Effects of adenosine and adenosine analogues on glycogen metabolism in isolated rat hepatocytes

Adenosine signalling in diabetes mellitus--pathophysiology and therapeutic considerations

Adenosine is a key extracellular signalling molecule that regulates several aspects of tissue function by activating four G-protein-coupled receptors, A1, A2A, A2B and A1 adenosine receptors. Accumulating evidence highlights a critical role for the adenosine system in the regulation of glucose homeostasis and the pathophysiology of type 1 diabetes mellitus (T1DM) and type 2 diabetes mellitus (T2DM). Although adenosine signalling is known to affect insulin secretion, new data indicate that adenosine signalling also contributes to the regulation of β-cell homeostasis and activity by controlling the proliferation and regeneration of these cells as well as the survival of β cells in inflammatory microenvironments. Furthermore, adenosine is emerging as a major regulator of insulin responsiveness by controlling insulin signalling in adipose tissue, muscle and liver; adenosine also indirectly mediates effects on inflammatory and/or immune cells in these tissues. This Review critically discusses the role of the adenosine-adenosine receptor system in regulating both the onset and progression of T1DM and T2DM, and the potential of pharmacological manipulation of the adenosinergic system as an approach to manage T1DM, T2DM and their associated complications.

Adenosine, adenosine receptors and their role in glucose homeostasis and lipid metabolism

Adenosine is an endogenous metabolite that is released from all tissues and cells including liver, pancreas, muscle and fat, particularly under stress, intense exercise, or during cell damage. The role of adenosine in glucose homeostasis has been attributed to its ability to regulate, through its membrane receptors, processes such as insulin secretion, glucose release and clearance, glycogenolysis, and glycogenesis. Additionally, adenosine and its multiple receptors have been connected to lipid metabolism by augmenting insulin-mediated inhibition of lipolysis, and the subsequent increase in free fatty acids and glycerol levels. Furthermore, adenosine was reported to control liver cholesterol synthesis, consequently affecting plasma levels of cholesterol and triglycerides, and the amount of fat tissue. Alterations in the balance of glucose and lipid homeostasis have implications in both cardiovascular disease and diabetes. The ability of different adenosine receptors to activate and inhibit the same signaling cascades has made it challenging to study the influence of adenosine, adenosine analogs and their receptors in health and disease. This review focuses on the role and significance of different adenosine receptors in mediating the effect of adenosine on glucose and lipid homeostasis. J. Cell. Physiol. © 2013 Wiley Periodicals, Inc.

Polyphenols in cocoa and cocoa products: is there a link between antioxidant properties and health?

Cocoa and cocoa products have received much attention due to their significant polyphenol contents. Cocoa and cocoa products, namely cocoa liquor, cocoa powder and chocolates (milk and dark chocolates) may present varied polyphenol contents and possess different levels of antioxidant potentials. For the past ten years, at least 28 human studies have been conducted utilizing one of these cocoa products. However, questions arise on which of these products would deliver the best polyphenol contents and antioxidant effects. Moreover, the presence of methylxanthines, peptides, and minerals could synergistically enhance or reduce antioxidant properties of cocoa and cocoa products. To a greater extent, cocoa beans from different countries of origins and the methods of preparation (primary and secondary) could also partially influence the antioxidant polyphenols of cocoa products. Hence, comprehensive studies on the aforementioned factors could provide the understanding of health-promoting activities of cocoa or cocoa products components.

Diabetes-induced alterations of adenosine receptors expression level in rat liver

Diabetes mellitus is associated with metabolic, functional, and structural changes in the liver. Adenosine has been demonstrated to play an important regulatory role in the liver, and its action has been associated with all four adenosine receptors (ARs) subtypes. The goal of this study was to evaluate the impact of streptozotocin-induced diabetes on expression level of ARs in rat liver. Performed analyses (real-time PCR, Western blots) revealed detectable levels of mRNA and protein of A(1)-AR, A(2A)-AR, A(2B)-AR, and A(3)-AR in the rat liver. Development of diabetes resulted in a significant increase of A(2A)-AR and A(3)-AR mRNA levels. This was associated with elevated ARs protein content. The level of A(2B)-AR mRNA in diabetic liver decreased approximately 40% and was accompanied by 60% drop in A(2B)-AR protein in liver membranes. Diabetes did not affect the expression level of A(1)-AR in the liver. Administration of insulin for four days to diabetic rats resulted in returning of the ARs expression to the levels observed in liver of normal rat. The changes in ARs genes expression and receptors protein content could be related to some pathological changes taking place in diabetic liver. This might suggest involvement of ARs in pathogenesis of liver disease.

