Molecular interactions between Neisseria meningitidis and its human host.

Neisseria meningitidis is a Gram-negative bacterium that asymptomatically colonises the nasopharynx of humans. For an unknown reason, N. meningitidis can cross the nasopharyngeal barrier and invade the bloodstream where it becomes one of the most harmful extracellular bacterial pathogen. This infectious cycle involves the colonisation of two different environments. (a) In the nasopharynx, N. meningitidis grow on the top of mucus-producing epithelial cells surrounded by a complex microbiota. To survive and grow in this challenging environment, the meningococcus expresses specific virulence factors such as polymorphic toxins and MDAΦ. (b) Meningococci have the ability to survive in the extra cellular fluids including blood and cerebrospinal fluid. The interaction of N. meningitidis with human endothelial cells leads to the formation of typical microcolonies that extend overtime and promote vascular injury, disseminated intravascular coagulation, and acute inflammation. In this review, we will focus on the interplay between N. meningitidis and these two different niches at the cellular and molecular level and discuss the use of inhibitors of piliation as a potent therapeutic approach.

Vaccination with filamentous bacteriophages targeting DEC-205 induces DC maturation and potent anti-tumor T-cell responses in the absence of adjuvants.

The efficacy of a new vaccine-delivery vector, based on the filamentous bacteriophage fd displaying a single-chain antibody fragment known to bind the mouse DC surface molecule DEC-205, is reported. We demonstrate both in vitro and in vivo an enhanced receptor-mediated uptake of phage particles expressing the anti-DEC-205 fragment by DCs. We also report that DCs targeted by fd virions in the absence of other stimuli produce IFN-α and IL-6, and acquire a mature phenotype. Moreover, DC-targeting with fd particles double-displaying the anti-DEC-205 fragment on the pIII protein and the OVA(257-264) antigenic determinant on the pVIII protein induced potent inhibition of the growth of the B16-OVA tumor in vivo. This protection was much stronger than other immunization strategies and similar to that induced by adoptively transferred DCs. Since targeting DEC-205 in the absence of DC activation/maturation agents has previously been described to result in tolerance, the ability of fd bacteriophages to induce a strong tumor-specific immune response by targeting DCs through DEC-205 is unexpected, and further validates the potential employment of this safe, versatile and inexpensive delivery system for vaccine formulation.

The filamentous phages fd and IF1 use different mechanisms to infect Escherichia coli.

The filamentous phage fd uses its gene 3 protein (G3P) to target Escherichia coli cells in a two-step process. First, the N2 domain of G3P attaches to an F pilus, and then the N1 domain binds to TolA-C. N1 and N2 are tightly associated, rendering the phage robust but noninfectious because the binding site for TolA-C is buried at the domain interface. Binding of N2 to the F pilus initiates partial unfolding, domain disassembly, and prolyl cis-to-trans isomerization in the hinge between N1 and N2. This activates the phage, and trans-Pro213 maintains this state long enough for N1 to reach TolA-C. Phage IF1 targets I pili, and its G3P contains also an N1 domain and an N2 domain. The pilus-binding N2 domains of the phages IF1 and fd are unrelated, and the N1 domains share a 31% sequence identity. We show that N2 of phage IF1 mediates binding to the I pilus, and that N1 targets TolA. Crystallographic and NMR analyses of the complex between N1 and TolA-C indicate that phage IF1 interacts with the same site on TolA-C as phage fd. In IF1-G3P, N1 and N2 are independently folding units, however, and the TolA binding site on N1 is permanently accessible. Activation by unfolding and prolyl isomerization, as in the case of phage fd, is not observed. In IF1-G3P, the absence of stabilizing domain interactions is compensated for by a strong increase in the stabilities of the individual domains. Apparently, these closely related filamentous phages evolved different mechanisms to reconcile robustness with high infectivity.

Satellite phage TLCφ enables toxigenic conversion by CTX phage through dif site alteration.

