Resensitization of hepatocyte glucagon-stimulated adenylate cyclase can be inhibited when cyclic AMP phosphodiesterase inhibitors are used to elevate intracellular cyclic AMP concentrations to supraphysiological values

Insulin and vasopressin elicit inhibition of cholera-toxin-stimulated adenylate cyclase activity in both hepatocytes and the P9 immortalized hepatocyte cell line through an action involving protein kinase C

Incubation of hepatocytes or the SV40-DNA-immortalized hepatocyte P9 cell line with cholera toxin led to a time-dependent activation of adenylate cyclase activity, which occurred after a defined lag period. When added together with cholera toxin, each of the hormones insulin and vasopressin was capable of attenuating the maximum stimulatory effect achieved by cholera toxin over a period of 60 min through a process which could be blocked by the compounds staurosporine and chelerythrine. Attenuating effects on cholera-toxin-stimulated adenylate cyclase activity could also be elicited by using either the protein kinase C (PKC)-stimulating phorbol ester PMA (phorbol 12-myristate 13-acetate) or the protein phosphatase inhibitor okadaic acid. Alkaline phosphatase treatment of membranes reversed the inhibitory effect of PMA. Cholera toxin also stimulated the adenylate cyclase activity of intact CHO (Chinese-hamster ovary) and NIH-3T3 cells, but this activity was insensitive to the addition of PMA. Overexpression of various PKC isoforms in CHO cell lines did not confer sensitivity to inhibition by PMA upon cholera-toxin-stimulated adenylate cyclase activity. Rather, overexpression of the gamma isoform of PKC allowed PMA to stimulate adenylate cyclase activity in CHO cells. It is suggested that the PKC-mediated phosphorylation of a membrane protein attenuates cholera-toxin-stimulated adenylate cyclase activity in hepatocytes and P9 cells. The cellular selectivity of such an action may be due to the target for this inhibitory action of PKC being a particular isoform of adenylate cyclase which provides the major activity in hepatocytes and P9 cells, but not in either CHO or NIH-3T3 cells.

Characterization of the G protein coupling of a glucagon receptor to the KATP channel in insulin-secreting cells

The G-protein-mediated coupling of a glucagon receptor to ATP-dependent K channels--KATP--has been studied in insulin-secreting cells using the patch clamp technique. In excised outside-out patches, KATP channel activity was inhibited by low concentrations of glucagon (IC50 = 2.4 nM); the inhibitory effect vanished at concentrations greater than 50 nM. In cell-attached patches, inhibition by bath-applied glucagon was seen most often, although stimulation was observed in a few cases. A dual action of the hormone is proposed to resolve these apparently divergent results. In excised inside-out patches, KATP channel activity was inhibited by addition of beta gamma subunits purified from either erythrocyte or retina (IC50 = 50 pM and 1 nM, respectively). Subsequent exposure of the patch to alpha i or alpha o reversed this effect. In excised inside-out patches, increasing Mg2+ in the bath stimulated the channel activity between 0 and 0.5 nM, but blocked it at higher concentrations (IC50 = 2.55 mM). In most cases (70%), GTP had a stimulatory effect at concentrations up to 100 microns. However, in three cases, similar GTP levels had clear inhibitory effects. In excised inside-out patches, cholera toxin (CTX) caused channel inhibition. Although the effect could not be reversed by removal of the toxin, the activity was restored by subsequent addition of purified alpha i or alpha o. These results are compatible with a model whereby channel inhibition by activated Gs-coupled receptors occurs, at least in part, via association of the beta gamma subunits of Gs with alpha i/alpha o subunits and deactivation of the alpha i/alpha o-dependent stimulatory pathway. On the basis of this hypothesis, a model is developed to describe the effects of G proteins on the KATP channel, as well as to account for the concentration-dependent stimulation and inhibition of KATP channel by Mg2+. An interpretation of the ability of glucagon to potentiate, but not initiate, insulin release is also given in terms of this model and the effects of ATP on KATP channels.

