Mutational analysis of F-pilin reveals domains for pilus assembly, phage infection and DNA transfer.

The F-pilus has been implicated in recipient cell recognition during the establishment of a stable mating pair before conjugation as well as forming part of the conjugative pore for DNA transfer. The F-pilus is the site of attachment of the filamentous phages (M13, f1 and fd), which attach to the F-pilus tip, and the RNA phages, R17 and Qbeta, which attach to different sites exposed on the sides of the pilus. R17 has been shown to undergo eclipse, or capsid release, outside the cell on pili attached to cells. New and existing mutants of traA combined with natural variants of F-pilin were assayed for pilin stability and processing, pilus elongation, transfer, phage sensitivity and R17 eclipse. Phenotypes of these mutants indicated that the F-pilin subunit contains specific regions that can be associated with pilus assembly, phage sensitivity and DNA transport. Mutations involving lysines and phenylalanines within residues 45-60 suggest that these residues might participate in transmitting a signal down the length of the pilus that initiates DNA transfer or R17 eclipse.

Comparison of proteins involved in pilus synthesis and mating pair stabilization from the related plasmids F and R100-1: insights into the mechanism of conjugation.

F and R100-1 are closely related, derepressed, conjugative plasmids from the IncFI and IncFII incompatibility groups, respectively. Heteroduplex mapping and genetic analyses have revealed that the transfer regions are extremely similar between the two plasmids. Plasmid specificity can occur at the level of relaxosome formation, regulation, and surface exclusion between the two transfer systems. There are also differences in pilus serology, pilus-specific phage sensitivity, and requirements for OmpA and lipopolysaccharide components in the recipient cell. These phenotypic differences were exploited in this study to yield new information about the mechanism of pilus synthesis, mating pair stabilization, and surface and/or entry exclusion, which are collectively involved in mating pair formation (Mpf). The sequence of the remainder of the transfer region of R100-1 (trbA to traS) has been completed, and the complete sequence is compared to that of F. The differences between the two transfer regions include insertions and deletions, gene duplications, and mosaicism within genes, although the genes essential for Mpf are conserved in both plasmids. F+ cells carrying defined mutations in each of the Mpf genes were complemented with the homologous genes from R100-1. Our results indicate that the specificity in recipient cell recognition and entry exclusion are mediated by TraN and TraG, respectively, and not by the pilus.

Epitopes fused to F-pilin are incorporated into functional recombinant pili.

In order to develop a system which allows infection by an epitope-specific phage-antibody via an F-pilus expressing that epitope, a study on the expression of foreign sequences on F-pilin was undertaken. Initially, a plasmid library was constructed with random sequences encoding one to five amino acid residues fused to the C terminus of F-pilin (traA) which was used to complement an F-plasmid with an amber mutation in traA. Functional F-pilin fusions were detected using the filamentous phage, fUSE2, which transduces tetracycline resistance, as well as immunoblots using a monoclonal antiserum specific for the acetylated N terminus of pilin. All the clones selected expressed the pilin-fusions and displayed full sensitivity towards fUSE2 infection, which was indistinguishable from the wild-type F-pilin. The sequences of fUSE2-sensitive clones when compared to randomly selected clones which were not fUSE2-sensitive, revealed no obvious pattern in the amino acid residues fused to the C terminus, except for a preference for a hydrophilic amino acid at position +1. Mutating the C-terminal Leu in wt (wild-type) pilin to Ser blocked pilus assembly and fUSE2 infection; the pilin was correctly processed but the level of acetylation at the N terminus appeared to decrease. Fusing a known epitope (myc) directly to the C terminus blocked processing of F-pilin leading to loss of F-pilus assembly and function. The introduction of random sequences between traA and this epitope yielded fully recombinant, functional F-pili but this appeared to be due to processing of the extension by an unidentified protease leading to loss of the epitope. Surface expression of another epitope (G2-10) was clearly demonstrated by immuno-electron microscopy of pili with a G2-10 monoclonal antibody. A different five amino acid residue spacer between the F-pilin C terminus and the G2-10 epitope produced a system that was transfer-proficient and fUSE2-sensitive, but the pili were barely detectable by immunoblots or by electron microscopy. While the underlying rules that govern successful epitope expression at the C terminus of F-pilin remain elusive, many types of foreign sequences can be displayed with varying degrees of success. Our results also suggest that pilin sequence determines a number of steps in the complex pathway for pilus assembly.

Analysis of the traLEKBP sequence and the TraP protein from three F-like plasmids: F, R100-1 and ColB2.

The sequence of a region of the F plasmid containing the traLEKBP genes involved in plasmid transfer was compared to the equivalent regions of two IncFII plasmids, R100-1 and ColB2. The traLEK gene products of all three plasmids were virtually identical, with the most changes occurring in TraE. The TraB genes were also nearly identical except for an 11-codon extension at the 3' end of the R100-1 traB gene. The TraP protein of R100-l differed from those of F and ColB2 at its N terminus, while the ColB2 TraP protein contained a change of sequence in a predicted loop which was shown to be exposed in the periplasmic space by TnphoA mutagenesis. The effect of the altered TraP sequences was determined by complementing a traP mutant with clones expressing the traKBP genes of F, R100-1, and ColB2. The traP mutation in pOX38 (pOX38-traP474), a derivative of F, was found to have little effect on pilus production, pilus retraction, and filamentous phage growth and only a moderate effect on transfer. The transfer ability of pOX38-traP474 was shown to be affected by mutations in the rfa (lipopolysaccharide) locus and in ompA in the recipient cell in a manner similar to that for the wild-type pOX38-Km plasmid itself and could be complemented with the traP analogs from R100-1 and ColB2 to give an F-like phenotype. Thus, the TraP protein appears to play a minor role in conjugation and may interact with TraB, which varies in sequence along with TraP, in order to stabilize the proposed transmembrane complex formed by the tra operon products.

The role of the pilus in recipient cell recognition during bacterial conjugation mediated by F-like plasmids.

The effects of defined mutations in the lipopolysaccharide (LPS) and the outer membrane protein OmpA of the recipient cell on mating-pair formation in liquid media by the transfer systems of the F-like plasmids pOX38 (F), ColB2 and R100-1 were investigated. Transfer of all three plasmids was affected differently by mutations in the rfa (LPS) locus of the recipient cell, the F plasmid being most sensitive to mutations that affected rfaP gene expression which is responsible for the addition of pyrophosphorylethanolamine (PPEA) to heptose I of the inner core of the LPS. ColB2 transfer was more strongly affected by mutations in the heptose II-heptose III region of the LPS (rfaF) whereas R100-1 was not strongly affected by any of the rfa mutations tested. ompA but not rfa mutations further decreased the mating efficiency of an F plasmid carrying a mutation in the mating-pair stabilization protein TraN. An F derivative with a chloramphenicol acetyltransferase (CAT) cassette interrupting the traA pilin gene was constructed and pilin genes from F-like plasmids (F, ColB2, R100-1) were used to complement this mutation. Unexpectedly, the results suggested that the differences in the pilin sequences were not responsible for recognizing specific groups in the LPS, OmpA or the TraT surface exclusion protein. Other corroborating evidence is presented suggesting the presence of an adhesin at the F pilus tip.