation. Microsomes contained three other substrates (M(r) 23, 19 and 17 kDa) that were phosphorylated by protein kinase A but not by calcium/calmodulin kinase. The protein kinase A-catalyzed phosphorylation of these three substrates was markedly (2-3 fold) increased by 5 microM okadaic acid. Calmodulin was found to antagonize the action of okadaic acid on such phosphorylation. Protein kinase A inhibitor was found to decrease the protein kinase A-catalyzed phosphorylation of microsomal polypeptides. Unexpectedly, inhibitor 2 was also found to markedly decrease protein kinase A-catalyzed phosphorylation of phospholamban as well these other microsomal substrates. These results are consistent with the views that protein phosphatase 1 is capable of dephosphorylating membrane-associated phospholamban when it is phosphorylated by protein kinase A, but not by calcium/calmodulin kinase, and that under certain conditions, calcium/calmodulin-stimulated protein phosphatase (protein phosphatase 2B) is also able to dephosphorylate PLN phosphorylated by protein kinase A. Additionally, the observations show that protein phosphatase 1 is extremely active against the three protein kinase A substrates (M(r) 23, 19 and 17 kDa) that were present in the isolated microsomes and whose state of phosphorylation was particularly affected in the presence of dimethylsulfoxide. Protein phosphatase 2B is also capable of dephosphorylating these three substrates.

Inhibition of a Src homology 2 domain containing protein tyrosine phosphatase by vanadate in the primary culture of hepatocytes.

Inhibition of protein tyrosine phosphatase (PTP) activities by vanadate was examined in cultured rat hepatocytes. The incubation of hepatocytes with sodium orthovanadate inhibited PTP activities, measured with labeled polyglutamate tyrosine (4:1) and insulin receptor peptide (1142-1153), in a dose- and time-dependent manner. The PTP activities in cytosolic and particulate fractions were inhibited with the IC50 values of 30-50 and 2-20 microM, respectively. Vanadate-mediated inhibition of protein phosphatase, type 1 (a serine phosphatase) was less pronounced, requiring 50- to 150-fold higher concentrations. Molybdate and tungstate, the other potent inhibitors of PTPs, exerted approximately 70% less inhibition of enzyme activities compared to vanadate in intact liver cells. The cytosolic and particulate PTPs inhibited by vanadate were further resolved by fast protein liquid chromatography on Mono Q and Superose-12 columns. Vanadate exerted stable and differential inhibition of several PTPs. One of them was identified as SHPTP2 (Syp, SHP-2) in cytosolic as well as particulate fractions. Immunoprecipitation of this PTP with Syp-antibody coupled to protein A-agarose confirmed the vanadate-induced decrease in SHPTP2 activity. Vanadate did not alter the expression of SHPTP2 and its distribution between cytosolic and particulate fractions as indicated by the immunoblots. The decrease in the activities of PTPs in vanadate-treated hepatocytes in general was found to be reversed by the reducing agent dithioerythreitol. This study shows that vanadate inhibits many PTPs in intact liver cells, one of them being SHPTP2/SHP-2. The inhibition is stable after chromatography on ion-exchange and gel filtration chromatography. The enzyme inhibition seems to involve the oxidation of the thiol group of PTPs.

Insulin decreases the glycogen synthase kinase-3 alpha mRNA levels by altering its stability in streptozotocin-induced diabetic rat liver.

The chronic effect of insulin on the expression of the glycogen synthase kinase-3 alpha gene in streptozotocin-induced diabetic rat liver is examined. The mRNA levels of glycogen synthase kinase-3 alpha were increased (143% of normal levels) in diabetic livers and these were normalized by insulin supplementation to the diabetic animals. Neither diabetes nor insulin supplementation to diabetic rats altered the transcription rate of glycogen synthase kinase-3 alpha. However, diabetes caused an increase in the half-life of glycogen synthase kinase-3 alpha mRNA from 5 h in normal hepatocytes to 8 h in diabetic ones. Insulin supplementation to the incubation medium of diabetic hepatocytes decreased the half-life of glycogen synthase kinase-3 alpha mRNA to a level comparable with normal values. This study suggests that the chronic effect of insulin decreases the levels of glycogen synthase kinase-3 alpha mRNA by altering its stability.

Decrease in protein tyrosine phosphatase activities in vanadate-treated obese Zucker (fa/fa) rat liver.

