Michael Koomey

PilT mutations lead to simultaneous defects in competence for natural transformation and twitching motility in piliated Neisseria gonorrhoeae

Neisseria gonorrhoeae, the Gram‐negative aetiological agent of gonorrhoea, is one of many mucosal pathogens of man that expresses competence for natural transformation. Expression of this phenotype by gonococci appears to rely on the expression of type IV pili (Tfp), but the mechanistic basis for this relationship remains unknown. During studies of gonococcal pilus biogenesis, a homologue of the PilT family of proteins, required for Tfp‐dependent twitching motility in Pseudomonas aeruginosa and social gliding motility in Myxococcus xanthus, was discovered. Like the findings in these other species, we show here that gonococcal pilT mutants constructed in vitro no longer display twitching motility. In addition, we demonstrate that they have concurrently lost the ability to undergo natural transformation, despite the expression of structurally and morphologically normal Tfp. These results were confirmed by the findings that two classes of spontaneous mutants that failed to express twitching motility and transformability carried mutations in pilT. Piliated pilT mutants and a panel of pilus assembly mutants were found to be deficient in sequence‐specific DNA uptake into the cell, the earliest demonstrable step in neisserial competence. The PilT‐deficient strains represent the first genetically defined mutants that are defective in DNA uptake but retain Tfp expression.

Phase variation of gonococcal protein II: Regulation of gene expression by slipped-strand mispairing of a repetitive DNA sequence

Expression of outer membrane protein II (P.II) of Neisseria gonorrhoeae is subject to reversible phase variation at a rate of 10(-3)-10(-4)/cell/generation. The signal peptide coding regions of P.II genes contain variable numbers of tandem repeats of the sequence CTCTT. Changes in the number of CTCTT units, leading to frameshifting within the gene, are responsible for changes in P.II expression. Phase variation mediated by the CTCTT repeat also occurred in E. coli, as assayed with a P.II-alkaline phosphatase (phoA) gene fusion. Phase variation in both the gonococcus and E. coli was recA-independent, occurred at similar rates, and involved insertions or deletions of one or more repeat units. The characteristics of the phase variation process were consistent with a model in which expression of P.II genes is regulated by slipped-strand mispairing of the DNA in the CTCTT repeat region.

Characterization of the pilF—pilD pilus‐assembly locus of Neisseria gonorrhoeae

Expression of Type IV pili by the bacterial pathogen Neisseria gonorrhoeae appears to be essential for colonization of the human host. Several N. gonorrhoeae gene products have been recently identified which bear homology to proteins involved in pilus assembly and protein export in other bacterial systems. We report here the isolation and characterization of transposon insertion mutants in N. gonorrhoeae whose phenotypes indicate that the N. gonorrhoeae pilF and pilD gene products are required for gonoccocal pilus biogenesis. Mutants lacking the pilD gene product, a pre‐pilin peptidase, were unable to process the pre‐pilin subunit into pilin and thus were non‐piliated. pilF mutants processed pilin but did not assemble the mature subunit. Both classes of mutants released S‐pilin, a soluble, truncated form of the pilin subunit previously correlated with defects in pilus assembly. In addition, mutants containing transposon insertions in pilD or in a downstream gene, orfX, exhibited a severely restricted growth phenotype. Deletion analysis of pilD indicated that the poor growth phenotype observed for the pilD transposon mutants was a result of polar effects of the insertions on orfX expression. orfX encodes a predicted polypeptide of 23 kDa which contains a consensus nucleotide‐binding domain and has apparent homologues in Pseudomonas aeruginosa, Pseudomonas putida, Thermus thermophilus, and the eukaryote Caenorhabditis elegans. Although expression of orfX and pilD appears to be transcriptionally coupled, mutants containing transposon insertions in orfX expressed pili. Unlike either pilF or pilD mutants, orfX mutants were also competent for DNA transformation.

