Intermediates in the assembly of the TonA polypeptide into the outer membrane of Escherichia coli K12

Assembly of Outer Membrane β-Barrel Proteins: the Bam Complex

The major class of integral proteins found in the outer membrane (OM) of E. coli and Salmonella adopt a β-barrel conformation (OMPs). OMPs are synthesized in the cytoplasm with a typical signal sequence at the amino terminus, which directs them to the secretion machinery (SecYEG) located in the inner membrane for translocation to the periplasm. Chaperones such as SurA, or DegP and Skp, escort these proteins across the aqueous periplasm protecting them from aggregation. The chaperones then deliver OMPs to a highly conserved outer membrane assembly site termed the Bam complex. In E. coli, the Bam complex is composed of an essential OMP, BamA, and four associated OM lipoproteins, BamBCDE, one of which, BamD, is also essential. Here we provide an overview of what we know about the process of OMP assembly and outline the various hypotheses that have been proposed to explain how proteins might be integrated into the asymmetric OM lipid bilayer in an environment that lacks obvious energy sources. In addition, we describe the envelope stress responses that ensure the fidelity of OM biogenesis and how factors, such as phage and certain toxins, have coopted this essential machine to gain entry into the cell.

Targeting and assembly of periplasmic and outer-membrane proteins in Escherichia coli

Escherichia coli must actively transport many of its proteins to extracytoplasmic compartments such as the periplasm and outer membrane. To perform this duty, E. coli employs a collection of Sec (secretion) proteins that catalyze the translocation of various polypeptides through the inner membrane. After translocation across the inner membrane, periplasmic and outer-membrane proteins are folded and targeted to their appropriate destinations. Here we review our knowledge of protein translocation across the inner membrane. We also discuss the various signal transduction systems that monitor extracytoplasmic protein folding and targeting, and we consider how these signal transduction systems may ultimately control these processes.

An aspartate deletion mutation defines a binding site of the multifunctional FhuA outer membrane receptor of Escherichia coli K-12

The FhuA protein of the outer membrane serves as a receptor for phages T5, T1, and phi 80, for colicin M, for the antibiotic albomycin, and for ferrichrome and related siderophores. To identify protein regions important for the multiple FhuA activities, fhuA genes of spontaneous chromosomal mutants which expressed wild-type amounts of the FhuA protein were sequenced. A mutant which was partially T5 sensitive but impaired in all other functions was missing aspartate residue 348 of the mature protein as a result of a three-base deletion. This aspartate residue is part of the hydrophilic sequence Asp-Asp-Glu-Lys. Replacement by site-specific mutagenesis of each of the Asp residues by Tyr, of Glu by Val, and of Lys by Met reduced FhuA activity but less than the Asp deletion did. Ferrichrome inhibited binding of phage phi 80 and of colicin M to these mutants in an allele-specific manner. A completely resistant derivative of the Asp deletion mutant contained, in addition, a leucine-to-proline substitution at position 106 and eight changed bases, converting at positions 576 to 578 an Arg-Pro-Leu sequence to Ala-Arg-Cys. The latter mutations and the Leu-to-Pro replacement alone did not alter sensitivity to the phages but reduced sensitivity to colicin M and albomycin 10- to 1,000-fold. The proline replacements probably disturb FhuA conformation and, in concert with the Asp deletion, inactivate FhuA completely. It is concluded that the Asp deletion site defines a region of FhuA which directly participates in binding of all FhuA ligands. Growth promotion studies on iron-limited media revealed that certain siderophores of the hydroxamate type, such as butylferrichrome, ferrichrysin, and ferrirubin, are taken up not only via FhuA but also via the FhuE outer membrane receptor protein.