Functional characterization of the adenosine receptor contributing to glycogenolysis and gluconeogenesis in rat hepatocytes

The adenosine receptor subtype mediating glucose production by glycogenolysis and gluconeogenesis was studied in primary cultured rat hepatocytes. Adenosine and adenosine agonists caused cyclic AMP accumulation in rat hepatocytes. The order of potency was 5'-N-ethylcarboxamidoadenosine (NECA)>R(-)-N(6)-(2-phenylisopropyl)adenosine (RPIA)>adenosine>2-[p-(carboxyethyl)phenylethylamino]-5'-N-ethylcarboxamidoadenosine (CGS21680). Furthermore, adenosine agonists stimulated glycogenolysis and gluconeogenesis. The order of potency was NECA>RPIA>CGS21680. The rank order of potency is typical for adenosine A(2B) receptors. Glycogenolysis stimulated by NECA was fully inhibited by nonselective adenosine antagonists, 9-chloro-2-(2-furanyl)[1,2,4]triazolo[1,5-c]quinazolin-5-amine (CGS15943). However, the adenosine A(2A) receptor-selective antagonist, 8-(3-chlorostyryl)caffeine (CSC), and the adenosine A(1) receptor-selective antagonist, (+)-(R)-[(E)-3-(2-phenylpyrazolo[1,5-alpha]pyridin-3-yl)acryloyl]-2-piperidine ethanol (FK453), had a low inhibitory potency. A strong correlation was found between the inhibitory effect of adenosine antagonists on NECA-induced glucose production and that on intracellular cyclic AMP generation in rat hepatocytes. Our results suggest that adenosine stimulates cyclic AMP formation and regulates glycogenolysis and gluconeogenesis, most likely through the adenosine A(2B) receptor subtype in rat hepatocytes.

Regulation of glycogen metabolism in hepatocytes through adenosine receptors. Role of Ca2+ and cAMP

The objective of this work is to identify the adenosine receptor subtype and the triggered events involved in the regulation of hepatic glycogen metabolism. Glycogenolysis, gluconeogenesis, cAMP, and cytosolic Ca2+ ([Ca2+](cyt)) were measured in isolated hepatocytes challenged with adenosine A1, A2A, and A3 receptor-selective agonists. Stimulation of adenosine receptor subtypes with selective agonists in Ca2+ media produced a dose-dependent increase in [Ca2+]cyt with A1>A2=A3, cAMP with A2A, glycogenolysis with A1>A2A>A3, and gluconeogenesis with A2A>A1>A3, in addition, a decrease in cAMP was observed with A1=A3. Comparatively, in Ca2+-free media or with a cell membrane-permeant Ca2+ chelator, activation of these adenosine receptors with the same selective agonists produced a smaller and transient rise in [Ca2+]cyt with A1=A3>A2, no rise in glycogenolysis and gluconeogenesis with A3>A1, but a full rise with A2A. Thus, in isolated rat hepatocytes activation of the adenosine A1 receptor triggered Ca2+-mediated glycogenolysis, activation of the adenosine A2A receptor stimulated cAMP-mediated gluconeogenesis, and activation of the adenosine A3 receptor increased [Ca2+]cyt and decreased cAMP with minor changes in glycogen metabolism.

O2 availability modulates transmembrane Ca2+ flux via second-messenger pathways in anoxia-tolerant hepatocytes