The inhibitory action of vanadate towards protein tyrosine phosphatase (PTPase) has been considered as a probable mechanism by which it exerts insulin-like effects. In this study, we have examined the in vivo effects of vanadate on PTPases in the liver of obese Zucker rats, a genetic animal model for obesity and type II diabetes. These animals were characterized by hyperinsulinemia and mild hyperglycemia. The number of insulin receptors were significantly (p < 0.01) decreased in liver. After chronic administration of vanadate in obese rats, 80% decrease in the plasma levels of insulin was observed. The insulin receptor numbers were significantly (p < 0.01) higher in vanadate-treated obese rats as compared to the untreated ones. The hepatic PTPase activities in cytosolic and particulate fractions, with phosphorylated poly glu:tyr (4:1) and the insulin receptor peptide (residues 1142-1153) as substrates, increased in obese rats. In vanadate-treated obese rat livers, the PTPase activities in both subcellular fractions with these substrates decreased significantly (p < 0.001). The decreases in PTPase activities from these groups of rats were further supported by chromatography on a Mono Q column. These data support the view that inhibition of PTPases plays a role in the insulin-mimetic action of vanadate.

In vivo modulation of N-myristoyltransferase activity by orthovanadate.

N-Myristoyltransferase (NMT) catalyses the transfer of myristate from myristoyl-CoA to the NH2-terminal glycine residue of several proteins and are important in signal transduction. STZ-induced diabetes (an animal model for insulin-dependent diabetes mellitus, IDDM) resulted in a 2-fold increase in rat liver NMT activity as compared with control animals. In obese Zucker (fa/fa) rats (an animal model for non-insulin dependent diabetes mellitus, NIDDM) there was a approximately 4.7-fold lower liver particulate NMT activity as compared with the control lean rat livers. Administration of sodium orthovanadate to the diabetic rats normalised liver NMT activity. These results would indicate that the rat liver particulate N-myristoyltransferase activity appears to be inversely proportional to the level of plasma insulin, implicating insulin in the control of N-myristoylation.

Vanadate induces normolipidemia and a reduction in the levels of hepatic lipogenic enzymes in obese Zucker rat.

The effects of vanadate administration on the plasma lipids and hepatic lipogenic enzymes were investigated in Zucker (fa/fa) rat, a model for obesity and non insulin-dependent diabetes. These animals were administered sodium orthovanadate through drinking water for a period of four months. The plasma levels of insulin, triacylglycerols and total cholesterol were significantly (p < 0.001) elevated in untreated obese control rats as compared to the lean animals. In the livers of obese rats, the number of insulin receptors decreased by 60% and the activities of lipogenic enzymes acetyl-CoA carboxylase and ATP-citrate lyase increased by 4.7- and 5.6-folds, respectively. The messenger RNA for ATP-citrate lyase as measured by Northern blot analysis showed a parallel increase in obese control rats. Treatment of these rats with vanadate caused 56-77% decreases in the plasma levels of insulin, triacylglycerols and total cholesterol. The insulin receptor numbers in vanadate-treated obese rats increased (119%) compared to levels in untreated obese animals. The elevated activities of acetyl-CoA carboxylase and ATP-citrate lyase observed in livers of obese rats were significantly reduced by vanadate. The messenger RNA for ATP-citrate lyase also decreased in vanadate-treated obese rats back to the lean control levels. This study demonstrates that vanadate exerts potent actions on lipid metabolism in diabetic animals in addition to the recognized effects on glucose homeostasis.

In vivo effects of vanadate on hepatic glycogen metabolizing and lipogenic enzymes in insulin-dependent and insulin-resistant diabetic animals.

