Calcium-dependent hormonal regulation of amino acid transport and cyclic AMP accumulation in rat hepatocyte monolayer cultures.

The effect of glucagon, epinephrine, norepinephrine, dexamethasone, insulin, and dexamethasone plus glucagon on the transport of 2-aminoisobutyric acid (AIB) and that of glucagon on the production of cyclic AMP were examined in rat hepatocyte monolayer cultures under three different culture conditions involving calcium. The hepatocytes were studied in calcium-contaning medium after treatment with or without 0.033% dimethyl sulfoxide, the solvent for the calcium ionophore A23187 (calcium controls); calcium-free medium after treatment with A23187 (calcium-depleted); and calcium-containing medium after treatment with ionophore (calcium-restored). The basal and hormonally regulated rates of AIB transport for hepatocytes in calcium control and calcium-depleted cultures were comparable. The restoration of calcium in calcium-restored cultures increased the basal and the hormonally stimulated transport of AIB when compared to the other conditions. Calcium markedly enhanced the stimulation of AIB transport in cultures treated with glucagon, catecholamines, and dexamethasone plus glucagon. The level of cyclic AMP production in response to glucagon in calcium control and calcium-depleted cultures was the same and it was conspicuously higher than the level in calcium-restored cultures. Varying the concentration of calcium in the medium used to maintain the hepatocytes in calcium control cultures did not affect the stimulation of AIB transport or cyclic AMP production by glucagon. However, in calcium-restored cultures, increasing the calcium concentration of the medium resulted in increased stimulation of AIB transport and decreased production of cyclic AMP by glucagon. In the calcium-restored cultures, calcium in the absence of glucagon enhanced AIB transport but had no effect on cyclic AMP production. Cultures maintained for 6 hr in calcium-free medium after the depletion of calcium showed a 6- to 7-fold increase in the production of cyclic AMP in response to glucagon, but no stimulation of AIB transport. We suggest that mobilization of cellular calcium by glucagon either directly or through cyclic AMP mediates its stimulation of amino acid transport.