Transmembrane Ca(2+)-flux was studied from single isolated turtle hepatocytes by using a noninvasive Ca(2+)-selective self-referencing microelectrode. Cells in Ca(2+)-reduced culture medium demonstrated a vanadate- and lanthanum-inhibitable Ca(2+)-efflux of 4 x 10(-17) mol Ca2+. microns-2. s-1 continuously over 170 h. This flux diminished with 50 nM phorbol 12-myristate 13-acetate, a protein kinase C (PKC) activator, and was reinstated on PKC deactivation with sphingosine. Progressive hypoxia resulted in a reversible suppression of Ca2+ efflux to 90% of normoxic controls with an apparent Michaelis constant for oxygen of 145 microM. PKC activation was critical in this suppression, as anaerobic administration of sphingosine caused a Ca2+ influx and cell rupture. Hypoxia was also associated with an altered pattern of adenosine-mediated control over Ca2+ efflux. Adenosine (100 microM) elevated Ca2+ efflux twofold in normoxia, but neither adenosine nor the A1-purinoreceptor antagonist 8-phenyltheophylline altered the observed anaerobic suppression. Aerobic administration of 2-10 mM KCN failed to reproduce the anaerobic suppression; however, in conjunction with 10 mM iodoacetate, complete metabolic blockade caused a Ca2+ influx and cell rupture. These observations suggest modulatory control by oxygen over transmembrane Ca2+ efflux involving second-messenger systems in the hypoxic transition.

Modulation of glucose production by indomethacin and pentoxifylline in healthy humans

Indomethacin, an inhibitor of prostaglandin synthesis that modulates cytokine production, increases hepatic glucose output (HGO) in humans. However, prostaglandins stimulate glucose production in vitro. To investigate the mechanism of HGO stimulation by indomethacin, we compared the effect of pentoxifylline, an inhibitor of cytokine production, versus saline (study 1, n = 6) and of indomethacin versus the combination of indomethacin and pentoxifylline (study 2, n = 5) on basal HGO. HGO was measured by primed, continuous infusion of 3-3H-glucose. In study 1, pentoxifylline infusion resulted in an immediate, transient decrease of HGO of approximately 50% (from 12.9 +/- 0.4 to 6.0 +/- 1.7 micromol/kg/min after 15 minutes, P < .03 v control). There were no differences in concentrations of glucoregulatory hormones between the two experiments. In study 2, after indomethacin administration, HGO increased transiently by approximately 84% (from 9.7 +/- 0.7 at baseline to 16.7 +/- 2.4 micromol/kg/min after 135 minutes, P < .05). However, pentoxifylline did not affect the increase in HGO induced by indomethacin. There were no differences in concentrations of glucoregulatory hormones between the two experiments. Therefore, indomethacin stimulates HGO by mechanisms unrelated to glucoregulatory hormones, prostaglandins, or cytokines.

Adenosine stimulates calcium influx in isolated rat hepatocytes

The mechanism of stimulation of Ca2+ entry into hepatocytes by adenosine was investigated. When Fura-2-loaded hepatocytes were suspended in a nominally Ca(2+)-free buffer, adenosine produced only a small transient increase in the cytosolic free Ca2+ concentration ([Ca2+)i). However, on restoration of an extracellular Ca2+ concentration of 1.3 mM, a rapid increase in [Ca2+]i occurred, which indicates activation of a Ca(2+)-influx pathway. Adenosine augmented the rate of Ca2+ influx triggered by maximally effective concentrations of thapsigargin or cAMP, but was without effect on the rate of Ca2+ entry that resulted from phospholipase-C-linked-receptor activation by maximally effective concentrations of vasopressin or ATP. However, in contrast to vasopression and ATP, adenosine did not stimulate Mn2+ entry. The rate of Mn2+ influx after stimulation of the hepatocytes with vasopressin was not increased by adenosine treatment. The stimulation of hepatocytes with adenosine did not result in significant accumulation of inositol phosphates or cAMP. Furthermore, the rate of adenosine-induced Ca2+ entry in hepatocytes was only slightly reduced in the presence of the P1 purinoceptor antagonist 8-phenyltheophylline. In contrast, the receptor-mediated-Ca(2+)-entry antagonist SK&F 96365 nearly completely blocked the Ca(2+)-entry response without any effect on internal-Ca(2+)-pool mobilisation by adenosine. It is concluded that adenosine activates the internal-pool-regulated pathway of Ca2+ entry and an additional pathway that appears comparable to the previously reported receptor-dependent pathway, except that Mn2+ entry is not stimulated.

