Minor Pilins of the Type IV Pilus System Participate in the Negative Regulation of Swarming Motility

Pseudomonas aeruginosa exhibits distinct surface-associated behaviors, including biofilm formation, flagellum-mediated swarming motility, and type IV pilus-driven twitching. Here, we report a role for the minor pilins, PilW and PilX, components of the type IV pilus assembly machinery, in the repression of swarming motility. Mutating either the pilW or pilX gene alleviates the inhibition of swarming motility observed for strains with elevated levels of the intracellular signaling molecule cyclic di-GMP (c-di-GMP) due to loss of BifA, a c-di-GMP-degrading phosphodiesterase. Blocking PilD peptidase-mediated processing of PilW and PilX renders the unprocessed proteins defective for pilus assembly but still functional in c-di-GMP-mediated swarming repression, indicating our ability to separate these functions. Strains with mutations in pilW or pilX also fail to exhibit the increase in c-di-GMP levels observed when wild-type (WT) or bifA mutant cells are grown on a surface. We also provide data showing that c-di-GMP levels are increased upon PilY1 overexpression in surface-grown cells and that this c-di-GMP increase does not occur in the absence of the SadC diguanylate cyclase. Increased levels of endogenous PilY1, PilX, and PilA are observed when cells are grown on a surface compared to liquid growth, linking surface growth and enhanced signaling via SadC. Our data support a model wherein PilW, PilX, and PilY1, in addition to their role(s) in type IV pilus biogenesis, function to repress swarming via modulation of intracellular c-di-GMP levels. By doing so, these pilus assembly proteins contribute to P. aeruginosa's ability to coordinately regulate biofilm formation with its two surface motility systems.     

The physical basis of type 4 pilus-mediated microcolony formation by Vibrio cholerae O1

The Vibrio cholerae toxin co-regulated pilus (TCP) is a type 4b pilus that mediates bacterial microcolony formation, which is essential for intestinal colonization. Structural analyses have defined a surface domain of the TcpA pilin subunit that is displayed repeatedly around the pilus filament surface and forms the molecular basis for pilus-pilus interactions required for microcolony formation. The physical attributes of this domain that lead to pilus-pilus association between bacteria are not known. Mutational analysis has revealed alterations within this domain that allow pilus-pilus interactions among pili expressed by individual bacteria, but do not allow pilus-pilus mediated association between bacteria. We characterized these altered strains using conventional microscopy, as well as three-dimensional high-resolution field emission scanning electron microscopy (FESEM), to reveal the physical difference between nonproductive and productive pilus associations that lead to interactions among multiple bacteria and result in microcolony formation. These findings pave the way towards investigation of the biophysical parameters involved in this basic bacterial property that promotes colonization of intestinal and other biological surfaces.     

Development and maturation of Escherichia coli K-12 biofilms

The development and maturation of E. coli biofilms in flow-chambers was investigated. We found that the presence of transfer constitutive IncF plasmids induced biofilm development forming structures resembling those reported for Pseudomonas aeruginosa. The development occurred in a step-wise process: (i). attachment of cells to the substratum, (ii). clonal growth and microcolony formation, and (iii). differentiation into expanding structures rising 70-100 microm into the water phase. The first two steps were the same in the plasmid-carrying and plasmid-free strains, whereas the third step only occurred in conjugation pilus proficient plasmid-carrying strains. The final shapes of the expanding structures in the mature biofilm seem to be determined by the pilus configuration, as various mutants affected in the processing and activity of the transfer pili displayed differently structured biofilms. We further provide evidence that flagella, type 1 fimbriae, curli and Ag43 are all dispensable for the observed biofilm maturation. In addition, our results indicate that cell-to-cell signalling mediated by autoinducer 2 (AI-2) is not required for differentiation of E. coli within a biofilm community. We suggest on the basis of these results that E. coli K-12 biofilm development and maturation is dependent on cell-cell adhesion factors, which may act as inducers of self-assembly processes that result in differently structured biofilms depending on the adhesive properties on the cell surface.     

