Paula Fives-Taylor

Isolation and characterization of Fap1, a fimbriae-associated adhesin of Streptococcus parasanguis FW213

An adhesin of Streptococcus parasanguis FW213, a primary colonizer of the tooth surface, has been purified from the culture medium by immunoaffinity chromatography. The purified protein has a molecular mass of 200 kDa and stains positively for carbohydrate. The amino‐terminal sequence indicated that this protein represented a unique streptococcal surface protein. Immunogold labelling of the bacterium indicated that this protein was associated with fimbriae and designated Fap1 (fimbriae‐associated protein). A polymerase chain reaction (PCR) product based on the amino terminus of Fap1 was used to probe an FW213 genomic library. A 9 kb fragment containing the fap1 gene was isolated and 2.5 kb have been sequenced. Generation of fap1 mutants by a single cross‐over (Campbell insertion) or a non‐polar allelic exchange abolished the expression of Fap1. The inactivation of fap1 resulted in a dramatic reduction in the expression of the long peritrichous fimbriae and adhesion to saliva‐coated hydroxylapatite (SHA). Northern blots probed with an internal gene fragment of fap1 hybridized to a 9 kb transcript, which suggests that fap1 is transcribed as a polycistronic message. These data demonstrate that Fap1 is a unique streptococcal adhesin that is involved in the assembly of S. parasanguis FW213 fimbriae and adhesion to SHA.

Oral pathogens: from dental plaque to cardiac disease

Oral bacteria exhibit highly specific adherence mechanisms and as a result they colonize and cause disease principally in the oral cavity. Oral pathogens, however, can produce systemic disease and are known causative agents of infective endocarditis. Recent studies have revealed that periodontal disease per se is also a statistically significant risk factor for cardiovascular disease. A link between the two diseases is the secretion and systemic appearance in periodontitis of pro-inflammatory cytokines capable of eliciting effects associated with atherosclerosis and coronary heart disease.

The role of Actinobacillus actinomycetemcomitans in the pathogenesis of periodontal disease

Periodontal disease consists of a constellation of complex bacterium-host cell interactions. One example of these oral pathogens, Actinobacillus actinomycetemcomitans, has an arsenal of putative virulence determinants that account for its potent periodontopathogenicity. Of these determinants, invasion of host cells and leukocytotoxicity have been studied extensively.

The fimA locus of Streptococcus parasanguis encodes an ATP‐binding membrane transport system

The gene encoding fimA, a 36 kDa fimbrial adhesin of Streptococcus parasanguis FW213, is highly conserved in all four genetic groups of sanguis streptococci. FimA‐like peptides were produced by all strains tested. The nucleotide sequence directly upstream of fimA contains two open reading frames, ORF5 and ORF1, whose deduced protein products are homologous to members of a superfamily of ATP‐binding cassette membrane transport proteins, including both prokaryotic and aukaryotic uptake and export systems. The amino acid sequence of FimA contains the consensus prolipoprotein cleavage site (LxxC) common to the‘periplasmic’ binding proteins of Gram‐positive transport systems. The deduced product of ORF5 is a 28.6 kDa membrane‐associated protein that has the consensus binding site for ATP (GxxGxGKS). It shares significant homology with AmiE of Streptococcus pneumoniae as well as with Escherichia coli proteins involved in iron(III) uptake. Allelic‐replacement mutagenesis of ORF5 resulted in greatly Increased resistance to aminopterin. These data demonstrate functionality with the amiE locus as well. The deduced product of ORF1 is an extremely hydrophobic integral membrane protein of 30.8 kDa with a pattern of six potential membrane‐spanning regions, typical of a component of these types of transport system. The nucleotide sequence downstream of fimA. ORF3, encodes a 20 kDa protein having 78% identity with the 20 kDa protein encoded downstream of ssaB, a fimA homologue in S. sanguis 12. It also exhibits significant homology with bacterioferritin co‐migratory protein (Bcp) of E. coli K‐12. Allelic‐replacement mutagenesis in the fimA locus of FW213 showed that (i) expression of fimA was initiated at a site far upstream of the fimA start codon, and (ii) expression of fimA was not linked to expression of ORF3. Northern blots probed with internal fragments of ORF5, ORF1, fimA or ORF3 hybridized to the same transcript of 3.3 kb, which suggested that these loci were transcribed as a polycistronic message. The ORF3 probe also hybridized to a 540 bp transcript consistent with the size of ORF3 alone and supportive of the mutagenesis data of non‐linkage. Strains mutated in fimA continued to produce fimbriae, indicating that FimA was not the fimbrial structural subunit. Immunoelectron microscopy revealed FimA was localized at the tips of the fimbriae of FW213. This is the first study that demonstrates that an adhesin which binds a bacterial cell to a substrate is associated with an ATP‐binding cassette.

The Fap1 fimbrial adhesin is a glycoprotein: antibodies specific for the glycan moiety block the adhesion of Streptococcus parasanguis in an in vitro tooth model.