Cross-talk between glucagon- and adenosine-mediated signalling systems in rat hepatocytes: effects on cyclic AMP-phosphodiesterase activity

The effect of adenosine analogues on glucagon-stimulated cyclic AMP accumulation in rat hepatocytes was explored. N6-Cyclopentyladenosine (CPA), 5'-N-ethylcarboxamidoadenosine and N6-(R-phenylisopropyl)adenosine inhibited in a dose-dependent manner the cyclic AMP accumulation induced by glucagon. This effect seems to be mediated through A1 adenosine receptors. Pertussis toxin completely abolished the effect of CPA on glucagon-stimulated cyclic AMP accumulation in whole cells which suggested that a pertussis-toxin-sensitive G-protein was involved. On the other hand, this action of adenosine analogues on glucagon-induced cyclic AMP accumulation was reverted by the selective low-Km cyclic AMP-phosphodiesterase inhibitor Ro 20-1724. Analysis of cyclic AMP-phosphodiesterase activity in purified hepatocyte plasma membranes showed that glucagon in the presence of GTP inhibited basal PDE activity by 45% and that CPA reverted this inhibition in dose-dependent manner. In membranes derived from pertussis-toxin-treated rats, we observed no inhibition of cyclic AMP-phosphodiesterase activity by glucagon in the absence or presence of CPA. Our results indicate that in hepatocyte plasma membranes, stimulation of adenylate cyclase activity and inhibition of a low-Km cyclic AMP phosphodiesterase activity are co-ordinately regulated by glucagon, and that A1 adenosine receptors can inhibit glucagon-stimulated cyclic AMP accumulation by blocking glucagon's effect on phosphodiesterase activity.

Equilibrative adenosine transport in rat hepatocytes after chronic ethanol feeding

Acute treatment of cells with ethanol in vitro inhibits adenosine uptake via equilibrative nucleoside transporters. After longer periods of exposure to ethanol in culture, rechallenge with ethanol no longer inhibits adenosine uptake. Herein, we have investigated the long-term effects of ethanol consumption in vivo on equilibrative nucleoside transport. Rats were fed a liquid diet containing 35% of calories as ethanol (ethanol-fed). Control rats were pair-fed a liquid diet that isocalorically substituted maltose dextrins for ethanol. After 4 weeks of ethanol consumption, nucleoside transport was measured in isolated hepatocytes. Uptake of [3H]adenosine was lower in ethanol-fed rats compared with control. Influx of the nonmetabolizable nucleoside analog, [3H]formycin B, was also decreased after ethanol feeding. However, neither the number of nitrobenzylthioinosine (NBMPR) binding sites or inhibition of adenosine uptake by NBMPR were affected by ethanol feeding. In controls, acute treatment of isolated hepatocytes with 100 mM ethanol inhibited [3H]adenosine uptake by 30-40%. However, in ethanol-fed rats, acute challenge with ethanol did not inhibit [3H]adenosine uptake. These data demonstrate that long-term ethanol feeding decreases equilibrative nucleoside transport in hepatocytes independent of a change in the number of nucleoside transporters and renders adenosine uptake insensitive to inhibition by ethanol.

Adenosine inhibits protein synthesis in isolated rat hepatocytes. Evidence for a lack of involvement of intracellular calcium in the mechanism of inhibition

Extracellularly added adenosine and ATP are potent inhibitors of protein synthesis in liver cells. In this study, the possible involvement of Ca2+ in the mechanism of inhibition of protein synthesis by adenosine was investigated. Stimulation of freshly isolated hepatocytes with adenosine or ATP, at concentrations that impaired protein synthesis, induced an increase in the cytosolic free Ca2+ concentration ([Ca2+]i). However, there was no correlation between the increase in [Ca2+]i and inhibition of radiolabelled leucine incorporation into proteins. Thus, the stimulation of hepatocytes with the V1-receptor agonist, vasopressin, or with the nucleotide triphosphates, UTP and GTP, elicited changes in [Ca2+]i similar to those observed after ATP or adenosine addition, but did not affect protein synthesis. ATP produced near complete discharge of Ca2+ from the inositol 1,4,5-trisphosphate-sensitive Ca2+ pool in isolated hepatocytes, whereas adenosine only had a partial effect. Depletion of the hormone-sensitive Ca2+ pool by adenosine was transient. In contrast, prolonged depletion of internal Ca2+ by thapsigargin resulted in the inhibition of protein synthesis in hepatocytes. However, the inhibition of radiolabelled leucine incorporation into proteins by thapsigargin was further augmented by the additional presence of adenosine. These results show that the inhibition of protein synthesis by adenosine in isolated hepatocytes is not mediated by an increase in [Ca2+]i or depletion of internal pool(s) sensitive to inositol 1,4,5-trisphosphate or thapsigargin.