The insulin-mimetic action of vanadate is well established but the exact mechanism by which it exerts this effect is still not clearly understood. The role of insulin in the regulation of hepatic glycogen metabolizing and lipogenic enzymes is well known. In our study, we have, therefore, examined the effects of vanadate on these hepatic enzymes using four different models of diabetic and insulin-resistant animals. Vanadate normalized the blood glucose levels in all animal models. In streptozotocin-induced diabetic rats, the amount of liver glycogen and the activities of the active-form of glycogen synthase, both active and inactive-forms of phosphorylase, and lipogenic enzymes like glucose 6-phosphate dehydrogenase and malic enzyme were decreased and vanadate treatment normalized all of these to near normal levels. The other three animal models (db/db mouse, sucrose-fed rats and fa/fa obese Zucker rats) were characterized by hyperinsulinemia, hypertriglyceridemia, increases in activities of lipogenic enzymes, and marginal changes in glycogen metabolizing enzymes. Vanadate treatment brought all of these values towards normal levels. It should be noted that vanadate shows differential effects in the modulation of lipogenic enzymes activities in type I and type II diabetic animals. It increases the activities of lipogenic enzymes in streptozotocin-induced diabetic animals and prevents the evaluation of activities of these enzymes in hyperinsulinemic animals. The insulin-stimulated phosphorylation of insulin receptor beta subunit and its tyrosine kinase activity was increased in streptozotocin-induced diabetic rats after treatment with vanadate. Our results support the view that insulin receptor is one of the sites involved in the insulin-mimetic actions of vanadate.

The phosphorylation state of the cAMP response element binding protein is decreased in diabetic rat liver.

Phosphoenolpyruvate carboxykinase (PEPCK) is the rate-limiting enzyme of gluconeogenesis. This metabolically important enzyme is unique in that it has no known allosteric modifiers, and all of the regulation of its activity is exerted at the level of gene expression. The expression of the PEPCK gene in liver is elevated in most forms of diabetes, and plays a major contributory role in the hyperglycemia characteristic of this disease. In this study, we initiated studies to determine the molecular basis for the increased PEPCK gene expression in diabetes. RNase protection assays of RNA isolated from control, streptozotocin-induced diabetic, and insulin-treated diabetic rat liver indicated that PEPCK mRNA levels are elevated two- to threefold in diabetic rat liver compared to controls. Nuclear run-on assays indicated that the increased PEPCK mRNA levels can be fully accounted for by changes in the transcription rate of the gene. We next initiated characterization of the cAMP response element binding protein (CREB) in diabetic rat liver, since it is known to play a major role in mediating the it is known to play a major role in mediating the basal transcriptional activity of the PEPCK gene as well as the cAMP-dependent stimulation of PEPCK gene transcription, the latter through the phosphorylation of serine 133 of CREB. Western blot analysis of nuclear lysates prepared from rat livers indicated that CREB protein levels in diabetic rat liver nuclei were similar to those of controls. However, using an antibody which specifically recognizes the serine 133-phosphorylated form of CREB, we found that the levels of phospho-CREB were significantly decreased in diabetic rat liver, an effect which insulin treatment reversed. This observation suggests that overexpression of the PEPCK gene in diabetes is not linked to the cAMP signaling system in liver.

The effects of streptozotocin-induced diabetes and insulin supplementation on expression of the glycogen phosphorylase gene in rat liver.

We have previously observed that the chronic effects of streptozotocin-induced diabetes cause a decrease in the total hepatic glycogen phosphorylase activity with a corresponding reduction in the phosphorylase protein levels. These effects were normalized by insulin administration to diabetic rats. There was no change in the total glycogen synthase activity as a result of diabetes or insulin supplementation. These results are extended to examine the effects of diabetes and insulin administration to diabetic animals on the expression of phosphorylase and glycogen synthase enzymes. The expression (i.e. mRNA levels) of phosphorylase was down-regulated (45% of normal levels) in diabetic livers, and this was normalized by insulin supplementation to diabetic animals. Diabetes or insulin supplementation to diabetic rats showed no effect on the transcription rate of phosphorylase. As expected, diabetes (or insulin administration to diabetic animals) did not cause any alteration in the mRNA levels or in the transcription rate of hepatic glycogen synthase. The stability of phosphorylase mRNA was then examined using hepatocytes prepared from normal and diabetic rats. Diabetes caused a decrease in the half-life of phosphorylase mRNA from 14 h in normal hepatocytes to 6.5 h in diabetic hepatocytes. Insulin supplementation to the medium of diabetic hepatocytes increased the half-life of phosphorylase mRNA to a level comparable with normal values. This study indicates that the chronic effect of insulin on the activation of the total hepatic phosphorylase activity (and protein) is mediated through the stabilization of its mRNA levels.

Regulation of glycogen synthase activation in isolated hepatocytes.

