Studies on the alpha-adrenergic activation of hepatic glucose output. I. Studies on the alpha-adrenergic activation of phosphorylase and gluconeogenesis and inactivation of glycogen synthase in isolated rat liver parenchymal cells.

Epinephrine and the alpha-adrenergic agonist phenylephrine activated phosphorylase, glycogenolysis, and gluconeogenesis from lactate in a dose-dependent manner in isolated rat liver parenchymal cells. The half-maximally active dose of epinephrine was 10-7 M and of phenylephrine was 10(-6) M. These effects were blocked by alpha-adrenergic antagonists including phenoxybenzamine, but were largely unaffected by beta-adrenergic antagonists including propranolol. Epinephrine caused a transient 2-fold elevation of adenosine 3':5'-monophosphate (cAMP) which was abolished by propranolol and other beta blockers, but was unaffected by phenoxybenzamine and other alpha blockers. Phenoxybenzamine and propranolol were shown to be specific for their respective adrenergic receptors and to not affect the actions of glucagon or exogenous cAMP. Neither epinephrine (10-7 M), phenylephrine (10-5 M), nor glucagon (10-7 M) inactivated glycogen synthase in liver cells from fed rats. When the glycogen synthase activity ratio (-glucose 6-phosphate/+ glucose 6-phosphate) was increased from 0.09 to 0.66 by preincubation of such cells with 40 mM glucose, these agents substantially inactivated the enzyme. Incubation of hepatocytes from fed rats resulted in glycogen depletion which was correlated with an increase in the glycogen synthase activity ratio and a decrease in phosphorylase alpha activity. In hepatocytes from fasted animals, the glycogen synthase activity ratio was 0.32 +/- 0.03, and epinephrine, glucagon, and phenylephrine were able to lower this significantly. The effects of epinephrine and phenylephrine on the enzyme were blocked by phenoxybenzamine, but were largely unaffected by propranolol. Maximal phosphorylase activation in hepatocytes from fasted rats incubated with 10(-5) M phenylephrine preceded the maximal inactivation of glycogen synthase. Addition of glucose rapidly reduced, in a dose-dependent manner, both basal and phenylephrine-elevated phosphorylase alpha activity in hepatocytes prepared from fasted rats. Glucose also increased the glycogen synthase activity ratio, but this effect lagged behind the change in phosphorylase. Phenylephrine (10-5 M) and glucagon (5 x 10(-10) M) decreased by one-half the fall in phosphoryalse alpha activity seen with 10 mM glucose and markedly suppressed the elevation of glycogen synthase activity. The following conclusions are drawn from these findings. (a) The effects of epinephrine and phenylephrine on carbohydrate metabolism in rat liver parenchymal cells are mediated predominantly by alpha-adrenergic receptors. (b) Stimulation of these receptors by epinephrine or phenylephrine results in activation of phosphorylase and gluconeogenesis and inactivation of glycogen synthase by mechanisms not involving an increase in cellular cAMP. (c) Activation of beta-adrenergic receptors by epinephrine leads to the accumulation of cAMP, but this is associated with minimal activation of phosphorylase or inactivation of glycogen synthase...     

Effects of catecholamines and glucagon on glycogen metabolism in human polymorphonuclear leukocytes.

Addition of 10 micron of the alpha-adrenergic agonist phenylephrine to polymorphonuclear leukocytes suspended in glucose-free Krebs-Ringer bicarbonate buffer (pH 6.7) activated phosphorylase, inactivated glycogen synthase R maximally within 30 s, and resulted in glycogen breakdown. Phenylephrine increased 45Ca efflux relative to control of 45Ca prelabelled cells, but did not affect cyclic adenosine 3',5'-monophosphate (cAMP) concentration. The effects of phenylephrine were blocked by 20 micron phentolamine and were absent in cells incubated at pH 7.4. The same unexplained dependency of extracellular pH was observed with 2.5 nM--2.5 micron glucagon, which activated phosphorylase and inactivated synthase-R, but in addition caused a 30-s burst in cAMP formation. 25 nM glucagon also increased 45Ca efflux. The activation of phosphorylase by phenylephrine and possibly also by glucagon are thought mediated by an increased concentration of cytosolic Ca2+ activating phosphorylase kinase. The effects of 5 micron isoproterenol or 5 micron epinephrine were independent of extracellular pH 6.7 and 7.4 and resulted in a sustained increase in cAMP, an activation of phosphorylase and inactivation of synthase-R within 15 s, and in glycogenolysis. The effects of both compounds were blocked by 10 micron propranolol, whereas 10 micron phentolamine had no effect on the epinephrine action. The efflux of 45Ca was not affected by either isoproterenol or epinephrine. The beta-adrenergic activation of phosphorylase is consistent with the assumption of a covalent modification of phosphorylase kinase by the cAMP dependent protein kinase. Phosphorylation of synthase-R to synthase-D can thus occur independently of increase in cAMP, but the evidence is inconclusive with respect to the cAMP dependent protein kinase also being active in this phosphorylation.     

