Growth of Male-Specific Bacteriophage in Pasteurella Harboring F-Genotes Derived from Escherichia coli

When either the F' lac or the F'Cm plasmid was transferred from Escherichia coli into Pasteurella pseudotuberculosis, the P. pseudotuberculosis (F') strains isolated formed plaques with both ribonucleic acid (RNA)-containing and deoxyribonucleic acid-containing male-specific phages. In contrast, strains of P. pestis harboring E. coli (F') plasmids did not form plaques with male-specific phages, although such strains permitted limited multiplication of phage MS2. The adsorption and burst size of MS2 were approximately the same in both species of Pasteurella, but the per cent of adsorbed MS2 that produced infective centers was much lower in P. pestis than it was in P. pseudotuberculosis. By use of a sib-selection technique of P. pestis (F') cells, we isolated a single clone that could form MS2 plaques. (32)P-labeled MS2 adsorbed equally to and its RNA penetrated equally into both the typical MS2-nonpermissive P. pestis cells and the MS2-permissive P. pestis cells. No host modification occurred after growth of MS2 in Pasteurella. Our data suggest that typical strains of P. pestis inhibit the intracellular development of phage MS2.     

Cloning and characterization of a gene from Pasteurella haemolytica A1 involved in lipopolysaccharide biosynthesis

Abstract A Pasteurella haemolytica A1 gene involved in the biosynthesis of a moiety on the core of the lipopolysaccharide molecule has been cloned and characterized. Escherichia coli clones which carry this gene showed an alteration of its lipopolysaccharide migration profile on tricine SDS-PAGE and exhibited resistance to the core-specific phage U3. In addition, lipopolysaccharide extracted from the E. coli clones was recognized by an anti-corespecific antiserum, but not by antiserum specific for the O antigen of P. haemolytica A1 lipopolysaccharide. Nucleotide sequence analysis of the cloned DNA identified an open reading frame ( lpsA ) coding for a protein of 263 amino acids which showed significant homology with a Haemophilus influenzae type b lipooligosaccharide biosynthesis gene. PCR amplification of genomic DNA, using primers based on the P. haemolytica A1 lpsA sequence, yielded products from only the A biotypes of P. haemolytica .     

Pasteurella Bacteriophage Sex Specific in Escherichia coli

Phage H, thought to be specific for Pasteurella pestis, was shown to plate efficiently on F⁻ strains of Escherichia coli but not on F⁺, F′, or Hfr strains. The phage was adsorbed rapidly to F⁻ strains but was not adsorbed to strains carrying F. Comparison with seven other reported female-specific phages showed that, although phage H was similar to the other phages in some characteristics, the exceptionally low efficiency of plating (<10⁻⁹) on F-containing cells makes phage H a particularly useful female-specific phage.     

Diversity of temperate bacteriophages induced in bovine and ovine Mannheimia haemolytica isolates and identification of a new P2-like phage

The diversity of temperate bacteriophages was examined in 32 Mannheimia haemolytica, six Mannheimia glucosida and four Pasteurella trehalosi isolates. Phage particles were induced and identified by electron microscopy in 24 (75%) M. haemolytica isolates, but in only one (17%) M. glucosida and one (25%) P. trehalosi isolate. The M. haemolytica phages were relatively diverse as seven Siphoviridae, 15 Myoviridae and two Podoviridae-like phages were identified; the Myoviridae-type phages also exhibited structural variation of their tails. The bacteriophages induced in M. glucosida and P. trehalosi were of the Myoviridae type. Restriction endonuclease (RE) analysis identified nine distinct RE types among the M. haemolytica bacteriophages, providing further evidence of their relative diversity. A limited number of phages caused plaques on indicator strains and the phages exhibited a narrow host range. A subgroup of 11 bovine serotype A1 and A6 isolates contained Myoviridae-type phages of the same RE type (type A), but these differed in their abilities to infect and form plaques on the same panel of indicator strains. A P2-like phage (phiPHL213.1), representative of the RE type A phages, was identified from the incomplete M. haemolytica genome sequence. The phiPHL213.1 genome contains previously unidentified genes and represents a new member of the P2 phage family.     

