Three phages φVh1, φVh2, and φVh4 had an icosahedral head of 60–1

Three phages φVh1, φVh2, and φVh4 had an icosahedral head of 60–115 nm size with a long, noncontractile tail of 130–329 × 1–17 nm, belonged Linsitinib cell line to the family Siphoviridae. φVh3 had an icosahedral head (72 ± 5 nm) with a short tail (27 × 12 nm) and belonged to Podoviridae. REA with DraI and PFGE of genomic DNA digested with ScaI and XbaI and cluster analysis of their banding patterns indicated that φVh3 was distinct from the other three siphophages. PFGE-based genome mean size of the four bacteriophages φVh1, φVh2, φVh3, and φVh4 was estimated to be about 85, 58, 64, and 107 kb, respectively. These phages had the property of generalized transduction as demonstrated by transduction with plasmid pHSG 396 with

frequencies ranging from 4.1 × 10−7 to 2 × 10−9 per plaque-forming unit, suggesting a potential ecological role in gene transfer among aquatic vibrios. Vibrio harveyi, a gram-negative marine bacterium, has been described as a significant pathogen of marine vertebrates and invertebrates (Austin & Zhang, 2006). V. harveyi causes luminescent bacterial

disease (LBD) click here in larval shrimp, resulting in considerable economic loss to shrimp hatcheries world over (Lavilla-Pitogo et al., 1990; Karunasagar et al., 1994). Pathogenicity mechanism of V. harveyi has been attributed to various virulence factors such as production of proteases (Liu & Lee, 1999), siderophores (Owens et al., 1996), and hemolysin (Zhang et al., 2001). Besides these virulence factors, the association of a V. harveyi myovirus-like (VHML) bacteriophage is reported to impart virulence however to V. harveyi (Austin et al., 2003). Munro et al. (2003) also demonstrated that naïve

strains of V. harveyi could be converted into virulent strains by infecting them with bacteriophage VHML. It was almost three decades ago that the first description of bacteriophages infecting luminescent bacteria was reported (Keynan et al., 1974). After a long gap of 25 years, bacteriophage-mediated toxicity of V. harveyi in Penaeus monodon by the transfer of a gene controlling toxin production was reported (Ruangpan et al., 1999), followed by the description of VHML associated with toxin-producing strains (Oakey & Owens, 2000; Oakey et al., 2002). There are also some reports on the isolation and characterization of lytic bacteriophages of V. harveyi from coastal ecosystem and shrimp culture ponds (Shivu et al., 2007). A lytic bacteriophage was evaluated as a biocontrol agent of V. harveyi and was reported to provide encouraging results (Vinod et al., 2006; Karunasagar et al., 2007). In our earlier work, we reported isolation of bacteriophages of V. harveyi from shrimp hatchery (Chrisolite et al., 2008). Here, we present our work on the characterization of four selected bacteriophages with broad spectrum of infectivity against luminescent V. harveyi isolates, considering their potential as biocontrol agent of LBD in shrimp hatcheries.

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