Studies on the alpha-andrenergic activation of hepatic glucose output. II. Investigation of the roles of adenosine 3':5'-monophosphate and adenosine 3':5'-monophosphate-dependent protein kinase in the actions of phenylephrine in isolated hepatocytes.

The effects of the alpha-adrenergic agonist phenylephrine on the levels of adenosine 3':5'-monophosphate (cAMP) and the activity of the cAMP-dependent protein kinase in isolated rat liver parenchymal cells were studied. Cyclic AMP was very slightly (5 to 13%) increased in cells incubated with phenylephrine at a concentration (10(-5) M) which was maximally effective on glycogenolysis and gluconeogenesis. However, the increase was significant only at 5 min. Cyclic AMP levels with 10(-5) M phenylephrine measured at this time were reduced by the beta-adrenergic antagonist propranolol, but were unaffected by the alpha-blocker phenoxybenzamine, indicating that the elevation was due to weak beta activity of the agonist. When doses of glucagon, epinephrine, and phenylephrine which produced the same stimulation of glycogenolysis or gluconeogenesis were added to the same batches of cells, there were marked rises in cAMP with glucagon, minimal increases with epinephrine, and little or no changes with phenylephrine, indicating that the two catecholamine stimulated these processes largely by mechanisms not involving cAMP accumulation. DEAE-cellulose chromatography of homogenates of liver cells revealed two major peaks of cAMP-dependent protein kinase activity. These eluted at similar salt concentrations as the type I and II isozymes from rat heart. Optimal conditions for preservation of hormone effects on the activity of the enzyme in the cells were determined. High concentrations of phenylephrine (10(-5) M and 10(-4) M) produced a small increase (10 tp 16%) in the activity ratio (-cAMP/+cAMP) of the enzyme. This was abolished by propranolol, but not by phenoxybenzamine, indicating that it was due to weak beta activity of the agonist. The increase in the activity ratio of the kinase with 10(-5) M phenylephrine was much smaller than that produced by a glycogenolytically equivalent dose of glucagon. The changes in protein kinase induced by phenylephrine and the blockers and by glucagon were thus consistent with those in cAMP. Theophylline and 1-methyl-3-isobutylxanthine, which inhibit cAMP phosphodiesterase, potentiated the effects of phenylephrine on glycogenolysis and gluconeogenesis. The potentiations were blocked by phenoxybenzamine, but not by propranolol. Methylisobutylxanthine increased the levels of cAMP and enhanced the activation of protein kinase in cells incubated with phenylephrine. These effects were diminished or abolished by propanolol, but were unaffected by phenoxybenzamine. It is concluded from these data that alpha-adrenergic activation of glycogenolysis and gluconeogenesis in isolated rat liver parenchymal cells occurs by mechanisms not involving an increase in total cellular cAMP or activation of the cAMP-dependent protein kinase. The results also show that phosphodiesterase inhibitors potentiate alpha-adrenergic actions in hepatocytes mainly by a mechanism(s) not involving a rise in cAMP.     

Ca2+, K+ redistributions and alpha-adrenergic activation of glycogenolysis in perfused rat livers

