Characterization of a novel Morganella morganii bacteriophage FSP1 isolated from river water.

Morganella morganii has been identified as a causative agent of opportunistic infections and histamine poisoning. Bacteriophage is a virus and has recently been considered an alternative agent to antibiotics for the control of bacteria that have developed antibiotic resistance. In this study, a novel M. morganii bacteriophage isolated from river water was characterized. The isolated phage, termed FSP1, was purified by polyethylene glycol precipitation followed by cesium chloride density-gradient centrifugation. FSP1 has infectivity against only M. morganii and was identified as a Myoviridae bacteriophage through morphological analysis with transmission electron microscopy. According to the one-step growth curve, the FSP1 latent period, eclipse period, and burst size were 30, 20 min, and 42 PFU infected cell(-1) , respectively. The genome size of FSP1 was estimated to be c. 45.6-49.4 kb by restriction endonuclease analyses. Moreover, challenge testing against M. morganii in vitro revealed that FSP1 had high lytic activity and that the viable cell count of M. morganii was reduced by 6.12 log CFU mL(-1) after inoculation with FSP1 at a multiplicity of infection (MOI) = 10. These results suggested that FSP1 could be used as a biocontrol agent against M. morganii for treatment of infectious disease treatment or food decontamination.

Identification of lytic bacteriophage MmP1, assigned to a new member of T7-like phages infecting Morganella morganii.

MmP1 (Morganella morganii phage 1) is a lytic bacteriophage newly isolated from the host bacterium M. morganii. The entire genome was sequenced, and final assembly yielded a 38,234bp linear double-stranded DNA (dsDNA) with a G+C content of 46.5%. In the MmP1 genome, 49 putative genes, 10 putative promoters and 2 predicted sigma-independent terminators were determined through bioinformatic analysis. A striking feature of the MmP1 genome is its high degree of similarity to the T7 group of phages. All of the 49 predicted genes exist on the same DNA strand, and functions were assigned to 35 genes based on the similarity of the homologues deposited in GenBank, which share 30-80% identity to their counterparts in T7-like phages. The analyses of MmP1 using CoreGenes, phylogenetic tree of RNA polymerase and structural proteins have demonstrated that bacteriophage MmP1 should be assigned as a new member of T7-like phages but as a relatively distant member of this family. This is the first report that a T7-like phage adaptively parasitizes in M. morganii, and this will advance our understanding of biodiversity and adaptive evolution of T7-like phages.