Pseudomonas aeruginosa Minor Pilins Are Incorporated into Type IV Pili

Type IV pili are long filamentous appendages required for both adhesion and a unique form of motility known as twitching. Twitching motility involves the extension and retraction of the pilus and requires a number of gene products, including five conserved pilin-like proteins of unknown function (FimU, PilV, PilW, PilX, and PilE in Pseudomonas aeruginosa), termed ‘minor’ pilins. Maintenance of a specific stoichiometric ratio among the minor pilins was important for function, as loss or overexpression of any component impaired motility. Disruption of individual minor pilin genes, or of the AlgR positive regulator of minor pilin operon expression in a strain where pilus retraction was blocked by inactivation of the PilT retraction ATPase, revealed that pili were produced, although levels of piliation were reduced relative to pilT positive control. Differences in the levels of piliation of complemented strains pointed to specific roles for each protein in the assembly process, with FimU and PilX being implicated as key promoters of pilus assembly on the cell surface. Using specific antibodies for each protein, we showed that the minor pilins FimU, PilV, PilW, PilX, and PilE were processed by the pre-pilin peptidase PilD and incorporated throughout the growing pilus filament. This is the first study to demonstrate that the minor pilins, conserved among bacteria expressing type IVa pili, are incorporated into the fiber and support a role for them in the initiation, but not termination, of pilus assembly.     

Microcolonies, quorum sensing and cytotoxicity determine the survival of Pseudomonas aeruginosa biofilms exposed to protozoan grazing

This study was based on the hypothesis that biofilms of the opportunistic pathogen Pseudomonas aeruginosa are successfully adapted to situations of protozoan grazing. We tested P. aeruginosa wild type and strains that were genetically altered, in structural and regulatory features of biofilm development, in response to the common surface-feeding flagellate Rhynchomonas nasuta. Early biofilms of the wild type showed the formation of grazing resistant microcolonies in the presence of the flagellate, whereas biofilms without the predator were undifferentiated. Grazing on biofilms of quorum sensing mutants (lasR and rhlR/lasR) also resulted in the formation of microcolonies, however, in lower numbers and size compared to the wild type. Considerably fewer microcolonies than the wild type were formed by mutant cells lacking type IV pili, whereas no microcolonies were formed by flagella-deficient cells. The alginate-overproducing strain PDO300 developed larger microcolonies in response to grazing. These observations suggest a role of quorum sensing in early biofilms and involvement of flagella, type IV pili, and alginate in microcolony formation in the presence of grazing. More mature biofilms of the wild type exhibited acute toxicity to the flagellate R. nasuta. Rapid growth of the flagellate on rhlR/lasR mutant biofilms indicated a key role of quorum sensing in the upregulation of lethal factors and in grazing protection of late biofilms. Both the formation of microcolonies and the production of toxins are effective mechanisms that may allow P. aeruginosa biofilms to resist protozoan grazing and to persist in the environment.     

Multiple roles of biosurfactants in structural biofilm development by Pseudomonas aeruginosa

Recent studies have indicated that biosurfactants produced by Pseudomonas aeruginosa play a role both in maintaining channels between multicellular structures in biofilms and in dispersal of cells from biofilms. Through the use of flow cell technology and enhanced confocal laser scanning microscopy, we have obtained results which suggest that the biosurfactants produced by P. aeruginosa play additional roles in structural biofilm development. We present genetic evidence that during biofilm development by P. aeruginosa, biosurfactants promote microcolony formation in the initial phase and facilitate migration-dependent structural development in the later phase. P. aeruginosa rhlA mutants, deficient in synthesis of biosurfactants, were not capable of forming microcolonies in the initial phase of biofilm formation. Experiments involving two-color-coded mixed-strain biofilms showed that P. aeruginosa rhlA mutants were defective in migration-dependent development of mushroom-shaped multicellular structures in the later phase of biofilm formation. Experiments involving three-color-coded mixed-strain P. aeruginosa biofilms demonstrated that the wild-type and rhlA and pilA mutant strains formed distinct subpopulations on top of each other dependent on their ability to migrate and produce biosurfactants.     