Role of adenosine A1 receptors in inhibition of receptor-stimulated cyclic AMP production by ethanol in hepatocytes

Brief exposure of primary cultures of hepatocytes to ethanol had a biphasic effect on glucagon receptor-dependent cyclic AMP (cAMP) production: 25-50 mM ethanol decreased cAMP levels, whereas treatment with 100-200 mM ethanol increased cAMP. This biphasic effect was also observed after pretreatment with 10 microM 4-methylpyrazole, an inhibitor of alcohol dehydrogenase. Adenosine A1 and A2 receptors in primary cultures of rat hepatocytes are coupled to inhibition and stimulation of adenylyl cyclase, respectively. Since primary cultures of hepatocytes release adenosine into their extracellular media, we tested whether the acute effects of ethanol on cAMP were mediated by extracellular adenosine. Co-incubation with 2 U/mL adenosine deaminase prevented inhibition of cAMP production by 25-50 mM ethanol, but had no effect on stimulation by 100-200 mM ethanol. Pretreatment of hepatocytes with 110 nM 8-cyclopentyl-1,3-dimethylxanthine, an adenosine A1 receptor antagonist, also completely blocked the inhibitory effects of ethanol on cAMP production. Low concentrations of ethanol enhanced the inhibitory effects of R(-)N6-(2-phenylisopropyl)adenosine, an A1 receptor agonist, on cAMP production in cells pretreated with adenosine deaminase to remove endogenous adenosine. These data suggest that endogenously produced adenosine can be an important modulator of the effects of ethanol on receptor-stimulated cAMP production in primary cultures of rat hepatocytes.

Adenosine A1 receptors mediate chronic ethanol-induced increases in receptor-stimulated cyclic AMP in cultured hepatocytes

Cellular responses to adenosine depend on the distribution of the two adenosine receptor subclasses. In primary cultures of rat hepatocytes, adenosine receptors were coupled to adenylate cyclase via A1 and A2 receptors which inhibit and stimulate cyclic AMP production respectively. R-(-)-N6-(2-phenylisopropyl)-adenosine (R-PIA), the adenosine A1 receptor-selective agonist, inhibited glucagon-stimulated cyclic AMP production with an IC50 of 19 nM. This inhibition was blocked by the A1-specific antagonist 8-cyclopentyl-1,3-dimethylxanthine (CPDX). 5'-N- Ethylcarboxamidoadenosine (NECA), an agonist which stimulates A2 receptors, increased cyclic AMP production with an EC50 of 0.6 microM. Treatment of primary cultures of rat hepatocytes with 100 mM ethanol for 48 h decreases the quantity and function of the inhibitory guanine-nucleotide regulatory protein (G(i)), resulting in a sensitization of receptor-stimulated cyclic AMP production [Nagy and deSilva (1992) Biochem. J. 286, 681-686]. When cells were cultured with 2 units/ml adenosine deaminase, to degrade extracellular adenosine, ethanol-induced increases in cyclic AMP production were completely prevented. Moreover, the specific A1-receptor antagonist, CPDX, also blocked the chronic effects of ethanol on receptor-stimulated cyclic AMP production. Treatment with adenosine deaminase or CPDX also prevented the decrease in quantity of the alpha subunit protein of G(i) observed in hepatocytes after chronic treatment with ethanol. Taken together, these results suggest that activation of adenosine A1 receptors on primary cultures of hepatocytes is involved in the development of chronic ethanol-induced sensitization of receptor-stimulated cyclic AMP production.