Internal deletions in the FhuA receptor of Escherichia coli K-12 define domains of ligand interactions

The ferrichrome-iron receptor encoded by the fhuA gene of Escherichia coli K-12 is a multifunctional outer membrane receptor required for the binding and uptake of ferrichrome and bacteriophages T5, T1, phi 80, and UC-1 as well as colicin M. To identify domains of the protein which are important for FhuA activities, a library of 31 overlapping deletion mutants in the fhuA gene was generated. Export of FhuA deletion proteins to the outer membrane and receptor functions of the deletion proteins were analyzed. All but three of the deletion mutant FhuA proteins cofractionated with the outer membrane; no FhuA proteins were detected in outer membrane preparations or in cell extracts when the deletions spanned amino acids 418 to 440. Most deletion proteins were susceptible to cleavage by endogenous proteolytic activity; some degradation products were detected on Coomassie blue-stained gels and on Western blots (immunoblots). Receptor functions were measured with the mutated genes present on multicopy plasmids. Two deletion mutants, FhuA delta 060-069 and FhuA delta 129-168, conferred wild-type phenotypes: they demonstrated growth promotion by ferrichrome and the same efficiency of plating of bacteriophages as that of wild-type FhuA; killing by colicin M was also unaffected. For FhuA delta 021-128 and FhuA delta 406-417, reduced sensitivity to colicin M was detected; wild-type phenotypes were observed for all other FhuA functions. Deletions from amino acids 169 to 195 slightly reduced sensitivities to bacteriophages and to colicin M; ferrichrome growth promotion was unaffected. When deletions extended into the region of amino acids 196 to 405, all FhuA functions were either reduced or abolished. The results indicate that selected regions of the FhuA protein have receptor activities and demonstrate the presence of both shared and unique ligand-responsive domains.

A genetic engineering approach to study the mode of assembly of the OmpF porin in the envelope of E coli

Inducible hybrid genes encoding two large domains, a periplasmic domain consisting of the PhoS sequence and an outer membrane domain corresponding to various lengths of the OmpF mature sequence were constructed. The synthesized hybrid polypeptides are correctly processed during the early times of induction, their precursor forms being accumulated at later times. These hybrids restore sensitivity toward colicin A to ompF E coli B strain which suggests an outer membrane location. At least 2 of them are indeed localized in the outer membrane after immunogold labelling on ultrathin cryosections. Insertion of a hydrophobic sequence between PhoS and OmpF improves the trimerization and the assembly of the OmpF part. Only the hybrids presenting the last C-terminal 29 residues of OmpF are able to promote the colicin N killing action and to exhibit a trimeric conformation which is recognized by specific antibodies. Moreover, the deletion of the C-terminal region impairs the functional insertion of the OmpF domain; this indicates that the last membrane-spanning region of OmpF is necessary for the correct folding and orientation of the protein in the outer membrane.

Insertion mutagenesis of the gene encoding the ferrichrome-iron receptor of Escherichia coli K-12

The ferrichrome-iron receptor of Escherichia coli K-12 encoded by the fhuA gene is a multifunctional outer membrane receptor with an Mr of 78,000. It is required for the binding and uptake of ferrichrome and is the receptor for bacteriophages T5, T1, phi 80, and UC-1 as well as for colicin M. The fhuA gene was cloned into pBR322, and the recombinant plasmid pGC01 was mutagenized by the insertion of 6-base-pair TAB (two amino acid Barany) linkers into CfoI and HpaII restriction sites distributed throughout the coding region. A library of 18 TAB linker insertions in fhuA was generated; 8 of the mutations were at CfoI sites and 10 were at HpaII sites. All mutations inserted a hexamer that encoded a unique SacI site. A large deletion in fhuA was also isolated by TAB linker mutagenesis. Except for the deletion mutant, all of the linker insertion mutant FhuA proteins were found in the outer membrane in amounts similar to those found in the wild type. Five of the linker insertion mutants were susceptible to cleavage by endogenous proteolytic activity: a second FhuA-related band that migrated at approximately 72 kilodaltons could be detected on Coomassie blue-stained gels and on Western blots (immunoblots) by using a carboxy terminus-specific anti-peptide antibody. Receptor functions were measured with the mutated genes present in a single copy on the chromosome. Some of the receptors conferred wild-type phenotypes: they demonstrated growth promotion by ferrichrome and the same efficiency of plating as that of wild-type FhuA; killing by colicin M was also unaffected. Several mutants were altered in their sensitivities to the lethal agents. TAB linker insertions after amino acids 69 and 128 abolished all receptor functions. Phage T5 id not bind to these mutant FhuA proteins in detergent extracts. The deletion mutant was also defective in all FhuA functions. Sensitivity to the lethal agents of cellsl that expressed mutant FhuAs with insertions after amino acids 59 and 135 was reduced by several orders of magnitude. Insertion at other selected sites decreased some or all receptor functions only slightly. An insertion after amino acid 321 selectively eliminated ferrichrome growth promotion. Finally, a strain carrying a mutant fhuA gene on the chromosome in which the linker insertion occurred after amino acid 82 showed a tonB phenotype. These subtle perturbations that were introduced into the FhuA protein resulted in changes in its stability and in the binding and uptake of its cognate ligands.

