Complete genome sequence of Finegoldia magna, an anaerobic opportunistic pathogen.

Finegoldia magna (formerly Peptostreptococcus magnus), a member of the Gram-positive anaerobic cocci (GPAC), is a commensal bacterium colonizing human skin and mucous membranes. Moreover, it is also recognized as an opportunistic pathogen responsible for various infectious diseases. Here, we report the complete genome sequence of F. magna ATCC 29328. The genome consists of a 1,797,577 bp circular chromosome and an 189,163 bp plasmid (pPEP1). The metabolic maps constructed based on the genome information confirmed that most F. magna strains cannot ferment most sugars, except fructose, and have various aminopeptidase activities. Three homologs of albumin-binding protein, a known virulence factor useful for antiphagocytosis, are encoded on the chromosome, and one albumin-binding protein homolog is encoded on the plasmid. A unique feature of the genome is that F. magna encodes many sortase genes, of which substrates may be involved in bacterial pathogenesis, such as antiphagocytosis and adherence to the host cell. The plasmid pPEP1 encodes seven sortase and seven substrate genes, whereas the chromosome encodes four sortase and 19 substrate genes. These plasmid-encoded sortases may play important roles in the pathogenesis of F. magna by enriching the variety of cell wall anchored surface proteins.

An immunohistological study of the localization of bacteria invading root pulpal walls of teeth with periapical lesions.

We immunohistologically examined the prevalence and localization of bacteria invading dentinal tubules of the roots of teeth with infected canals. Forty extracted teeth with apical lesions were selected and divided into two groups: a group of untreated teeth and a group of canal-enlarged teeth. The bacteria in the specimens were detected by Brown-Brenn stain and the labeled-streptavidin-biotin method with specific antisera for 16-bacteria. Seventy percent of the examined teeth showed bacteria invading the dentinal tubules of the roots. Fusobacterium nucleatum, Eubacterium alactolyticum, E. nodatum, Lactobacillus casei, and Peptostreptococcus micros were abundant. Even in the canal-enlarged group, invasion of bacteria was observed in 65% of teeth. This study revealed the actual condition of bacteria in infected root dentin and suggested that the canal-enlargement procedure could not completely remove all the bacteria in the infected dentinal tubules of the root.

Cloning of fibA, encoding an immunogenic subunit of the fibril-like surface structure of Peptostreptococcus micros.

Although we are currently unaware of its biological function, the fibril-like surface structure is a prominent characteristic of the rough (Rg) genotype of the gram-positive periodontal pathogen Peptostreptococcus micros. The smooth (Sm) type of this species as well as the smooth variant of the Rg type (RgSm) lack these structures on their surface. A fibril-specific serum, as determined by immunogold electron microscopy, was obtained through adsorption of a rabbit anti-Rg type serum with excess bacteria of the RgSm type. This serum recognized a 42-kDa protein, which was subjected to N-terminal sequencing. Both clones of a lambdaTriplEx expression library that were selected by immunoscreening with the fibril-specific serum contained an open reading frame, designated fibA, encoding a 393-amino-acid protein (FibA). The 15-residue N-terminal amino acid sequence of the 42-kDa antigen was present at positions 39 to 53 in FibA; from this we conclude that the mature FibA protein contains 355 amino acids, resulting in a predicted molecular mass of 41,368 Da. The putative 38-residue signal sequence of FibA strongly resembles other gram-positive secretion signal sequences. The C termini of FibA and two open reading frames directly upstream and downstream of fibA exhibited significant sequence homology to the C termini of a group of secreted and surface-located proteins of other gram-positive cocci that are all presumably involved in anchoring of the protein to carbohydrate structures. We conclude that FibA is a secreted and surface-located protein and as such is part of the fibril-like structures.

Antibacterial activities of tosufloxacin against anaerobic bacteria and the electron micrograph of its bactericidal effects.

Tosufloxacin, a quinolone, showed a broad antibacterial spectrum against gram-positive and gram-negative bacteria including anaerobic bacteria. Tosufloxacin was 4- to 8-fold more active than levofloxacin and ciprofloxacin. The MIC90 of tosufloxacin for clinical isolates of Bacteroides fragilis, Bacteroides vulgatus, Bacteroides thetaiotaomicron and Peptostreptococcus asaccharolyticus were 0.78, 0.39, 1.56 and 0.39 micrograms/ml, respectively. Morphological observation with the scanning and transmission electron microscope revealed that exposure of B. fragilis ATCC 25285 to tosufloxacin resulted in the formation of filamentous cells with mesosome-like structures. Tosufloxacin also induced the mini-cell resulting from the unusual cell division system and a number of holes in the outer membrane. Tosufloxacin at 4 MIC caused some change in cell wall organization and cell lysis. After exposure of P. asaccharolyticus ATCC 14953 to tosufloxacin, the cells increased considerably in size and the cell wall and cross wall thickening was observed.

