Biosynthesis of K88 fimbriae in Escherichia coli: interaction of tip-subunit FaeC with the periplasmic chaperone FaeE and the outer membrane usher FaeD.

K88 fimbriae are ordered polymeric protein structures at the surface of enterotoxigenic Escherichia coli cells. Their production and assembly requires a molecular chaperone located in the periplasm (FaeE) and a molecular usher located in the outer membrane (FaeD). FaeC is the tip component of the K88 fimbriae. We studied the expression of the subcloned faeC gene, the subcellular localization of FaeC and its interaction with the chaperone and the outer membrane usher. In the absence of the chaperone or the usher, FaeC could not be detected in E. coli cells harbouring the faeC gene and its ribosome binding site under contol of the IPTG inducible lpp/lac promoter/operator. The expression of FaeC was detectable in the presence of chaperone FaeE, but a direct interaction between the chaperone and FaeC was not found. The expression of FaeC was also detectable in cells co-expressing the outer membrane usher FaeD. Overexpression of FaeC after changing the faeC ribosome binding site appeared to induce lethality. Expression of subcloned FaeC in the absence of FaeE or FaeD could be detected when faeC was cloned under the tight control of the ara promoter/operator and when lethality induction was avoided. The direct interaction of FaeC with outer membranes containing the usher FaeD was studied by cell fractionation, isopycnic sucrose density gradient centrifugation, SDS-PAGE and immunoblotting. FaeC was found to bind to outer membranes containing FaeD or a FaeD-PhoA hybrid construct containing 215 amino-terminal residues of FaeD. This binding was not observed when control outer membranes without FaeD were used. No other K88 specific proteins were required for this interaction. The direct interaction between FaeC and FaeD in the outer membranes was shown by affinity blotting experiments. FaeE was not required for this interaction. Together these data indicate that the minor fimbrial subunit FaeC, unlike FaeG, H and F, does not have a strong interaction with the chaperone FaeE in the E. coli periplasm, but directly binds to the outer membrane molecular usher FaeD.

Membrane association of FtsY, the E. coli SRP receptor.

FtsY, the Escherichia coli homologue of the eukaryotic SRP receptor (SR alpha), is located both in the cytoplasm and in the inner membrane of E. coli. Similar to SR alpha, FtsY consists of two major domains: a strongly acidic N-terminal domain (A) and a C-terminal GTP binding domain (NG) of which the crystal structure has recently been determined. The domains were expressed both in vivo and in vitro to examine their subcellular localization. The results suggest that both domains associate with the membrane but that the nature of the association differs.

The signal recognition particle receptor of Escherichia coli (FtsY) has a nucleotide exchange factor built into the GTPase domain.

Targeting of many secretory and membrane proteins to the inner membrane in Escherichia coli is achieved by the signal recognition particle (SRP) and its receptor (FtsY). In E. coli SRP consists of only one polypeptide (Ffh), and a 4.5S RNA. Ffh and FtsY each contain a conserved GTPase domain (G domain) with an alpha-helical domain on its N terminus (N domain). The nucleotide binding kinetics of the NG domain of the SRP receptor FtsY have been investigated, using different fluorescence techniques. Methods to describe the reaction kinetically are presented. The kinetics of interaction of FtsY with guanine nucleotides are quantitatively different from those of other GTPases. The intrinsic guanine nucleotide dissociation rates of FtsY are about 10(5) times higher than in Ras, but similar to those seen in GTPases in the presence of an exchange factor. Therefore, the data presented here show that the NG domain of FtsY resembles a GTPase-nucleotide exchange factor complex not only in its structure but also kinetically. The I-box, an insertion present in all SRP-type GTPases, is likely to act as an intrinsic exchange factor. From this we conclude that the details of the GTPase cycle of FtsY and presumably other SRP-type GTPases are fundamentally different from those of other GTPases.

The N-terminal beta-barrel domain of the Escherichia coli K88 periplasmic chaperone FaeE determines fimbrial subunit recognition and dimerization.

