The initial lag phase of insulin action on glucose transport in adipocytes reflects an unknown process that couples receptor binding and glucose transport activity. The influence of temperature, cellular ATP, cyclic AMP, and calcium on this process and a possible relation to internalization of insulin were studied. The Arrhenius plot of the coupling shows a break in slope at 30 degrees C; the activation energy below 30 degrees C is 17.5 kcal/mol. Reduction of cellular ATP by 70% prolongs the coupling process; initial binding and final maximal response of the glucose transport remain unaffected. Further reduction of ATP (greater than 90%) before addition of insulin abolishes the coupling completely. Reduction of ATP at different time points after addition of insulin blocks further activation; however, the actual state of activity is preserved. Calcium depletion by EDTA prolongs the coupling and decreases the maximal response. Internalization of insulin as determined in chloroquine-treated cells begins later than transport activation and is in contrast to transport activation not observable at 15 degrees C. In conclusion, the coupling is not related to internalization; it is ATP-dependent, whereas the initial binding and the activated transport system are ATP-independent. Calcium but not cyclic AMP might be second messenger or cofactor in the coupling process.
Kinetics of association and dissociation of 125I-insulin and of activation and deactivation of 3-O-methylglucose transport were determined in isolated rat fat cells. Equilibrium bound insulin (7.5, 25, 100 microunits/ml) dissociated with a t1/2 of 2 min (100 microunits/ml), 4 min (25 microunits/ml), and 16 min (7.5 microunits/ml). Consecutive deactivation of transport is observed only in the presence of glucose (1 mM); the t1/2 of deactivation is approximately 60 min (100 and 25 microunits/ml) and 20 min (7.5 microunits/ml). At 15 degrees C, the t1/2 of dissociation (7.5 microunits/ml) is 25 min, and deactivation is not observed. Addition of dithioerythritol (5 mM) during the association of insulin decreased the binding rapidly; however, a reduced insulin effect was only seen if the binding decreased during the early activation phase of transport. In conclusion, the maintenance of the insulin effect on transport does not require persistent receptor occupancy; dissociation and deactivation are, with respect to kinetics, temperature dependency and requirement of glucose, independent processes. Receptor occupancy probably only controls the activation of transport; deactivation seems to be controlled by postreceptor processes.
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