The phorbol ester TPA inhibits cyclic AMP phosphodiesterase activity in intact hepatocytes

Treatment of intact hepatocytes with the phorbol ester 12-O-tetradecanoyl phorbol 13-acetate (TPA) potentiated the ability of glucagon to increase intracellular cyclic AMP concentrations. This effect was dose-dependent upon TPA, exhibiting an EC50 of 0.39 ng/ml and such activation was observed at both saturating and sub-saturating concentrations of glucagon. However, this stimulatory effect of TPA was completely abolished by the presence of the cyclic AMP phosphodiesterase inhibitor 1-isobutyl-3-methylxanthine, when TPA now inhibited the glucagon-stimulated increase in intracellular cyclic AMP concentrations. It is suggested that, as well as inhibiting glucagon-stimulated adenylate cyclase activity, TPA also inhibits cyclic AMP phosphodiesterase activity in intact hepatocytes. Treatment of either hepatocyte homogenates or purified cyclic AMP phosphodiesterase with TPA failed to show any direct inhibitory effect of TPA on activity showing that TPA did not exert any direct inhibitory action on phosphodiesterase activity. However, homogenates made from hepatocytes that had been pre-treated with TPA did show a reduced cyclic AMP phosphodiesterase activity. It is suggested that TPA might inhibit cyclic AMP phosphodiesterase activity through phosphorylation by C-kinase.     

The phorbol ester TPA prevents the expression of both glucagon desensitisation and the glucagon-mediated block of insulin stimulation of the peripheral plasma membrane cyclic AMP phosphodiesterase in rat hepatocytes

The phorbol ester TPA (12-O-tetradecanoyl phorbol-13-acetate) causes a dose-dependent inhibition of the glucagon-stimulated adenylate cyclase activity expressed in plasma membranes isolated from TPA-treated hepatocytes. However, no observable inhibitory effect of TPA on adenylate cyclase activity was observed in cells which had been exposed to glucagon for 5 min, prior to isolation, to desensitise adenylate cyclase. The degree of inhibition of adenylate cyclase elicited by both glucagon desensitisation and TPA treatment of hepatocytes was identical. Pre-treatment of hepatocytes with TPA was also found to prevent glucagon from blocking insulin's activation of the peripheral plasma membrane cyclic AMP phosphodiesterase in intact hepatocytes. TPA treatment also inhibited the ability of cholera toxin to activate the peripheral cyclic AMP phosphodiesterase in intact hepatocytes. It is suggested that in these particular instances TPA and glucagon elicit mutually exclusive processes rather than TPA mimicking glucagon desensitisation per se.     

N6-(Phenylisopropyl)adenosine prevents glucagon both blocking insulin''s activation of the plasma-membrane cyclic AMP phosphodiesterase and uncoupling hormonal stimulation of adenylate cyclase activity in hepatocytes.

Glucagon (10nM) prevented insulin (10nM) from activating the plasma-membrane cyclic AMP phosphodiesterase. This effect of glucagon was abolished by either PIA [N6-(phenylisopropyl)adenosine] (100nM) or adenosine (10 microM). Neither PIA nor adenosine exerted any effect on the plasma-membrane cyclic AMP phosphodiesterase activity either alone or in combination with glucagon. Furthermore, PIA and adenosine did not potentiate the action of insulin in activating this enzyme. 2-Deoxy-adenosine (10 microM) was ineffective in mimicking the action of adenosine. The effect of PIA in preventing the blockade by glucagon of insulin's action was inhibited by low concentrations of theophylline. Half-maximal effects of PIA were elicited at around 6nM-PIA. It is suggested that adenosine is exerting its effects on this system through an R-type receptor. This receptor does not appear to be directly coupled to adenylate cyclase, however, as PIA did not affect either the activity of adenylate cyclase or intracellular cyclic AMP concentrations. Insulin's activation of the plasma-membrane cyclic AMP phosphodiesterase, in the presence of both glucagon and PIA, was augmented by increasing intracellular cyclic AMP concentrations with either dibutyryl cyclic AMP or the cyclic AMP phosphodiesterase inhibitor Ro-20-1724. PIA also inhibited the ability of glucagon to uncouple (desensitize) adenylate cyclase activity in intact hepatocytes. This occurred at a half-maximal concentration of around 3 microM-PIA. However, if insulin (10 nM) was also present in the incubation medium, PIA exerted its action at a much lower concentration, with a half-maximal effect occurring at around 4 nM.     