Autoinducer 2 production by Streptococcus gordonii DL1 and the biofilm phenotype of a luxS mutant are influenced by nutritional conditions

The luxS gene, present in many bacterial genera, encodes the autoinducer 2 (AI-2) synthase. AI-2 has been implicated in bacterial signaling, and this study investigated its role in biofilm formation by Streptococcus gordonii, an organism that colonizes human tooth enamel within the first few hours after professional cleaning. Northern blotting and primer extension analyses revealed that S. gordonii luxS is monocistronic. AI-2 production was dependent on nutritional conditions, and maximum AI-2 induction was detected when S. gordonii was grown in the presence of serum and carbonate. In planktonic cultures, AI-2 production rose sharply during the transition from exponential to stationary phase, and the AI-2 concentration peaked approximately 4 h into stationary phase. An S. gordonii luxS mutant that did not produce AI-2 was constructed by homologous recombination. Complementation of the mutant by insertion of an intact luxS gene into the chromosome in tandem with the disrupted gene restored AI-2 production to a level similar to that of the wild-type strain. In planktonic culture, no growth differences were observed between the mutant and wild-type strains when five different media were used. However, when grown for 4 h as biofilms in 25% human saliva under flow, the luxS mutant formed tall microcolonies that differed from those formed by the wild-type and complemented mutant strains. Biofilms of the luxS mutant exhibited finger-like projections of cells that extended into the flow cell lumen. Thus, the inability to produce AI-2 is associated with altered microcolony architecture within S. gordonii biofilms formed in saliva during a time frame consistent with initial colonization of freshly cleaned enamel surfaces.     

Limited variation and maintenance of tight genetic linkage characterize heteroallelic pilE recombination following DNA transformation of Neisseria gonorrhoeae

Genetic recombination impacts on neisserial biology in two ways: (i) specific loci undergo rearrangement at high frequency leading to the formation of many different alleles; and (ii) Neisseria , being naturally competent for DNA transformation, provide a means to disseminate the novel alleles throughout a population. In this study pilE was used as a model system to examine heteroallelic recombination following DNA transformation. When gonococci were transformed with chromosomal donor DNA containing different pilE alleles, the majority of pilE recombinants arose through allelic replacement. Co-conversion analysis across pilE showed that in ∼ 85–90% of recombination events encompassing pilE and an adjacent opa locus, linkage was maintained (i.e. ∼ 10–15% of recombination events terminated within the ∼ 1000 base pair pilE/opaE interval). In addition to those recombinants that arose through allelic replacement, a large pilus-minus subpopulation was also observed (∼ 10% of all recombinants), indicating that many recombination events did not yield recombinant pilE s that could be assembled into functional pili. PilE mosaics increased following transformation with plasmid donor DNAs carrying pilE with limited flanking-sequence homology, suggesting a potential role for flanking-sequence homologies in mosaic formation. Overall, the data support the view that horizontal transmission of chromosomal DNA between gonococci will favour the spread of intact alleles, as opposed to expanding the allelic repertoire through the formation of gene mosaics.     

Role of chromosomal rearrangement in N. gonorrhoeae pilus phase variation

N. gonorrhoeae undergoes pilus phase and antigenic variation. During phase variation, the pilin gene is turned on and off at high frequencies. Two loci on the gonococcal chromosome from strain MS11 function as expression sites for the pilin gene (pilE1 and pilE2); many other sites apparently contain silent variant pilin sequences. We reported previously that during pilus phase variation, when cells switch from the pilus expressing state (P+) to the nonexpressing state (P-), genome rearrangement occurs. We have examined phase variation in more detail, and we report that in most P+ to P- switches a deletion of pilin gene information occurs in one or both expression sites. This deletion is due to either a simple or a multiple-step recombination event involving directly repeated sequences in the expression loci. The deletion explains the state of some P- cells, but not all. In the latter cells pilin expression is probably controlled by an undefined regulator.     

