Dicarboxylic acid transport in Escherichia coli K12: involvement of a binding protein in the translocation of dicarboxylic acids across the outer membrane of the cell envelope.

We have previously found that the dicarboxylate transport system in Escherichia coli K12 is an active transport system and that at least one binding protein and two cytoplasmic membrane transport components are involved in the uptake of dicarboxylic acids. Recently, through surface labelling studies, some dicarboxylate binding proteins were found to be exposed on the cell surface. In the present paper, we demonstrate that the dicarboxylate transport component located in the outer membrane can be inactivated by two different kinds of nonpenetrating inhibitors, viz. proteases, and diazosulfanilic acid. These inhibitors seem to act on the dicarboxylate binding protein. By adding this protein to inactivated cells or to transport-negative mutants, we have succeeded in reconstituting the dicarboxylate transport system. These findings suggest that the dicarboxylate binding protein found on the cell surface plays an essential role in the translocation of dicarboxylic acids across the outer membrane.     

Occurrence of cis-7-tetradecenoic acid in the envelope phospholipids of Escherichia coli K12

We have isolated a tetradecenoic acid from $\text{E}\text{.}\text{coli}$ and have identified this new acid as $\text{cis}$-7-tetradecenoic by its ¹³C nuclear magnetic resonance spectrum. This identification was confirmed by conventional structural studies. The acid is a component of the phospholipids of $\text{E}\text{.}\text{coli}$ and comprises about 15% of the total phospholipid unsaturated fatty acid.     

Growth of the Escherichia coli cell envelope

The growth pattern of the Escherichia coli envelope was studied by immunoelectron microscopy, using the outer membrane protein LamB specifically labelled by a double antibody gold particle technique. An operon fusion placing the lamB gene under lac promoter control permitted rapid turn-off of LamB synthesis. In the generation following turn-off no lamB-free regions appeared, strongly suggesting that bulk outer membrane material is not inserted in restricted growth zones.     

Probing FhuA''-''PhoA fusion proteins for the study of FhuA export into the cell envelope of Escherichia coli K12

Summary The FhuA protein (formerly TonA) is located in the outer membrane of Escherichia coli K12. Fusions between fhuA and phoA genes were constructed. They determined proteins containing a truncated but still active alkaline phosphatase of constant size and a variable FhuA portion which ranged from 11%–90% of the mature FhuA protein. The fusion sites were nearly randomly distributed along the FhuA protein. The FhuA segments directed the secretion of the truncated alkaline phosphatase across the cytoplasmic membrane. The fusion proteins were proteolytically degraded up to the size of alkaline phosphatase and no longer reacted with anti-FhuA antibodies. The fusion proteins were more stable in lon and pep mutants lacking cytoplasmic protease and peptidases, respectively. The larger fusion proteins above a molecular weight of 64000 dalton were predominantly found in the outer membrane fraction. They were degraded by trypsin when cells were converted to spheroplasts so that trypsin gained access to the periplasm. In contrast, FhuA protein in the outer membrane was largely resistant to trypsin. It is concluded that the larger FhuA-PhoA fusion proteins were associated with, but not properly integrated into, the outer membrane.     

Action of a major outer cell envelope membrane protein in conjugation of Escherichia coli K-12.

Protein II, a major outer cell envelope membrane protein, was found together with lipopolysaccharide to stoichiometrically inhibit conjugation in Escherichia coli K12.     

Major proteins of the outer cell envelope membrane of Escherichia coli K12: multiple species of protein I differ in primary structure.

Summary Protein I, one of the major outer membrane proteins of E. coli in most K12 strains is represented by two very similar polypeptides Ia and Ib. Sequential mutations (involving selections for phage resistance) can lead to loss of proteins Ia and Ib. Among revertants of such Ia^- Ib^- mutants clones exist that instead of Ia or Ib produce a third species of protein I, polypeptide Ic.Ichihara and Mizushima [J. Biochem. 83, 1095–1100 (1978)] have shown that proteins Ia and Ib exhibit differences in primary structure. Here evidence is presented indicating that protein Ic also is not identical in primary structure with Ia or Ib. Thus, 3 very similar structural genes appear to exist for the protein I species known to date, and that for Ic normally is silent. Introduction of a functional Ic locus into a Ia⁺ Ib⁺ strain caused expression of all three proteins with a reduced rate of synthesis of protein Ia.     

Expression and regulation of protein K, an Escherichia coli K1 porin, in Escherichia coli K-12

Using a modified lambda phage as a vector and a procedure developed in Dr. C. Schnaitman's laboratory, we have cloned the structural gene for protein K from an Escherichia coli K1 strain to an E coli K-12 strain. The cloned inserts consist of two HindIII fragments, 4 kb and 6.5 kb in size. The protein produced by the insert is nearly identical to "authentic" protein K when chymotryptic peptides of 125I-labeled proteins are compared. Protein K was found to respond to changes in the osmolarity of the medium, being favored in trypticase soy broth (high osmolarity). This fluctuation was not dependent on a functional ompR gene. However, protein K was not expressed in strains carrying the envZ-473 mutation. Thus, protein K appears to be within a class of exported proteins whose expression is regulated by the envZ gene independent of the ompR gene.     