Bacterial chromosomes often carry integrated genetic elements (for example plasmids, transposons, prophages and islands) whose precise function and contribution to the evolutionary fitness of the host bacterium are unknown. The CTXφ prophage, which encodes cholera toxin in Vibrio cholerae, is known to be adjacent to a chromosomally integrated element of unknown function termed the toxin-linked cryptic (TLC). Here we report the characterization of a TLC-related element that corresponds to the genome of a satellite filamentous phage (TLC-Knφ1), which uses the morphogenesis genes of another filamentous phage (fs2φ) to form infectious TLC-Knφ1 phage particles. The TLC-Knφ1 phage genome carries a sequence similar to the dif recombination sequence, which functions in chromosome dimer resolution using XerC and XerD recombinases. The dif sequence is also exploited by lysogenic filamentous phages (for example CTXφ) for chromosomal integration of their genomes. Bacterial cells defective in the dimer resolution often show an aberrant filamentous cell morphology. We found that acquisition and chromosomal integration of the TLC-Knφ1 genome restored a perfect dif site and normal morphology to V. cholerae wild-type and mutant strains with dif(-) filamentation phenotypes. Furthermore, lysogeny of a dif(-) non-toxigenic V. cholerae with TLC-Knφ1 promoted its subsequent toxigenic conversion through integration of CTXφ into the restored dif site. These results reveal a remarkable level of cooperative interactions between multiple filamentous phages in the emergence of the bacterial pathogen that causes cholera.

Host recognition and integration of filamentous phage phiRSM in the phytopathogen, Ralstonia solanacearum.

Two prophages, called varphiRSM3 and varphiRSM4, that are closely related to, but differ from, filamentous phage varphiRSM1, have been detected in strains of the Ralstonia solanacearum species complex. The prophage varphiRSM3, found in host strain MAFF730139, could be converted to infectious phage by means of PCR and transfection. The nucleotide sequence of varphiRSM3 is highly conserved relative to varphiRSM1 except for open reading frame 2 (ORF2), encoding an unknown protein, and ORF9 encoding the presumed adsorption protein that determines host range. The two host ranges differ dramatically and correlate closely with different gel electrophoresis banding patterns for cell surface fimbriae. Infections by varphiRSM1 and varphiRSM3 enhance bacterial cell aggregation and reduce the bacterial host virulence in tomato plants. Database searches in the R. solanacearum strains of known genomic sequence revealed two inovirus prophages, one designated varphiRSM4 that is homologous to varphiRSM1 and varphiRSM3, and one homologues to RSS1, in the genome of strain UW551.

Mutations in the N-terminus of the major coat protein (pVIII, gp8) of filamentous bacteriophage affect infectivity.

Filamentous bacteriophages are nonlytic, male-specific bacteriophages which infect Escherichia coli carrying an F-episome. The molecular mechanism of infection remains elusive, including the role of the major coat protein pVIII. In order to evaluate the contributions of major coat protein pVIII in the process of infection, two phage display libraries were generated. One library consisted of random amino acids at positions 2, 4, 5, 8, 11 and 12 of the N-terminus of major coat protein pVIII. The second library was generated by randomizing these positions as well as position 1. All these residues were previously shown to be exposed at the surface of the virions by being accessible to ligands. The infectivity of randomly selected mutant phages was analyzed. The present results demonstrate that phages modified at these positions can be correctly assembled and secreted into the exoplasm, although the efficiency was slightly lower than that of wild-type phage. Their infectivity varied greatly, and a general structural pattern underlying infectivity did not emerge. However, residual differences were observed between infectious and defective phage; in general, uncharged polar amino acids present at positions 5 and 11 of the N-terminus of pVIII reduced phage infectivity, whereas polar residues at position 8 facilitated infection. The first position of pVIII is remarkably critical for infection; when this alanine was substituted with other residues, most of the phages lost their infectivity. These results shed new light on the true complexity of random peptide pVIII phage display libraries.

A morphologic study of filamentous phage infection of Escherichia coli using biotinylated phages.

Using biotinylated phage (BIO-phages), we observed the infection of filamentous phages into Escherichia coli JM109 morphologically. BIO-phages and BIO-phage-derived proteins, mainly pVIII, were detected in E. coli by using the avidin-biotin-peroxidase complex method with electron microscopy. Infected cells revealed positive staining on the outer and inner membranes and in the periplasmic space. Some cells showed specific or predominant staining of the outer membrane, whereas others showed predominant staining of the inner membrane or equivalent staining of the outer and inner membranes. The periplasmic spaces in some infected cells were expanded and filled with reaction products. Some cells showed wavy lines of positive staining in the periplasmic space. BIO-phages were detected as thick filaments or clusters covered with reaction products. The ends of the infecting phages were located on the surface of cells, in the periplasmic space, or on the inner membrane. These findings suggest that phage major coat proteins are integrated into the outer membrane and that phages cause periplasmic expansion during infection.