Esp-independent biofilm formation by Enterococcus faecalis

Enterococcus faecalis is a gram-positive opportunistic pathogen known to form biofilms in vitro. In addition, this organism is often isolated from biofilms on the surfaces of various indwelling medical devices. However, the molecular mechanisms regulating biofilm formation in these clinical isolates are largely unknown. Recent work has suggested that a specific cell surface protein (Esp) of E. faecalis is critical for biofilm formation by this organism. However, in the same study, esp-deficient strains of E. faecalis were found to be capable of biofilm formation. To test the hypothesis that Esp is dispensable for biofilm formation by E. faecalis, we used microtiter plate assays and a chemostat-based biofilm fermentor assay to examine biofilm formation by genetically well-defined, non-Esp-expressing strains. Our results demonstrate that in vitro biofilm formation occurs, not only in the absence of esp, but also in the absence of the entire pathogenicity island that harbors the esp coding sequence. Using scanning electron microscopy to evaluate biofilms of E. faecalis OG1RF grown in the fermentor system, biofilm development was observed to progress through multiple stages, including attachment of individual cells to the substratum, microcolony formation, and maturation into complex multilayered structures apparently containing water channels. Microtiter plate biofilm analyses indicated that biofilm formation or maintenance was modulated by environmental conditions. Furthermore, our results demonstrate that expression of a secreted metalloprotease, GelE, enhances biofilm formation by E. faecalis. In summary, E. faecalis forms complex biofilms by a process that is sensitive to environmental conditions and does not require the Esp surface protein.     

Evolutionary and functional diversity of the Pseudomonas type IVa pilin island

In Pseudomonas aeruginosa, most proteins involved in type IVa pilus (T4aP) biogenesis are highly conserved except for the major pilin PilA and the minor pilins involved in pilus assembly. Here we show that each of the five major pilin alleles is associated with a specific set of minor pilins, and unrelated strains with the same major pilin type have identical minor pilin genes. The sequences of the minor pilin genes of strains with group III and V pilins are identical, suggesting that these groups diverged recently through further evolution of the major pilin cluster. Both gene clusters are localized on a single ‘pilin island’ containing putative tRNA recombinational hotspots, and a similar organization of pilin genes was identified in other Pseudomonas species. To address the biological significance of group‐specific differences, cross‐complementation studies using group II (PAO1) and group III (PA14) minor pilins were performed. Heterologous minor pilins complemented twitching motility to various extents except in the case of PilX, which was non‐functional in non‐native backgrounds. A recombinant PA14 strain expressing the PAO1 minor pilins regained motility only upon co‐introduction of the PA14 pilX gene. Comparison of PilX and PilQ secretin sequences from group II, III and V genomes revealed discrete regions of sequence that co‐varied between groups. Our data suggest that changes in PilX sequence have led to compensatory changes in the PilQ secretin monomer such that heterologous PilX proteins are no longer able to promote opening of the secretin to allow pili to appear on the cell surface.     

Type IV pili—a numbers game

Type IV pili are long polymers located on the surface of a wide variety of bacterial cells, including the pathogen Neisseria meningitidis. They are responsible for a diverse range of functions, including adhesion, motility and natural transformation. In this issue of The EMBO Journal, Imhaus and Duménil show that two minor pilins, PilX and PilV, exert some of their effects by changing mean surface pilus number and that this modulates different pilus‐dependent functions.     

Recombinational error and deletion formation in Neisseria gonorrhoeae: a role for RecJ in the production of pilE L deletions

Genetic linkage within Neisseria gonorrhoeae populations is in equilibrium, yet the physical linkage map indicates a relatively stable chromosome structure, despite an apparently vast potential for mispairing between repeated sequences (e.g. between the multiple pil or opa alleles, or through mispairing of any of the numerous small repeated sequences that are liberally scattered throughout the chromosome). Therefore, the stability of the physical linkage map suggests that aberrant recombination between repeated sequences is a rare event. This study was undertaken to explore some of the parameters that may govern deletion events between short direct oligonucleotide repeats, using a chromosomal locus that appears to be especially prone to deletions (the pilin expression locus; pilE). In this report, we demonstrate that deletion formation at pilE occurs primarily through recombinational error following a pilE/pilS interaction; illegitimate (i.e. RecA-independent) events can occur, but they are infrequent. In contrast, when genetically engineered opa deletion substrates were constructed and placed in the chromosome, deletions at the opa loci were infrequent even under rec(+) conditions. A model is presented in which the gonococcal RecA and RecJ proteins promote pilE deletions through a recombination event that is templated or stabilised by a pilE/pilS interaction.     

