Development of multi locus sequence typing (MLST) of Rodentibacter pneumotropicus.

The aim of the investigation was to develop a definitive typing system for Rodentibacter pneumotropicus. A total of 79 strains including the type strain of R. pneumotropicus, all associated with rodents were used to develop a multi-locus sequence typing scheme (MLST). Primers were designed for conserved regions of seven house-keeping genes (atpG, frdB, gdh, pgi, pmi, recA, zwf) and internal fragments of 399-839 bp were sequenced for all strains. The genes were also extracted in full length from whole genomic sequences of 14 strains of which 10 were sequenced in the current study. The number of alleles at the different loci ranged from 5 to 7 and a total of 20 allelic profiles or sequence types were recognized amongst the 79 strains. Analysis of the MLST data showed that some STs have been stable over many years probably circulating in the same colonies and probably transferred between colonies. We assume that this MLST scheme may provide a high level of resolution and might be an excellent tool for studying the population structure and epidemiology of R. pneumotropicus. Further development of the scheme is expected by including more genes and more strains and involve whole genomic sequencing.

From the [Pasteurella] pneumotropica complex to Rodentibacter spp.: an update on [Pasteurella] pneumotropica.

The species [Pasteurella] pneumotropica has been reclassified into the new genus Rodentibacter, within the family Pasteurellaceae. Along with the type species (Rodentibacter pneumotropicus) of the new genus, seven new species have been named. These organisms were formerly mainly known as the [P.] pneumotropica complex and [P.] pneumotropica was considered as the most important Pasteurellaceae species colonizing laboratory rodents. The aim of this review is to update the veterinary relevant aspects of clinical manifestations, pathogenesis, virulence and diagnostics of members of Rodentibacter with a focus on the most important species from a veterinary perspective. The organisms are obligate commensals of the mucous membranes and members of Rodentibacter are not able to persist for long in the environment. Members of Rodentibacter spp. are responsible for the most prevalent bacterial infections in laboratory mice and rats, but are also common in rodents outside laboratory settings. Some Rodentibacter spp. produce mainly localised disease in connection with favouring factors and seldomly act as primary pathogens in healthy immunocompetent animals. The subclinical infection with Rodentibacter spp. can affect the results of certain types of research using contaminated animals thus placing them on a list of microbes which are often not tolerated in experimental rodent facilities. The presences of RTX toxins, YadA-like proteins and a capsule with possible role in the pathogenesis have been described. Some species of Rodentibacter are able to form robust biofilms which might be involved in colonisation and persistence within the host. Current possibilities for diagnostics and differentiation among Rodentibacter spp. are outlined and options for treatment and control are provided.

Exhaust Air Dust Monitoring is Superior to Soiled Bedding Sentinels for the Detection of Pasteurella pneumotropica in Individually Ventilated Cage Systems.

Reliable detection of unwanted organisms is essential for meaningful health monitoring in experimental animal facilities. Currently, most rodents are housed in IVC systems, which prevent the aerogenic transmission of pathogens between cages. Typically soiled-bedding sentinels (SBS) exposed to soiled bedding collected from a population of animals within an IVC rack are tested as representatives, but infectious agents often go undetected due to inefficient transmission. Pasteurellaceae are among the most prevalent bacterial pathogens isolated from experimental mice, and the failure of SBS to detect these bacteria is well established. In this study, we investigated whether analysis of exhaust air dust (EAD) samples by using a sensitive and specific real-time PCR assay is superior to conventional SBS monitoring for the detection of Pasteurella pneumotropica (Pp) infections. In a rack with a known prevalence of Pp-positive mice, weekly EAD sampling was compared with the classic SBS method over 3 mo. In 6 rounds of testing, with a prevalence of 5 infected mice in each of 7 cages in a rack of 63 cages, EAD PCR detected Pp at every weekly time point; SBS failed to detect Pp in all cases. The minimal prevalence of Pp-infected mice required to obtain a reliable positive result by EAD PCR testing was determined to be 1 in 63 cages. Reliable detection of Pp was achieved after only 1 wk of exposure. Analysis of EAD samples by real-time PCR assay provides a sensitive, simple, and reliable approach for Pp identification in laboratory mice.

Identification of a virulence determinant that is conserved in the Jawetz and Heyl biotypes of [Pasteurella] pneumotropica.

