The size of haloes ranged from some millimeters to some centimeters in diameter and tended to expand with time. The haloes surrounding the plaque centers can indicate the presence of phage depolymerase capable of degrading exopolysaccharide (EPS) secreted by A. baumannii cells (Marti et al., 2011). Numerous phages inducing enzymes capable of depolymerizing the gram-negative bacterial EPS are characterized by plaques with size-varying haloes (Sutherland et al., 2004). In liquid culture, the titer of the phage
lysate was close to 1010 PFU mL−1. Morphological characterization of the phage AP22 using EM is shown in Fig. 1. The phage has an icosahedral head of 63–65 nm in diameter and a contractile tail of 85–90 nm in length. Thus, the bacterial virus was classified as a representative of the Myoviridae family. It has a 22- to 23-nm base plate with tail fibers, each 42–43 nm long. The fibers are clearly visible after tail contraction Obeticholic Acid (Fig. 1c). The phage was morphologically Lapatinib manufacturer similar to earlier isolated
phage BS46 (Soothill, 1992; Ackermann et al., 1994). The phage genome is presented by double-stranded DNA that is digested with restriction endonucleases HindIII, DraI, VspI, SspI, TaqI, AluI, RsaI, HinfI, MspI, CfrI, and EcoRI. It is partially digested with EcoRV, PstI, SalI, XmiI, SmiI, ClaI, BamHI, PvuII, BglII, EcoR91I, NcoI, and NheI. Numerous restriction fragments are formed by digestion of the phage DNA with endonucleases that recognize hexanucleotide palindromic sequences containing only A+T base pairs such as DraI, SspI, and VspI (Fig. 2). On the other hand, enzymes recognizing G+C–rich sequences (ApaI, SmaI, NotI, Eco52I) do not digest phage AP22 DNA (data not shown). It is quite possible that the phage genome has low G+C content. The phage genome size was estimated as 46 kb (Fig. 2). Purified phage particles were subjected to SDS-PAGE for the detection of the number of structural phage learn more proteins. Four major protein bands and three minor protein bands were detected, with molecular weights ranging from approximately 18–87 kDa (Fig. 3). The most predominant polypeptide band of approximately
32 kDa was presumably corresponding to a major capsid protein. The phage infection process was investigated by the estimation of the AP22 adsorption efficiency to the host and one-step growth of the phage. As shown in Fig. 4a, the phage adsorption occurred rapidly; more than 99% of the phage adsorbed within 5 min. Adsorption constant of AP22 was 1.53 × 10−7 mL min−1. One-step growth experiment was completed to determine the latent period and the phage burst size (Fig. 4b). The latent period of AP22 was 40 min, followed by the rise period (increasing in the concentration of phage particles) of 40 min, and plateau phase. The burst size was approximately 240 particles per one infected cell. The phage stability was investigated at different pH levels. The phage remained stable within 24 h between pH 4 and 9. But only 0.