Overproduction of the proFhuA outer membrane receptor protein of Escherichia coli K-12: isolation, properties, and immunocytochemical localization at the inner side of the cytoplasmic membrane

Engineering of an E. coli outer membrane protein FhuA with increased channel diameter

Background

Channel proteins like FhuA can be an alternative to artificial chemically synthesized nanopores. To reach such goals, channel proteins must be flexible enough to be modified in their geometry, i.e. length and diameter. As continuation of a previous study in which we addressed the lengthening of the channel, here we report the increasing of the channel diameter by genetic engineering.

Results

The FhuA Δ1-159 diameter increase has been obtained by doubling the amino acid sequence of the first two N-terminal β-strands, resulting in variant FhuA Δ1-159 Exp. The total number of β-strands increased from 22 to 24 and the channel surface area is expected to increase by ~16%. The secondary structure analysis by circular dichroism (CD) spectroscopy shows a high β-sheet content, suggesting the correct folding of FhuA Δ1-159 Exp. To further prove the FhuA Δ1-159 Exp channel functionality, kinetic measurement using the HRP-TMB assay (HRP = Horse Radish Peroxidase, TMB = 3,3',5,5'-tetramethylbenzidine) were conducted. The results indicated a 17% faster diffusion kinetic for FhuA Δ1-159 Exp as compared to FhuA Δ1-159, well correlated to the expected channel surface area increase of ~16%.

Conclusion

In this study using a simple "semi rational" approach the FhuA Δ1-159 diameter was enlarged. By combining the actual results with the previous ones on the FhuA Δ1-159 lengthening a new set of synthetic nanochannels with desired lengths and diameters can be produced, broadening the FhuA Δ1-159 applications. As large scale protein production is possible our approach can give a contribution to nanochannel industrial applications.

Periplasmic chaperone FkpA is essential for imported colicin M toxicity

Chaperones facilitate correct folding of newly synthesized proteins. We show here that the periplasmic FkpA chaperone is required for killing Escherichia coli by colicin M entering cells from the outside. Highly active colicin M preparations were inactive against fkpA mutant cells; 10⁴-fold dilutions killed fkpA⁺ cells. Three previously isolated spontaneous mutants tolerant to colicin M carried a stop codon or an IS1 insertion in the peptidyl-prolyl-cis-trans-isomerase (PPIase) domain (C-domain) of FkpA, which resulted in deletion of the domain. A randomly generated mutant carried a G148D mutation in the C-domain. A temperature-sensitive mutant tolerant to colicin M carried a Y25N mutation in the FkpA N-domain. Mutants transformed with wild-type fkpA were colicin M-sensitive. Isolated FkpA-His reduced colicin M-His cleavage by proteinase K and renatured denatured colicin M-His in vitro; renaturation was prevented by the PPIase inhibitor FK506. In both assays, periplasmic SurA-His had no effect. No other tested periplasmic chaperone could activate colicin M. Among the tested colicins, only colicin M required FkpA for activity. Colicin M bound to cells via FhuA was inactivated by trypsin; unbound colicin M retained activity. We propose that colicin M unfolds during import across the outer membrane, FkpA specifically assists in folding colicin M into an active toxin in the periplasm and PPIase is essential for colicin M activity. Colicin M is a suitable tool for the isolation of FkpA mutants used to elucidate the functions of the FkpA N- and C-domains.

Loop deletions indicate regions important for FhuA transport and receptor functions in Escherichia coli

Precise deletions of cell surface-exposed loops of FhuA resulted in mutants of Escherichia coli with distinct phenotypes. Deletion of loop 3 or 11 inactivated ferrichrome transport activity. Deletion of loop 8 inactivated receptor activity for colicin M and the phages T1, T5, and phi80. The loop 7 deletion mutant was colicin M resistant but fully phage sensitive. The loop 4 deletion mutant was resistant to the TonB-dependent phages T1 and phi80 but fully sensitive to the TonB-independent phage T5. The phenotypes of the deletion mutants revealed important sites for the multiple FhuA transport and receptor activities. The ligand binding sites are nonidentical and are distributed among the entire exposed surface. Presumably, FhuA evolved as a ferrichrome transporter and was subsequently used as a receptor by the phages and colicin M, which selected the same as well as distinct loops as receptor sites.

