13-Lactamase with the -20 to -1 region of the leader peptide deleted (almost complete deletion of the leader peptide) [A(-20,-1) 13-lactamasel was released from Escherichia coli cells by osmotic shock. Fractionation of the cells by conversion to spheroplasts and protease accessibility experiments further indicated that a portion of the protein may be bound to the cytoplasmic membrane and be partially exposed in the periplasmic space.Expression of A(-20,-1) ,-lactamase conferred a 25-fold increase in the 50%o lethal dose for ampicillin relative to that for controls, thus confirming that a small amount (about 2%) of the active protein is completely exported from the cytoplasm. These results suggest that even in the absence of a leader peptide, mature 13-lactamase is able to interact with the cytoplasmic membrane and be translocated into the periplasmic space, albeit with a low efficiency.Essentially all exported proteins in Escherichia coli are synthesized as precursors containing a leader peptide (22,25,28). The most important function of the leader peptide is probably to maintain the precursor in an export-competent conformation, a process which is facilitated by interactions with chaperonins. According to the kinetic competition model suggested by Pugsley (20) and elaborated by Hardy and Randall (10), protein precursors destined for secretion are able to bind to chaperonins, such as GroEL and SecB, partly because they exhibit slower folding kinetics. Cytoplasmic proteins, on the other hand, reach their native state much more rapidly and do not have an opportunity to enter the export pathway.Certain mature proteins expressed without a leader peptide and a few bona fide cytoplasmic polypeptides are found together with periplasmic components following cell fractionation by osmotic shock. Proteins which appear in the osmotic shock fraction in the absence of a leader peptide include Vitreoscilla hemoglobin, human proapolipoprotein, and mouse interleukin-13 expressed in E. coli and the native cytoplasmic proteins thioredoxin and elongation factor Tu (2,11,13,23). Even though cell fractionation techniques, particularly osmotic shock, are prone to artifacts (18), it is conceivable that the unexpected fractionation behavior of the above proteins stems from their atypical localization within the cell. For example, there is evidence that thioredoxin is found predominantly in adhesion sites between the inner and outer membranes (2).In this report, we show that P-lactamase expressed without a functional leader peptide is found associated with the cytoplasmic membrane and the periplasmic fraction, provided that the cells are grown under conditions which prevent "trapping" of the protein within cytoplasmic inclusion bod- 3-Lactamase in the osmotic shock fraction and in the lysed cells was measured as described previously (24). The sum of activities obtained after cell fractionation agreed, within 10%, with the values determined from assays of total-cell lysates. In all experiments, the release of ,B-galactosidase activity (...