Desensitization of alpha 1-, beta- and glucagon receptors in rat hepatocytes: influence of ageing

The alpha 1-agonist phenylephrine in hepatocytes from mature and senescent rats, and the beta-agonist isoproterenol in hepatocytes from senescent rats, elicited a time-dependent, homologous desensitization of alpha 1- and beta-receptor-mediated glycogenolysis respectively, which was maximal after 20 min of exposure to the agonists. Glucagon triggered desensitization of the glycogenolytic response to glucagon, isoproterenol and phenylephrine, which was maximal after less than 5 min; this was followed by resensitization of the glucagon response only. After 20 min of treatment with phenylephrine or isoproterenol, no change in cellular distribution of alpha 1- or beta-receptors was noticed, using sucrose gradient centrifugation. After a 1-h exposure to both agonists, a shift of both receptors to a light density fraction was found, reflecting receptor internalization. Neither the rate of functional desensitization, nor the degree of receptor internalization was altered upon ageing. We conclude that functional desensitization and internalization of adrenergic receptors in rat hepatocytes are separate events in time and are largely unaffected by the ageing process. Thus, despite the absence of a beta-receptor-mediated glycogenolytic response in hepatocytes from mature rats, isoproterenol triggers the internalization of beta-receptors.

Stimulatory and inhibitory effects of catecholamines on DNA synthesis in primary rat hepatocyte cultures: role of alpha 1- and beta-adrenergic mechanisms

Previous studies suggest that catecholamines may be involved in the regulation of liver growth. Considerable evidence implicates alpha 1-adrenergic mechanisms in the initiation of hepatocyte proliferation, while the role of beta-adrenoceptors is less clear. We have examined further the adrenergic regulation of hepatocyte DNA synthesis, using primary monolayer cultures. In hepatocytes that were also treated with epidermal growth factor and insulin, epinephrine or norepinephrine added early after the seeding strongly accelerated the rate of S phase entry. The beta-adrenergic agonist isoproterenol and the alpha-adrenergic agonist phenylephrine also stimulated the DNA synthesis, but were less efficient than epinephrine and norepinephrine. Experiments with the alpha 1-receptor blocker prazosine and the beta-receptor blocker timolol showed that the stimulatory effect of norepinephrine consisted of both an alpha 1- and a beta-adrenergic component. The alpha 1-component was most prominent in terms of maximal response at high concentrations of the agonist, but the beta-component contributed significantly and predominated at low concentrations (less than 0.1 microM) of norepinephrine. At later stages (about 40 h) of culturing norepinephrine strongly but reversibly inhibited the cells, acting at a point late in the G1 phase. This inhibition was mimicked by isoproterenol and abolished by timolol but was unaffected by prazosine, suggesting a beta-adrenoceptor-mediated effect. The results confirm the alpha 1-adrenoceptor-mediated stimulatory effect, but also show that beta-adrenoceptors may contribute to the growth stimulation by catecholamines. Furthermore, catecholamines, via beta-adrenoceptors and cyclic AMP, inhibit the G1-S transition, and may thus play a role in the termination of hepatic proliferation.

Treatment of intact hepatocytes with synthetic diacyl glycerols mimics the ability of glucagon to cause the desensitization of adenylate cyclase

Incubation of intact hepatocytes with either of the synthetic diacyl glycerols 1-oleoyl-2-acetyl glycerol (OAG) or dihexanoyl glycerol (DHG) caused the transient uncoupling of the ability of glucagon to stimulate adenylate cyclase in membranes prepared from those cells. No change occurred in either the activity of the catalytic unit of adenylate cyclase or the coupling of Gs to adenylate cyclase. Diacyl glycerol action appeared to mimic glucagon-mediated desensitization of adenylate cyclase, suggesting that protein kinase C activation may provide the molecular trigger for glucagon desensitization.

Okadaic acid identifies a phosphorylation/dephosphorylation cycle controlling the inhibitory guanine-nucleotide-binding regulatory protein Gi2

