Adrenergic regulation of glycogenolysis in rat liver after cholestasis. Modulation of the balance between alpha 1 and beta 2 receptors.

The effects of extrahepatic cholestasis upon adrenergic regulation of glycogenolysis and upon the numbers of adrenoceptors in rat liver were studied using isolated hepatocytes and plasma membranes, respectively. A 60% decrease in the number of alpha 1 adrenoceptors (285 vs. 680 fmol/mg protein) and a simultaneous 2.7-fold increase in the number of beta adrenergic sites (67 vs. 25 fmol/mg protein) were observed beginning 36 h after bile flow obstruction and persisted for at least 68 h. The reciprocal modification of the numbers of alpha 1 and beta adrenoceptors was accompanied by a change in the manner of stimulation of glycogen phosphorylase by catecholamines in hepatocytes; originally alpha 1 adrenergic in normal rats (phenylephrine Ka = 0.9 microM, isoproterenol Ka = 7.1 microM), the stimulation became predominantly beta adrenergic in cholestatic animals (phenylephrine Ka = 3.7 microM, isoproterenol Ka = 0.06 microM). In normal rats, activation of the enzyme by epinephrine was inhibited by the alpha blocker phentolamine, without inhibition by the beta blocker propranolol. In contrast, propranolol was more effective than phentolamine in cholestatic rat hepatocytes. Modification of the regulation of glycogenolysis after cholestasis did not seem to be secondary to an alteration in the metabolism of thyroid hormones or in the action of glucocorticoids. However, cholestasis provoked a 10-fold increase in the number of hepatic mitoses and in the incorporation of thymidine into liver DNA of cholestatic animals. Similar changes were observed in regenerating livers, following two-thirds hepatectomy. We propose that the changes following extrahepatic cholestasis might, as well, be explained by a regenerative process.

The hormonal induction of gamma glutamyltransferase in rat liver and in a hepatoma cell line.

Gamma glutamyltransferase (GGT) is a membrane-bound enzyme that is involved in glutathione metabolism and aminoacids uptake. GGT activity is stimulated by a number of hormones and pharmacological agents in certain animal tissues. In rat liver, adrenalectomy causes a 2-fold decrease in GGT activity and hydrocortisone treatment of adrenalectomized animals specifically stimulates this enzyme activity. In a highly differentiated hepatoma cell line, Fao, GGT activity is similar to rat liver and is under glucocorticoids control. These hormones specifically stimulate GGT activity (2- to 3-fold). Translation and transcription inhibitors prevent the hormonal effect. The stimulation of GGT activity is therefore probably due to an increase in GGT mRNA synthesis. The results reported suggest that the Fao cell line is a very convenient system for the study of the molecular mechanisms of both the glucocorticoid effects on differentiated cells as well as the modulation of membrane-bound enzymes biosynthesis.

Glucocorticoid hormones increase the activity of gamma-glutamyltransferase in a highly differentiated hepatoma cell line.

Gamma-Glutamyltransferase activity was detected in the plasma membrane of the highly differentiated hepatoma cell line Fao, (0.93 mU/mg cell protein). Dexamethasone (1 microM) provoked a 2-3-fold increase in the activity of the enzyme in the presence of fetal calf serum. Maximal induction occurred 48-72 h after addition of the glucocorticoid to the cell culture medium. The hormonal specificity was demonstrated by the relative potencies of several glucocorticoids and sex steroids: hydrocortisone and corticosterone increased gamma-glutamyltransferase activity while tetrahydrocorticosterone and all sex steroids tested were ineffective. The effect of dexamethasone on gamma-glutamyltransferase activity wa specific since the activities of several other plasma membrane enzymes were not modified. The mechanism of the dexamethasone-induced increase in gamma-glutamyltransferase activity was neither by modification of the affinity of the enzyme for its substrates nor by alteration of the subcellular distribution of the enzyme. This increase was prevented by cycloheximide and actinomycin D. The data presented are consistent with a specific glucocorticoid receptor-mediated induction of gamma-glutamyltransferase activity in Fao cells. The kinetic parameters of the induction process by glucocorticoids are very similar to those found in adult rat liver. These results suggest that the Fao cell line is a very convenient system for the study of the molecular mechanisms of glucocorticoid effects on differentiated cells.

In vivo modulation of rat hepatic gamma-glutamyltransferase activity by glucocorticoids.

The gamma-glutamyltransferase (gamma-GT) activity decreased by 50% following adrenalectomy of female rats, in homogenate as well as in a purified plasma membrane preparation from liver. In contrast, such a variation was not found in the kidney. None of 3 other enzyme activities of the plasma membrane, namely 5'-nucleotidase, alkaline phosphatase, and alkaline phosphodiesterase I, was decreased by adrenalectomy. Administration of hydrocortisone (5 mg/100 g body weight) resulted in a 2.6-fold increase in hepatic gamma-GT activity from adrenalectomized rats. The hydrocortisone-mediated stimulation of gamma-GT activity was dose- and time-dependent. The 5'-nucleotidase and leucine aminopeptidase activities were not modified by the hydrocortisone treatment. The activity of gamma-GT was mainly associated with nuclear fractions (nuclei and plasma membranes) obtained from liver homogenates of either control, adrenalectomized or adrenalectomized hydrocortisone-treated animals, and this activity was purified 18-fold in a plasma-membrane preparation as compared to homogenate. These data suggest that adrenalectomy and conversely hydrocortisone treatment modulate specifically the hepatic plasma-membrane gamma-GT activity. This represents one of the first demonstrations of a specific modulation by glucocorticoids of an enzyme activity typical of the plasma membrane.

[Role of guanidylic nucleotides in the adenylate cyclase activity of the rat liver]. / Rôle des nucléotides guanidyliques dans l'activité adénylate cyclasique du foie de rat

Glucagon and adrenaline exert their action upon the liver via the cyclic AMP synthetizing system located in the plasma membrane. The enzyme adenylate cyclase is further regulated by guanyl nucleotides. It has been recently shown that the rat liver plasma membrane system could respond to GTP by simultaneous increase in the cyclase activity in response to glucagon and by the dissociation of this hormone from its binding sites (1). Unambiguous relationship between the activating effect of GTP upon the cyclase and its action upon glucagon binding has not been determined yet (2). This problem was approached using the in vitro action of epinephrine as a model. When 1 to 100 muM GTP or DGP were added to rat liver plasma membranes isolated from adrenalectomized animals, they increased markedly the response of the cyclase system to epinephrine. These effects could be observed in the absence of an ATP-regenerating system and were mimicked by 5'-guanylyl diphosphonate; GTP and GDP were the most active compounds followed by ITP, CTP and by a series of guanyl derivatives. UTP, as well as guanosine, GMP, cyclic GMP and ppGpp were inactive. Guanyl nucleotides did not increase the affinity of the cyclase system for the activating hormones, but enhanced the affinity for ATP-Mg and also the Vmax of the reaction. Finally, GTP, ATP, CTP, UTP but not GDP displaced epinephrine bound to plasma membranes by a mere chelation phenomenon. It is concluded that 1) guanyl nucleotides do not act primarily by influencing the binding of hormones to the membranes; 2) they act directly upon the catalytic subunit of the cyclase; 3) the low concentrations of GTP required for its action strongly suggest that this nucleotide plays a role in the physiological regulation of the intrahepatic cyclic AMP level.