In vivo reconstitution of the FhuA transport protein of Escherichia coli K-12

The FhuA protein in the outer membrane of Escherichia coli actively transports ferrichrome and the antibiotics albomycin and rifamycin CGP 4832 and serves as a receptor for the phages T1, T5, and phi80 and for colicin M and microcin J25. The crystal structure reveals a beta-barrel with a globular domain, the cork, which closes the channel formed by the barrel. Genetic deletion of the cork resulted in a beta-barrel that displays no FhuA activity. A functional FhuA was obtained by cosynthesis of separately encoded cork and the beta-barrel domain, each endowed with a signal sequence, which showed that complementation occurs after secretion of the fragments across the cytoplasmic membrane. Inactive complete mutant FhuA and an FhuA fragment containing 357 N-proximal amino acid residues complemented the separately synthesized wild-type beta-barrel to form an active FhuA. Previous claims that the beta-barrel is functional as transporter and receptor resulted from complementation by inactive complete FhuA and the 357-residue fragment. No complementation was observed between the wild-type cork and complete but inactive FhuA carrying cork mutations that excluded the exchange of cork domains. The data indicate that active FhuA is reconstituted extracytoplasmically by insertion of separately synthesized cork or cork from complete FhuA into the beta-barrel, and they suggest that in wild-type FhuA the beta-barrel is formed prior to the insertion of the cork.

Identification of a new site for ferrichrome transport by comparison of the FhuA proteins of Escherichia coli, Salmonella paratyphi B, Salmonella typhimurium, and Pantoea agglomerans

The fhuA genes of Salmonella paratyphi B, Salmonella typhimurium, and Pantoea agglomerans were sequenced and compared with the known fhuA sequence of Escherichia coli. The highly similar FhuA proteins displayed the largest difference in the predicted gating loop, which in E. coli controls the permeability of the FhuA channel and serves as the principal binding site for the phages T1, T5, and phi80. All the FhuA proteins contained the region in the gating loops required in E. coli for ferrichrome and albomycin transport. The three subdomains required for phage binding were contained in the gating loop of S. paratyphi B which is infected by the E. coli phages, whereas two of the subdomains were deleted in S. typhimurium and P. agglomerans which are resistant to the E. coli phages. Small deletions in a surface loop adjacent to the gating loop, residues 236 to 243 and 236 to 248, inactivated E. coli FhuA with regard to transport of ferrichrome and albomycin, but sensitivity to T1 and T5 was fully retained and sensitivity to phi80 and colicin M was reduced 10-fold. Full-size FhuA hybrid proteins of S. paratyphi B and S. typhimurium displayed S. paratyphi B FhuA activity when the hybrids contained two-thirds of either the N- or the C-terminal portions of S. paratyphi B and displayed S. typhimurium FhuA activity to phage ES18 when the hybrid contained two-thirds of the N-terminal region of the S. typhimurium FhuA. The central segment of the S. paratyphi B FhuA flanked on both sides by S. typhimurium FhuA regions conferred full sensitivity only to phage T5. The data support the essential role of the gating loop for the transport of ferrichrome and albomycin, identified an additional loop for ferrichrome and albomycin uptake, and suggest that several segments and their proper conformation, determined by the entire FhuA protein, contribute to the multiple FhuA activities.