Insulin and glucagon regulate the activation of two distinct membrane-bound cyclic AMP phosphodiesterases in hepatocytes.

Glucagon (10 nM) caused a transient elevation of intracellular cyclic AMP concentrations, which reached a peak in around 5 min, and slowly returned to basal values in around 30 min. When 1 mM-3-isobutyl-1-methylxanthine (IBMX) was present, this process yielded a Ka of 1 nM for glucagon. The addition of insulin (10 nM) after 5 min exposure to glucagon (10 nM) caused intracellular cyclic AMP concentrations to fall dramatically, attaining basal values within 10 min. The regulation of this process was dose-dependent, exhibiting a Ka of 0.4 nM for insulin. If insulin and glucagon were added together to hepatocytes, then insulin decreased the magnitude of the cyclic AMP response to glucagon. IBMX (1 mM) prevented insulin antagonizing the action of glucagon in both of these instances. A gentle homogenization procedure followed by a rapid subcellular fractionation of hepatocytes on a Percoll gradient was developed. This was used to resolve subcellular membrane fractions and to identify cyclic AMP phosphodiesterase activity in both membrane and cytosol fractions. Glucagon and insulin only affected the activity of two distinct membrane-bound species, a plasma-membrane enzyme and a 'dense vesicle' enzyme. Glucagon (10 nM), insulin (10 nM), IBMX (1 mM), dibutyryl cyclic AMP (10 microM) and cholera toxin (1 microgram/ml) all elicited the activation of the 'dense vesicle' enzyme. The plasma-membrane enzyme was not activated by glucagon, IBMX or dibutyryl cyclic AMP, although insulin and cholera toxin both led to its activation. The degree of activation of the plasma-membrane enzyme produced by insulin was increased in the presence of IBMX or dibutyryl cyclic AMP. Glucagon pretreatment (5 min) of hepatocytes blocked the ability of insulin to activate the plasma-membrane enzyme. The activity state of these phosphodiesterases is discussed in relation to the observed changes in intracellular cyclic AMP concentrations. It is suggested that insulin exerts its action on the plasma-membrane phosphodiesterase through a mechanism involving a guanine nucleotide-regulatory protein.     

The rapid desensitization of glucagon-stimulated adenylate cyclase is a cyclic AMP-independent process that can be mimicked by hormones which stimulate inositol phospholipid metabolism.

Treatment of intact hepatocytes with glucagon, TH-glucagon [( 1-N-alpha-trinitrophenylhistidine, 12-homoarginine]glucagon), angiotensin or vasopressin led to a rapid time- and dose-dependent loss of the glucagon-stimulated response of the adenylate cyclase activity seen in membrane fractions isolated from these cells. Intracellular cyclic AMP concentrations were only elevated with glucagon. All ligands were capable of causing both desensitization/loss of glucagon-stimulated adenylate cyclase activity and stimulation of inositol phospholipid metabolism in the intact hepatocytes. Maximally effective doses of angiotensin precluded any further inhibition/desensitizing action when either glucagon or TH-glucagon was subsequently added to these intact cells, as has been shown previously for the phorbol ester TPA (12-O-tetradecanoylphorbol 13-acetate) [Heyworth, Wilson, Gawler & Houslay (1985) FEBS Lett. 187, 196-200]. Treatment of intact hepatocytes with these various ligands caused a selective loss of the glucagon-stimulated adenylate cyclase activity in a washed membrane fraction and did not alter the basal, GTP-, NaF- and forskolin-stimulated responses. Angiotensin failed to inhibit glucagon-stimulated adenylate cyclase activity when added directly to a washed membrane fraction from control cells. Glucagon GR2 receptor-stimulated adenylate cyclase is suggested to undergo desensitization/uncoupling through a cyclic AMP-independent process, which involves the stimulation of inositol phospholipid metabolism by glucagon acting through GR1 receptors. This action can be mimicked by other hormones which act on the liver to stimulate inositol phospholipid metabolism. As the phorbol ester TPA also mimics this process, it is proposed that protein kinase C activation plays a pivotal role in the molecular mechanism of desensitization of glucagon-stimulated adenylate cyclase. The site of the lesion in desensitization is shown to be at the level of coupling between the glucagon receptor and the stimulatory guanine nucleotide regulatory protein Gs, and it is suggested that one or both of these components may provide a target for phosphorylation by protein kinase C.     