A visualization method of filamentous phage infection and phage-derived proteins in Escherichia coli using biotinylated phages.

Direct visualization of filamentous phage infection in Escherichia coli (E. coli) was attempted using biotinylated phages (BIO-phages). The biotinylation of the phages did not influence their infectivity into E. coli. E. coli infected with BIO-phages could be detected by using fluorescein-conjugated avidin with confocal laser scanning microscopy, and BIO-phages and BIO-phage-derived proteins in E. coli could be directly observed by using the avidin-biotin-peroxidase complex method with electron microscopy. This is the first report of direct visualization of phage infection and phage-derived proteins in the host cell using a biotin-avidin interaction. This simple and powerful method is applicable to the study of infection by various viruses.

Interdomain interactions within the gene 3 protein of filamentous phage.

Infection of Escherichia coli by filamentous phage fd is mediated by the phage gene 3 protein (g3p). The g3p consists of three domains (g3p-D1, D2 and D3) linked by flexible glycine-rich linkers. All three domains are indispensable for phage infectivity; the g3p-D1 domain binds to the TolA receptor presumably at the inner face of the outer membrane, the g3p-D2 domain to the F-pilus and the g3p-D3 domain anchors g3p to the phage coat. The N-terminal domains g3p-D1 and D2 interact with each other; this interaction is abrogated by binding of g3p-D2 to the F-pilus leading to the release of g3p-D1 to bind to TolA. Here, using phages with deletions in g3p, we have discovered a specific interaction between the two N-terminal domains and g3p-D3, the C-terminal domain of g3p. We propose that these interdomain interactions within g3p lead to a compact and stable organisation when displayed on the phage tip, but that during infection, this compact state must be unraveled.

The adsorption protein genes of Xanthomonas campestris filamentous phages determining host specificity.

Gene III (gIII) of phiLf, a filamentous phage specifically infecting Xanthomonas campestris pv. campestris, was previously shown to encode a virion-associated protein (pIII) required for phage adsorption. In this study, the transcription start site for the gene and the N-terminal sequence of the protein were determined, resulting in the revision of the translation initiation site from the one previously predicted for this gene. For comparative study, the gIII of phiXv, a filamentous phage specifically infecting X. campestris pv. vesicatoria, was cloned and sequenced. The deduced amino acid sequences of these two pIIIs exhibit a high degree of identity in their C-terminal halves and possess the structural features typical of the adsorption proteins of filamentous phages: a signal sequence in the N terminus, a long glycine-rich region near the center, and a hydrophobic membrane anchorage domain in the C terminus. The regions between gIII and the upstream gVIII, 128 nucleotides in both phages, are larger than those of other filamentous phages. A hybrid phage of phiXv, consisting of the phiLf pIII and all the other components derived from phiXv, was able to infect X. campestris pv. campestris but not X. campestris pv. vesicatoria, indicating that gIII is the gene specifying host specificity and demonstrating the interchangeability of the pIIIs.

Selecting proteins with improved stability by a phage-based method.

We describe a method for the stabilization of proteins that links the protease resistance of stabilized variants of a protein with the infectivity of a filamentous phage. A repertoire of variants of the protein to be stabilized is inserted between two domains (N2 and CT) of the gene-3-protein of the fd phage. The infectivity of fd phage is lost when the three domains are disconnected by the proteolytic cleavage of unstable protein inserts. Rounds of in vitro proteolysis, infection, and propagation can thus be performed to enrich those phage containing the most stable variants of the protein insert. This strategy discriminates between variants of a model protein (ribonuclease T1) differing in conformational stability and selects from a large repertoire variants that are only marginally more stable than others. Because fd phage are exceptionally stable and the proteolysis in the selection step takes place in vitro a wide range of solvent conditions can be used, tailored for the protein to be stabilized.

Roles of pIII in filamentous phage assembly.