Crystalline surface protein of Peptostreptococcus anaerobius.

The surface ultrastructure of three anaerobic Gram-positive cocci frequently encountered in oral infections, Peptostreptococcus micros, P. magnus and P. anaerobius, was studied. The type strains of P. micros (DSM 20468) and P. anaerobius (ATCC 27337), several clinical isolates of both species and the type strain of P. magnus (DSM 20470) were included. Thin-sectioned cells studied by electron microscopy revealed a homogeneous layer outside the peptidoglycan layer in P. anaerobius. In P. micros and P. magnus a more amorphous layer was present. No periodic structures were seen in negatively stained whole cells of these three species. However, in freeze-etched cells of P. anaerobius a crystalline surface protein layer (S-layer) was detected. No periodicity was seen in any of the P. micros strains or the P. magnus type strain by the methods used, but a periodic pattern was observed in negatively stained specimens of cell wall fragments of sonicated P. anaerobius cells. No capsular material was visible outside the S-layer in P. anaerobius. The cells of the Peptostreptococcus spp. were extracted for 30 min with detergents and urea. One per cent SDS and M urea both extracted a major 78 kDa protein from all strains of P anaerobius. Extraction of P. micros and P. magnus cells did not reveal any major protein bands comparable to that of P. anaerobius. Surface biotinylation of cells followed by Western blotting and detection by alkaline-phosphatase-conjugated extravidin showed strong staining of the 78 kDa band in P. anaerobius, further indicating that this molecule is located on the surface of the cell and is the S-protein.(ABSTRACT TRUNCATED AT 250 WORDS)

Description of two morphotypes of Peptostreptococcus micros.

Peptostreptococcus micros is often isolated from abscesses in several parts of the human body. The oral cavity is considered the natural habitat for the species, which has been implicated as a periodontal pathogen. In plaque samples from periodontitis patients we observed the presence of a rough morphotype of P. micros in addition to the previously recognized smooth morphotype. The rough morphotype has not been described previously. Both morphotypes are frequently isolated simultaneously from the same patient. In this paper strains of both morphotypes are described. The smooth morphotype, represented by the type strain, grew as small, dome-shaped, bright white, nonhemolytic colonies. The rough morphotype grew as equally white dry colonies which were hemolytic and had wrinkled edges. DNA-DNA reassociation studies revealed homology at the species level between the two morphotypes; in addition, no differences in physiological characteristics were observed when the organisms were tested with API-32A and API-ZYM kits. The rough cells had long, thin fibrillar structures outside the cell envelope when they were stained negatively for electron microscopy. In the smooth morphotype these structures were not present. The sodium dodecyl sulfate-polyacrylamide gel electrophoresis profiles of whole-cell extracts were different for the two morphotypes. In xylene-water phase partition studies, the smooth morphotype was found to be hydrophobic, whereas the rough morphotype was found to be relatively hydrophilic. The distinct morphotypes were stable on blood agar; however, the rough morphotype changed to a nonfibrillar type with a smooth colony morphology after repeated subculturing in broth.

Physico-chemical and structural properties of the surfaces of Peptostreptococcus micros and Streptococcus mitis as compared to those of mutans streptococci, Streptococcus sanguis and Streptococcus salivarius.

The surface properties of nine Streptococcus mitis and four Peptostreptococcus micros strains from the oral cavity were examined and compared with a large group of oral streptococci. Zeta potential and contact angle measurements were employed to determine physico-chemical cell surface properties. In addition, elemental surface concentration ratios were obtained via X-ray photoelectron spectroscopy, and surface structures were examined with transmission electron microscopy. The S. mitis and P. micros strains were found to have higher isoelectric points, higher hydrophobicities and higher N/C surface concentration ratios than some other oral streptococci. The combined data suggest that both species possess large amounts of surface protein. All the S. mitis strains displayed abundant surface fibrils in negative staining, but the P. micros strains were devoid of surface appendages indicating that surface protein is present in different forms in the two species. The surfaces of S. mitis and P. micros type strains differed significantly from the other strains examined.

Isolation and characterization of a mucin-degrading strain of Peptostreptococcus from rat intestinal tract.

A mucin-degrading microorganism was isolated from the intestinal tract by serial sectioning from the serosal side of the caecum wall from a conventional rat. The ability of degrading the intestinal water-soluble mucin was present both in vivo after monocontamination of germ-free rats and in vitro, when adding the microbe to Mucin medium. The morphology, Gram-positive cocci single or in short chains and the very weak biochemical activities allow us to place this strain in the species Peptostreptococcus micros.