Characterization of envelope proteins from Pasteurella haemolytica and Pasteurella multocida

A method was devised for the reproducible isolation of envelopes from Pasteurella haemolytica serotype A2. It was also possible to prepare envelopes from other serotypes of P. haemolytica and Pasteurella multocida using this methodology. Examination of these preparations by SDS-PAGE showed major differences between strains of P. haemolytica and strains of P. multocida which allowed the clear distinction of isolates of these species. Amongst the P. haemolytica serotypes it was possible to distinguish envelope preparations made from A biotype and T biotype organisms easily, but it was not possible to identify individual serotypes from each other. Envelope profiles were sufficiently different between the individual P. multocida serotypes examined to allow each to be identified by its polypeptide profile. Experiments using radiolabelling, antibody absorption, and susceptibility to protease digestion, together with heat modifiability and detergent solubility characteristics indicated that 13 of the envelope proteins were probably surface-located. A high molecular mass immunogenic envelope protein was shown, by immunoblotting, to be present in all strains of P. haemolytica and P. multocida examined.     

Survival and transmissibility of Pasteurella pneumotropica

Survival has been determined for Pasteurella pneumotropica on various surfaces found in an animal room at 23+/-1 degrees C and 50+/-10% relative humidity. Longest survival (120 min) was found on mouse hair, shortest (< 30 min) on laboratory coat fabric. Transmission experiments were performed using sentinel animals in order to evaluate the efficiency of their use for the detection of P. pneumotropica in quarantined mice. In sentinels exposed to infected mice by close contact, P. pneumotropica was detected by culture 2 weeks post-exposure and seroconversion 3 weeks after contact. Transfer of soiled bedding from Pasteurella-infected mice did not infect sentinels within a period of 12 weeks as tested by cultivation or serum antibodies.     

Transformation of Pasteurella novicida

Deoxyribonucleic acid from a streptomycin-resistant mutant of Pasteurella novicida transformed portions of P. novicida streptomycin-sensitive populations to streptomycin-resistant. Similarly, mutants auxotrophic for tryptophan or purine biosynthesis were also transformed to nutritional independence.     

Ultrastructural characteristics of the external surfaces of Pasteurella pneumotropica from mice and Pasteurella multocida from rabbits

The surface structures of the cells of Pasteurella pneumotropica from mice and Pasteurella multocida from rabbits were examined by transmission electron microscopy after ruthenium red staining and polycationic ferritin labelling. P. pneumotropica strains ATCC 35149 and K 79114 had slight extracellular fibrous materials associated with cell walls with ruthenium red staining. Ferritin labelling method revealed thick strands or sparsely ferritin-labelled materials on the cell surface of the strains. P. multocida strains Pm-78 and P-2440 had ferritin-labelled capsules surrounded with the cell wall. Strain Pm-78, which was serotyped as A:12, had a thick capsule, whereas serotype -:3 strain P-2440 had a thin and irregular capsule.     

Phenotypic and pathobiological characteristics of Pasteurella piscicida

Pasteurellosis, caused by Pasteurella piscicida, is one of the most threatening diseases of wild and cultured marine fish, and has been reported from many geographical areas including the USA, Japan and the Mediterranean countries. The objective of this article is to construct a picture of the current state of knowledge about this bacterial pathogen and the pathogenesis of the disease it causes. We review some important questions such as the controversial taxonomic position of the bacterium, and its main virulence mechanisms. The epidemiology of the disease, the routes of transmission and the putative reservoirs of P. piscicida in the environment are also discussed. Finally, a detailed survey of the strategies for controlling the disease is performed, including new diagnostic procedures, chemotherapy, employment of immunostimulants, and improvements in immunization programs.     

Morphology of Pasteurella multocida bacteriophages

Twenty-one tailed phages with icosahedral heads belong to the Myoviridae, Siphoviridae, and Podoviridae families and to four morphological types. Type AU, with 10 phages, has a contractile tail and is morphologically identical with coliphage P2. Lysates contain contracted tail sheaths assembled end-to-end and abnormal structures with long tails and multiple tail sheaths. Types C-2 and 32, with one and three phages, respectively, have long, noncontractile tails. Type 22 includes seven phages, has a short tail, and resembles coliphage T7. Our results agree with previous biological data and suggest that types AU, C-2, 32, and 22 correspond to four different phage species.