Isolation and sequencing of a temperate transducing phage for Pasteurella multocida

A temperate bacteriophage (F108) has been isolated through mitomycin C induction of a Pasteurella multocida serogroup A strain. F108 has a typical morphology of the family Myoviridae, presenting a hexagonal head and a long contractile tail. F108 is able to infect all P. multocida serogroup A strains tested but not those belonging to other serotypes. Bacteriophage F108, the first P. multocida phage sequenced so far, presents a 30,505-bp double-stranded DNA genome with cohesive ends (CTTCCTCCCC cos site). The F108 genome shows the highest homology with those of Haemophilus influenzae HP1 and HP2 phages. Furthermore, an F108 prophage attachment site in the P. multocida chromosome has been established to be inside a gene encoding tRNA(Leu). By using several chromosomal markers that are spread along the P. multocida chromosome, it has been demonstrated that F108 is able to perform generalized transduction. This fact, together with the absence of pathogenic genes in the F108 genome, makes this bacteriophage a valuable tool for P. multocida genetic manipulation.     

Pasteurella pestis Bacteriophage H and Escherichia coli Bacteriophage φII Are Nearly Identical

Electron microscopy examination of II-H deoxyribonucleic acid heteroduplexes, together with polyacrylamide gel electrophoretic analyses of phage ribonucleic acid species and proteins labeled in II or H-infected cells, demonstrates that Pasteurella pestis phage H is nearly identical to coliphage II.     

Characterization of rabbit Pasteurella multocida isolates by use of whole-cell, outer-membrane, and polymerase chain reaction typing.

PURPOSE: To characterize Pasteurella multocida isolates from laboratory rabbits using serotyping, sodium dodecyl sulfate-polyacrylamide gel electrophoresis of whole-cell proteins (WCPs) and outer-membrane proteins (OMPs), and polymerase chain reaction (PCR) fingerprinting. METHODS: Fifty isolates were obtained from five sources: ATCC (1), Oklahoma (4), Michigan (9), Minnesota (7), and Texas (29). The PCR fingerprinting was conducted using two minisatellite probes for M13 and a modified M13 core sequence and two microsatellite probes--(GTG)5 and (GACA)4. RESULTS: Forty-five isolates were serogroup A, and five were serogroup D. Ten WCP patterns (W1-W10) with one variation (W1a) and 10 OMP (OM1-OM10) patterns were found. Primers M13 phage, modified M13 phage, (GTG)5, and (GACA)4 generated 7, 9, 5, and 9 fingerprint types, respectively. Combination of WCP, OMP, and PCR fingerprint results yielded 39 groups with a discrimination index of 0.98. The PCR fingerprint results generally indicated clonal association among isolates within geographic locations except for the isolates from Texas, which varied markedly in PCR fingerprint types. CONCLUSION: Single primer PCR fingerprinting provided a simple and rapid means of typing P. multocida isolates from laboratory rabbits. Combinations of conventional and molecular typing enhanced differentiation among P. multocida isolated from rabbits with pasteurellosis.     

The Pasteurella multocida toxin is encoded within a lysogenic bacteriophage

Toxigenic strains of Pasteurella multocida produce a 146 kDa toxin (PMT) that acts as a potent mitogen. Sequence analysis of the structural gene for PMT, toxA, previously suggested it was horizontally acquired, because it had a low G + C content relative to the P. multocida genome. To address this, the sequence of DNA flanking toxA was determined. The sequence analysis showed the presence of homologues to bacteriophage tail protein genes and a bacteriophage antirepressor, suggesting that the toxin gene resides within a prophage. In addition to phage genes, the toxA flanking DNA contained a homologue of a restriction/modification system that was shown to be functional. The presence of a bacteriophage was demonstrated in spent medium from toxigenic P. multocida isolates. Its production was increased by mitomycin C addition, a treatment that is known to induce the lytic cycle of many temperate bacteriophages. The genomes of bacteriophages from three different toxigenic P. multocida strains had similar but not identical restriction profiles, and were approximately 45-50 kb in length. The prophages from two of these had integrated at the same site in the chromosome, in a tRNA gene. Southern blot analysis confirmed that these bacteriophages contained the toxA gene.     

