Prostaglandin deficiency promotes sensitization of adenylyl cyclase

Inhibition of prostaglandin synthesis by the drug indomethacin suppresses the synthesis of the cyclic AMP antagonist, prostaglandylinositol cyclic phosphate (cyclic PIP), and leads to a metabolic state comparable to type II diabetes. It was of interest whether prostaglandin-deficiency likewise causes sensitization of adenylyl cyclase, as this has been reported for the diabetic state. In liver plasma membranes of indomethacin-treated male rats, basal and forskolin-stimulated cyclic AMP synthesis remained unchanged when compared to untreated control rats. In control rats, stimulation of cyclic AMP synthesis by fluoride (2.2-fold) or glucagon (3.5-fold) was much lower than stimulation by forskolin (6.6-fold). In contrast, in indomethacin-treated rats, stimulation of cAMP synthesis by fluoride (4.6-fold) or glucagon (5.2-fold) nearly matched the stimulation by forskolin (6.4-fold). The level of alpha1-adrenergic receptors was slightly reduced, from 450 to 320 fmol/mg protein, by the indomethacin treatment. Independent of the treatment by indomethacin, stimulation of cyclic AMP synthesis by adrenaline failed, in agreement with the low density of adrenergic beta-receptors. In conclusion, PGE deficiency sensitizes adenylyl cyclase in rat liver for G protein-coupled receptors (glucagon) and also for fluoride.     

Effect of electrical stimulation of the autonomic nerves on the levels and synthesis of cyclic nucleotides in the rat salivary glands: relationship to enhanced growth.

Electrical stimulation of either the parasympathetic or the sympathetic nerve supply to the parotid and submaxillary glands increases the intracellular level of cyclic GMP and the rate of DNA synthesis and cell division while only sympathetic stimulation raises cyclic AMP levels. The periods of electrical stimulation inducing hyperplasia also raise the cyclic GMP concentration but there is no similar correlation with changes in cyclic AMP levels. However, the extent of hyperplasia induced by parasympathetic and sympathetic stimulation is not directly related to the size of the increase in cyclic GMP concentration that these treatments produce. Changes in cyclic AMP levels are reflected in altered in vitro adenylate cyclase activity. This activity is raised after 2 min sympathetic stimulation and markedly decreased with 30 min sympathetic or parasympathetic stimulation. Guanylate cyclase activity shows no such changes with nerve stimulation.     

Control of glucose balance in the perfused rat liver by the parasympathetic innervation

Electrical stimulation of the nerve bundles around the hepatic artery and the portal vein activates both the sympathetic and parasympathetic liver nerves; the sympathetic effects clearly predominate. Parasympathetic effects were therefore studied in the rat liver perfused in situ by perivascular nerve stimulation in the presence of both an alpha- and a beta-blocker. In the presence of the alpha-blocker phentolamine and the beta-blocker propranolol all sympathetic nerve effects were prevented; the remaining parasympathetic stimulation had no influence on the basal glucose and lactate metabolism nor on the hemodynamics. Insulin alone, with both alpha- and beta-blockade, provoked a small, parasympathetic nerve stimulation in the presence of insulin a more pronounced enhancement of glucose utilization. In the presence of an alpha- and beta-blocker perivascular nerve stimulation antagonized the glucagon stimulated glucose release, but did not affect lactate exchange. The nerve effect was abolished by the parasympathetic antagonist atropine. Acetylcholine or insulin, with both an alpha- and beta-blocker present, mimicked the effects of nerve stimulation antagonizing the glucagon-stimulated glucose release. Nerve stimulation in the presence of insulin was more effective than either stimulus alone. The present results show that in rat liver stimulation of the parasympathetic hepatic nerves has direct effects on glucose metabolism synergistic with insulin and antagonistic to glucagon.     

Regulation of the expression of the phosphoenolpyruvate carboxykinase gene in cultured rat hepatocytes by glucagon and insulin