Recently, the alpha-subunit of the inhibitory guanine-nucleotide-binding protein Gi2 (alpha-Gi2) has been shown to be a substrate for phosphorylation both by protein kinase C and also by other unidentified kinase(s) which are activated as a result of elevated cyclic AMP levels in intact rat hepatocytes [Bushfield, Murphy, Lavan, Parker, Hruby, Milligan & Houslay (1990) Biochem. J. 268, 449-457]. Here we show that the incorporation of [32P]Pi into alpha-Gi2 was enhanced 3-fold by incubation of intact hepatocytes with the tumour promoter and protein phosphatase (1 and 2A) inhibitor, okadaic acid. This action was both time- and concentration-dependent and was accompanied by a loss of guanine-nucleotide-induced inhibition of adenylate cyclase. The increased labelling of alpha-Gi2 induced by okadaic acid was partially additive with that elicited by 8-bromo cyclic AMP, but not with that elicited by the protein kinase C activator phorbol 12-myristate 13-acetate. We suggest that, in the absence of hormones, the activity of alpha-Gi2 is under the control of a dynamic phosphorylation/dephosphorylation system involving protein kinase C and protein phosphatases 1 and/or 2A. This highlights the regulation of kinases and phosphatases as both providing potentially important mechanisms for causing 'cross-talk' between different signalling systems, in this instance controlling cellular responsiveness through regulation of alpha-Gi2 phosphorylation.

Glucagon-induced refractoriness of hepatocyte adenylate cyclase: comparison of homologous and heterologous components and evidence against a role of cAMP

Exposure of cultured hepatocytes to glucagon leads to a partial refractoriness of the adenylate cyclase both to glucagon (homologous desensitization) and to isoproterenol (heterologous desensitization). In contrast, isoproterenol produces a very strong homologous desensitization but almost no heterologous desensitization. The present study compared the pattern of the homologous and heterologous components of glucagon-induced desensitization in these cells, particularly during the first 4 hours, and examined the role of cyclic 3',5'-adenosine monophosphate (cAMP) in the mechanism of refractoriness development. The decrease in glucagon-sensitive and isoproterenol-sensitive adenylate cyclase activities were closely parallel with respect to the extent, the time course and the dose required. 8-Bromoadenosine 3',5'-monophosphate (8-Bromo-cAMP) also reduced the hormone-responsive adenylate cyclase activity, but this effect developed more slowly than the desensitization after glucagon treatment. No consistent relationship was found between cAMP levels and induction of hormone refractoriness when the cells were exposed to glucagon, isoproterenol, cholera toxin or forskolin. Furthermore, addition of 0.5 mM 3-isobutyl-1-methylxanthine) (IBMX) which strongly amplified the cAMP response, did not potentiate the glucagon-induced desensitization of either glucagon-sensitive or isoproterenol-sensitive adenylate cyclase activity. Taken together, the results suggest that homologous and heterologous desensitization of the adenylate cyclase developing after glucagon exposure occur by similar (agonist-non-specific) mechanisms which do not involve cAMP.

Glucagon desensitization of adenylate cyclase and stimulation of inositol phospholipid metabolism does not involve the inhibitory guanine nucleotide regulatory protein Gi, which is inactivated upon challenge of hepatocytes with glucagon

Brief exposure of hepatocytes to glucagon, angiotensin or the protein kinase C activator TPA (12-O-tetradecanoylphorbol 13-acetate) caused the inactivation of the inhibitory guanine nucleotide regulatory protein Gi. Glucagon-mediated desensitization of glucagon-stimulated adenylate cyclase activity was seen in hepatocytes from both normal rats and those made diabetic with streptozotocin, where Gi is not functionally expressed. Normal glucagon desensitization was seen in hepatocytes from young animals, 6 weeks of age, which had amounts of Gi in their hepatocyte membranes which were some 45% of that seen in mature animals (3.4 pmol/mg of plasma-membrane protein). Streptozotocin-induced diabetes in young animals abolished the appearance of functional Gi in hepatocyte plasma membranes. Pertussis-toxin treatment of hepatocytes from both normal mature animals and those made diabetic, with streptozotocin, blocked the ability of glucagon or angiotensin or TPA to elicit desensitization of adenylate cyclase. The isolated B (binding)-subunit of pertussis toxin was ineffective in blocking desensitization. Neither induction of diabetes nor treatment of hepatocytes with pertussis toxin inhibited the ability of glucagon and angiotensin to stimulate the production of inositol phosphates in intact hepatocytes. Thus (i) Gi does not appear to play a role in the molecular mechanism of glucagon desensitization in hepatocytes, (ii) the G-protein concerned with receptor-stimulated inositol phospholipid metabolism in hepatocytes appears not to be a substrate for the action of pertussis toxin, (iii) in intact hepatocytes, treatment with glucagon and/or angiotensin can elicit the inactivation of the inhibitory G-protein Gi, and (iv) pertussis toxin blocks desensitization by a process which does not involve Gi.