[Pasteurella] pneumotropica is a ubiquitous bacterium frequently isolated from laboratory rodents. Although this bacterium causes various diseases in immunosuppressed animals, little is known about major virulence factors and their roles in pathogenicity. To identify virulence factors, we sequenced the genome of [P.] pneumotropica biotype Heyl strain ATCC 12555, and compared the resulting non-contiguous draft genome sequence with the genome of biotype Jawetz strain ATCC 35149. Among a large number of genes encoding virulence-associated factors in both strains, four genes encoding for YadA-like proteins, which are known virulence factors that function in host cell adherence and invasion in many pathogens. In this study, we assessed YadA distribution and biological activity as an example of one of virulence-associated factor shared, with biotype Jawetz and Heyl. More than half of mouse isolates were found to have at least one of these genes; whereas, the majority of rat isolates did not. Autoagglutination activity, and ability to bind to mouse collagen type IV and mouse fibroblast cells, was significantly higher in YadA-positive than YadA-negative strains. To conclude, we identified a large number of candidate genes predicted to influence [P.] pneumotropica pathogenesis.

Bacteria-reactive immune response may induce RANKL-expressing T cells in the mouse periapical bone loss lesion.

INTRODUCTION: The present study investigated whether bacteria infecting the root canal can activate any infiltrating T cells to produce receptor activator of nuclear factor kappa B (NF-κB) ligand (RANKL). METHODS: Using a mouse model of periapical lesion induced by artificial dental pulp exposure, the presence of RANKL-positive T cells and osteoclasts in the periapical lesion was examined by an immunohistochemical approach. The bacteria colonizing the exposed root canal were identified by 16S ribosomal RNA (rRNA) sequence analysis. The isolated endodontic bacteria were further immunized to normal mice, and soluble activator of NF-κB ligand (sRANKL) production by the T cells isolated from the immunized mice was evaluated by ex vivo culture system. RESULTS: RANKL-positive T cells along with TRAP+ osteoclasts were identified in periapical bone resorption lesions. The gram-negative bacterium Pasteurella pnumotropica, which was most frequently detected from the root canal of exposed pulp, showed remarkably elevated serum immunoglobulin G (IgG)-antibody response in pulp-exposed mice compared with control nontreated mice. Immunization of mice with P. pneumotropica induced not only serum IgG-antibody but also primed bacteria-reactive T cells that produced sRANKL in response to ex vivo exposure to P. pneumotropica. CONCLUSIONS: T cells infiltrating the periapical region express RANKL, and the endodontic bacteria colonizing the root canal appear to induce RANKL expression from bacteria-reactive T cells, suggesting the possible pathogenic engagement of the immune response to endodontic bacteria in the context of developing bone resorptive periapical lesions.

Assessment of rpoB and 16S rRNA genes as targets for PCR-based identification of Pasteurella pneumotropica.

Diagnosis of Pasteurella pneumotropica in laboratory animals relies on isolation of the organism, biochemical characterization, and, more recently, DNA-based diagnostic methods. 16S rRNA and rpoB gene sequences were examined for development of a real-time PCR assay. Partial sequencing of rpoB (456 bp) and 16S rRNA (1368 bp) of Pasteurella pneumotropica isolates identified by microbiologic and biochemical assays indicated that either gene sequence can be used to distinguish P. pneumotropica from other members of the Pasteurellaceae family. However, alignment of rpoB sequences from the Pasteurella pneumotropica Heyl (15 sequences) and Jawetz (16 sequences) biotypes with other Pasteurellaceae sequences from GenBank indicated that although rpoB DNA sequencing could be used for diagnosis, development of diagnostic primers and probes would be difficult, because the sequence variability between Heyl and Jawetz biotypes is not clustered in any particular region of the rpoB sequence. In contrast, alignment of 16S rRNA sequences revealed a region with unique and stable nucleotide motifs sufficient to permit development of a specific fluorogenic real-time PCR assay to confirm P. pneumotropica isolated by culture and to differentiate Heyl and Jawetz biotypes.

Comparative analysis of Pasteurella pneumotropica isolates from laboratory mice and rats.

Selected biochemical and genetic characteristics of the wild-type strains of Pasteurella pneumotropica isolated from mice and rats were investigated and compared in order to determine the significant differences among the isolates. The isolates were divided into six groups on the basis of the patterns of carbon source utilization in the host rodents. The genome sizes were determined by electrophoretic analysis, and the mean genome size of the isolates from mice was larger than that of the isolates from rats (P < 0.05). Cluster analysis of the rpoB sequences discriminated five clusters; the differences might have correlated with the host associations. Principal component analysis (PCA) based on both the biochemical and genetic characteristics revealed total 44 strains discriminated into three groups comprising the host-dependent and host-independent groups. Although the P. pneumotropica isolates were mainly classified on the basis of the host rodents by the examinations, the existence of isolates that could not be discriminated on the basis of the host rodents alone was confirmed by the PCA. These results indicated that the P. pneumotropica isolates could be further classified by taxonomic analysis and also suggested the existence of a host-independent group in addition to the host-dependent groups.