Calcium dependence of beta-adrenoceptor mediated cyclic AMP accumulation in human lymphocytes

In intact human lymphocytes, cyclic AMP accumulation in response to isoproterenol was inhibited by 5 mM EDTA, by deletion of calcium ions from the medium and by 1 mM lanthanum chloride, but not by 1 microM verapamil or by 10 microM nifedipine. A23187 caused a modest increase in cyclic AMP content. Exposure of lymphocytes to 5 microM 1-isoproterenol desensitized the cells to subsequent beta-adrenergic stimulation, reducing cyclic AMP accumulation. With higher concentrations of 1-isoproterenol (50 microM), receptor density was reduced as well. None of the above agents attenuated losses in agonist-stimulated cyclic AMP accumulation induced by treatment with 5 microM isoproterenol for 90 min. These data suggest that calcium ions, both those present in the extracellular medium and those bound to the plasma membrane, are required for isoproterenol-stimulation of adenylate cyclase. In addition, it appears that neither the presence of extracellular calcium ions nor full activation of adenylate cyclase are required for desensitization.     

Adenosine potentiates lutropin-stimulated cyclic AMP production and inhibits lutropin-induced desensitization of adenylate cyclase in rat Leydig tumour cells.

The action of adenosine on lutropin (LH)-stimulated cyclic AMP production and LH-induced desensitization of adenylate cyclase in rat Leydig tumour cells was investigated. Adenosine and N6-(phenylisopropyl)adenosine caused a dose-dependent potentiation of LH-stimulated cyclic AMP production at concentrations (0.01-10 microM) which alone did not produce an increase in cyclic AMP production. However, 2-deoxyadenosine had no effect either alone or in combination with LH on cyclic AMP production. The potentiation produced by adenosine was unaffected by concentrations of the specific nucleoside-transport inhibitor dipyridamole, which inhibited [3H]adenosine uptake by up to 90%. The phosphodiesterase inhibitor 3-isobutyl-l-methylxanthine, but not RO-10-1724, inhibited the adenosine-induced potentiation. In the presence of adenosine, the kinetics of LH-stimulated cyclic AMP production were linear with time up to 2h, compared with those with LH alone, which showed a characteristic decrease in rate of cyclic AMP production after the first 15-20 min. Consistent with the altered kinetics, adenosine also inhibited the LH-induced desensitization of adenylate cyclase. These results suggest that adenosine has effects on rat tumour Leydig cells through receptors on the external surface of the plasma membrane. This receptor has characteristics similar to those of the R-type receptors, which have been shown either to stimulate or to inhibit adenylate cyclase. However, the effects of adenosine in the present studies does not involve a direct inhibition or activation of adenylate cyclase, but may involve an as yet undefined receptor-mediated modulation of adenylate cyclase.     

Nalpha-trinitrophenyl glucagon: an inhibitor of glucagon-stimulated cyclic AMP production and its effects on glycogenolysis.