The induction of phosphoenolpyruvate carboxykinase (PEPCK) by glucagon was studied in primary rat hepatocyte cultures by determining the time course of the sequential events, increases in the enzyme's mRNA abundance, synthesis rate, amount and activity, and by investigating the antagonistic action of insulin on the induction by glucagon. 1. The mRNA of PEPCK was induced maximally 2-3 h after addition of 10 nM glucagon, as detected by Northern-blot analysis after hybridization with a biotinylated antisense RNA of PEPCK. 2. The synthesis rate of PEPCK increased maximally 2-3 h after application of glucagon as revealed by pansorbin-linked immunoprecipitation of [35S]methionine-labelled PEPCK. 3. The enzyme amount and activity was maximally induced 4 h after glucagon application. 4. The mRNA of PEPCK was half-maximally induced by 0.1 nM and maximally by 1 nM and 10 nM glucagon. The half-maximal induction by 0.1 nM glucagon was antagonized almost totally, and the maximal induction by 1 nM glucagon partially, while the maximal induction by 10 nM glucagon remained unaffected by 10 nM insulin. The results show that in cultured rat hepatocytes physiological concentrations of glucagon stimulated the induction of PEPCK by an increase in mRNA, that the glucagon-dependent increase in mRNA and enzyme-synthesis rate occurred in parallel and preceded the increase of enzyme amount and activity by 1-1.5 h, and that physiological levels of insulin antagonized the induction by glucagon in the physiological concentration range, with glucagon being the dominant hormone.     

Pretranslational regulation of tyrosine aminotransferase and phosphoenolpyruvate carboxykinase (GTP) synthesis by glucagon and dexamethasone in adult rat hepatocytes.

The regulation of synthesis of the gluconeogenic cytosolic enzyme phosphoenolpyruvate carboxykinase (PEPCK) and of tyrosine aminotransferase (TAT) by glucagon and glucocorticoid hormones was studied in hepatocytes maintained in suspension culture for 7 h. Specific antibodies were used to measure relative rates of enzyme synthesis after pulse-labelling of the cells with [3H]leucine or [35S]methionine. Concomitantly, amounts of mRNA were quantified after translation in vitro in a reticulocyte lysate and specific immunoprecipitation of the proteins. Glucagon stimulated the rate of synthesis of PEPCK by 4-6-fold and that of TAT by 6-8-fold in 2h. In contrast, dexamethasone had little effect on PEPCK synthesis, whereas it increased TAT synthesis by 5-9-fold. When used in combination, the two hormones displayed additive effects on TAT synthesis, whereas the glucocorticoid hormone strongly potentiated stimulation of PEPCK synthesis by glucagon. In every instance, changes in rates of synthesis of the two enzymes were totally accounted for by increases in amounts of the corresponding functional mRNA, suggesting a pretranslational site of action for both glucagon and dexamethasone.     

Effects of hormones on the synthesis of α1 (acute-phase) glycoprotein in isolated rat hepatocytes

Hormone effects on the synthesis of alpha(1) (acute-phase) glycoprotein and of albumin by isolated rat hepatocytes in suspension were examined. Insulin, glucagon, cortisol, somatotropin (bovine growth hormone) and tri-iodothyronine were added to achieve physiological concentrations in the medium [Jeejeebhoy, Ho, Greenberg, Phillips, Bruce-Robertson & Sodtke (1975) Biochem. J.146, 141-155]. After periodic additions, there were increases (compared with values for non-hormone-treated suspensions) in the concurrent absolute syntheses of alpha(1) (acute-phase) glycoprotein and of albumin. Trends were detectable after 24h, and significant increases were demonstrated after 48h of incubation (219 and 119% respectively of control values). Manipulation of hormones, by omission from the mixture or by addition of only one or two hormones in various combinations, indicated that for alpha(1) (acute-phase) glycoprotein (which may be representative of some other acute-phase proteins), cortisol was one of the most important hormones involved in the stimulation of synthesis, with glucagon enhancing the effect of cortisol but not being stimulatory by itself. Addition of actinomycin D inhibited this stimulation, suggesting that cortisol might have acted through promotion of RNA synthesis. For albumin, cortisol alone did not stimulate synthesis, but its absence from a hormone mixture significantly decreased synthesis compared with that observed with the complete hormone mixture. Our findings support the possibility that following tissue injury, synthesis of alpha(1) (acute-phase) glycoprotein may be stimulated by the hormonal response to this injury (which response includes elevated blood concentrations of cortisol and glucagon).     