Glycogen synthase, the regulatory enzyme of glycogen synthesis undergoes multisite phosphorylation leading to its inactivation. The kinases responsible for this covalent modification (ex. cAMP-dependent protein kinase, protein kinase C and glycogen synthase kinase-3) are controlled by the second messengers generated by different hormones. The isolated hepatocytes has been used as one of the experimental models for studying this complex regulatory process. Inactivation of glycogen synthase by glucagon and vasopressin has been shown to be accompanied with incorporation of phosphate into the enzyme protein. Insulin has been shown to activate glycogen synthase by inhibition of kinases and activation of synthase phosphatase. Glycogen synthase is activated by several gluconeogenic substrates, in addition to glucose. Studies in hepatocytes with activators and inhibitors of protein kinase C show that this enzyme negatively controls glycogen synthase. The differential effects of the phosphatase inhibitors, calyculin A and okadaic acid in liver cells provide supporting evidence that protein phosphatase type-1 plays a major role in the regulation of glycogen synthase. Hepatocytes isolated from diabetic rats of both types (insulin-dependent and non-insulin-dependent) mimic the defective glycogen synthase activation seen in vivo.

Effects of metformin on glucose and glucagon regulated gluconeogenesis in cultured normal and diabetic hepatocytes.

The effects of glucose and glucagon on the anti-gluconeogenic action of metformin were investigated in normal and diabetic hepatocytes. Glucose production from lactate was elevated by 88% in hepatocytes from fasted normal rats compared with hepatocytes from fed animals. Diabetes caused 3.5- and 2.1-fold increases in hepatic gluconeogenesis under fasting and fed conditions, respectively. Metformin (250 microM) suppressed glucose production by 37% in normal and by 30% in diabetic hepatocytes from fed rats. This drug was more effective (up to 67%) with increasing concentrations of glucose in the medium. Potentiation by metformin of insulin action on gluconeogenesis was elevated significantly (P < 0.01 to 0.001) by glucose in vitro. Metformin (75-250 microM) also counteracted the effects of glucagon at optimal concentrations in normal (32-68%) as well as diabetic (8-46%) hepatocytes. The findings of this study indicate that (i) the anti-gluconeogenic effect of metformin is enhanced by glucose in vivo and in vitro; and (ii) the suppression of glucagon-induced gluconeogenesis by metformin could play a role in its glucose-lowering effects in diabetic conditions.

Reciprocal effects of the protein kinase C inhibitors staurosporine and H-7 on the regulation of glycogen synthase and phosphorylase in the primary culture of hepatocytes.

The effects of the protein kinase C inhibitors staurosporine and H-7 [1-(5-isoquinolinylsulfonyl)-2-methylpiperazine] on glucose-induced regulation of glycogen synthase and phosphorylase activities were investigated in the primary culture of hepatocytes. Glycogen synthesis as measured by the incorporation of [14C]glucose into glycogen was enhanced up to 78% (P < .001) by 100 nmol/L staurosporine. In contrast, H-7 inhibited glycogen synthesis in a dose-dependent manner, with an IC50 value of 70 mumol/L. Activation of glycogen synthase by 30 mmol/L glucose was enhanced significantly (P < .02 and less) by staurosporine at 20 nmol/L and higher concentrations whereas the activity of this enzyme was inhibited by H-7 (IC50 = 50 mumol/L). The inactivation of phosphorylase by glucose was significantly greater when staurosporine was included in the medium. However, H-7 increased the phosphorylase activity ratio by 1.5- to 2.5-fold at concentrations of 20 to 100 mumol/L. The time course of synthase activation and phosphorylase inactivation showed that the effect of glucose was enhanced by staurosporine and inhibited by H-7. These novel reciprocal effects of protein kinase C inhibitors were also observed at different concentrations of glucose. The effects of H-8, a compound with structural resemblance to H-7 and an inhibitor of protein kinase A, were similar to those of staurosporine but not to those of H-7. Staurosporine blocked the effects of vasopressin and 4 beta-phorbol 12 beta-myristate 13 alpha-acetate (PMA), whereas H-7 in combination with these protein kinase C activators acted in the same direction. The effects of staurosporine, a relatively more specific inhibitor of protein kinase C, indicated that this enzyme plays a role in the regulation of glycogen metabolism in liver. However, H-7, which is known to have protein kinase C-independent effects in intact cells, seems to alter the activities of glycogen synthase and phosphorylase by a different mechanism.

Does the insulin-mimetic action of vanadate involve insulin receptor kinase?