Sequence of the fhuE outer-membrane receptor gene of Escherichia coli K12 and properties of mutants

The fhuE gene of Escherichia coli codes for an outer-membrane receptor protein required for the uptake of iron(III) via coprogen, ferrioxamine B and rhodotorulic acid. The amino acid sequence, deduced from the nucleotide sequence, consisted of 729 residues. The mature form, composed of 693 residues, has a calculated molecular weight of 77,453, which agrees with the molecular weight of 76,000 determined by polyacrylamide gel electrophoresis. The FhuE protein contains four regions of homology with other TonB-dependent receptors. A valine to proline exchange in the 'TonB box' abolished transport activity. Phenotypic revertants with substitutions of arginine, glutamine, or leucine at the valine position exhibited increasing iron-coprogen transport rates. Point mutations resulting in the replacement of glycine (127) in the second homology region with either alanine, aspartate, valine, asparagine or histidine exhibited decreased transport rates (listed in descending order). A truncated FhuE protein lacking 24 amino acids at the C-terminal end was exported to the periplasm but failed to be inserted into the outer membrane.

Secretion and membrane integration of a filamentous phage-encoded morphogenetic protein

The filamentous phage-encoded gene IV protein is required at high levels for virus assembly, although it is not a constituent of the virion. It is an integral membrane protein that does not contain an extended hydrophobic region of the kind often required for stable integration in the inner membrane. Rather, like a number of Escherichia coli outer membrane proteins, pIV is rich in charged amino acid residues and is predicted to consist of extensive beta-sheet structures. In phage-producing cells, pIV is primarily detected in the outer membrane, while in cells that produce it from the cloned gene, pIV is found in both the inner and outer membranes. The protein is synthesized as a precursor. Following cleavage of the signal sequence and translocation into the periplasm, the mature form is initially found as a soluble species. Soluble pIV then integrates into the membrane with a half-time of one to two minutes. Neither phage assembly nor other phage proteins are needed for this membrane integration, and phage assembly does not require the presence of the soluble form. The gene IV protein may be part of the structure through which the assembling phage is extruded.

In vitro trimerization of OmpF porin secreted by spheroplasts of Escherichia coli

It is not yet clear how bacterial outer membrane proteins reach their correct destination after they are secreted across the cytoplasmic membrane. We show here that porin OmpF is secreted into the medium as a water-soluble monomeric protein by spheroplasts of Escherichia coli. Furthermore, this monomeric porin is taken up by cell envelope preparations or purified lipopolysaccharides in the presence of 0.03% Triton X-100 and is converted correctly into the mature trimeric conformation. These results appear to reproduce a part of the physiological export and targeting steps of this protein.

Export and activity of hybrid FhuA'-'Iut receptor proteins and of truncated FhuA' proteins of the outer membrane of Escherichia coli