A numerical taxonomic study of Actinobacillus, Pasteurella and Yersinia

A numerical taxonomic study of strains of Actinobacillus, Pasteurella and Yersinia, with some allied bacteria, showed 23 reasonably distinct groups. These fell into three major areas. Area A contained species of Actinobacillus and Pasteurella: A. suis, A. equuli, A. lignieresii, P. haemolytica biovar A, P. haemolytica biovar T, P. multocida, A. actinomycetemcomitans, 'P. bettii', 'A. seminis', P. ureae and P. aerogenes. Also included in A was a composite group of Pasteurella pneumotropica and P. gallinarum, together with unnamed groups referred to as 'BLG', 'Mair', 'Ross' and 'aer-2'. Area B contained species of Yersinia: Y. enterocolitica, Y. pseudotuberculosis, Y. pestis and a group 'ent-b' similar to Y. enterocolitica. Area C contained non-fermenting strains: Y. philomiragia, Moraxella anatipestifer and a miscellaneous group 'past-b'. There were also a small number of unnamed single strains.     

Isolation of Pasteurella haemolytica from tonsillar biopsies of Rocky Mountain bighorn sheep

Isolations of Pasteurella haemolytica were compared from tonsillar biopsies versus nasal passages for 29 free-ranging Rocky Mountain bighorn sheep (Ovis canadensis canadensis) from central Idaho. Overall, P. haemolytica was isolated from 11 (38%) of 29 sheep. Two (18%) of the 11 positive samples were from only nasal passages compared to eight (73%) from tonsillar biopsies. Pasteurella haemolytica biotype T was isolated from tonsils of nine sheep and from nasal biopsies. Pasteurella haemolytica biotype T was isolated from tonsils of nine sheep and from nasal passages of only one sheep. Two sheep were positive for P. haemolytica biotype A from nasal passages. Culturing tonsillar biopsies as compared to nasal swab samples was a more reliable technique in detecting P. haemolytica, especially biotype T, in bighorn sheep.     

A minimal medium for growth of Pasteurella multocida

Abstract We developed a minimal medium supporting the growth of both toxigenic and nontoxigenic strains of Pasteurella multocida to optical densities of > 0.5 (600 nm ). P. multocida P1059 (ATCC 15742), one of a number of strains which can cause fowl cholera, was used as the model strain in this study. The medium was composed of 17 ingredients including cysteine, glutamic acid, leucine, methionine, inorganic salts, nicotinamide, pantothenate, thiamine, and an energy source. Leucine was not required for growth but was stimulatory, and thiamine could be replaced by adenine. An additional 46 strains of P. multocida were tested, and 40 out of 46 (87%) strains grew as well as strain P1059 through a minimum of 10 serial transfers. P. multocida toxin (PMT) was produced when cells of a known toxigenic strain (P4261) were cultivated in the minimal medium. No growth of Pasteurella haemolytica or Pasteurella trehalosi strains was observed in this minimal medium.     

Multivariate analysis of quantitative chemical and enzymic characterization data in classification of Actinobacillus, Haemophilus and Pasteurella spp

Chemotaxonomic data for strains of Actinobacillus, Haemophilus and Pasteurella spp. were analysed using three multivariate statistical strategies: principal components, partial least squares discriminant, and soft independent modelling of class analogy. The species comprised Actinobacillus actinomycetemcomitans. Haemophilus aphrophilus, H. paraphrophilus, H. influenzae, Pasteurella multocida, P. haemolytica and P. ureae. Strains were characterized by cell sugar and fatty acid composition, lysis kinetics during EDTA and EDTA plus lysozyme treatment, and methylene blue reduction. In total 23 quantitative variables were compiled from chemotaxonomic analyses of 25 strains. A. actinomycetemcomitans and H. aphrophilus formed distinct classes which differed from those of H. paraphrophilus, H. influenzae and Pasteurella spp. All characterization variables, except those describing fatty acid content, contributed significantly to inter-species discrimination.     