Streptococcus parasanguis is a primary colonizer of the tooth surface and plays a pivotal role in the formation of dental plaque. The fimbriae of S. parasanguis are important in mediating adhesion to saliva‐coated hydroxylapatite (SHA), an in vitro tooth adhesion model. The Fap1 adhesin has been identified as the major fimbrial subunit, and recent studies suggest that Fap1 is a glycoprotein. Monosaccharide analysis of Fap1 purified from the culture supernatant of S. parasanguis indicated the presence of rhamnose, glucose, galactose, N‐acetylglucosamine and N‐acetylgalactosamine. A glycopeptide moiety was isolated from a pronase digest of Fap1 and purified by immunoaffinity chromatography. The monosaccharide composition of the purified glycopeptide was similar to that of the intact molecule. The functionality of the glycan moiety was determined using monoclonal antibodies (MAbs) specific for the intact Fap1 glycoprotein. These antibodies were grouped into two categories based on their ability to block adhesion of S. parasanguis to SHA and their corresponding specificity for either protein or glycan epitopes of the Fap1 protein. ‘Non‐blocking’ MAb epitopes were mapped to unique protein sequences in the N‐terminus of the Fap1 protein using non‐glycosylated recombinant Fap1 proteins (rFap1 and drFap1) expressed in Escherichia coli. In contrast, the ‘blocking’ antibodies did not bind to the recombinant Fap1 proteins, and were effectively competed by the binding to the purified glycopeptide. These data suggest that the ‘blocking’ antibodies are specific for the glycan moiety and that the adhesion of S. parasanguis is mediated by sugar residues associated with Fap1.

Streptococcus parasanguis Fimbria-Associated Adhesin Fap1 Is Required for Biofilm Formation

ABSTRACT The sanguis streptococci are primary colonizers of the tooth surface and thus form the foundation for the complex multiple species biofilm known as dental plaque. In addition, these bacteria can colonize native and prosthetic heart valves and are a common cause of endocarditis. Little is known about the molecular mechanisms governing multiple or single species biofilm development within this group of organisms. Using an in vitro assay for biofilm formation, we determined that (i) Streptococcus parasanguis FW213 can form biofilms on inert surfaces such as polystyrene and (ii) environmental and nutritional factors, such as glucose, affect S. parasanguisbiofilm formation. Several isogenic mutants of FW213 were tested in the biofilm assay. Strains containing mutations in fap1, a gene encoding a protein required for assembly of fimbriae, were deficient in biofilm formation. Mutants defective in recA, PepO endopeptidase activity, or the production of a fimbriae-associated protein, FimA, were still capable of biofilm formation. Phase-contrast microscopy was used to follow biofilm development by wild-type andfap1 mutant strains on plastic coverslips over time. Wild-type FW213 attached to the surface, formed aggregates of cells, and eventually formed a dense layer of cells that included microcolonies. In contrast, few fap1 mutant cells were observed attached to the surface, and no cell aggregates or microcolonies were formed. These results suggest that the long peritrichous fimbriae of FW213 are critical for the formation of biofilms on solid surfaces.

Identification of dipeptide repeats and a cell wall sorting signal in the fimbriae‐associated adhesin, Fap1, of Streptococcus parasanguis

Fap1, a fimbriae‐associated protein, is involved in fimbriae assembly and adhesion of Streptococcus parasanguis FW213 ( Wu et al., 1998 ). In this study, the sequence of the fap1 gene was resolved using a primer island transposition system. Sequence analysis indicated that fap1 was composed of 7659 nucleotides. The predicted Fap1 protein contains an unusually long signal sequence (50 amino acid residues), a cell wall sorting signal and two repeat regions. Repeat regions I and II have a similar dipeptide composition (E/V/I)S, composed of 28 and 1000 repeats respectively. The two regions combined accounted for 80% of the Fap1 coding region. The experimental amino acid composition and isoelectric point (pI) of Fap1 were similar to that predicted from the deduced Fap1 protein. Results of Northern analyses revealed that the fap1 open reading frame (ORF) was transcribed as a 7.8 kb monocistronic message. Insertional inactivation at the 3′ end, downstream of the fap1 ORF, did not affect Fap1, fimbrial expression or bacterial adhesion. Insertional inactivation of fap1 immediately upstream of the repeat region II abolished expression of Fap1 and fimbriae, and was concurrent with a diminution in adhesion of FW213. Inactivation of the cell wall sorting signal of fap1 also eliminated long fimbrial formation and reduced the ability of FW213 to bind to SHA. Fap1 was no longer anchored on the cell surface. Large quantities of truncated Fap1 were found in the growth medium instead. These results suggest that the fap1 ORF alone is sufficient to support Fap1 expression and adhesion, and demonstrate that anchorage of Fap1 on the cell surface is required for long fimbriae formation. These data further document the role of long fimbriae in adhesion of S. parasanguis FW213 to SHA.