Protective effect of various calcium antagonists against an experimentally induced calcium overload in isolated hepatocytes

The effect of the hepatotoxic substance diamidinothionaphthene (98/202) on cytosolic, mitochondrial and extra-mitochondrial calcium distribution was measured in isolated rat hepatocytes. The drastic disturbance of the intracellular calcium homeostasis caused by this substance (increase of the cytosolic and mitochondrial calcium contents and depletion of extra-mitochondrial calcium stores, which at last lead to cell death) gave rise to an investigation of the possible cytoprotective effect of calcium antagonists of various chemical classes: verapamil, diltiazem, and nifedipine on isolated hepatocytes. Our results show that all three calcium antagonists prevented cell death caused by 98/202. The 98/202-induced increase of cytosolic and mitochondrial calcium content was inhibited by all three calcium antagonists. However, only verapamil was able to inhibit the depletion of extra-mitochondrial calcium stores. Since 98/202-induced cell death occurs only in the presence of extracellular calcium, it is concluded that calcium antagonists are also able to inhibit the influx of extracellular calcium in liver cells, which leads to a calcium overload of the cytosol and mitochondria. The various ways of interfering with the calcium homeostasis of liver cells qualifies the hepatotoxic substance 98/202 as a suitable in vitro hepatotoxicity model for testing the hepatoprotective effect of different calcium antagonists.

Hepatocyte heterogeneity in response to extracellular adenosine

Metabolic and haemodynamic effects of adenosine were studied in antegrade and retrograde rat liver perfusions with influent nucleoside concentrations either below (i.e. 20 microM) or exceeding (i.e. 200-300 microM) the single-pass clearance capacity of the liver. Adenosine (20 microM) increased in antegrade perfusions the perfusion pressure and markedly stimulated prostaglandin D2, thromboxane B2 and glucose output, whereas in retrograde perfusions no pressure and eicosanoid response occurred and glucose output was stimulated only slightly. The perfusion-direction-dependent differences in the glucose and pressure response to adenosine (20 microM) were fully abolished in presence of ibuprofen (50 microM). When the adenosine concentration in influent was raised to 200-300 microM, i.e. to a concentration exceeding single-pass clearance of the nucleoside, the adenosine-induced prostaglandin D2 release was about 10-fold higher in retrograde perfusions than in antegrade perfusions. On the other hand, both adenosine (20-300 microM)-induced cyclic AMP (cAMP) and K+ release from the liver were not affected by the direction of perfusion, and maximal effects on cAMP release were observed at influent adenosine concentrations of 100 microM. The basal rate (adenosine absent) of prostaglandin D2 and thromboxane B2 release was about 10-fold higher in retrograde than in antegrade perfusion experiments, whereas the basal cAMP release from the liver was not affected by the direction of perfusion. Maximal adenosine-stimulated glucose output was significantly higher in antegrade than in retrograde perfusions at all adenosine concentrations tested (range 10-300 microM). Ibuprofen abolished this difference, indicating that eicosanoids liberated under the influence of adenosine contribute to the glycogenolytic response in antegrade, but not in retrograde, perfusion. Desensitization occurred following repetitive adenosine infusion; this was more pronounced for adenosine-induced prostaglandin release than for cAMP or K+ efflux. The data suggest the following. (i) Both cAMP and eicosanoids are involved in the stimulation of glycogenolysis by adenosine. (ii) Eicosanoids are probably liberated under the influence of extracellular adenosine from a portal pre-sinusoidal compartment and accordingly stimulate glycogenolysis only in antegrade perfusions. Thus signals derived from portal vein structures can modulate hepatocellular function. (iii) Contractile elements are probably located also inside the liver acinus. (iv) Eicosanoids released into the hepatic vein reflect less than 10% of hepatic eicosanoid formation, because of marked clearance by perivenous hepatocytes.

Modulation of maximal glycogenolysis in perfused rat liver by adenosine and ATP

Rat livers perfused at constant flow via the portal vein with dibutyryl cyclic AMP produced glucose equivalents at a steady maximal rate (6 mumol/min per g of liver). Addition of adenosine (150 microM) caused a biphasic effect. (i) First, the glycogenolytic rate rose transiently, to a mean peak of 150% of control levels after 2 min. This glycogenolytic burst was reproduced by two P1-receptor agonists, but not by ATP, and was blocked by a P1-antagonist (8-phenyltheophylline), as well as by inhibitors of eicosanoid synthesis (indomethacin, ibuprofen or aspirin). It did not occur in phosphorylase-kinase-deficient livers. The adenosine-induced glycogenolytic burst coincided with moderate and transient changes in portal pressure (+6 cmH2O) and O2 consumption (-20%), but it could not be explained by an increase in cytosolic Pi, since the n.m.r. signal fell precipitously. (ii) Subsequently, the rate of glycogenolysis decreased to one-third of the preadenosine value, in spite of persistent maximal activation of phosphorylase. The decrease could be linked to the decline in cytosolic Pi: both changes were prevented by the adenosine kinase inhibitor 5-iodotubercidin, whereas they were not affected by ibuprofen or 8-phenyltheophylline, and were not reproduced by non-metabolized adenosine analogues. In comparison with adenosine, ATP caused a slower decrease of Pi and of glycogenolysis. The fate of the cytosolic Pi was unclear, especially with administered ATP, which did not increase the n.m.r.-detectable intracellular ATP.