1. The alpha-adrenergic activation of glycogenolysis was investigated in isolated rat livers perfused in a non-recirculating system. Net uptake and/or release of Ca2+, K+ and H+ by the liver (measured by ion-selective electrodes) were correlated with the glycogenolytic effects of phenylephrine. Uptake and retention of 45Ca by the mitochondria of perfused livers were studied to obtain information on the role played by exchangeable mitochondrial calcium in alpha-adrenergic activation of glycogenolysis. 2. Between 1 and 5 min after starting the addition of phenylephrine a net release of Ca2+ was observed, this was paralleled by an uptake of K+. Production rates of glucose and lactate from endogenous glycogen started to increase at the same time. During the following minutes K+ was released. 2 mM EGTA and a high concentration of Mg2+ strongly diminished the ionic and metabolic responses to phenylephrine, 0.2 mM EGTA was less effective. 3. High concentrations of K+ prevented the metabolic response to phenylephrine but had no effect on the release of Ca2+ into the extracellular medium. Tetracaine activated glycogenolysis and suppressed all the effects of the alpha-adrenergic agonist. 4. Experiments with 45Ca provided no evidence for an alpha-adrenergic release of Ca2+ from the exchangeable mitochondrial pool. Incorporation of 45Ca into the mitochondria of perfused livers was enhanced by phenylephrine. 5. We propose that the alpha-adrenergic release of Ca2+ from a pool located close to the surface of the cell is capable of triggering the glycogenolytic response.     

Role of calcium in the phenylephrine-induced activation of phosphorylase "A" in isolated liver cells

The ability of phenylephrine to activate phosphorylase in liver cells with variable degrees of Ca2+ loading was studied. Phenylephrine has been found to be capable of stimulating phosphorylase at saturating Ca2+ concentrations that precluded any further action of this ion. Furthermore the degree of activation was proportional to the cellular calcium content. These results allow to conclude that alpha-adrenergic agonists activate phosphorylase by a mechanism apparently unrelated to their ability to mobilize and subsequently increase the cytosolic concentration of free Ca2+.     

Effects of adrenalectomy on hormone action on hepatic glucose metabolism. Impaired glucagon activation of glycogen phosphorylase in hepatocytes from adrenalectomized rats.

The effects of adrenalectomy on glucagon activation of liver glycogen phosphorylase and glycogenolysis were studied in isolated hepatocytes. Adrenalectomy resulted in reduced responsiveness of glycogenolysis and phosphorylase to glucagon activation. Stimulation of cAMP accumulation and cAMP-dependent protein kinase activity by glucagon was unaltered in cells from adrenalectomized rats. Adrenalectomy did not alter the proportion of type I and type II protein kinase isozymes in liver, whereas this was changed by fasting. Activation of phosphorylase kinase by glucagon was reduced in hepatocytes from adrenalectomized rats, although the half-maximal effective concentration of glucagon was unchanged. No difference in phosphorylase phosphatase activity between liver cells from control and adrenalectomized rats was detected. Glucagon-activated phosphorylase declined rapidly in hepatocytes from adrenalectomized rats, whereas the time course of cAMP increase in response to glucagon was normal. Addition of glucose (15 mM) rapidly inactivated glucagon-stimulated phosphorylase in both adrenalectomized and control rat hepatocytes. The inactivation by glucose was reversed by increasing glucagon concentration in cells from control rats, but was accelerated in cells from adrenalectomized rats. It is concluded that impaired activation of phosphorylase kinase contributes to the reduced glucagon stimulation of hepatic glycogenolysis in adrenalectomized rats. The possible role of changes in phosphorylase phosphatase is discussed.     

Mechanisms involved in alpha-adrenergic effects of catecholamines on liver metabolism.

Recent results have indicated that alpha-adrenergic receptors are the major mediators of catecholamine actions on liver metabolism in several species. It is well-established that cAMP and cAMP-dependent protein kinase are not involved in hepatic alpha-adrenergic effects. This review presents evidence that alpha-adrenergic stimulation of glycogenolysis in rat liver involves the mobilization of Ca2+ ions from mitochondria and stimulation of phosphorylase kinase by the resulting increase in cytosolic Ca2+ concentration. Possible mechanisms by which activation of alpha-adrenergic receptors causes release of mitochondrial Ca2+ and affects other cell processes are discussed.     

On the role of intra-adrenal unesterified cholesterol in the steroidegenic effect of corticotropin