Comparison of microcolony formation between Vibrio sp. strain S141 and a flagellum-negative mutant developing on agar and glass substrata

A flagellum-negative mutant, M8.2, of the marine bacterium Vibrio sp. S141 was produced by transposon mutagenesis. Time-lapse video imaging of surface colonisation behaviour and microcolony formation of S141 compared to M8.2 cells was carried out to investigate the role of the flagellum of Vibrio sp. S141 in microcolony formation on agar and glass substrata. On an agar surface, S141 cells formed a tetrad pattern after the first two cell divisions, during initial surface colonisation. Developed microcolonies consisted of tight circular arrangements of cells with infrequent branching of cells from the main body. In contrast, M8.2 cells did not form tetrad patterns and micro-colonies generally showed enhanced branching and did not develop circular arrangements of cells. On a glass surface under flow conditions, S141 cells displayed several types of movement behaviours at the surface which may have assisted microcolony formation. M8.2 cells appeared unable to develop micro-colonies, but rather displayed a behaviour which enabled them to spread out across the substratum. Laser scanning confocal microscopy revealed S141 mature biofilms consisted of characteristic towers of bacterial growth with scattered troughs. The flagellum-negative M8.2 biofilm did not form such architecture, displaying a homogeneous distribution of cells throughout the biofilm and across the entire substratum. Although not required for attachment to the glass substratum, the flagellum was required for alignment as well as specific movement behaviours by S141 cells.     

The role of quorum sensing mediated developmental traits in the resistance of Serratia marcescens biofilms against protozoan grazing

Resistance against protozoan grazers is a crucial factor that is important for the survival of many bacteria in their natural environment. However, the basis of resistance to protozoans and how resistance factors are regulated is poorly understood. In part, resistance may be due to biofilm formation, which is known to protect bacteria from environmental stress conditions. The ubiquitous organism Serratia marcescens uses quorum sensing (QS) control to regulate virulence factor expression and biofilm formation. We hypothesized that the QS system of S. marcescens also regulates mechanisms that protect biofilms against protozoan grazing. To investigate this hypothesis, we compared the interactions of wild-type and QS mutant strains of S. marcescens biofilms with two protozoans having different feeding types under batch and flow conditions. Under batch conditions, S. marcescens forms microcolony biofilms, and filamentous biofilms are formed under flow conditions. The microcolony-type biofilms were protected from grazing by the suspension feeder, flagellate Bodo saltans, but were not protected from the surface feeder, Acanthamoeba polyphaga. In contrast, the filamentous biofilm provided protection against A. polyphaga. The main findings presented in this study suggest that (i) the QS system is not involved in grazing resistance of S. marcescens microcolony-type biofilms; (ii) QS in S. marcescens regulates antiprotozoan factor(s) that do not interfere with the grazing efficiency of the protozoans; and (iii) QS-controlled, biofilm-specific differentiation of filaments and cell chains in biofilms of S. marcescens provides an efficient mechanism against protozoan grazing.     

The role of direct oligonucleotide repeats in gonococcal pilin gene variation

Previous studies indicate that gonococcal pilin phase and antigenic variation occur by intragenomic pilin gene recombination, the outcome of which resembles that of gene conversion. During such transitions, the expressed complete pilin gene (pilE) acquires a novel sequence corresponding to that of a silent pilin gene (pilS). In the present study, we find that internal deletions of pilE can produce pilus-/pilus+ phase transitions: direct oligonucleotide repeats in the pilin-encoding portion of pilE bracket the deleted segments. A novel, orthodox pilE is formed upon repair of the internal deletions, with pilS sequence probably acting as a template for repair. Such deletion/repair of pilE is suggested as a principal mechanism underlying gonococcal pilus variation.     

Structural analysis of the pilE region of Neisseria gonorrhoeae P9

We have determined the nucleotide sequence of an expressed structural pilus gene (pilE) derived from Neisseria gonorrhoeae strain P9-2. Detailed analysis of nucleotide sequences upstream from pilE revealed a silent, truncated pilin gene segment that was linked to families of DNA elements (RS1 and RS3) that have previously been identified at the major silent pilin gene locus (pilS1) and at pilE of the independently isolated N. gonorrhoeae strain MS11ms. A nucleotide sequence downstream from pilE was reminiscent of the recognition sequences of several recombinases, including Tn3 tnpR product (resolvase), suggesting a possible role for site-specific events in the recombinational modulation of pilus expression.