Role of acidic subcellular compartments in the degradation of internalized insulin and in the recycling of the internalized insulin receptor in liver cells: in vivo and in vitro studies.

Upon interaction with liver cells, insulin is internalized along with its receptor into nonlysosomal endocytic structures termed endosomes. In this work, the biochemical evidence supporting the role of endosomal acidity in the degradation of internalized insulin and in the recycling of the internalized insulin receptor is described. Treatment of rats by chloroquine and/or quinacrine, two acidotropic drugs, increases by 5-10 fold the amount of endogenous insulin associated with endosomal fractions and, in rats injected by 125I-labeled or native insulin, the endosomal uptake of these ligands at late times after injection. With 125I-insulin, these drugs inhibit the degradation of internalized hormone as judged on physical, biological and immunological criteria. Chloroquine and quinacrine treatment also increases the insulin receptor content of endosomal fractions and, in rats injected by native insulin, the ligand-induced accumulation of receptors in endosomal fractions at late times after injection. Subfractionation of endosomal fractions on Percoll gradients shows that chloroquine treatment shifts the distribution of both insulin and the insulin receptor towards higher densities, the receptor shift being slightly more pronounced in insulin-injected rats. Incubation of isolated endosomes containing internalized insulin at 30-37 degrees C results in a rapid degradation of this ligand, with a maximal at pH 5-6. Addition of ATP, by decreasing the endosomal pH, stimulates insulin degradation above pH 7, whereas addition of chloroquine and quinacrine, by elevating endosomal pH, exerts opposite effects. These data indicate that endosomal acidity is required for optimum degradation of internalized insulin within endosomes and recycling of the internalized receptor.