The K88 periplasmic chaperone FaeE is a homodimer, whereas the K99 chaperone FanE is a monomer. The structural requirements for dimerization of the K88 fimbrial periplasmic chaperone and for fimbrial subunit-binding specificity were investigated by analysis of mutant chaperones. FaeE contains a C-terminal extension of 19 amino acid residues when compared to FanE and most other fimbrial chaperones. A C-terminal truncate of the K88 chaperone FaeE was constructed that lacked 19 C-terminal amino acid residues. Expression and complementation experiments revealed that this C-terminal shortened chaperone was still functional in binding the K88 major subunit FaeG and K88 biosynthesis. Two hybrid chaperones were constructed. Each hybrid protein contained one beta-barrel domain of FaeE and the other beta-barrel domain of FanE (Fae/FanE or Fan/FaeE, respectively). Expression and complementation experiments revealed that the Fae/FanE but not the Fan/FaeE hybrid chaperone was functional in the formation of K88 fimbriae. The Fan/FaeE hybrid chaperone was active in the bio-synthesis of K99 fimbriae. The truncated FaeE mutant chaperone and the hybrid Fae/FanE chaperone were able to form stable periplasmic protein complexes with the K88 major fimbrial subunit FaeG. Cross-linking experiments suggested that the C-terminal shortened chaperone and the Fae/FanE hybrid chaperone were homodimers, as is the wild-type K88 chaperone. Altogether, the data suggested that the N-terminal beta-barrel domain of a fimbrial chaperone determines subunit specificity. In the case of the K88 periplasmic chaperone, this N-terminal domain also determines dimerization of the protein.

Molecular and structural aspects of fimbriae biosynthesis and assembly in Escherichia coli.

Fimbriae are long filamentous polymeric protein structures located at the surface of bacterial cells. They enable the bacteria to bind to specific receptor structures and thereby to colonise specific surfaces. Fimbriae consist of so-called major and minor subunits, which form, in a specific order, the fimbrial structure. In this review emphasis is put on the genetic organisation, regulation and especially on the biosynthesis of fimbriae of enterotoxigenic Escherichia coli strains, and more in particular on K88 and related fimbriae, with ample reference to well-studied P and type 1 fimbriae. The biosynthesis of these fimbriae requires two specific and unique proteins, a periplasmic chaperone and an outer membrane located molecular usher ('doorkeeper'). Molecular and structural aspects of the secretion of fimbrial subunits across the cytoplasmic membrane, the interaction of these subunits with periplasmic molecular chaperone, their translocation to the inner site of the outer membrane and their interaction with the usher protein, as well as the (ordered) translocation of the subunits across the outer membrane and their assembly into a growing fimbrial structure will be described. A model for K88 fimbriae is presented.

The Escherichia coli K99 periplasmic chaperone FanE is a monomeric protein.

The monomeric or dimeric nature of the K99 periplasmic chaperone FanE was examined. The gene encoding FanE was subcloned in a pINIIIA1 derivative expression vector. A complementation experiment showed that the subcloned FanE was biologically functional. The protein was purified from the periplasm of cells harbouring the constructed plasmid. Automated Edman degradation experiments confirmed the predicted N-terminal amino acid sequence of FanE. A polyclonal mouse antiserum was raised against the FanE chaperone. The monomeric or oligomeric nature of the protein in the periplasm was studied by gel filtration, immunoblotting and chemical cross-linking experiments. The results indicated that FanE is a monomeric protein, in contrast to the K88 periplasmic chaperone.

The Escherichia coli K88 periplasmic chaperone FaeE forms a heterotrimeric complex with the minor fimbrial component FaeH and with the minor fimbrial component FaeI.