Effects of vanadate administration on the insulin receptor status in liver were examined in streptozotocin-induced diabetic rats. Diabetic rats were characterized by hyperglycemia (4-fold increase), hypoinsulinemia (81% decrease) and a significant (P < 0.01) increase in hepatic insulin receptor numbers. Autophosphorylation of the beta subunit of insulin receptor and its tyrosine kinase activity towards the synthetic peptide (poly glut4tyr1) decreased by approximately 60% as a result of diabetes. After chronic treatment of these rats with sodium orthovanadate, the plasma glucose levels were normalized to near control values with the hypoinsulinemia remaining unaltered. The insulin-stimulated phosphorylation of the beta subunit increased significantly (P < 0.001) in diabetic rats after treatment with vanadate. However, the improvement in the tyrosine kinase activity was marginal. In vitro, vanadate prevented the dephosphorylation of the phosphorylated insulin receptor and increased its tyrosine kinase activity in the absence as well as presence of insulin. The findings of this study further support the view that insulin receptor is one of the sites involved in the insulin-mimetic actions of vanadate.

Differential effects of calyculin A and okadaic acid on the glucose-induced regulation of glycogen synthase and phosphorylase activities in cultured hepatocytes.

The effects of the phosphatase inhibitors calyculin A and okadaic acid were investigated to determine the roles of protein phosphatases type 1 and 2A in the regulation of the activities of glycogen synthase and phosphorylase by glucose in a primary culture of hepatocytes. Glycogen synthesis, as measured by the incorporation of labelled glucose into glycogen, was inhibited in a dose-dependent manner by calyculin A (IC50 = 2.2 nM) and okadaic acid with (IC50 = 14 nM). Glucose-induced activation of glycogen synthase was inhibited by calyculin A and okadaic acid with IC50 values of 3.7 nM and 90 nM, respectively. Phosphorylase was simultaneously activated by these inhibitors with calyculin A again being more active (P < 0.001) than okadaic acid. The differing potencies (P < 0.001) of these inhibitors on the activities of glycogen synthase and phosphorylase were also observed with varying concentrations of glucose (5.6-60 mM) in the medium and at different incubation periods upto 120 min. It has been previously shown that both inhibitors inhibit protein phosphatase-2A with equal potency and calyculin A is a more potent inhibitor of protein phosphatase-1 than okadaic acid. Heat- and proteinase-treated cytosolic fractions from hepatocytes incubated with calyculin A and okadaic acid showed similar differential inhibitory activities towards purified types 1 and 2-A protein phosphatases. Hence, these data provide further evidence that protein phosphatase type-1 plays a major role in the control of glycogen synthesis by regulating the activities of glycogen synthase and phosphorylase.

Membrane-associated N-myristoyltransferase activity is reduced in obese (fa/fa) Zucker rat liver.

N-Myristoyltransferase is the enzyme that catalyses the transfer of myristate from myristoyl-CoA to the NH2-terminal glycine residue of a number of protein of diverse functions. Many of the known myristoylated proteins are important in signal transduction. We have compared the activity of rat liver N-myristoyltransferase from lean and obese (fa/fa) Zucker rats (a model for non-insulin dependent diabetes mellitus, NIDDM). N-myristoyltransferase activity isolated from the particulate fraction of obese (fa/fa) Zucker rat liver was approximately 4.7-fold lower than the corresponding activity observed in either the controls or the vanadate-treated obese rat livers. This pattern was only observed in the particulate fraction; the homogenate and soluble N-myristoyltransferase activities were not significantly different to the control activities. N-myristoyltransferase activity isolated from the brain of the four groups showed no significant variations. These results, and previous work [King, M. J., Pugazhenthi, S., Khandelwal, R. L. and Sharma, R. K. (1993) Biochim. Biophys. Acta. 1165, 259-262], would indicate that the rat liver particulate N-myristoyltransferase activity appears to be inversely proportional to the level of plasma insulin, implicating insulin in the control of N-myristoylation. The specific activity of the particulate liver N-myristoyltransferase was approximately 10-fold higher than that of the soluble liver N-myristoyltransferase, raising the possibility that N-myristoyltransferase exists in 2 populations, with the active form of N-myristoyltransferase residing in the membranous fraction. This situation could provide a system whereby N-myristoylation is regulated by the translocation of N-myristoyltransferase from the cytosol to its active site in the membranes.