Age-related decrease in sensitivity to glucagon and dibutyryl cyclic AMP inhibition of fatty acid synthesis in hepatocytes isolated from obese female Zucker rats

Hepatocytes were isolated from 3 and 5 month old female genetically obese Zucker rats and their lean littermate controls. An age-dependent loss in sensitivity of fatty acid synthesis to inhibition by both glucagon and dibutyryl cyclic AMP was observed with hepatocytes from the obese rats. Hepatocytes from lean animals were much more sensitive to these agents, regardless of age. Low concentrations of glucagon and dibutyryl cyclic AMP actually produced some stimulation of fatty acid synthesis with hepatocytes prepared from the older obese rats. 5-Tetradecyloxy-2-furoic acid, a compound which inhibits fatty acid synthesis, was a very effective inhibitor of fatty acid synthesis by hepatocytes isolated from all rats used in the study. An inhibition of lactate plus pyruvate accumulation and a strong stimulation of glycogenolysis occurred in response to both glucagon and dibutyryl cyclic AMP with hepatocytes from both age groups of lean and obese rats. The results suggest that with aging of the obese female Zucker rat some step of hepatic fatty acid synthesis becomes progressively less sensitive to inhibition by glucagon and dibutyryl cyclic AMP. This may play an important role in maintenance of obesity in these animals.     

Bidirectional concentration-dependent effects of glucagon and dibutyryl cyclic AMP on DNA synthesis in cultured adult rat hepatocytes

Glucagon and dibutyryl cyclic AMP exerted both stimulatory and inhibitory effects on hepatocyte DNA synthesis when added to primary monolayer cultures in the presence of serum, dexamethasone, insulin and epidermal growth factor. The stimulation occurred at low concentrations of glucagon (1 pM-1 nM) or dibutyryl cyclic AMP (1 nM-1 microM), while the agents inhibited DNA synthesis at higher concentrations (usually glucagon at over 10 nM or dibutyryl cyclic AMP at over 10 microM). The stimulatory effect was stronger at low cell densities (less than 20 X 10(3) hepatocytes/cm2). When the hepatocytes were cultured at higher densities, stimulatory effects were reduced or absent and the inhibition of (hormone-induced) DNA synthesis by a high concentration of glucagon was much more pronounced than at low cell densities. These results indicate dual, bidirectional, effects of cyclic AMP on hepatocyte DNA synthesis.     

Phosphoenolpyruvate carboxykinase and glucose-6-phosphate dehydrogenase expression in fetal hepatocyte primary cultures under proliferative conditions

Fetal hepatocytes cultured for 64 h in the presence of glucagon and dexamethasone maintain a quiescent state, showing a low expression of glucose-6-phosphate dehydrogenase (G6PD) and a high induction of phosphoenolpyruvate carboxykinase (PEPCK). Under these culture conditions, the presence of EGF produced hepatocyte proliferation, with a concomitant increase of DNA synthesis, DNA content, and G6PD expression, meanwhile the expression of PEPCK was drastically reduced. The presence of forskolin plus IBMX nearly suppressed the increase in DNA synthesis and G6PD expression induced by EGF, showing a very high expression of PEPCK. Accordingly, it is possible to establish an inverse relation between G6PD, highly expressed in proliferating fetal hepatocytes, and PEPCK expression, highly expressed in quiescent fetal hepatocytes under specific hormonal stimulation.     

The nervous control of rat glucagon secretion in vivo

In order to study the efferent pathways of the nervous regulation of rat A and B cells, portal blood samples were obtained in vivo without interruption of the blood flow. Glucagon, insulin and catecholamines were determined and hepatic blood flow (EHBF) was estimated by a Brome-Sulfone-Phtaleine extraction method. Carotid blood pressure was monitored and a normal volaemia was maintained. Stimulation of the right vagus nerve increased EHBF and the releases of glucagon and insulin. Stimulation of splanchnic nerve increased the glucagon and catecholamine secretions and decreased that of insulin. Acute hypovolaemia as induced by blood withdrawal, caused hormonal consequences similar to those of splanchnic stimulation. It is suggested that the nervous control of pancreatic islets plays an important role in the rat species. Assessment of the haemodynamic status is critical for the valid interpretation of pancreatic hormone concentrations in experimental conditions. A sympathetic stimulation can account for the high glucagon and relatively low insulin secretions which characterize the hormonal pattern of stress.     

Effects of hypo- or hyperosmotic stress on lipid synthesis and gluconeogenic activity in tissues of the crab Neohelice granulata