Identification and characterization of pilG, a highly conserved pilus-assembly gene in pathogenic Neisseria

Expression of type IV pili appears to be a requisite determinant of infectivity for the strict human pathogens Neisseria gonorrhoeae and Neisseria meningitidis. The assembly of these colonization factors is a complex process. This report describes a new pilus‐assembly gene, pilG, that immediately precedes the gonococcal (Gc) pilD gene encoding the pre‐pilin leader peptidase. The nucleotide sequence of this region revealed a single complete open reading frame whose derived polypeptide displayed significant identities to the pilus‐assembty protein PilC of Pseudomonas aeruginosa and other polytopic integral cytoplasmic membrane constituents involved in protein export and competence. A unique polypeptide of Mr 38kDa corresponding to the gene product was identified. A highly related gene and flanking sequences were cloned from a group E polysaccharide‐producing strain of N. meningitidis (Mc). The results indicate that the pilG genes and genetic organization at these loci in Gc and Me are extremely conserved. Hybridization studies strongly suggest that pilG‐related genes exist in commensal Neisseria species and other species known to express type IV pili. Defined genetic lesions were created by using insertional and transposon mutagenesis and moved into the Gc and Me chromosomes by allelic replacement. Chromosomal pilG insertion mutants were devoid of pili and displayed dramatically reduced competence for transformation. These findings could not be ascribed to pilin‐gene alterations or to polarity exerted on pilD expression. The results indicated that PilG exerts its own independent role in neisserial pilus biogenesis.

PilP, a pilus biogenesis lipoprotein in Neisseria gonorrhoeae, affects expression of PilQ as a high‐molecular‐mass multimer

Studies of gonococcal pilus biogenesis are fundamental to understanding organelle structure/function relationships and identifying new approaches to controlling disease. This area of research is also relevant to elucidating the basic mechanisms of outer membrane translocation of macromolecules, which requires components highly related to those involved in type IV pilus expression. Previous studies have shown that products of several ancillary pil genes are required for organelle biogenesis but of these only PilQ, a member of the GspD protein family, is a component of the outer membrane. DNA sequencing of the region upstream of pilQ revealed the presence of two open reading frames (ORFs) whose deduced polypeptides shared significant identities with proteins required for pilus expression in Pseudomonas aeruginosa and Pseudomonas syringae, the genes for which are arrayed upstream of a gene encoding a PilQ homologue. Gonococcal mutants bearing transposon insertions in these ORFs were non‐piliated and failed to express pilus‐associated phenotypes, and the corresponding genes were designated pilO and pilP. The piliation defects in the mutants could not be ascribed to polarity on distal pilQ expression as shown by direct measurement of PilQ antigen in those backgrounds and the use of a novel technique to create tandem duplications in the gonococcus (Gc) genome. As predicted by the presence of a consensus lipoprotein signal sequence, PilP expressed in both Escherichia coli and Gc could be labelled with [3H]‐palmitic acid. PilP− as well as PilQ− mutants shed PilC, a protein which facilitates pilus assembly and is implicated in epithelial cell adherence, in a soluble form. Combined with the finding that levels of multimerized PilQ were greatly reduced in PilP− mutants, the results suggest that PilP is required for PilQ function and that PilQ and PilC may interact during the terminal stages of pilus biogenesis. The findings also support the hypothesis that the Gc PilQ multimer corresponds to a physiologically relevant form of the protein required for pilus biogenesis.

The pilus colonization factor of pathogenic neisserial species: organelle biogenesis and structure/function relationships--a review.

Type-IV pilus expression plays a critical role in the interactions between Neisseria gonorrhoeae, Neisseria meningitidis and their human host. We have focused on experiments designed to elucidate the mechanisms of organelle biogenesis as one means of understanding the complexities of pilus biology in these species. Employing a variety of approaches, genes and gene products essential to pilus biogenesis have been identified and characterized. The findings indicate that the neisserial type-IV pilus biogenesis machinery is most closely related to that operating in Pseudomonas aeruginosa and other pseudomonad species. This interrelatedness is documented at the levels of gene organization, DNA homologies and identities between the primary structures of the components. Despite these similarities, the biological correlates of pilus expression in the pathogenic Neisseria are quite unique. The current status of our embryonic understanding of the factors influencing organelle biogenesis is presented. In the context of this workshop, emphasis has been placed on specific contributions made through studies of gonococci and meningococci to the field as a whole..