Nalpha-Trinitrophenyl glucagon was prepared by reaction with trinitrobenzene sulfonic acid and purified by ion-exchange chromatography. This derivative has essentially no ability to activate adenylate cyclase from rat liver nor to increase the levels of cyclic AMP in isolated hepatocytes nor to stimulate protein kinase activity. This derivative also can act as a glucagon antagonist with regard to cyclic AMP production and can decrease the degree of stimulation of adenylate cyclase caused by glucagon, as well as lowering the glucagon-stimulated elevation of cyclic AMP levels in intact hepatocytes. Nevertheless, this derivative is capable of activating glycogenolysis in isolated hepatocytes and in augmenting the effect of glucagon on glycogenolysis. This metabolic effect of the glucagon derivative thus appears to occur independent of changes in cyclic AMP levels. These results suggest that glucagon can also activate glycogenolysis by a cyclic AM-independent process.     

Prostaglandin E1 effects on cyclic AMP and glycogen metabolism in rat liver.

Prostaglandins E₁ or E₂ (PGE₁, PGE₂)¹ stimulated adenylate cyclase(s) from particulate fractions of whole liver homogenates 5- to 6-fold, but caused only slight (1.5- to 2-fold) stimulation of the enzyme from homogeneous hepatocytes. In contrast, glucagon stimulated enzyme from hepatocytes 12- to 15-fold and enzyme from whole liver 8- to 10-fold. Accordingly, most of the total prostaglandin-sensitive adenylate cyclase in cell suspensions was recovered in fractions containing non-parenchymal cells, and most of the total glucagon-sensitive activity was recovered with hepatocytes. PGE₁ did not change adenosine-3′,5′-monophosphate (cyclic AMP) concentrations, or alter cyclic AMP increases caused by glucagon in hepatocytes. Glucagon consistently increased hepatocyte cyclic AMP concentrations and stimulated glycogenolysis by 35 to 40%. PGE₁ did not affect basal or glucagon-stimulated glycogenolysis in the intact cells.     

Changes in hormone responsiveness and cyclic AMP metabolism in rat hepatocytes during primary culture and effects of supplementing the medium with insulin and dexamethasone

Primary monolayer cultures of rat hepatocytes were used for studies of long-term and acute effects of hormones on the cyclic AMP system. When hepatocyte lysates were assayed at various times after plating of the cells three major changes in the metabolism of cyclic AMP and its regulation were observed: Glucagon-sensitive adenylate cyclase activity gradually declined in culture. In contrast, catecholamine-sensitive activity, being very low in normal adult male rat liver and freshly isolated hepatocytes, showed a strong and rapid increase after seeding of the cells. Concomitantly, there was an early elevation (peak approximately equal to 6 h) and a subsequent decrease in activity of both high-Km and low-Km cyclic AMP phosphodiesterase. These enzymic changes probably explained the finding that in intact cultured cells the cyclic AMP response to glucagon was diminished for 2-24 h after seeding, followed by an increase in the responsiveness to glucagon as well as to adrenergic agents up to 48 h of culture. Supplementation of the culture media with dexamethasone and/or insulin influenced the formation and breakdown of cyclic AMP in the hepatocytes. Insulin added at the time of plating moderately increased the adenylate cyclase activity assayed at 48 h, while dexamethasone had no significant effect. In the presence of dexamethasone, insulin exerted a stronger, and dose-dependent (1 pM - 1 microM), elevation of the adenylate cyclase activity in the lysates, particularly of the glucagon responsiveness. Thus, insulin plus dexamethasone counteracted the loss of glucagon-sensitive adenylate cyclase activity occurring in vitro. Kinetic plots of the cyclic AMP phosphodiesterase activity showed three affinity regions for the substrate. Of these, the two with high and intermediate substrate affinity (Km approximately equal to 1 and approximately equal to 10 microM) were decreased in the dexamethasone-treated cells. Insulin partly prevented this effect of dexamethasone. Accumulation of cyclic AMP in intact cells in response to glucagon or beta-adrenergic agents was strongly increased in cultures pretreated with dexamethasone. The results suggest that insulin and glucocorticoids modulate the effects of glucagon and epinephrine on hepatocytes by exerting long-term influences on the cyclic AMP system.     