Addition of 10 μM of the α-adrenergic agonist phenylephrine to polymorphonuclear leukocytes suspended in glucose-free Krebs-Ringer bicarbonate buffer (pH 6.7) activated phosphorylase, inactivated glycogen synthase R maximally within 30 s, and resulted in glycogen breakdown. Phenylephrine increased ⁴⁵Ca efflux relative to control of ⁴⁵Ca prelabelled cells, but did not affect cyclic adenosine 3′,5′-monophosphate (cAMP) concentration. The effects of phenylephrine were blocked by 20 μM phentolamine and were absent in cells incubated at pH 7.4.The same unexplained dependency of extracellular pH was observed with 2.5 nM–2.5 μM glucagon, which activated phosphorylase and inactivated synthase-R, but in addition caused a 30-s burst in cAMP formation. 25 nM glucagon also increased ⁴⁵Ca efflux. The activation of phosphorylase by phenylephrine and possibly also by glucagon are thought mediated by an increased concentration of cytosolic Ca²⁺ activating phosphorylase kinase.The effects of 5 μM isoproterenol or 5 μM epinephrine were independent of extracellular pH 6.7 and 7.4 and resulted in a sustained increase in cAMP, an activation of phosphorylase and inactivation of synthase-R within 15 s, and in glycogenolysis. The effects of both compounds were blocked by 10 μM propranolol, whereas 10 μM phentolamine had no effect on the epinephrine action. The efflux of ⁴⁵Ca was not affected by either isoproterenol or epinephrine. The β-adrenergic activation of phosphorylase is consistent with the assumption of a covalent modification of phosphorylase kinase by the cAMP dependent protein kinase.Phosphorylation of synthase-R to synthase-D can thus occur independently of increase in cAMP, but the evidence is inconclusive with respect to the cAMP-dependent protein kinase also being active in this phosphorylation.     

Hormonal and ionic control of the glycogenolytic cascade in rat liver.

1. A parallel dose-dependent activation of histone kinase, phosphorylase kinase and phosphorylase was observed in isolated hepatocytes incubated in the presence of glucagon; the effect of suboptimal concentrations of glucagon was antagonized by insulin. 2. An activation of phosphorylase which was not accompanied by a stable change in the activity of phosphorylase kinase was observed in hepatocytes incubated with phenylephrine, isoproterenol or vasopressin as well as on decapitation of unanesthetized animals. A dissociation of the two enzymic activities was also observed in hepatocytes incubated in the presence of a high concentration of glucose, in which phosphorylase was strongly inactivated with no change in the activity of phosphorylase kinase. 3. The activation of phosphorylase by phenylephrine in isolated hepatocytes was counteracted by insulin, greatly decreased by the absence of Ca2+ from the incubation medium, and completely suppressed by the replacement of Na+ by K+. 4. In a liver extract, phosphorylase kinase could also be activated by trypsin. Control, glucagon-activated or trypsin-activated phosphorylase kinase was inhibited by about 70% by EGTA and the activity was restored by the addition of Ca2+. 5. The mechanisms that control the activity of phosphorylase kinase and of phosphorylase are discussed.     

Studies of the interaction between glucagon and alpha-adrenergic agonists in the control of hepatic glucose output

alpha-Adrenergic stimulation of hepatocytes prevented, in a dose-dependent manner, the stimulation of [U-14C]lactate conversion to [14C]glucose by glucagon and exogenously added cAMP and Bt2cAMP. The inhibition was referable to an interaction with adrenergic receptors which resulted in a small decrease in hepatic cAMP levels. Low concentrations of epinephrine (10 nM) were able to inhibit phosphorylase activation and glucose output elicited by low doses of glucagon (5 X 10(-11) M to 2 X 10(-10) M). The ability of epinephrine (acting via alpha 1-adrenergic receptors), vasopressin, and angiotensin II to elicit calcium efflux was inhibited by glucagon, suggesting that intracellular redistributions of Ca2+ are importantly involved in the gluconeogenic process. It is proposed that vasopressin, angiotensin II, and catecholamines, acting primarily via alpha 1-adrenergic receptors, are responsible for inhibition of glucagon mediated stimulation of gluconeogenesis by altering subcellular calcium redistribution and decreasing cAMP levels.     

On the role of calcium as second messenger in liver for the hormonally induced activation of glycogen phosphorylase.