Metabolic responses of isolated hepatocytes to adenosine; dependence on external calcium

The role of cyclic-adenosine monophosphate (cAMP) and calcium (Ca2+) in the metabolic responses to adenosine was studied in isolated hepatocytes from fed rats. In the presence of 1.2 mM Ca but not in the absence of Ca2+, adenosine stimulated ureagenesis without increasing cAMP. Adenosine inhibited the glucagon mediated increase in cAMP. Adenosine increased free cytoplasmic Ca2+ provided that cells were incubated in the presence of external Ca2+. In the absence of added Ca2+ adenosine did not stimulate ureagenesis or the movements of Ca2+. It is suggested that, in the liver cell, Ca2+ may be a second messenger for adenosine.

Stimulation of release of prostaglandin D2 and thromboxane B2 from perfused rat liver by extracellular adenosine

In isolated perfused rat liver, adenosine infusion (50 microM) led to increases in glucose output and portal pressure and a net K+ release of 3.7 +/- 0.21 mumol/g, which was followed by an equivalent net K+ uptake after cessation of the nucleoside infusion. These effects were accompanied by a transient stimulation of hepatic prostaglandin D2 and thromboxane B2 release. The Ca2+ release observed upon adenosine infusion (50 microM) was 23.5 +/- 5.2 nmol/g, i.e. 10-20% of the Ca2+ release observed with extracellular ATP (50 microM). Indomethacin (10 microM) prevented the adenosine-induced stimulation of glucose output and the increase in portal pressure by 79 and 63% respectively, and completely abolished the stimulation of prostaglandin D2 release. The thromboxane A2 receptor antagonist BM 13.177 (20 microM), the phospholipase A2 inhibitor 4-bromophenacyl bromide (20 microM) and the cyclo-oxygenase inhibitor ibuprofen (50 microM) also decreased the glycogenolytic and vasoconstrictive responses of the perfused rat liver upon adenosine infusion by 50-80%. When the indomethacin inhibition of adenosine-induced prostaglandin D2 release was titrated, a close correlation between prostaglandin D2 release and the metabolic and vascular responses to adenosine was observed. These findings suggest an important role for eicosanoids in mediating the nucleoside responses in the perfused rat liver. Since eicosanoids are known to be formed by non-parenchymal cells in rat liver [Decker (1985) Semin. Liver Dis. 5, 175-190], the present study gives further evidence for an important role of eicosanoids as signal molecules between the different liver cell populations.

Multiple controls by adenosine receptors on the adenylate cyclase in the rat hepatic membrane

The effects of an adenosine analog, N6-phenyl-isopropyl-adenosine (PIA), on the glucagon-stimulated adenylate cyclase activity in rat hepatic membranes were studied. Adenosine at high concentrations (greater than 10 microM) has been reported exclusively to inhibit the adenylate cyclase via intracellular P-sites of the hepatic membrane. The stimulation by glucagon of the enzyme was attenuated by nanomolar concentrations of PIA in the presence of low concentrations (less than 1.0 microM) of GTP, indicating the effect of the guanine nucleotide inhibitory system (Ni). This inhibition by PIA required the presence of sodium chloride and was antagonized with isobutyl methylxanthine, an antagonist for the extracellular R-site receptors. The inhibitory effects of PIA disappeared and reversed into a stimulatory phase with increasing concentrations of GTP, suggesting the presence of a stimulatory (Ns) and an inhibitory (Ni) guanine nucleotide system of the enzyme in the action of the adenosine. PIA concentrations over a micromolar were observed to stimulate the enzyme activity in a GTP-dependent manner, indicating the presence of the stimulatory receptor (A2 or Ra) coupled to the Ns. These results suggest that receptors for adenosine of the inhibitory type (A1 or Ri) and the stimulatory type (A2 or Ra) are present on the rat hepatic membrane, showing multiple controls of the adenylate cyclase system, depending on the cellular concentrations of GTP and/or sodium chloride.

