Effects of skyrin, a receptor-selective glucagon antagonist, in rat and human hepatocytes.

Peptidic glucagon antagonists have been shown to lower blood glucose levels in diabetic models (1-3), but attempts to identify small molecular weight glucagon receptor-binding antagonists have met with little success. Skyrin, a fungal bisanthroquinone, exhibits functional glucagon antagonism by uncoupling the glucagon receptor from adenylate cyclase activation in rat liver membranes (1). We have examined the effects of skyrin on cells transfected with the human glucagon receptor and on isolated rat and human hepatocytes. The skyrin used was isolated from Talaromyces wortmanni American Type Culture Collection 10517. In rat hepatocytes, skyrin (30 micromol/l) inhibited glucagon-stimulated cAMP production (53%) and glucose output (IC50 56 micromol/l). There was no detectable effect on epinephrine or glucagon-like peptide 1 (GLP-1) stimulation of these parameters, which demonstrates skyrin's selective activity. Skyrin was also evaluated in primary cultures of human hepatocytes. Unlike cell lines, which are largely unresponsive to glucagon, primary human hepatocytes exhibited glucagon-dependent cAMP production for 14 days in culture (EC50 10 nmol/l). Skyrin (10 micromol/l) markedly reduced glucagon-stimulated cAMP production (55%) and glycogenolysis (27%) in human hepatocytes. The inhibition of glucagon stimulation was a specific property displayed by skyrin and oxyskyrin but not shared by other bisanthroquinones. Skyrin is the first small molecular weight nonpeptidic agent demonstrated to interfere with the coupling of glucagon to adenylate cyclase independent of binding to the glucagon receptor. The data presented in this study indicate that functional uncoupling of the human glucagon receptor from cAMP production results in metabolic effects that could reduce hepatocyte glucose production and hence alleviate diabetic hyperglycemia.

Plasma glucose levels are reduced in rats and mice treated with an inhibitor of glucose-6-phosphate translocase.

The activity of glucose-6-phosphatase (G-6-Pase) in isolated rat microsomes was inhibited by a new selective inhibitor of the multi-subunit G-6-Pase system, 1-[2-(4-chloro-phenyl)-cyclopropylmethoxy]-3,4-dihydroxy-5-(3-imid azo[4,5-b]pyridin-1-yl-3-phenyl-acryloyloxy)-cyclohexanecarboxylic acid (compound A) with a 50% inhibitory concentration (IC50) of approximately 10 nmol/l. Compound A (500 nmol/l) inhibited the uptake of [14C]glucose-6-phosphate (G-6-P) into intact isolated rat microsomes, confirming that this agent blocks G-6-P translocation, as suggested by previous studies using intact and permeabilized microsomes. The inhibition of microsomal G-6-P transport by compound A was associated with inhibition of the rate of glucose output from rat hepatocytes incubated in the presence of 25 nmol/l glucagon (IC50 approximately 320 nmol/l.) Compound A (1 micromol/l) also inhibited the basal rate of glucose production by rat hepatocytes by 47%. Intraperitoneal administration of compound A to fasted mice lowered circulating plasma glucose concentrations dose-dependently at doses as low as 1 mg/kg. This effect was comparatively short-lived; glucose lowering was maximal at 30 min after dosing with 100 mg/kg compound A (-71%) and declined thereafter, being reversed within 3 h. A similar time course of glycemic response was observed in fasted rats; glucose lowering was maximal 30 min after dosing with 100 mg/kg compound A (-36%) and declined until the effect was fully reversed by 3 h postdose. In rats subjected to compound A treatment, liver glycogen content was increased. G-6-P and lactate levels were maximally elevated 30 min after dosing and declined thereafter. Cumulatively, these results suggest that the mechanism of glucose lowering by compound A was via inhibition of G-6-Pase activity, mediated through inhibition of the T1 subunit of the microsomal G-6-Pase enzyme system. Drug levels measured over the same time course as that used to assess in vivo efficacy peaked within 30 min of administration, then declined, which is consistent with the transient changes in plasma glucose and liver metabolites.