Characteristics of Actinobacillus Actinomycetemcomitans Invasion of and Adhesion to Cultured Epithelial Cells

Actinobacillus actinomycetemcomitans (A.a.) is highly implicated in periodontitis. We have developed several in vitro models using the KB oral cell line to examine A.a.-epithelial cell interactions. In support of the use of KB cell line model systems is our finding that A.a. invaded KB and primary gingival cells to the same extent. Invasion is an active event which requires new protein synthesis by both KB and A.a. Like many other intracellular parasites, A.a. invade by receptor-mediated endocytosis. We observed that internalized A.a. were surrounded by foci of actin which had been transported from the periphery of the KB cell. Adhesion of A.a. to KB cells occurred rapidly and stimulated the formation of microvilli. Adhesion is affected by both host factors (saliva, serum, [NaCI]) and culture conditions. Multiple determinants [fimbriae, outer membrane proteins, vesicles, and/or an extracellular amorphous material (ExAmMat)] which are either associated with the A.a. surface or are released into the milieu are involved. We determined that ExAmMat can convey adhesiveness to weakly adherent A.a. and to at least one other oral species (Streptococcus parasanguis).

Molecular Strategies for Fimbrial Expression and Assembly

Fimbriae or pili are long, filamentous, multimeric macromolecules found on the bacterial cell surface. Bacteria express a diverse array of fimbriae or pili that are involved in bacterial adherence and invasion. Fimbriae can be categorized based on their modes of expression and assembly. Type I fimbriae and P pili are distributed peritrichously and translocated to the cell surface by a chaperone/usher pathway. Type 4 pili are located at the pole of the cell and assembled via the type II secretion system. Curli fimbriae are coiled surface structures assembled by an extracellular nucleation/precipitation pathway. Fimbriae of oral gram-negative and gram-positive bacteria have not been well-studied as compared with the fimbriae of enteric pathogens. Oral pathogens, such as Eikenella corrodens, Actinobacillus actinomycetemcomitans, and Porphyromonas gingivalis, possess fimbriae that have been implicated in bacterial adhesion and invasion. These fimbriae are potential virulence factors in oral infectious processes. A. actinomycetemcomitans and E. corrodens have Type 4-like fimbriae, whereas P. gingivalis displays a unique type of fimbriae. To date, fimbriae of the oral primary colonizers, Actinomyces naeslundii and Streptococcus parasanguis, represent the only fimbriae characterized for any gram-positive bacteria. The putative major fimbrial subunits, FimA and FimP of A. naeslundii and Fap1 of S. parasanguis, contain a signal sequence and cell-wall-sorting signal. The presence of extensive dipeptide repeats in Fap1 makes it unique among fimbrial molecules. Based on experimental data, a nucleation/precipitation pathway is proposed for fimbrial biogenesis of both S. parasanguis and A. naeslundii, although we cannot rule out an alternative covalent linkage model. The model systems described in this review served as a framework for hypotheses for how the known molecular factors of fimbriae on oral bacteria may be expressed and assembled.

Models of Invasion of Enteric and Periodontal Pathogens Into Epithelial Cells: A Comparative Analysis

Bacterial invasion of epithelial cells is associated with the initiation of infection by many bacteria. To carry out this action, bacteria have developed remarkable processes and mechanisms that co-opt host cell function and stimulate their own uptake and adaptation to the environment of the host cell. Two general types of invasion processes have been observed. In one type, the pathogens (e.g., Salmonella and Yersinia spp.) remain in the vacuole in which they are internalized and replicate within the vacuole. In the other type, the organism (e.g., Actinobacillus actinomycetemcomitans, Shigella flexneri, and Listeria monocytogenes) is able to escape from the vacuole, replicate in the host cell cytoplasm, and spread to adjacent host cells. The much-studied enteropathogenic bacteria usurp primarily host cell microfilaments for entry. Those organisms which can escape from the vacuole do so by means of hemolytic factors and C type phospholipases. The cell-to-cell spread of these organisms is mediated by microfilaments. The investigation of invasion by periodontopathogens is in its infancy in comparison with that of the enteric pathogens. However, studies to date on two invasive periodontopathogens. A actinomycetemcomitans and Porphyromonas (Bacteroides) gingivalis, reveal that these bacteria have developed invasion strategies and mechanisms similar to those of the enteropathogens. Entry of A. actinomycetemcomitans is mediated by microfilaments, whereas entry of P. gingivalis is mediated by both microfilaments and microtubules. A. actinomycetemcomitans, like Shigella and Listeria, can escape from the vacuole and spread to adjacent cells. However, the spread of A. actinomycetemcomitans is linked to host cell microtubules, not microfilaments. The paradigms presented establish that bacteria which cause chronic infections, such as periodontitis, and bacteria which cause acute diseases, such as dysentery, have developed similar invasion strategies.