The present study assesses the effects of osmotic stress on phosphoenolpyruvate carboxykinase (PEPCK), fructose 1,6-bisphosphatase (FBPase) and glucose 6-phosphatase (G6Pase) activities and (14)C-total lipid synthesis from (14)C-glycine in the anterior and posterior gills, jaw muscle, and hepatopancreas of Neohelice granulata. In posterior gills, 24-h exposure to hyperosmotic stress increased PEPCK, FBPase and G6Pase activities. Increase in (14)C-lipid synthesis was associated to the decrease in PEPCK activity after 72-h exposure to hyperosmotic stress. Hypo-osmotic stress decreased PEPCK and G6Pase activities in posterior gills; however, (14)C-lipids increased after 72-h exposure to stress. In anterior gills, decreases in the G6Pase activity after 72-h of hyperosmotic stress and in (14)C-lipogenesis after 144-h were observed, while PEPCK activity increased after 144 h. Exposure to hypo-osmotic stress increased (14)C-lipid synthesis and PEPCK activity in anterior gills. Muscle G6Pase activity increased after 72-h exposure to hypo-osmotic stress; however, no significant change was observed in the lipogenesis. PEPCK decreased in muscle after 144-h exposure to hyperosmotic, coinciding with increased (14)C-lipid synthesis. In the hepatopancreas, a decrease in the (14)C-lipogenesis occurred after 24-h exposure to hyperosmotic stress, accompanied by increase in (14)C-lipid synthesis. Additionally, PEPCK activity returned to control levels. The hepatopancreatic lipogenesis from amino acids was not involved in the metabolic adjustment during hypo-osmotic stress. However, gluconeogenesis is one of the pathways involved in the adjustment of the intracellular concentration of nitrogenated compounds.     

Uncoupling of the Glucagon Receptor-Adenylate Cyclase System by Glucagon in Cloned Differentiated Rat Hepatocytes

Abstract

The ability of glucagon to induce a state of desens it ization to glucagon responsiveness has been examined in a cloned line of normal, differentiated, diploid rat hepatocytes (RL-PR-C). These cells, which respond to glucagon with increased production of cyclic AMP, become refractory to further stimulation of cyclic AMP synthesis following a 4 hour exposure period of the cells to the hormone. Refractoriness to glucagon was demonstrated over a wide range of hormone concentrations (10^?12 to 10^?6 M). In desensitized cells that were subsequently washed free of the hormone, recovery from refractoriness was complete by 20 hours. The mechanism underlying this desensitization does not appear to involve decreased receptor numbers, increased efflux of cyclic AMP from the cells, increased degradation of cyclic AMP by phosphodtesterase, or an alteration in the catalytic unit of the adenylate cyclase enzyme system. By elimination, the diminished cellular cyclic AMP responsiveness to glucagon in normal RL-PR-C hepatocytes may involve a reversible uncoupling of glucagon receptors from adenylate cyclase. In addition, late passage, spontaneously transformed RL-PR-C hepatocytes were found to exist in a state in which glucagon receptors are permanently uncoupled from adenylate cyclase.     

Glucose uptake during centrally induced stress is insulin independent and enhanced by adrenergic blockade.

Glucose utilization increases markedly in the normal dog during stress induced by the intracerebroventricular (ICV) injection of carbachol. To determine the extent to which insulin, glucagon, and selective (alpha/beta)-adrenergic activation mediate the increment in glucose metabolic clearance rate (MCR) and glucose production (R(a)), we used five groups of normal mongrel dogs: 1) pancreatic clamp (PC; n = 7) with peripheral somatostatin (0.8 microg x kg(-1) x min(-1)) and intraportal replacement of insulin (1,482 +/- 84 pmol x kg(-1) x min(-1)) and glucagon (0.65 ng x kg(-1) x min(-1)) infusions; 2) PC plus combined alpha (phentolamine)- and beta (propranolol)-blockade (7 and 5 microg x kg(-1) x min(-1), respectively; alpha+beta; n = 5); 3) PC plus alpha-blockade (alpha; n = 6); 4) PC plus beta-blockade (beta; n = 5); and 5) a carbachol control group without PC (Con; n = 10). During ICV carbachol stress (0-120 min), catecholamines, ACTH, and cortisol increased in all groups. Baseline insulin and glucagon levels were maintained in all groups except Con, where glucagon rose 33%, and alpha, where insulin increased slightly but significantly. Stress increased (P < 0.05) plasma glucose in Con, PC, and alpha but decreased it in beta and alpha+beta. The MCR increment was greater (P < 0.05) in beta and alpha+beta than in Con, PC, and alpha. R(a) increased (P < 0.05) in all groups but was attenuated in alpha+beta. Stress-induced lipolysis was abolished in beta (P < 0.05). The marked rise in lactate in Con, PC, and alpha was abolished in alpha+beta and beta. We conclude that the stress-induced increase in MCR is largely independent of changes in insulin, markedly augmented by beta-blockade, and related, at least in part, to inhibition of lipolysis and glycogenolysis, and that R(a) is augmented by glucagon and alpha- and beta-catecholamine effects.     