K88ab fimbriae are long polymeric protein structures mainly composed of FaeG proteins. The Escherichia coli K88 periplasmic chaperone FaeE is a homodimer and forms a heterotrimeric complex with the K88 major fimbrial component FaeG in the periplasm. In this study the direct interaction of FaeE and the minor K88 fimbrial subunits FaeH and FaeI were investigated. The faeH gene and the faeI gene were subcloned in a pINIIIA1-derivative vector containing the faeE gene. SDS-PAGE using normal and gradient gels and immunoblotting revealed that the subcloned genes were expressed in the periplasm. Analyses of periplasmic fractions by native gel electrophoresis and isoelectric focusing (IEF) showed that FaeE and FaeH, as well as FaeE and FaeI formed protein complexes. These complexes were isolated and purified by FPLC or IEF and native gel electrophoresis. The stoichiometry of the proteins in these complexes was studied by automated Edman degradation and gel image analysis. The results showed that FaeE and FaeH, and FaeE and FaeI formed heterotrimeric E2H and E2I complexes, respectively. In addition to the E2H complex, cells expressing FaeE and FaeH accumulated unbound FaeH in their periplasm. In contrast to the E2G complex, the purified E2H complex was not stable and was partly dissociated in the experimental conditions used, suggesting that the interaction between FaeE and FaeH is not as strong as the interaction of FaeE and FaeG.

Morphological appearances of K88ab fimbriae and optical diffraction analysis of K88 paracrystalline structures.

K88ab fimbriae are filamentous protein structures at the surface of certain enterotoxigenic Escherichia coli strains. Electron microscopy analysis of K88ab fimbriae showed that these structures have different morphological appearances dependent on the medium in which cells expressing these fimbriae or in which purified fimbriae were suspended. Thin and curled structures, thin and flexible fimbriae, a wider and rigid form of the fimbriae, and, in addition, paracrystalline structures were detected. Optical diffraction analysis of the paracrystalline structures indicated a helical conformation of K88ab fimbriae.

Escherichia coli periplasmic chaperone FaeE is a homodimer and the chaperone-K88 subunit complex is a heterotrimer.

The interaction of FaeE, a periplasmic chaperone involved in K88 biosynthesis, and the major fimbrial subunit FaeG was investigated. The genes encoding the two proteins were subcloned together in the expression vector pINIIIA1. Cells expressing the subcloned genes accumulated in their periplasm a complex of FaeE and FaeG. This complex was purified by isoelectric focusing and anion-exchange fast-protein liquid chromatography. SDS-PAGE, native gel electrophoresis, immunoblotting and determination of the N-terminal amino acid sequences and the molar ratio of the N-terminal amino acid residues revealed that the complex is a heterotrimer consisting of two molecules of FaeE and one molecule of FaeG. The periplasmic chaperone FaeE was purified from the periplasm of cells expressing only the subcloned faeE gene. Gel filtration, protein cross-linking analysis and a biophysical approach in which the rotation diffusion coefficient of the purified FaeE was determined led to the conclusion that the native FaeE chaperone is a homodimer.

Escherichia coli SecB, SecA, and SecY proteins are required for expression and membrane insertion of the bacteriocin release protein, a small lipoprotein.

The SecB, SecA, and SecY dependency of a small outer membrane lipoprotein in Escherichia coli, the bacteriocin release protein (BRP), was studied. The detrimental effect of BRP expression on the culture turbidity (quasi-lysis) was strongly reduced in the sec mutants. Immunoblotting and radioactive labeling experiments showed that the expression, membrane insertion, and processing of the BRP precursor are dependent on SecB, SecA, and SecY. Labeling experiments with hybrid BRP gene constructs revealed that the mature part of the BRP precursor and not its stable signal sequence is important for its SecB dependency.

Further characterization of monoclonal antibodies to lipopolysaccharide of Salmonella Minnesota strain R595.

We have shown here that despite the use of monoclonal antibodies with well-defined epitope-specificities, and despite testing them in the most simple animal model available (i.e., mixing of homologous LPS with Mab prior to injection), we are not yet able to explain why some of the antibodies were effective and others not. For some of the clones (e.g., clone 20), an even better definition of binding sites is currently taking place in an attempt to obtain this understanding. We also do not yet understand why clone 20 was not effective in the mucin model, while using much lower amounts of injected antibody, and much higher challenge doses, this Mab was effective against E. coli in the gentamicin-treated mouse model. Very clear is, however, that in order to be protective in the latter model, Mabs are not required to be specific for lipid A. In the future it will be essential to develop procedures which measure specific interaction between smooth LPS/bacteria and antibodies to the LPS core region. In addition, it will be of great help when the chemical structure of non-substituted, rough-form LPS, as occurring in smooth LPS preparations, would be defined. This applies also to O-substituted core molecules.