For the first time, the standard free energy change, delta Gzero, of a membrane-inserting protein with a leader sequence has been determined experimentally, using M13 procoat protein as an example. The partition coefficient for the distribution of the procoat protein between the aqueous phase and the membrane phase of preformed lipid vesicles yielded a value of gamma = 6.5 x 10(5) M-1, corresponding to a delta Gzero of -10.4 kcal/mol, based on measurements of the fluorescence energy transfer between the intrinsic tryptophan of the protein and a suitably labeled lipid membrane of POPC. For comparison, the partition coefficient of the M13 coat protein between the aqueous and the POPC lipid bilayer phase was determined to be distinctly lower: gamma = 1 x 10(5) M-1 (delta Gzero = -9.3 kcal/mol). Proteinase K digestion experiments have been performed, showing that 20% of the procoat protein bound to lipid vesicles spontaneously integrate in a transbilayer form, whereas 80% remain inserted in the interfacial membrane region. By taking together these results, an upper limit for the free energy change of the transmembrane insertion of procoat protein was estimated to be -14.8 kcal/mol. In order to distinguish further the contribution arising from insertion of the procoat protein into the membrane interfacial region from that due to transmembrane insertion, the partition coefficient of the mutant procoat protein OM30R [which contains a positively charged amino acid in its mature hydrophobic segment (exchange of a Val to an Arg residue at position 30)] was determined, yielding gamma = 0.3 x 10(5) M-1 (delta Gzero = -8.6 kcal/mol). Previously reported in vivo experiments have shown that the OM30R mutant protein is not translocated across Escherichia coli membranes but only binds to the inner surface. The results presented here indicate that although the insertion of the procoat protein into the interfacial region of the lipid bilayer contributes the major part to delta Gzero, it is the final energy gain of the interaction of the hydrophobic portions of the folded pre-protein with the lipid chains which drives the transmembrane insertion of the M13 procoat protein. Neither the leader sequence nor the mature coat protein alone yields this free energy gain. For the different proteins investigated here, spontaneous membrane insertion occurs only for fluid lipid bilayers, but not for membranes in the crystalline lipid phase. Furthermore, by using lipid bilayers with negative membrane surface charges, it was shown that both procoat and coat proteins are electrostatically attracted to the surface of the lipid membrane, though only to a small extent, with apparent partition coefficients of the same order of magnitude as for the phosphatidylcholine lipid membrane.
Bacteriophage M13 procoat protein is synthesized on free polysomes prior to its assembly into the inner membrane of Escherichia coli. As an initial step of the membrane insertion pathway, the precursor protein interacts with the cytoplasmic face of the inner membrane. We have used oligonucleotide‐directed mutagenesis to study the regions of the procoat protein involved in membrane binding. We find that there is an absolute requirement for positively charged amino acids at both ends of the protein. Replacing these with negatively charged residues resulted in an accumulation of the precursor in the cytoplasm. We propose that the positively charged amino acids are directly involved in membrane binding, possibly directly to the negatively charged phospholipid head groups. This was tested in vitro with artificial liposomes. Whereas wild‐type procoat interacted with these liposomes, we found that procoat mutants with negatively charged amino acids at both ends did not bind. Therefore, we conclude that newly synthesized M13 procoat protein binds electrostatically to the negatively charged inner membrane of E. coli.
M13 procoat protein has two hydrophobic domains, one in the leader peptide and one which anchors the mature coat protein in the membrane. Disruption of the membrane anchor region by insertion of arginyl residues does not yield periplasmic coat protein. Instead, the rate of membrane assembly is slowed greater than 100‐fold (t1/2 less than 5 s for wild‐type, t1/2 greater than 10 min for mutant). The hydrophobic region of mature coat protein not only functions as a membrane anchor, but has an important role in the membrane assembly process per se.
The M13 phage Procoat protein is one of the best characterized substrates for the novel YidC pathway. It inserts into the membrane independent of the SecYEG complex but requires the 60 kDa YidC protein. Mutant Procoat proteins with alterations in the periplasmic region had been found to require SecYEG and YidC. In this report, we show that the membrane insertion of these mutants also strongly depends on SecDF that bridges SecYEG to YidC. In a cold-sensitive mutant of YidC, the Sec-dependent function of YidC is strongly impaired. We find that specifically the SecDF-dependent mutants are inhibited in the cold-sensitive YidC strain. Finally, we find that subtle changes in the periplasmic loop such as the number and location of negatively charged residues and the length of the periplasmic loop can make the Procoat strictly Sec-dependent. In addition, we successfully converted Sec-independent Pf3 coat into a Sec-dependent protein by changing the location of a negatively charged residue in the periplasmic tail. Protease mapping of Pf3 coat shows that the insertion-arrested proteins that accumulate in the YidC- or in the SecDF-deficient strains are not translocated. Taken together, the data suggest that the Sec-dependent mutants insert at the interface of YidC and the translocon with SecDF assisting in the translocation step in vivo.
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