Specific in vivo labeling of cell surface-exposed protein loops: reactive cysteines in the predicted gating loop mark a ferrichrome binding site and a ligand-induced conformational change of the Escherichia coli FhuA protein

The FhuA protein of Escherichia coli K-12 transports ferrichrome, the antibiotic albomycin, colicin M, and microcin 25 across the outer membrane and serves as a receptor for the phages T1, T5, phi80, and UC-1. FhuA is activated by the electrochemical potential of the cytoplasmic membrane, which probably opens a channel in FhuA. It is thought that the proteins TonB, ExbB, and ExbD function as a coupling device between the cytoplasmic membrane and the outer membrane. Excision of 34 residues from FhuA, tentatively designated the gating loop, converts FhuA into a permanently open channel. FhuA contains two disulfide bridges, one in the gating loop and one close to the C-terminal end. Reduction of the disulfide bridges results in a low in vivo reaction of the cysteines in the gating loop and no reaction of the C-terminal cysteines with biotin-maleimide, as determined by streptavidin-beta-galactosidase bound to biotin. In this study we show that a cysteine residue introduced into the gating loop by replacement of Asp-336 displayed a rather high reactivity and was used to monitor structural changes in FhuA upon binding of ferrichrome. Flow cytometric analysis revealed fluorescence quenching by ferrichrome and albomycin of fluorescein-maleimide bound to FhuA. Ferrichrome did not inhibit Cys-336 labeling. In contrast, labeling of Cys-347, obtained by replacing Val-347 in the gating loop, was inhibited by ferrichrome, but ferrichrome quenching was negligible. It is concluded that binding of ferrichrome causes a conformational change of the gating loop and that Cys-347 is part of or close to the ferrichrome binding site. Fluorescence quenching was independent of the TonB activity. The newly introduced cysteines and the replacement of the existing cysteines by serine did not alter sensitivity of cells to the FhuA ligands tested (T5, phi80, T1, colicin M, and albomycin) and fully supported growth on ferrichrome as the sole iron source. Since cells of E. coli K-12 display no reactivity to thiol reagents, newly introduced cysteines can be used to determine surface-exposed regions of outer membrane proteins and to monitor conformational changes during their function.

Specific in vivo thiol-labeling of the FhuA outer membrane ferrichrome transport protein of Escherichia coli K-12: evidence for a disulfide bridge in the predicted gating loop

The multifunctional FhuA protein of Escherichia coli K-12 forms a channel that is closed by a loop, tentatively designated the 'gating loop', which is also the principal binding site for all FhuA ligands. In this report, it is shown by in vivo labeling that the two cysteines in the gating loop form a disulfide bridge, and they react weakly after reduction with biotin-maleimide, as determined by streptavidin-beta-galactosidase bound to biotin. The two cysteines close to the C-terminus of FhuA also form a disulfide bridge and react with the thiol reagents only after heat denaturation of FhuA in SDS. Replacement of the existing cysteines by serine did not alter the sensitivity of cells to the FhuA ligands tested (T5, phi 80, T1, colicin M, and albomycin) and supported growth on ferrichrome as sole iron source. The cysteines in the gating loop play no specific functional role; they are largely buried in the interior of the loop, and the disulfide bridges are not essential for maintaining the conformation of FhuA. The C-terminal cysteines are in the interior of FhuA and are also not important for the structure of FhuA. The method used allows the identification of free cysteines and disulfides in surface exposed protein regions.

Insertion derivatives containing segments of up to 16 amino acids identify surface- and periplasm-exposed regions of the FhuA outer membrane receptor of Escherichia coli K-12