We have studied the mode of action of three hormones (angiotensin, vasopressin and phenylephrine, an alpha-adrenergic agent) which promote liver glycogenolysis in a cyclic AMP-independent way, in comparison with that of glucagon, which is known to act essentially via cyclic AMP. The following observations were made using isolated rat hepatocytes: (a) In the normal Krebs-Henseleit bicarbonate medium, the hormones activated glycogen phosphorylase (EC 2.4.1.1) to about the same degree. In contrast to glucagon, the cyclic AMP-independent hormones did not activate either protein kinase (EC 2.7.1.37) or phosphorylase b kinase (EC 2.7.1.38). (b) The absence of Ca2+ from the incubation medium prevented the activation of glycogen phosphorylase by the cyclic AMP-independent agents and slowed down that induced by glucagon. (c) The ionophore A 23187 produced the same degree of activation of glycogen phosphorylase, provided that Ca2+ was present in the incubation medium. (d) Glucagon, cyclic AMP and three cyclic AMP-dependent hormones caused an enhanced uptake of 45Ca; it was verified that concentrations of angiotensin and of vasopressin known to occur in haemorrhagic conditions were able to produce phosphorylase activation and stimulate 45Ca uptake. (e) Appropriate antagonists (i.e. phentolamine against phenylephrine and an angiotensin analogue against angiotensin) prevented both the enhanced 45Ca uptake and the phosphorylase activation. We interpret our data in favour of a role of calcium (1) as the second messenger in liver for the three cyclic AMP-independent glycogenolytic hormones and (2) as an additional messenger for glucagon which, via cyclic AMP, will make calcium available to the cytoplasm either from extracellular or from intracellular pools. The target enzyme for Ca2+ is most probably phosphorylase b kinase.     

Regulation of hepatic glycogenolysis by glucagon in male and female rats. Role of cAMP and Ca2+ and interactions between epinephrine and glucagon

The effects of 10(-10) to 10(-7) M glucagon on cAMP, phosphorylase a, cell calcium, and glucose production, and glucagon interactions with epinephrine were studied in isolated hepatocytes from adult male and female rats. At physiological concentrations (10(-10) - 10(-9) M), glucagon activated phosphorylase by increasing cAMP and not by raising the cytosolic free calcium. At supra-physiologic concentrations (and in the male only), glucagon slightly increased the cytosolic free calcium, the fractional efflux of calcium, and, after 2 h, decreased the cell calcium content. Exposure of hepatocytes to the simultaneous administration of 10(-9) M glucagon and 10(-7) M epinephrine resulted in a prolongation of the activation of phosphorylase a and a greater release of glucose from glycogen stores than exposure to either agonist alone. In the male, the effects of low concentrations of the two hormones on phosphorylase a activity were additive. Cytosolic free calcium was increased by 10(-6) M epinephrine from 280 to 500 nM while physiological concentrations of glucagon did not change it. In these intact cells, there was no evidence of an alpha 2-adrenergic inhibition of adenyl cyclase and no indication that cAMP depresses the rise in cell calcium induced by alpha-adrenergic stimuli.     

A hypersensitivity of glycogen phosphorylase activation in hearts of diabetic rats

This study was initiated to determine whether glycogen phosphorylase activation was defective in hearts of alloxan diabetic rats. When hearts were perfused by gravity flow for 1 to 10 min with various concentrations of epinephrine, activation of glycogen phosphorylase in the diabetic was significantly greater at every time and epinephrine concentration than that seen in the normal. Cyclic AMP accumulation and protein kinase activation by epinephrine in the diabetic were not appreciably different or were lower than the normal responses to the hormone. The effects of epinephrine on cAMP and protein kinase were blocked in both normal and diabetic hearts by propranolol. While the beta blocker prevented phosphorylase activation in the normal hearts, it did not block phosphorylase activation by epinephrine in the diabetic hearts. Likewise, the alpha agonist phenylephrine activated phosphorylase in the diabetic but not in the normal hearts. While glucagon produced the same phosphorylase hypersensitivity in diabetic hearts, the cAMP and protein kinase responses were not altered by diabetes. Phosphorylase phosphatase activity was found to be unaltered by either epinephrine or diabetes, whereas phosphorylase kinase activation by epinephrine in the diabetic was double the normal response. These data are consistent with a diabetes-related unmasking of an alpha effect on cardiac phosphorylase activation and an unexplained increase in the sensitivity of phosphorylase kinase activation by protein kinase.     

Insulin inhibition of alpha-adrenergic actions in liver.