Ultrastructural localization of the maltose-binding protein within the cell envelope of Escherichia coli

Logarithmically growing cells of Escherichia coli were fixed with glutaraldehyde and incubated with antimaltose-binding protein F_ab coupled to horseradish peroxidase (molecular weight of the complex 80,000). The position of this complex within the cell envelope was determined by reacting with diaminobenzidine-H₂O₂, staining with osmium tetroxide and processing for thin section electron microscopy. The following observations were made: (i) induction of the maltose-binding protein resulted in swelling and staining of the outer membrane; (ii) the swelling and staining was more prominent in short cells, less prominent or absent in long cells; (iii) rare examples exhibited granular staining in the space between the plasma membrane and the peptidoglycan layer. These stainings were observable mainly in pole caps; (iv) a mutant lacking the receptor for phage showed altered staining pattern. Treatment of glutaraldehyde-fixed cells with EDTA-lysozyme prevented the specific labelling of the maltose-binding protein.Lists of Non Common Abbreviations MBP maltose-binding protein - MBP-F_ab)-HRPO F_ab fragments against maltose-binding, protein coupled to horseradish peroxidase - IgG immunoglobulin - PBS pnosphate buffered saline     

Protein complexes of the Escherichia coli cell envelope

Protein complexes are an intrinsic aspect of life in the membrane. Knowing which proteins are assembled in these complexes is therefore essential to understanding protein function(s). Unfortunately, recent high throughput protein interaction studies have failed to deliver any significant information on proteins embedded in the membrane, and many membrane protein complexes remain ill defined. In this study, we have optimized the blue native-PAGE technique for the study of membrane protein complexes in the inner and outer membranes of Escherichia coli. In combination with second dimension SDS-PAGE and mass spectrometry, we have been able to identify 43 distinct protein complexes. In addition to a number of well characterized complexes, we have identified known and orphan proteins in novel oligomeric states. For two orphan proteins, YhcB and YjdB, our findings enable a tentative functional assignment. We propose that YhcB is a hitherto unidentified additional subunit of the cytochrome bd oxidase and that YjdB, which co-localizes with the ZipA protein, is involved in cell division. Our reference two-dimensional blue native-SDS-polyacrylamide gels will facilitate future studies of the assembly and composition of E. coli membrane protein complexes during different growth conditions and in different mutant backgrounds.     

The molecular mechanisms of dicarboxylic acid transport in Escherichia coli K12. The role and orientation of the two membrane-bound dicarboxylate binding proteins.

Previous communications from this laboratory have indicated that dicarboxylic acid transport in Escherichia coli is an active process, and that at least three genes are responsible for this transport system. In attempts to identify the transport components, one periplasmic binding protein and two membrane integral proteins (SBP 1 and SBP 2) were implicated to participate in the transport system in vivo. In the present communication, we demonstrate, through biochemical analysis of the transport mutants, that the two membrane transport genes, dctA and dctB, are responsible for the two membrane-bound dicarboxylate binding proteins, SBP 2 and SBP 1, respectively. We also find that the substrate recognition sites of SBP 1 and SBP 2 are exposed to the inner and outer surfaces of the membrane, respectively. This may have important implications for the role of SBP 1 and SBP 2 in the translocation process.     

Synthesis of OmpA protein of Escherichia coli K12 in Bacillus subtilis

We have inserted a C-terminally truncated gene of the major outer membrane protein OmpA of Escherichia coli downstream from the promoter and signal sequence of the secretory alpha-amylase of Bacillus amyloliquefaciens in a secretion vector of Bacillus subtilis. B. subtilis transformed with the hybrid plasmid synthesized a protein that was immunologically identified as OmpA. All the protein was present in the particulate fraction. The size of the protein compared to the peptide synthesized in vitro from the same template indicated that the alpha-amylase derived signal peptide was not removed; this was verified by N-terminal amino acid sequence determination. The lack of cleavage suggests that there was little or no translocation of OmpA protein across the cytoplasmic membrane. This is an unexpected difference compared with periplasmic proteins, which were both secreted and processed when fused to the same signal peptide. A requirement of a specific component for the export of outer membrane proteins is suggested.     

Termination troubles in Escherichia coli K12

In this issue of Molecular Microbiology, Schaub and Hayes report that, compared with other enterobacteria, Escherichia coli K12 carries two mutations - one in the prfB gene encoding the release factor RF2, and the other in the rpsG gene encoding r-protein S7 - that together concur in compromising translation termination at the essential rpsG gene. As a consequence, the growth of E. coli K12 is very sensitive to a further mutation (rluD(-) ) that depresses RF2 activity, whereas the growth of its close relative, E. coli B, is not. We tentatively discuss how the K12-specific mutations in RF2 and S7 might have occurred and why inefficient translation termination at rpsG inhibits growth. The work of Schaub and Hayes illustrates the fact that, due probably to its long history in the laboratory, E. coli K12 has accumulated mutations that sometimes limit its value as a model for studying basic steps in prokaryotic gene expression.     

Interaction of the lamB protein with the peptidoglycan layer in Escherichia coli K12

In Escherichia coli K12 the product of gene lamB is an outer membrane protein involved in the transport of maltose and maltodextrins and serving as a receptor for several bacteriophages including lambda. About 30 to 40% of this protein can be recovered associated to peptidoglycan when the cells are dissolved in sodium dodecyl sulfate in the presence of 2 mM Mg2+ ions. The bound protein can then be quantitatively eluted from peptidoglycan by incubating the complex in Triton X-100 and EDTA, or sodium dodecyl sulfate and NaCl. The protein eluted in such ways is still totally active in its phage-neutralizing activity. Two other membrane proteins known to behave similarly to the lamB protein are proteins Ia and Ib. However the binding of these proteins to peptidoglycan appears tighter, in several respects, than that of the lamB protein. The lamB protein may span the outer membrane since it appears to interact with the peptidoglycan on the inner side of this membrane while it is known to be accessible to both phages and antibodies at the cell surface.