The FhuA receptor in the outer membrane of Escherichia coli K-12 is involved in the uptake of ferrichrome, colicin M, and the antibiotic albomycin and in infection by phages T1, T5, and phi 80. Fragments of up to 16 amino acid residues were inserted into FhuA and used to determine FhuA active sites and FhuA topology in the outer membrane. For this purpose antibiotic resistance boxes flanked by symmetric polylinkers were inserted into fhuA and subsequently partially deleted. Additional in-frame insertions were generated by mutagenesis with transposon Tn1725. The 68 FhuA protein derivatives examined contained segments of 4, 8, 12, 16, and 22 additional amino acid residues at 34 different locations from residues 5 to 646 of the mature protein. Most of the FhuA derivatives were found in normal amounts in the outer membrane fraction. Half of these were fully active toward all ligands, demonstrating proper insertion into the outer membrane. Seven of the 12- and 16-amino-acid-insertion derivatives (at residues 378, 402, 405, 415, 417, 456, and 646) were active toward all of the ligands and could be cleaved by subtilisin in whole cells, suggesting a surface location of the extra loops at sites which did not affect FhuA function. Two mutants were sensitive to subtilisin (insertions at residues 511 and 321) but displayed a strongly reduced sensitivity to colicin M and to phages phi 80 and T1. Four of the insertion derivatives (at residues 162, 223, 369, and 531) were cleaved only in spheroplasts and probably form loops at the periplasmic side of the outer membrane. The number and size of the proteolytic fragments indicate cleavage at or close to the sites of insertion, which has been proved for five insertions by amino acid sequencing. Most mutants with functional defects were affected in their sensitivity to all ligands, yet frequently to different degrees. Some mutants showed a specifically altered sensitivity to a few ligands; for example, mutant 511-04 was partially resistant only to colicin M, mutant 241-04 was reduced in ferrichrome and albomycin uptake and showed a reduced colicin M sensitivity, and mutant 321-04 was fully resistant to phage T1 and partially resistant to phage phi 80. The altered residues define preferential binding sites for these ligands. Insertions of 4 to 16 residues at positions 69, 70, 402, 530, 564, and 572 resulted in strongly reduced amounts of FhuA in the outer membrane fraction, varying in function from fully active to inactive. These results provide the basis for a model of FhuA organization in the outer membrane.

Iron(III) hydroxamate transport in Escherichia coli K-12: FhuB-mediated membrane association of the FhuC protein and negative complementation of fhuC mutants

Iron(III) hydroxamate transport across the cytoplasmic membrane is catalyzed by the very hydrophobic FhuB protein and the membrane-associated FhuC protein, which contains typical ATP-binding domains. Interaction between the two proteins was demonstrated by immunoelectron microscopy with anti-FhuC antibodies, which showed FhuB-mediated association of FhuC with the cytoplasmic membrane. In addition, inactive FhuC derivatives carrying single amino acid replacements in the ATP-binding domains suppressed wild-type FhuC transport activity, which arose either from displacement of active FhuC from FhuB by the mutated FhuC derivatives or from the formation of mixed inactive FhuC multimers between wild-type and mutated FhuC proteins. Inactive FhuC derivatives containing internal deletions and insertions showed no phenotypic suppression, indicating conformational alterations that rendered the FhuC derivatives unable to displace wild-type FhuC. It is concluded that the physical interaction between FhuC and FhuB implies a coordinate activity of both proteins in the transport of iron(III) hydroxamates through the cytoplasmic membrane.

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.

Cloning and expression of the exbB gene of Escherichia coli K-12

The exbB locus of Escherichia coli is involved in the uptake of certain iron(III) siderophore compounds, of vitamin B12 and of certain colicins. Outer membrane receptor proteins are essential constituents of the corresponding uptake systems. The DNA carrying the exbB locus was cloned into pACYC184 and subcloned into pUC18. With the use of insertion mutagenesis employing transposon Tn1000 and by deletion analysis, the exbB locus was confined to a 1.9 kb DNA fragment. An in vitro transcription/translation system and minicells programmed by exbB+ plasmids expressed a protein with an apparent molecular weight of 26,000. One plasmid, designated pKE7, expressed this protein to an extent that it became a prominent band in the membrane fraction of transformants. In contrast, chromosomally encoded ExbB protein could not be detected. The plasmid-encoded ExbB protein was mainly localized in the cytoplasmic membrane. Ferrichrome transport in exbB mutants was restored by exbB+ plasmids. Moderate overexpression of ExbB resulted in an enhanced ferrichrome transport, strong overexpression reduced the transport rate compared to a wild-type strain. The ExbB function shares some properties with the TonB function.