Adenosine deaminase and porcine meat quality. II. Effects of adenosine analogues on plasma free fatty acids, glucose and lactate in pigs representing high and low adenosine deaminase red cell activity

The adenosine analogues 5'-(N-ethyl) carboxamidoadenosine (NECA) and N6-(phenylisopropyl) adenosine (R-PIA) were shown to differ in their effect on the plasma level of free fatty acids (FFA), glucose and lactate in pigs representing low (Ada 0) and high (Ada A) red cell adenosine deaminase activity. At the same dosage range (0.001-0.005 mg/kg) R-PIA produced a much stronger suppression of the FFA level than NECA, indicating that A1 adenosine receptors predominate in porcine adipose tissue. Pretreatment with 8-phenyltheophylline completely abolished the antilipolytic effect of both adenosine analogues. NECA in contrast to R-PIA elevated the blood glucose concentration, suggesting that A2 adenosine receptors are involved in the stimulation of glycogenolysis. This effect of NECA was not altered by a beta-adrenoceptor blockade providing evidence for a direct effect of adenosine on glycogenolysis. Whereas the changes in plasma FFA following NECA administration were of similar magnitude in Ada A and Ada 0 pigs, the changes in the blood glucose concentration were different in these two groups of pigs.

"Hormone-like" effect of adenosine and inosine on gluconeogenesis from lactate in isolated hepatocytes

In isolated rat hepatocytes adenosine and inosine showed a dose-dependent increase in the rate of glucose synthesis from lactate with a Ka of 7.5 x 10(-8) and 9 x 10(-8) M, respectively. Absence of this action was recorded with: IMP, xanthosine, adenine, hypoxanthine, and uric acid. A reciprocal inhibition of individual gluconeogenic stimulation was found in cells incubated with glucagon or epinephrine and adenosine, but not with inosine. 5'-(N-ethyl) carboxamido adenosine was more potent than adenosine, whereas N6-(L-2-phenylisopropyl)-adenosine antagonized the stimulation of gluconeogenesis by adenosine. Neither of the analogs used modified the stimulatory role of inosine on the studied pathway. Adenosine and inosine may be involved in the short term regulation of gluconeogenesis.

Potentiation of the glycogenolytic and haemodynamic actions of adenosine in the perfused rat liver by verapamil

The effects of calcium channel blockers on the glycogenolytic and haemodynamic responses to adenosine were determined in perfused rat liver. Verapamil, 5-25 microM, potentiated the increased glucose output and vasoconstriction observed in response to adenosine. In the absence of perfusate calcium, adenosine responses were inhibited and verapamil was without effect. Verapamil did not potentiate the elevation of hepatic cAMP observed in response to a sub-maximal adenosine concentration (15 microM). In contrast to verapamil, nifedipine, 5 microM, was without effect on hepatic responses to adenosine. It is concluded that the potentiating effects of verapamil on hepatic responses to adenosine may be unrelated to the calcium-channel blocking activity of the compound

Stimulation of glycogenolysis in isolated hepatocytes by adenosine and one of its analogues is inhibited by caffeine

The adenosine analogues 5'-(N-ethyl)carboxamidoadenosine (NECA) and N6-(phenylisopropyl)adenosine (PIA) activate glycogen phosphorylase 5-fold and 4.2-fold respectively in rat hepatocytes incubated in the absence of endogenous adenosine. Half-maximally effective concentrations are 0.5 microM for NECA and 20 microM for PIA, demonstrating the presence of A2-adenosine receptors. Exogenous adenosine activates phosphorylase 4.6-fold, but high rates of adenosine disappearance from the medium render estimates of its half-maximally effective concentration unreliable. These effects of NECA and adenosine are inhibited by 0.1 mM-caffeine. Activation of phosphorylase by a physiological concentration of adenosine (3.3 microM) was 50% inhibited by a physiological concentration of caffeine (35 microM).