AI Article Synopsis
- GP-2, a major glycoprotein in pancreatic zymogen granule membranes, is released from acinar cells and is initially synthesized as a larger membrane-bound form (80,000 Mr) that is later processed to a smaller soluble form (75,000 Mr).
- The conversion of GP-2 from membrane-bound to soluble occurs over time, with its detachment from the membrane observed at various stages of the process.
- Immunocytochemical studies confirm the presence of GP-2 on zymogen granule membranes, plasma membranes, and within the acinar lumen, indicating its role in secretion from pancreatic cells.
Article Abstract
The major glycoprotein of pancreatic zymogen granule membranes (GP-2) was detected in the medium of acinar cell suspensions from rat pancreas. Its release from the cells was studied in pulse-chase metabolic labeling experiments with radioactive methionine. GP-2 (apparent Mr = 80 000) was found to be processed to a form of slightly lower apparent Mr (75 000) after about 4 h chase. At about the same time this smaller form of GP-2 appeared in the medium. These results are in accordance with earlier findings in vivo. At different chase times acinar cells were extracted with Triton X-114 to separate water-soluble proteins from membrane-associated (hydrophobic) proteins. This experiment showed that GP-2 is slowly converted from a membrane-bound glycoprotein to a soluble glycoprotein after its reduction in apparent molecular mass, causing its detachment from the membrane. Further analysis indicated that the detachment process may occur at the zymogen granule membrane as well as the plasma membrane. Immunocytochemistry on ultrathin cryosections of pancreatic tissue showed that GP-2 is localized on zymogen granule membranes, plasma membranes and in the acinar lumen. Although in much smaller quantities, GP-2 is also present in the granule content. Thus, in summary, GP-2 is synthesized as a true membrane glycoprotein which is gradually processed to a soluble species and is found in the secretion.
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