Effect of glucagon administration on mice liver fructose-1, 6-bisphosphatase.

Intravenous administration of glucagon in mouse (200 μg/100 gm body wt), stimulated liver fructose-1,6-bisphosphatase at physiological pH by approximately 100% within 15 minutes. The stimulation was not due to protein synthesis. Similar stimulation was also observed on administration of cyclic AMP. Removal of the adrenal gland abolished the stimulatory effect of glucagon but not of cyclic AMP.     

Endocrine stress response in jugular-vein cannulated rats upon multiple exposure to either diethyl-ether, halothane/O2/N2O or sham anaesthesia

The main objective of this study was to assess the endocrine stress response to multiple anaesthesia followed by sham anaesthesia in order to detect any memory effects. For this purpose, jugular-vein cannulated rats were subjected to either sham, diethyl-ether or halothane/O2/N2O anaesthesia, and their plasma ACTH, corticosterone, glucose, adrenaline and noradrenaline levels measured. The study had three separate experiments, each consisting of a control and treatment group. In two experiments, the rats were exposed to high or low concentrations (40-15%) of diethyl ether, using either a jar containing cotton soaked in diethyl ether or a vaporizer. In the third experiment, rats were exposed to halothane/O2/N2O. Control animals underwent sham anaesthesia. Blood samples were taken 6 min before and at 5, 15 and 55 min after starting the exposure (t = 0 min). For each variable, the dt5 (level at t = 5 min minus that at t = -6 min) and the cumulative levels over the one-hour period as determined by the area under the curve (AUC) were calculated. Further, the peak levels (Cmax) were determined. The mean time needed to induce anaesthesia was 68, 121 and 55 s for exposure to high and low concentrations of diethyl ether and to halothane/O2/N2O, respectively. Increased noradrenaline and adrenaline dt5 levels were observed only after the first exposure to the high concentration of diethyl ether. Multiple anaesthesia sessions using either diethyl ether or halothane/O2/N2O did not clearly influence adrenaline and noradrenaline levels. Diethyl ether induced a sharp rise in plasma ACTH and glucose levels, irrespective of the concentration used. The response of the ACTH and glucose was similar for single and multiple exposure. An increased response of ACTH, corticosterone and glucose to sham anaesthesia following multiple induction of anaesthesia was observed for the high concentration of diethyl ether only. Halothane/O2/N2O raised plasma glucose without differences between single and multiple anaesthesia sessions. Upon sham anaesthesia following multiple exposures to halothane/O2/N2O, glucose levels were significantly increased. This study indicates that repeated anaesthesia in rats can elicit an increased stress response during subsequent handling and change of environment.     

Impaired glucagon response to sympathetic nerve stimulation in the BB diabetic rat: effect of early sympathetic islet neuropathy

We investigated the functional impact of a recently described islet-specific loss of sympathetic nerves that occurs soon after the autoimmune destruction of beta-cells in the BB diabetic rat (35). We found that the portal venous (PV) glucagon response to sympathetic nerve stimulation (SNS) was markedly impaired in newly diabetic BB rats (BB D). We next found a normal glucagon response to intravenous epinephrine in BB D, eliminating the possibility of a generalized secretory defect of the BB D alpha-cell as the mediator of the impaired glucagon response to SNS. We then sought to determine whether the glucagon impairment to SNS in BB D was due solely to their loss of islet sympathetic nerve terminals or whether other effects of autoimmune diabetes contributed. We therefore reproduced, in nondiabetic Wistar rats, an islet nerve terminal loss similar to that in BB D with systemic administration of the sympathetic neurotoxin 6-hydroxydopamine. The impairment of the glucagon response to SNS in these chemically denervated, nondiabetic rats was similar to that in the spontaneously denervated BB D. We conclude that the early sympathetic islet neuropathy of BB D causes a functional defect of the sympathetic pathway to the alpha-cell that can, by itself, account for the impaired glucagon response to postganglionic SNS.     