The FhuA protein in the outer membrane of Escherichia coli serves as a multifunctional receptor for the phages T5, T1, phi 80, for colicin M, for ferrichrome (Fe3+-siderophore) and for the structurally related antibiotic, albomycin. To determine structural domains required for these receptor functions and for export, a fusion protein between FhuA and Iut (receptor for Fe3+-aerobactin and cloacin DF13) was constructed. In the FhuA'-'Iut hybrid protein, 24 amino acids of FhuA were replaced by 19 amino acids, 18 of which were from Iut. The number of plaque forming units of phage T5 and T1 on cells expressing FhuA'-'Iut was nearly as high as on cells expressing plasmid-encoded wild-type FhuA. However, 10(7)-fold higher concentrations of phage phi 80 and 10(3) times more colicin M were required to obtain a zone of growth inhibition. Truncated FhuA' proteins in which the last 24 amino acids at the carboxy-terminus were replaced by 16 (FhuA'2) or 3 (FhuA'T) amino acids could hardly be detected on polyacrylamide electrophoretograms of outer membrane proteins, due to proteolytic degradation. Sensitivity of cells expressing FhuA'2 to phage T5 and T1 was reduced by several orders of magnitude and sensitivity to phage phi 80 and colicin M was totally abolished. In contrast, cells expressing FhuA'T were nearly as sensitive to pahge T5, T1, and phi 80 and to colicin M as cells containing FhuA'-'Iut. None of the constructs could grow on ferrichrome as sole iron source and none was sensitive to albomycin.(ABSTRACT TRUNCATED AT 250 WORDS)

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

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 64,000 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.

Role of SecA and SecY in protein export as revealed by studies of TonA assembly into the outer membrane of Escherichia coli

The growth of secAts or secYts mutants at the restrictive temperature has been shown to inhibit the export of many outer membrane proteins. We report here that in two secAts strains the rate of incorporation of newly synthesized protein into both inner and outer membrane fractions decreased by about 70% at the restrictive temperature. The export of the outer membrane protein TonA was used as a model system in which to study the effects of SecA or SecY inactivation. pre-TonA that accumulated at the restrictive temperature was found to co-sediment with the outer membrane fraction. However, the precursor was sensitive to protease and did not float up a sucrose gradient with the membrane fractions. It was therefore concluded that pre-TonA was not integrated into the outer membrane fraction but probably accumulated in the cytoplasm. Studies on the rate of processing of pre-TonA, pulse-labelled at the restrictive temperature then chased at the permissive temperature, revealed differences between secA and secY mutants. In the secAts mutant the great majority of cytoplasmic pre-TonA was not apparently processed to the mature form, whereas in the secYts mutant significant amounts of precursors were rapidly chased into mature TonA, which appeared in the outer membrane. These results suggest that SecA and SecY may act sequentially in the export of proteins to the outer membrane. In particular these data indicate that SecA is required to maintain pre-TonA in a translocationally competent form prior to interaction with the SecY export site.

The Escherichia coli cell division proteins FtsY, FtsE and FtsX are inner membrane-associated

The cell division genes ftsY, ftsE and ftsX form an operon mapping at 76 min on the Escherichia coli chromosome. The protein products of these genes have been identified previously. We have studied the cellular location of the radiolabelled Fts proteins using maxicells and standard fractionation procedures. Previous protein sequence homologies suggested an inner membrane location for FtsE. We have confirmed this predicted location and have shown that FtsY and FtsX are also inner membrane-associated. These results are in agreement with the hypothesis that FtsE may act at the inner membrane, in a "septalsome" complex, by coupling ATP hydrolysis to the process of bacterial cell division.

The carboxy-terminal region of haemolysin 2001 is required for secretion of the toxin from Escherichia coli

As a first step in the detailed analysis of the mechanism of secretion of haemolysin, we sought to identify sequences or domains within haemolysin A (HlyA) that are essential for its secretion. For this purpose we examined the properties of a deletion and Tn5 insertions into the region of the HlyA gene encoding the C-terminal part of the protein, since both of these are relatively simple to generate. We showed that removal of 27 amino acids from the C-terminus of HlyA is sufficient to inhibit secretion drastically, although the residual polypeptide is still haemolytically active. Cellular fractionation studies showed that haemolytic activity does not accumulate in large amounts within the periplasmic space during normal secretion. More significantly, activity does not appear to accumulate within this compartment when the export functions hlyB and hlyD are removed. These results are consistent with a mechanism in which interaction of the C-terminus of HlyA with the secretion machinery, located in the inner membrane, is followed by direct transfer of haemolysin to the medium.