Filamentous phage protein III (pIII), located at one end of the phage, is required for infectivity and stability of the particle. Cells infected with phage from which gene III has been completely deleted produce particles that are not released into the medium but stay associated at the surface. These particles are much longer than normal phage. They can be released by subsequent expression of pIII. Viewed with the electron microscope, cells infected with gene III deletion phage are decorated with structures that resemble extremely long pili. Surprisingly, such cells are viable and can form colonies. The pIII deficiency can be complemented in trans, but there is a threshold concentration below which assembly does not occur. Above this threshold, pIII is used very efficiently and is incorporated into infectious but longer than unit length phage. As the concentration of pIII is increased, the number of infectious particles increases, and their average length decreases.pIII stabilizes pVI, a second phage protein found at the pIII end of the particle. In the absence of pIII, degradation of pVI is very rapid. pIII is thus not only required for infectivity and particle stability, but to terminate assembly and release the phage from its assembly site.

The Vibrio cholerae mannose-sensitive hemagglutinin is the receptor for a filamentous bacteriophage from V. cholerae O139.

We previously isolated from a 1994 isolate of Vibrio cholerae O139 a filamentous lysogenic bacteriophage, choleraphage 493, which inhibits pre-O139 but not post-O139 El Tor biotype V. cholerae strains in plaque assays. We investigated the role of the mannose-sensitive hemagglutinin (MSHA) type IV pilus as a receptor in phage 493 infection. Spontaneous, Tn5 insertion, and mshA deletion mutants are resistant to 493 infection. Susceptibility is restored by mshA complementation of deletion mutants. Additionally, the 493 phage titer is reduced by adsorption with MSHA-positive strains but not with a DeltamshA1 strain. Monoclonal antibody against MSHA inhibits plaque formation. We conclude that MSHA is the receptor for phage 493. The emergence and decline of O139 in India and Bangladesh are correlated with the susceptibility and resistance of El Tor strains to 493. However, mshA gene sequences of post-O139 strains are identical to those of susceptible pre-O139 isolates, indicating that phage resistance of El Tor is not due to a change in mshA. Classical biotype strains are (with rare exceptions) hemagglutinin negative and resistant to 493 in plaque assays. Nevertheless, they express the mshA pilin gene. They can be infected with 493 and produce low levels of phage DNA, like post-O139 El Tor strains. Resistance to 493 in plaque assays is thus not equivalent to resistance to infection. The ability of filamentous phages, such as 493, to transfer large amounts of DNA provides them, additionally, with the potential for quantum leaps in both identity and pathogenicity, such as the conversion of El Tor to O139.

Selectively-infective phage (SIP): a mechanistic dissection of a novel in vivo selection for protein-ligand interactions.

Selectively-infective phage (SIP) is a novel methodology for the in vivo selection of interacting protein-ligand pairs. It consists of two components, (1) a phage particle made non-infective by replacing its N-terminal domains of geneIII protein (gIIIp) with a ligand-binding protein, and (2) an "adapter" molecule in which the ligand is linked to those N-terminal domains of gIIIp which are missing from the phage particle. Infectivity is restored when the displayed protein binds to the ligand and thereby attaches the missing N-terminal domains of gIIIp to the phage particle. Phage propagation is thus strictly dependent on the protein-ligand interaction. We have shown that the insertion of beta-lactamase into different positions of gIIIp, mimicking the insertion of a protein-ligand pair, led to highly infective phage particles. Any phages lacking the first N-terminal domain were not infective at all. In contrast, those lacking only the second N-terminal domain showed low infectivity irrespective of the presence or absence of the F-pilus on the recipient cell, which could be enhanced by addition of calcium. An anti-fluorescein scFv antibody and its antigen fluorescein were examined as a protein-ligand model system for SIP experiments. Adapter molecules, synthesized by chemical coupling of fluorescein to the purified N-terminal domains, were mixed with non-infective anti-fluorescein scFv-displaying phages. Infection events were strictly dependent on fluorescein being coupled to the N-terminal domains and showed a strong dependence on the adapter concentration. Up to 10(6) antigen-specific events could be obtained from 10(10) input phages, compared to only one antigen-independent event. Since no separation of binders and non-binders is necessary, SIP is promising as a rapid procedure to select for high affinity interactions.