Regulation of phosphoenolpyruvate carboxykinase (GTP) synthesis in rat liver cells. Rapid induction of specific mRNA by glucagon or cyclic AMP and permissive effect of dexamethasone

Isolated rat liver cells maintained in suspension culture for 4 to 5 h synthesize the gluconeogenic cytosolic enzyme phosphoenolpyruvate carboxykinase at a rate approximately 5-fold lower than the in vivo hepatic rate. Glucagon rapidly re-induces phosphoenolpyruvate carboxykinase synthesis in such cells. The rate of enzyme synthesis doubles in 40 min and plateaus at a level 6- to 13-fold higher than in control cells 120 min after glucagon addition at maximal concentration. Consistent with the presumed role of cyclic AMP as a mediator of enzyme induction, the phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine, added simultaneously with glucagon, shifts the hormone dose-response curve 2 log units to the left. Moreover, cyclic AMP supplied exogenously to the cells mimics the inductive effect of glucagon. Total cellular RNA isolated from hepatocytes induced by glucagon contains an increased level of mRNA coding for phosphoenolpyruvate carboxykinase, as determined by translational assay. The kinetics and extent of the rise in mRNA level are adequate to explain the stimulation of enzyme synthesis. Although glucagon on its own induces a build-up of phosphoenolpyruvate carboxykinase mRNA and a commensurate stimulation of enzyme synthesis, the glucagon induction is very markedly amplified when the cells are first preincubated with dexamethasone. The glucocorticoid by itself, however, does not have any substantial effect on the level of phosphoenolpyruvate carboxykinase mRNA or on the rate of enzyme synthesis. Its role can therefore be characterized as permissive.     

Evaluation of topical phenol as a means of producing autonomic denervation of the liver

Topical application of 90% phenol around the bile duct, portal vein, and hepatic artery, as well as along each of the three hepatic ligaments was tested for effectiveness of rapid and chronic denervation in cats. Because phenol produces nonselective nerve degeneration, it was assumed that proof of functional sympathectomy was adequate proof of disruption of parasympathetic and afferent nerves as well. Functional sympathetic neurons were evaluated by measuring physiological responses to direct electrical stimulation of the anterior hepatic plexus. Acute or rapid denervation was assessed by the degree of rise in portal blood pressure produced by nerve stimulation. Complete denervation appeared within 20 min and was still present by 80 min postapplication. Chronic denervation was tested by applying the phenol and recovering the cats for 6-14 days. An equal number (n = 6) of sham-denervated cats were compared. Phenol denervation did not alter basal glucose, insulin or glucagon levels, hematocrit, blood pressure, or hepatic glycogen levels. These variables are a good index of stress and metabolic status. Nerve stimulation in the chronic sham group raised portal pressure, arterial pressure, and blood glucose levels, whereas the chronic-denervated group showed no responses. The health of the two groups appeared normal with the sole difference being that the painted tissues were mildly discolored and more adhesions appeared in the phenol-denervated set. Thus phenol is a useful tool for producing hepatic denervation. It is less traumatic, faster, and more certain than surgical denervation. In addition, the hepatic lymphatics can be preserved using the topical application of phenol.     

Regulation by insulin of gluconeogenesis in isolated rat hepatocytes.

Insulin (10nM) completely suppressed the stimulation of gluconeogenesis from 2 mM lactate by low concentrations of glucagon (less than or equal to 0.1 nM) or cyclic AMP (less than or equal to 10 muM), but it had no effect on the basal rate of gluconeogenesis in hepatocyctes from fed rats. The effectiveness of insulin diminished as the concentration of these agonists increased, but insulin was able to suppress by 40% the stimulation by a maximally effective concentration of epinephrine (1 muM). The response to glucagon, epinephrine, or insulin was not dependent upon protein synthesis as cycloheximide did not alter their effects. Insulin also suppressed the stimulation by isoproterenol of cyclic GMP. These data are the first demonstration of insulin antagonism to the stimulation of gluconeogenesis by catecholamines. Insulin reduced cyclic AMP levels which had been elevated by low concentrations of glucagon or by 1 muM epinephrine. This supports the hypothesis that the action of insulin to inhibit gluconeogenesis is mediated by the lowering of cyclic AMP levels. However, evidence is presented which indicates that insulin is able to suppress the stimulation of gluconeogenesis by glucagon or epinephrine under conditions where either the agonists or insulin had no measurable effect on cyclic AMP levels. Insulin reduced the glucagon stimulation of gluconeogenesis whether or not extracellular Ca2+ were present, even though insulin only lowered cyclic AMP levels in their presence. Insulin also reduced the stimulation by epinephrine plus propranolol where no significant changes in cyclic AMP were observed without or with insulin. In addition, insulin suppressed gluconeogenesis in cells that had been preincubated with epinephrine for 20 min, even though the cyclic AMP levels had returned to near basal values and were unaffected by insulin. Thus insulin may not need to lower cyclic AMP levels in order to suppress gluconeogenesis.