The effects of insulin on alpha-agonist (phenylephrine)- and [Arg8]vasopressin-induced Ca2+ and glucose release and mitochondrial Ca2+ fluxes in isolated perfused rat livers were examined. Insulin (6 nM) inhibited the ability of phenylephrine (1 and 0.5 microM) to elicit Ca2+ and glucose release, whereas it was without effect on vasopressin (10 and 2.5 nM) actions. Correspondingly, insulin inhibited the action of phenylephrine to induce a stable increase in mitochondrial Ca2+ uptake, but it did not affect the alteration caused by vasopressin. Phenylephrine and vasopressin caused transient increases in hepatocyte respiration. Insulin inhibited the effect of phenylephrine on this parameter, but not that of vasopressin. Insulin added alone did not alter any of the above parameters. It is concluded from these data that insulin does not alter cellular Ca2+ fluxes and respiration themselves, but selectively inhibits alpha-adrenergic stimulation of these processes. It is proposed that insulin acts either to inhibit binding of alpha-agonists to their specific plasma-membrane receptors or to alter generation and/or degradation of the putative alpha-adrenergic 'second messenger'. If this latter possibility is the case, then the alpha-adrenergic 'second messenger' must be different from the 'second messenger' of vasopressin.     

Difference in the mechanism of action of alpha-adrenergic agonists and vasopressin or angiotensin II in stimulating hepatic glycogenolysis; a role of extracellular calcium concentration

The role of extracellular calcium in hormone-induced glycogenolysis was examined in a rat liver perfusion system by manipulating the perfusate calcium concentration and by using calcium antagonistic drugs. When the perfusate contained 1 mM CaCl2, 5 microM phenylephrine, 20 nM vasopressin, and 10 nM angiotensin II caused a persistent increase in glucose output and phosphorylase activity as well as a transient increase in 45Ca efflux from 45Ca preloaded liver. Verapamil hydrochloride (20-100 microM) inhibited the activation of glucose output by these hormones in a dose-dependent manner. This inhibitory effect was also associated with the inhibition of hormone-induced activation of phosphorylase and 45Ca efflux. In the absence of CaCl2 in the perfusate, the glycogenolytic effect of phenylephrine and its inhibition by verapamil were obtained equally as in the presence of CaCl2. However, the effects of vasopressin and angiotensin II were markedly attenuated and were not inhibited any further by verapamil. The substitution of diltiazem hydrochloride for verapamil produced essentially identical results. Cyclic AMP concentrations in the tissue did not change under any of these test conditions. The results indicate that the glycogenolytic effect of alpha-adrenergic agonists depends on intracellular calcium but those of vasopressin and angiotensin II on extracellular calcium, and support the concept that calcium antagonistic drugs inhibit the glycogenolytic effects of calcium-dependent hormones at least by inhibiting the mobilization of calcium ion from cellular pools.     

Glucagon and glucose as major regulators of glycogen metabolism in primary cultured rat hepatocytes

The short-term controls of glycogen synthase [EC 2.4.1.11] and glycogen phosphorylase [EC 2.4.1.1] by major regulators, such as insulin, glucose, catecholamine, and glucagon, were compared in a simple, yet organized experimental system, i.e., adult rat hepatocytes in primary culture. Glycogen synthase was activated by glucose markedly and dose-dependently (5-40 mM), but insulin alone (1 X 10(-8) M) activated this enzyme only two-fold. Therefore, activation of the enzyme by the two regulators together was mostly due to activation by glucose. Glucagon at a concentration of 5 X 10(-10) M suppressed this activation almost completely. Glucagon at this concentration activated phosphorylase considerably and this activation was slightly inhibited by insulin. Phenylephrine also activated phosphorylase, and this activation was inhibited by phenoxybenzamine or prazosin, suggesting that activation by catecholamine is through the alpha 1-adrenergic receptor. Similarly a high concentration of glucose diminished the effects of glucagon and phenylephrine. These results suggest that in rat liver, glycogen metabolism is controlled mainly by glucagon, catecholamine, and glucose; the former two activate phosphorylase and inactivate synthase, while glucose activates synthase strongly and inactivates phosphorylase partially. Insulin plays a minor role in both reactions. Thus, the liver is primarily an organ for glucose production, which is regulated by hormones, not for glycogen storage, which is increased only by a high glucose concentration in the portal blood.     