A specific polymerase chain reaction based on the gyrB gene sequence and subsequent restriction fragment length polymorphism analysis of Pasteurella pneumotropica isolates from laboratory mice.

For a molecular identification and typing tool, we developed a specific polymerase chain reaction (PCR) based on the gyrB gene sequence and a subsequent restriction fragment length polymorphism (RFLP) analysis using the products amplified from the specific PCR to facilitate discrimination of biotypes of Pasteurella pneumotropica from laboratory mice. Appropriate PCR products, a 1039-basepair fragment for biotype Jawetz and a 1033-basepair fragment for biotype Heyl, were amplified by use of the primers CZO-1 and NJO-2 from all 105 P. pneumotropica isolates tested and the 2 reference strains but not from other bacterial species tested. MspI digestion of PCR-generated products showed 3 RFLP patterns among the 105 isolates, and these patterns correlated with the biotype of the isolate (RFLP pattern 1, biotype Jawetz; RFLP pattern 2, biotype Heyl; and RFLP pattern 3, biotype Jawetz with Beta-hemolytic activity). Our procedure identifies and biotypes isolates of P. pneumotropica from laboratory mice, using simple PCR and enzymatic restriction techniques. Therefore, this procedure is useful as a rapid identification and biotyping tool for isolates of P. pneumotropica from laboratory mice.

Phylogenetic analysis of isolates of Pasteurella pneumotropica from laboratory animals based on the gyrB gene sequence.

Phylogenetic analysis using the gyrB sequence was performed to investigate the genetic relevance among 49 isolates of P. pneumotropica. In the phylogeny, the isolates were clearly classified into three groups as follows: group A for the isolates of biotype Jawetz derived from mice, group B for the isolates of biotype Jawetz derived from rats, and group C for the isolates of biotype Heyl. These results suggest that the gyrB sequence of P. pneumotropica differs between the isolates of two biotypes, and also between the isolates derived from mice and rats in the biotype Jawetz.

Phylogenetic relationship of Pasteurella pneumotropica isolates from laboratory rodents based on 16S rDNA sequence.

A 1344 bp fragment of the 16S ribosomal DNA (rDNA) sequence was used to determine the genetic relationship of Pasteurella pneumotropica isolates from laboratory rodents. A total of 30 nucleotide sequences of P. pneumotropica, including 24 wild strains, 3 reference strains, and 3 nucleotide sequences deposited in GenBank, were examined for heterogeneity of their 16S rDNA sequences. Phylogenetic analysis based on 16S rDNA sequence discriminated 5 types of branching lineages. Of these 5 types, 3 types had significant associations with mice or rats, and 2 had significant associations with the beta-hemolytic phenotype. These results suggest that 16S rDNA sequencing of P. pneumotropica isolates demonstrates genetic heterogeneity and phylogenetic discrimination in terms of their hemolytic phenotype and host associations.

Molecular typing of Pasteurella pneumotropica isolated from rodents by amplified 16S ribosomal DNA restriction analysis and pulsed-field gel electrophoresis.

A total of 52 isolates of Pasteurella pneumotropica obtained from rodents were examined for their genetic heterogeneity. On the basis of DNA restriction analysis, including amplified 16S ribosomal DNA restriction analysis (ARDRA) and pulsed-field gel electrophoresis (PFGE), differences were identified among the isolates. ARDRA typing with Hae III revealed 4 different banding patterns of the P. pneumotropica isolates. Eighty-two percent of the 23 isolates identified as a-1 were derived from mice, whereas all the isolates identified as a-3 were derived from rats. Most of the isolates, which showed hemolytic activity on blood agar, obtained from mice and rats, were identified as a-2 and a-4, respectively. By restriction analysis of genomic DNA, Apa I and Not I digestion differentiated 9 variants and an undiscriminating group. However, no close relation with regard to the phenotypic characteristics was observed among the variants. The isolates identified as a-2 and a-4 could not be distinguished by PFGE analysis. DNA restriction analysis revealed that the genetic diversity of the P. pneumotropica isolates was more complex than the phenotypic characteristics among the species, and that at least the P. pneumotropica isolates were clearly differentiated into 4 groups by ARDRA typing with Hae III.