Prostaglandins and muscarinic agonists induce cyclic AMP attenuation by two distinct mechanisms in the pregnant-rat myometrium. Interaction between cyclic AMP and Ca2+ signals.

In pregnant-rat myometrium (day 21 of gestation), isoprenaline-induced cyclic AMP accumulation, resulting from receptor-mediated activation of adenylate cyclase, was negatively regulated by prostaglandins [PGE2, PGF2 alpha; EC50 (concn. giving 50% of maximal response) = 2 nM] and by the muscarinic agonist carbachol (EC50 = 2 microM). PG-induced inhibition was prevented by pertussis-toxin treatment, supporting the idea that it was mediated by the inhibitory G-protein Gi through the inhibitory pathway of the adenylate cyclase. Both isoprenaline-induced stimulation and PG-evoked inhibition of cyclic AMP were insensitive to Ca2+ depletion. By contrast, carbachol-evoked attenuation of cyclic AMP accumulation was dependent on Ca2+ and was insensitive to pertussis toxin. The inhibitory effect of carbachol was mimicked by ionomycin. Indirect evidence was thus provided for the enhancement of cyclic AMP degradation by a Ca2(+)-dependent phosphodiesterase activity in the muscarinic-mediated effect. The attenuation of cyclic AMP elicited by carbachol coincided with carbachol-stimulated inositol phosphate (InsP3, InsP2 and InsP) generation, which displayed an almost identical EC50 (3 microM) and was similarly unaffected by pertussis toxin. Both carbachol effects were reproduced by oxotremorine, whereas pilocarpine (a partial muscarinic agonist) failed to induce any decrease in cyclic AMP accumulation and concurrently was unable to stimulate the generation of inositol phosphates. These data support our proposal for a carbachol-mediated enhancement of a Ca2(+)-dependent phosphodiesterase activity, compatible with the rises in Ca2+ associated with muscarinic-induced increased generation of inositol phosphates. They further illustrate that a cross-talk between the two major transmembrane signalling systems contributed to an ultimate decrease in cyclic AMP in the pregnant-rat myometrium near term.     

Nα-Trinitrophenyl glucagon An inhibitor of glucagon-stimulated cyclic AMP production and its effects on glycogenolysis

N^α-Trinitrophenyl glucagon was prepared by reaction with trinitrobenzene sulfonic acid and purified by ion-exchange chromatography. This derivative has essentially no ability to activate adenylate cyclase from rat liver nor to increase the levels of cyclic AMP in isolated hepatocytes nor to stimulate protein kinase activity. This derivative also can act as a glucagon antagonist with regard to cyclic AMP production and can decrease the degree of stimulation of adenylate cyclase caused by glucagon, as well as lowering the glucagon-stimulated elevation of cyclic AMP levels in intact hepatocytes. Nevertheless, this derivative is capable of activating glycogenolysis.in isolated hepatocytes and in augmenting the effect of glucagon on glycogenolysis. This metabolic effect of the glucagon derivative thus appears to occur independent of changes in cyclic AMP levels. These results suggest that glucagon can also activate glycogenolysis by a cyclic AMP-independent process.     

Evidence that the mitochondrial activator of phosphorylated branched-chain 2-oxoacid dehydrogenase complex is the dissociated E1 component of the complex

The ability of glucagon (10 nM) to increase hepatocyte intracellular cyclic AMP concentrations was reduced markedly by the tumour-promoting phorbol ester TPA (12-O-tetradecanoyl phorbol-13-acetate). The half-maximal inhibitory effect occurred at 0.14 ng/ml TPA. This action occurred in the presence of the cyclic AMP phosphodiesterase inhibitor isobutylmethylxanthine (1 mM) indicating that TPA inhibited glucagon-stimulated adenylate cyclase activity. TPA did not affect either the binding of glucagon to its receptor or ATP concentrations within the cell. TPA did inhibit the increase in intracellular cyclic AMP initiated by the action of cholera toxin (1 microgram/ml) under conditions where phosphodiesterase activity was blocked. TPA did not inhibit glucagon-stimulated adenylate cyclase activity in a broken plasma membrane preparation unless Ca2+, phosphatidylserine and ATP were also present. It is suggested that TPA exerts its inhibitory effect on adenylate cyclase through the action of protein kinase C. This action is presumed to be exerted at the point of regulation of adenylate cyclase by guanine nucleotides.     

