Small (10 residue) C-terminal deletions of PBP5 cause release of this inner membrane protein into the periplasm, indicating disruption of the membrane binding domain. To define the extent of the membrane anchoring domain, oligonucleotide-directed mutagenesis was used to introduce both single amino acid changes and novel restriction sites into the DNA, allowing subsequent construction of precise internal deletions. The 10 C-terminal amino acid residues possess very weak membrane anchoring potential. By extending the sequence to 18 residues membrane binding equivalent to that of authentic PBP5 was achieved. A proline substitution in this region, breaking a potential alpha-helix, also disrupts the membrane binding domain. These results are discussed with respect to the amphiphilicity of the C-terminal sequence when arranged in an alpha-helix.
Penicillin‐binding protein 5 (PBP5) has been previously identified as a component of the inner membrane of Escherichia coli and we present here further evidence that PBP5 is tightly bound to the membrane. To investigate the regions of PBP5 involved in membrane binding we have constructed a series of C‐terminal deletions and shown that the removal of as few as 10 amino acids results in the release of the truncated protein into the periplasm. The C terminus, therefore, appears to be important for interaction with the membrane; however, inspection of the amino acid sequence does not reveal extended runs of hydrophobicity typical of a membrane anchor. Thus we conclude that PBP5 is anchored to the inner membrane by a mechanism not previously described.
Internal deletions close to the C-terminus of the Escherichia coli penicillin binding protein 5 (PBP5, DacA) have defined the C-terminal 18 residues of the protein as essential for membrane binding. This C-terminal sequence is capable of forming a strongly amphiphilic alpha-helix. In this paper we show that the PBP5 amphiphilic helix is able to anchor the periplasmic TEM-beta-lactamase to the inner membrane. In addition, we have demonstrated that mature PBP5 (lacking the N-terminal signal sequence) possesses the ability to bind to the membrane from a soluble form of the protein, showing that translocation across the membrane is unnecessary for anchoring to be established.
To test the importance of N‐terminal pre‐sequences in translocation of different classes of membrane proteins, we exchanged the normal signal sequence of an Escherichia coli outer membrane protein, OmpF, for the pre‐sequence of the inner membrane protein, DacA. The DacA‐OmpF hybrid was efficiently assembled into the outer membrane in a functionally active form. Thus the pre‐sequence of DacA, despite its relatively low hydrophobicity compared with that of OmpF, contains all the essential information necessary to initiate the translocation of OmpF to the outer membrane. Since processing of DacA was also shown to be dependent upon SecA we conclude that the initiation of translocation of this inner membrane polypeptide across the envelope occurs by the same mechanism as outer membrane and periplasmic proteins. The N‐terminal 11 amino acids of mature OmpF, which in the hybrid are replaced by the N‐terminal nine amino acids of DacA, carry no essential assembly signals since the hybrid protein is apparently assembled with equal efficiency to OmpF.
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