Gene Transfer in Pasteurella pestis Harboring the F′Cm Plasmid of Escherichia coli

A strain of Pasteurella pestis, harboring the F'Cm plasmid from Escherichia coli, was able to donate its chromosome to auxotrophic recipient strains of P. pestis. The frequency of gene transfer in P. pestis was approximately 10(-6) per donor cell, 100 times less efficient than gene transfer in Pasteurella pseudotuberculosis, but efficient enough to determine entry times for the markers histidine, threonine, and tryptophan and to show linkage to the markers arginine and pigmentation. An attempt to extend the conjugation system to different serotypes of P. pseudotuberculosis and to Yersinia enterocolitica did not succeed.     

Isolation and Characterization of a New Generalized Transducing Bacteriophage Different from Pl in Escherichia coli

A new generalized transducing bacteriophage in the Escherichia coli system was isolated and characterized. This phage, designated D108, makes clear plaques on E. coli K-10, K-12, K-12(P1kc), K-12(D6), B/r, C, and 15 T(-), and Shigella dysenteriae. The plaque of phage D108 is larger in size than that of phage P1kc. Electron-microscopic observation revealed that phages D108 and P1kc are morphologically different from each other, suggesting that phage D108 belongs to a phage group different from phage P1. The fact that all of the 10 markers tested were transduced by phage D108 indicates that this phage is a generalized transducing phage in the E. coli system. The transduction frequency by phage D108 of chromosomal markers and of a drug resistance factor (R factor) ranged from 2 x 10(-6) to 3 x 10(-8) and 3 x 10(-9) to 6 x 10(-10) per phage, respectively. The cotransduction frequency of the thr and leu markers was 2.8% for phage P1kc and 1.5% for phage D108. The CM and TC markers (chloramphenicol-resistant and tetracycline-resistant markers, respectively) of the R factor were not cotransduced by phage D108, but the markers were generally cotransduced by phage P1kc. The results suggest that the transducing particle of phage D108 contains a smaller amount of host deoxyribonucleic acid than does phage P1kc.     

Isolation and Sequencing of a Temperate Transducing Phage for Pasteurella multocida

A temperate bacteriophage (F108) has been isolated through mitomycin C induction of a Pasteurella multocida serogroup A strain. F108 has a typical morphology of the family Myoviridae, presenting a hexagonal head and a long contractile tail. F108 is able to infect all P. multocida serogroup A strains tested but not those belonging to other serotypes. Bacteriophage F108, the first P. multocida phage sequenced so far, presents a 30,505-bp double-stranded DNA genome with cohesive ends (CTTCCTCCCC cos site). The F108 genome shows the highest homology with those of Haemophilus influenzae HP1 and HP2 phages. Furthermore, an F108 prophage attachment site in the P. multocida chromosome has been established to be inside a gene encoding tRNA^Leu. By using several chromosomal markers that are spread along the P. multocida chromosome, it has been demonstrated that F108 is able to perform generalized transduction. This fact, together with the absence of pathogenic genes in the F108 genome, makes this bacteriophage a valuable tool for P. multocida genetic manipulation.     

Elimination of Pasteurella pneumotropica from a contaminated mouse colony by oral administration of Enrofloxacin.

Enrofloxacin, a fluoroquinolone bactericidal antibiotic, was administered in an attempt to eradicate Pasteurella pneumotropica (P. pneumotropica) from a contaminated mouse colony. Contaminated mice, maintained within 4 animal rooms, were administered Enrofloxacin in drinking water at a daily dosage of 25.5 mg/kg for 2 weeks. Following one week of Enrofloxacin treatment, mice were selected randomly from each room and examined for P. pneumotropica. This procedure was repeated two or three times until all mice examined tested negative for the Pasteurella strain. With the exception of one room, treated mice consistently tested negative for P. pneumotropica for up to 45 weeks following completion of Enrofloxacin treatment. Thus, oral administration of Enrofloxacin significantly eliminated P. pneumotropica from a contaminated mouse colony.     

Phylogeny of 54 representative strains of species in the family Pasteurellaceae as determined by comparison of 16S rRNA sequences.