An assessment of the ability of insulin-stimulated cyclic AMP phosphodiesterase to decrease hepatocyte intracellular cyclic AMP concentrations.

Treatment of hepatocytes with either NH4Cl (10mM) or fructose (10mM) blocks insulin's activation of the 'dense-vesicle' cyclic AMP phosphodiesterase. The ability of insulin (10 nM) to decrease intracellular cyclic AMP concentrations raised by glucagon (10 nM) was unaffected by pre-treatment with either NH4Cl (10 mM) or fructose (10 mM). It is concluded that the 'dense-vesicle' enzyme does not play a significant role in this action of insulin and that as yet unidentified cyclic AMP phosphodiesterase(s) must be activated by insulin. Treatment of hepatocytes with either NH4Cl or fructose appeared to increase, reversibly, cyclic AMP phosphodiesterase activity. When N6-(phenylisopropyl)adenosine was used to prevent glucagon from blocking insulin's activation of the plasma-membrane cyclic AMP phosphodiesterase activity, insulin's ability to decrease intracellular cyclic AMP concentrations in glucagon-treated hepatocytes was increased markedly. Insulin's activation of the plasma-membrane cyclic AMP phosphodiesterase activity can exert a potent effect in decreasing intracellular cyclic AMP concentrations elevated by glucagon.     

An insulin mediator preparation serves to stimulate the cyclic GMP activated cyclic AMP phosphodiesterase rather than other purified insulin-activated cyclic AMP phosphodiesterases

An insulin mediator preparation was obtained from rat hepatocytes which had been treated with insulin. This preparation inhibited adenylate cyclase activity. It stimulated the activity of homogeneous preparations of both the cytosolic and membrane-bound forms of rat liver cyclic GMP-activated cyclic AMP phosphodiesterase. It failed to activate homogeneous preparations of both the peripheral plasma membrane and 'dense-vesicle' cyclic AMP phosphodiesterases. The insulin mediator preparation stimulated cyclic GMP-activated cyclic AMP phosphodiesterase activity in a dose-dependent fashion with a hill coefficient of 0.46. Insulin caused the dose-dependent production of mediator activity in intact hepatocytes with a Ka of 9 pM, although concentrations of insulin greater than 10 nM progressively reduced stimulatory activity.     

Variations in cyclic AMP level and specific activities of adenylate cyclase and cyclic AMP phosphodiesterase during the cell cycle of an Actinomycete (author's transl)

The variations in the concentrations of intra- and extracellular cyclic AMP and in he specific activities of adenylate cyclase (EC 4.6.1.1) and cyclic AMP phosphodiesterase (EC 3.1.4.17) have been monitored in synchronized cultures of Nocardia restricta, a prokaryote belonging to the group of Actinomycetes. At the beginning of the cell cycle, during a first period of RNA and protein synthesis, there is an increasing synthesis of adenylate cyclase which can be suppressed in the presence of chloramphenicol or rifampicin. Simultaneously, the specific activity of cyclic AMP phosphodiesterase decreases and the concentrations of intra- and extracellular cyclic AMP rise. After the end of DNA replication, during a second period of RNA and protein synthesis, the specific activity of cyclic AMP phosphodiesterase increases; during the same time, the specific activity of adenylate cyclase and the level of intracellular cyclic AMP drop. It appears that the overall metabolism of cyclic AMP is coordinated so that the cyclic AMP level will be high at the beginning of DNA replication and will fall thereafter. The results are discussed in comparison with known data about the variations of cyclic AMP during the cell cycle of mammalian cells in cultures.     

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.     