Single amino acid substitutions in the N-terminus of Vibrio cholerae TcpA affect colonization, autoagglutination, and serum resistance

The toxin‐coregulated pilus (TCP) of Vibrio cholerae O1 is required for successful infection of the host. TcpA, the structural subunit of TCP, belongs to the type IV family of pilins, which includes the PilE pilin of Neisseria gonorrhoeae. Recently, single amino acid changes in the N‐terminus of PilE were found to abolish autoagglutination in gonococci. As type IV pilins demonstrate some similarities in function and amino acid sequence, site‐directed mutagenesis and allelic exchange were used to create corresponding mutations in TcpA. All four mutant strains demonstrated autoagglutination defects, and all were highly defective for colonization in the infant mouse model. These results support the previously proposed correlation between autoagglutination and colonization. Finally, all four mutants are serum sensitive, indicating that TcpA plays a role in serum resistance, a phenotype previously attributed to TcpC. As the mutations have similar effects in N. gonorrhoeae and V. cholerae, our results support the idea that type IV pilins have similar functions in a variety of pathogenic bacteria.

The comP locus of Neisseria gonorrhoeae encodes a type IV prepilin that is dispensable for pilus biogenesis but essential for natural transformation.

The expression of type IV pili (Tfp) by Neisseria gonorrhoeae has been shown to be essential for natural genetic transformation at the level of sequence‐specific uptake of DNA. All previously characterized mutants defective in this step of transformation either lack Tfp or are altered in the expression of Tfp‐associated properties, such as twitching motility, autoagglutination and the ability to bind to human epithelial cells. To examine the basis for this relationship, we identified potential genes encoding polypeptides sharing structural similarities to PilE, the Tfp subunit, within the N. gonorrhoeae genome sequence database. We found that disruption of one such gene, designated comP (for competence‐associated prepilin), leads to a severe defect in the capacity to take up DNA in a sequence‐specific manner, but does not alter Tfp biogenesis or expression of the Tfp‐associated properties of autoagglutination, twitching motility and human epithelial cell adherence. Indirect evidence based on immunodetection suggests that ComP is expressed at very low levels relative to that of PilE. The process of DNA uptake in gonococci, therefore, is now known to require the expression of at least three distinct components: Tfp, the recently identified PilT protein and ComP.

Crystallographic structure reveals phosphorylated pilin from Neisseria : phosphoserine sites modify type IV pilus surface chemistry and fibre morphology

Understanding the structural biology of type IV pili, fibres responsible for the virulent attachment and motility of numerous bacterial pathogens, requires a detailed understanding of the three‐dimensional structure and chemistry of the constituent pilin subunit. X‐ray crystallographic refinement of Neisseria gonorrhoeae pilin against diffraction data to 2.6u2003Å resolution, coupled with mass spectrometry of peptide fragments, reveals phosphoserine at residue 68. Phosphoserine is exposed on the surface of the modelled type IV pilus at the interface of neighbouring pilin molecules. The site‐specific mutation of serine 68 to alanine showed that the loss of the phosphorylation alters the morphology of fibres examined by electron microscopy without a notable effect on adhesion, transformation, piliation or twitching motility. The structural and chemical characterization of protein phosphoserine in type IV pilin subunits is an important indication that this modification, key to numerous regulatory aspects of eukaryotic cell biology, exists in the virulence factor proteins of bacterial pathogens. These O‐linked phosphate modifications, unusual in prokaryotes, thus merit study for possible roles in pilus biogenesis and modulation of pilin chemistry for optimal in vivo function.

Conservation of genes encoding components of a type IV pilus assembly/two-step protein export pathway in Neisseria gonorrhoeae

Three gonococcal genes have been identified which encode proteins with substantial similarities to known components of the type IV pilus biogenesis pathway in Pseudomonas aeruginosa. Two of the genes were identified based on their hybridization with a DNA probe derived from the pilB gene of P. aeruginosa under conditions of reduced stringency. The product of the gonococcal pilF gene is most closely related to the pilus assembly protein PilB of P. aeruginosa while the product of the gonococcal pilT gene is most similar to the PilT protein of P. aeruginosa which is involved in pilus‐associated twitching motility and colony morphology. The products of both of these genes display canonical nucleoside triphosphate binding sites and are predicted to be to cytoplasmically localized based on their overall hydrophilicity. The gonococcal pilD gene, identified by virtue of its linkage to the pilF gene, is homologous to a family of prepilin leader peptidase genes. When expressed in Escherichia coli, the gonococcal PilD protein functions to process gonococcal prepilin in a manner consistent with its being gonococcal prepilin peptidase. These results suggest that Neisseria gonorrhoeae is capable of expressing many of the essential elements of a highly conserved protein translocation system and that these gene products are probably involved in pilus biogenesis.