Coupled induction of exocrine proteins and intracellular compartments involved in the secretory pathway in AR4-2J cells by glucocorticoids.

Treatment of AR4-2J cells with dexamethasone at 10 nM for 96 h inhibited cell replication by 75% and increased cell size (30%), protein content (1.6-fold) and protein synthesis (2-fold). The increase in protein synthesis was largely due to a 5 to 10-fold increase in the synthesis of secretory proteins. Amylase activity increased 20 to 30-fold in cellular homogenates and 10 to 20-fold in culture medium. Both in the presence and absence of dexamethasone AR4-2J cells release their secretory proteins by constitutive secretion. The proportion of newly synthesized amylase retained by the cells over the 14 h labeling period increased from 15 to 30% with hormone treatment. As judged by comigration on polyacrylamide gels and Western blots analyzed by immunospecific sera, AR4-2J cells synthesize and secrete the majority of known pancreatic secretory proteins. Dexamethasone increased the synthesis of trypsinogen 12 to 16-fold, chymotrypsinogen 4.5 to 6-fold, the group of procarboxypeptidases 6-fold, and amylase 7 to 10-fold. Messenger RNA levels for trypsinogen, amylase and lipase were each increased 4 to 5-fold. At the ultrastructural level dexamethasone led to significant increases in rough endoplasmic reticulum (RER) (30-fold) and Golgi elements (1.5-fold) and to the de novo appearance of electron-opaque granules (0.1-0.5 microns) which were shown to contain amylase by immunolocalization techniques employing protein A-gold. Dexamethasone also led to the formation of gap junctions between AR4-2J cells. These findings indicate that AR4-2J cells provide a model for differentiation of pancreatic acinar cells which should also be studied for the differentiation markers for the regulated secretory pathway.