Abstract
The ability of microsomal membranes to translocate nascent presecretory proteins across their lipid bilayer into the intravesicular space was investigated by using trypsin as a proteolytic probe. We found that under defined conditions trypsin is able to dissect the translocation activity of microsomal membranes into components that can be separated into two fractions, one soluble and the other membrane bound. The trypsinized membrane fraction has lost its translocation activity. Addition of the trypsin-generated soluble fraction, however, results in reconstitution of translocation activity. These results are compatible with the notion proposed in the signal hypothesis that the translocation activity of the microsomal membrane resides in transmembrane protein(s). We propose that trypsin effects solubilization from the membrane of cytosol-exposed domain(s) involved in recognition of the signal sequence or ribosome or both, leaving behind membrane-integrated domain(s) that provide the environment for the passage of the nascent chain across the membrane. Signal peptidase activity was unaffected by trypsinization of microsomal vesicles consistent with a localization of the active site of this enzyme on the cisternal side of the vesicles.