Two methods of polyacrylamide gel electrophoresis (the acid method of Eytan and Ohad and the Na dodecylsulfate (SDS) disc method of Maizel) have been used for analyzing the proteins of gel fractions isolated from the guinea pig pancreatic exocrine cells and in particular the proteins bound to the membranes involved in the synthesis, intracellular transport, and discharge of secretory enzymes: rough (RM) and smooth microsome (SM) membranes, zymogen granule (ZG) membranes, and plasma membranes (PM). Since in the two systems the electrophoretic mobility of proteins depends on different factors (size, shape, and net charge of molecules in the acid system; size only in the SDS system) a deeper insight into the protein composition of the fractions could be obtained. The gel patterns of RM, SM, and ZG membranes turned out to be accounted for mainly by segregated secretory enzymes (in rough microsomes also by ribosome proteins) and thus were found to share most of the bands. In contrast, with highly purified membrane fractions different patterns were obtained: RM and SM membrane proteins turn out to contain a large number of different proteins with molecular weights varying between ∼150,000 and 15,000 daltons. The pattern of ZG membranes was greatly different in the two systems: only two bands were separated by the acid method and as many as 23 by the SDS method. PM gave a rather complex pattern in either system. Both ZG membranes and PM were found to contain a large proportion of low molecular weight proteins. Nothing appears in common between the proteins of SM membranes (primarily of Golgi origin) and those of ZG membranes, while the latter and PM exhibit a certain degree of similarity. By amino acid analysis we found only slight differences: relative to the other fractions: RM membranes were higher in basic amino acids and ZG membranes contained a larger amount of methionine. Taken together with recent data on lipid composition and enzyme activities of the same fractions, these results indicate that the membranes of the pancreatic exocrine cells are chemically and functionally distinct, and hence do not mix randomly with one another during the transport of secretory products.

Several mechanisms have been suggested to explain how secretory cells remove from the plasmalemma the excess membrane resulting from the insertion of granule membrane during exocytosis: intact patches of membrane may be internalized and then reutilized within the cell; alternatively these membranes may be either disassembled to subunits or degraded. In the latter case new membranes should be synthetized at other sites of the cell, probably in the rough-surfaced endoplasmic reticulum (RER) and the Golgi complex. In the present research, membrane subfractions were obtained from rough microsomes (derived from fragmented and resealed RER cisternae) and from smooth microsomes (primarily contributed by Golgi stacks and vesicles) of the guinea pig pancreas by incubation at 4°C for 4 hr in 0.0005 M puromycin at high ionic strength followed by mild (pH 7.8) alkaline extraction with 0.2 M NaHCO 3 . Such treatments release the majority of nonmembrane components of both microsomal fractions (i.e., contained secretory enzymes, ribosomes, and absorbed proteins of the cell sap) and allow the membranes to be recovered by centrifugation. The effect of in vitro stimulation of enzyme secretion (brought about in pancreas slices by 0.0001 M carbamoyl choline) on the rate of synthesis of the phospholipid (PLP) and protein of these membranes was then investigated. In agreement with previous data, we observed that in stimulated slices the synthesis of microsomal PLP was greatly increased. In contrast, the synthesis of microsomal membrane proteins was unchanged. These results suggest that exocytosis is not coupled with an increased rate of synthesis of complete ER and Golgi membranes and are, therefore, consistent with the view that excess plasma membrane is preserved and reutilized, either as discrete membrane patches or as membrane macromolecules, throughout the secretory cycle.