Distribution of cyclic AMP phosphodiesterase in microdissected periportal and perivenous rat liver tissue with different dietary states.

Cyclic AMP phosphodiesterase was measured in liver homogenates and microdissected periportal and perivenous liver tissue from rats in different dietary states under different conditions of substrate saturation and effector stimulation. A radiochemical microtest, more sensitive by 2-3 orders of magnitude than the usual assay, was established for the determination of the activity in liver samples corresponding to 200-800 ng dry weight. At saturating cyclic AMP concentrations (46 microM) phosphodiesterase was homogeneously distributed within the liver acinus of fed rats. Starvation for 48 h led to a decrease in the overall activity and to a heterogenous distribution with slightly higher activities in the perivenous zone. At physiological cyclic AMP concentrations (1.8 microM) phosphodiesterase showed a flat zonal gradient in livers of fed rats with higher levels in the periportal zone; after 48 h starvation it was homogeneously distributed. In the presence of cyclic GMP (2 microM) the basal activity at physiological substrate concentrations was stimulated to a greater extent in the perivenous zone. This led to a homogeneous activity distribution in the fed state and to a heterogenous pattern with a slight perivenous maximum in the fasted state. Thus there was no or only a small zonal heterogeneity of signal transmitting enzymes such as cyclic AMP phosphodiesterase and glucagon-stimulated adenylate cyclase (Zierz and Jungermann 1984). This similar signal transducing capacity in the periportal and the perivenous area will contribute to maintain the zonation of signal input due to the hormone concentration gradients across the liver acinus.     

Pertussis toxin stimulates cholecystokinin-induced cyclic AMP formation but is without effect on secretagogue-induced calcium mobilization in exocrine pancreas

The role of a pertussis toxin sensitive GTP-binding protein in mediating between cholecystokinin receptors and phosphatidylinositol 4,5-bisphosphate phosphodiesterase as well as in preventing cholecystokinin from increasing cellular cyclic AMP has been investigated using dispersed acini from rabbit pancreas. Pertussis toxin pretreatment (500 ng/ml, 2 h) did not affect cholecystokinin(octapeptide) (CCK-8)-induced increases in cytosolic free Ca2+ as judged from changes in fluorescence obtained from quin2-loaded acini. Although pretreatment with pertussis toxin was also without effect on resting acinar cell cyclic AMP levels, adenylate cyclase activity was increased, since inhibition of cyclic AMP phosphodiesterase activity by isobutylmethylxanthine (IBMX) resulted in an additional increase in cyclic AMP levels in toxin-treated acini, indicating that acinar cell adenylate cyclase activity is under some tonic inhibitory control by the pertussis toxin-sensitive inhibitory GTP-binding protein (Gi) of the adenylate cyclase system. CCK-8 gave an increase in cyclic AMP levels in both control (1.6-fold) and toxin-treated (2.3-fold) acini, leading to cyclic AMP levels in the toxin-treated acini 2-times as high as those in control acini. In the presence of IBMX, the cyclic AMP response to CCK-8 was again markedly enhanced in acini pretreated with the toxin (3.2- vs. 1.8-fold), resulting in cAMP levels in the toxin-treated acini 3.7-times those in the absence of IBMX, 2.5-times those in control acini in the presence of IBMX and 7.0-times those in control acini in the absence of IBMX. Neither the pretreatment with pertussis toxin, nor the presence of IBMX alone, nor the combination had an effect on basal amylase secretion. However, all three treatments potentiated the stimulatory effect of CCK-8 on amylase secretion and the amount of potentiation was proportional to the cyclic AMP levels reached. Our findings suggest that in the intact pancreatic acinar cell Gi inhibition of the catalytic subunit of the adenylate cyclase may largely be responsible for preventing cholecystokinin from increasing cellular cyclic AMP. They moreover show that cyclic AMP is a modulatory agent in rabbit pancreatic enzyme secretion, not able to stimulate secretion itself, but potentiating effects mediated by the phosphatidylinositol-calcium pathway.