Role of extracellular calcium and calcium efflux in the activation of hepatic glycogenolysis by calcium-dependent hormones

The role of extracellular calcium in the glycogenolytic effects of calcium-dependent hormones was examined in a rat liver perfusion system. Decreasing the perfusate CaCl2 concentration resulted in a concentration-dependent inhibition of glucose output by maximal concentrations of vasopressin (20 nM) and angiotensin II (10 nM), but not of glucagon (1.4 nM), cyclic AMP (100 microM), dibutyryl cyclic AMP (10 microM) or phenylephrine (5 microM). However, the effect of phenylephrine was inhibited when livers were perfused with CaCl2-free perfusate containing 0.5 mM EGTA in a duration-dependent manner. These effects were exerted through the inhibition of the maximal response of each hormone, and were associated with a parallel decrease in phosphorylase activation but not with changes in tissue cyclic AMP concentrations. When livers were preloaded with 45Ca for 45 min and then washed for either 15 min or 45 min, these hormones elicited a rapid and transient 45Ca efflux regardless of the perfusate calcium concentration. The sequential perfusion of two hormones resulted in the loss of 45Ca efflux by the second hormone. These results suggest that the glycogenolytic effects of vasopressin and angiotensin II depend on the extracellular calcium and that of phenylephrine primarily on the cellular calcium. It was also demonstrated that these calcium-dependent hormones mobilize calcium from the same pools. However, the mobilization of cellular calcium does not necessarily correlate directly with the glycogenolytic actions of vasopressin and angiotensin II.     

Insulin counteraction of alpha-adrenergic effects on liver glycogen metabolism.

Insulin counteracted the effects of a pure alpha-adrenergic agonist, phenylephrine, on hepatocyte glycogen synthase and phosphorylase. These results argue against current concepts of insulin increasing cytoplasmic Ca2+ concentration.     

Stimulation by alpha-adrenergic agonists of Ca2+ fluxes, mitochondrial oxidation and gluconeogenesis in perfused rat liver.

Glucose output from perfused livers of 48 h-starved rats was stimulated by phenylephrine (2 microM) when lactate, pyruvate, alanine, glycerol, sorbitol, dihydroxyacetone or fructose were used as gluconeogenic precursors. Phenylephrine-induced increases in glucose output were immediately preceded by a transient efflux of Ca2+ and a sustained increase in oxygen uptake. Phenylephrine decreased the perfusate [lactate]/[pyruvate] ratio when sorbitol or glycerol was present, but increased the ratio when alanine, dihydroxyacetone or fructose was present. Phenylephrine induced a rapid increase in the perfusate [beta-hydroxybutyrate]/[acetoacetate] ratio and increased total ketone-body output by 40-50% with all substrates. The oxidation of [1-14C]octanoate or 2-oxo[1-14C]glutarate to 14CO2 was increased by up to 200% by phenylephrine. All responses to phenylephrine infusion were diminished after depletion of the hepatic alpha-agonist-sensitive pool of Ca2+ and returned toward maximal responses after Ca2+ re-addition. Phenylephrine-induced increases in glucose output from lactate, sorbitol and glycerol were inhibited by the transaminase inhibitor amino-oxyacetate by 95%, 75% and 66% respectively. Data presented suggest that the mobilization of an intracellular pool of Ca2+ is involved in the activation of gluconeogenesis by alpha-adrenergic agonists in perfused rat liver. alpha-Adrenergic activation of gluconeogenesis is apparently accompanied by increases in fatty acid oxidation and tricarboxylic acid-cycle flux. An enhanced transfer of reducing equivalents from the cytoplasmic to the mitochondrial compartment may also be involved in the stimulation of glucose output from the relatively reduced substrates glycerol and sorbitol and may arise principally from an increased flux through the malate-aspartate shuttle.     

Inhibition of the glycogenolytic effects of alpha-adrenergic stimulation and glucagon by cobalt ions in perfused rat liver

Cobalt ions (2 mM) inhibited the glycogenolysis induced by phenylephrine and glucagon in perfused rat liver. Cobalt ions also inhibited 45Ca++ efflux from prelabelled livers induced by phenylephrine and glucagon. In addition, they inhibited the rise in tissue levels of cyclic AMP caused by glucagon, but did not inhibit the stimulation of 45Ca++ efflux or glycogenolysis by cyclic AMP or dibutyryl cyclic AMP. The specific binding of glucagon and alpha-agonist to hepatocytes was not inhibited by cobalt ions. These data suggest that cobalt ions, presumably through their high affinity for calcium binding sites on membranes inhibit the stimulation of glycogenolysis by phenylephrine and glucagon in distinct ways; one by inhibiting calcium mobilization and the other by inhibiting cyclic AMP production. Therefore, it is conceivable that membrane-bound calcium plays an important role in stimulating Ca++ mobilization by phenylephrine, and cyclic AMP production by glucagon.