Characterization of a Unique Bordetella bronchiseptica vB_BbrP_BB8 Bacteriophage and Its Application as an Antibacterial Agent.

Bordetella bronchiseptica, an emerging zoonotic pathogen, infects a broad range of mammalian hosts. B. bronchiseptica-associated atrophic rhinitis incurs substantial losses to the pig breeding industry. The true burden of human disease caused by B. bronchiseptica is unknown, but it has been postulated that some hypervirulent B. bronchiseptica isolates may be responsible for undiagnosed respiratory infections in humans. B. bronchiseptica was shown to acquire antibiotic resistance genes from other bacterial genera, especially Escherichia coli. Here, we present a new B. bronchiseptica lytic bacteriophage-vB_BbrP_BB8-of the Podoviridae family, which offers a safe alternative to antibiotic treatment of B. bronchiseptica infections. We explored the phage at the level of genome, physiology, morphology, and infection kinetics. Its therapeutic potential was investigated in biofilms and in an in vivo Galleria mellonella model, both of which mimic the natural environment of infection. The BB8 is a unique phage with a genome structure resembling that of T7-like phages. Its latent period is 75 ± 5 min and its burst size is 88 ± 10 phages. The BB8 infection causes complete lysis of B. bronchiseptica cultures irrespective of the MOI used. The phage efficiently removes bacterial biofilm and prevents the lethality induced by B. bronchiseptica in G. mellonella honeycomb moth larvae.

Morphology and general characteristics of lytic phages infective on strains of Bradyrhizobium japonicum.

Biological characteristics of three isolated phages (SR1, SR2, and SR3) lytic against three Bradyrhizobium japonicum strains were studied. These phages had no cross-infectivity among the host strains. Phage morphology indicates that they belonged to Siphoviridae (long noncontractile tail; SR1 and SR2) and Podoviridae (short tail; SR3) classes of bacteriophages. Lytic cycle of phages studied under identical conditions showed a distinct adsorption rate (67.3-99.1%), latent period (150-300 min), rise period (60-150 min), and burst size (110-200 pfu/cell). Stability in liquids and inactivation by osmotic shock, thermal, and ultraviolet irradiation were also distinct in this heterogeneous phage group. Influence of soil factors such as temperature, soil moisture, soil pH, and degree of phage adsorption to the soil on phage survival was determined. Major percent of free infective phages were obtained after desorption of phages from soil. Overall, temperature appeared to be the most important parameter affecting rhizobiophage survival in the soil.