Virtually complete 16S rRNA sequences were determined for 54 representative strains of species in the family Pasteurellaceae. Of these strains, 15 were Pasteurella, 16 were Actinobacillus, and 23 were Haemophilus. A phylogenetic tree was constructed based on sequence similarity, using the Neighbor-Joining method. Fifty-three of the strains fell within four large clusters. The first cluster included the type strains of Haemophilus influenzae, H. aegyptius, H. aphrophilus, H. haemolyticus, H. paraphrophilus, H. segnis, and Actinobacillus actinomycetemcomitans. This cluster also contained A. actinomycetemcomitans FDC Y4, ATCC 29522, ATCC 29523, and ATCC 29524 and H. aphrophilus NCTC 7901. The second cluster included the type strains of A. seminis and Pasteurella aerogenes and H. somnus OVCG 43826. The third cluster was composed of the type strains of Pasteurella multocida, P. anatis, P. avium, P. canis, P. dagmatis, P. gallinarum, P. langaa, P. stomatis, P. volantium, H. haemoglobinophilus, H. parasuis, H. paracuniculus, H. paragallinarum, and A. capsulatus. This cluster also contained Pasteurella species A CCUG 18782, Pasteurella species B CCUG 19974, Haemophilus taxon C CAPM 5111, H. parasuis type 5 Nagasaki, P. volantium (H. parainfluenzae) NCTC 4101, and P. trehalosi NCTC 10624. The fourth cluster included the type strains of Actinobacillus lignieresii, A. equuli, A. pleuropneumoniae, A. suis, A. ureae, H. parahaemolyticus, H. parainfluenzae, H. paraphrohaemolyticus, H. ducreyi, and P. haemolytica. This cluster also contained Actinobacillus species strain CCUG 19799 (Bisgaard taxon 11), A. suis ATCC 15557, H. ducreyi ATCC 27722 and HD 35000, Haemophilus minor group strain 202, and H. parainfluenzae ATCC 29242. The type strain of P. pneumotropica branched alone to form a fifth group. The branching of the Pasteurellaceae family tree was quite complex. The four major clusters contained multiple subclusters. The clusters contained both rapidly and slowly evolving strains (indicated by differing numbers of base changes incorporated into the 16S rRNA sequence relative to outgroup organisms). While the results presented a clear picture of the phylogenetic relationships, the complexity of the branching will make division of the family into genera a difficult and somewhat subjective task. We do not suggest any taxonomic changes at this time.     

Structure of the lipid-containing bacteriophage PRD1: disruption of wild-type and nonsense mutant phage particles with guanidine hydrochloride.

The lipid-containing bacteriophage PRD1 was disrupted, and the subviral particles were studied. Guanidine treatment released two phage proteins (P3 and P5). These proteins form the polyhedral capsid. The remaining phage proteins were associated with the phage membrane vesicle. The vesicle was capable of forming a tubular structure. The isolated phage membrane vesicles aggregated readily. We found that aggregation and tube formation were associated with specific phage proteins (P11 and P18, respectively) by using protease treatment and an analysis of nonsense mutant phage particles. In addition, the possibility that free vesicles might be precursors to empty virions was studied.     

Some Improved Methods in P22 Transduction

Recent refinements simplify methods for P22 transduction in Salmonella and allow improved recovery of phage-free transductional clones. The methods include use of: integration- and lysis-defective phage mutants, heat-killed bacteria to eliminate free phage, direct plating of phage and bacteria, replica-plating for detection of phage content of individual clones, improved broth for phage growth, and procurement of high titer phage from P22 lysogens.     

Phage P22 helps phage MB78 to overcome blockage of DNA maturation in rifampicin-resistant host

Bacteriophage MB78, a virulent phage ofSalmonella typhimurium cannot grow in rifampicin-resistant mutant (rif-39) of the host having altered RNA polymerase. The temperate phage P22 which cannot multiply in presence of the virulent phage MB78 can, however, help MB78 to overcome replication inhibition in rif-39. The processing of concatemeric phage DNA to monomer is blocked in this nonpermissive host. Superinfection with P22 induces synthesis of at least five P22 specific polypeptides which help phage MB78 in the processing of the concatemeric DNA and maturation of phage particles.