Correlation of Host Range Expansion of Therapeutic Bacteriophage Sb-1 with Allele State at a Hypervariable Repeat Locus.

Staphylococci are frequent agents of health care-associated infections and include methicillin-resistant Staphylococcus aureus (MRSA), which is resistant to first-line antibiotic treatments. Bacteriophage (phage) therapy is a promising alternative antibacterial option to treat MRSA infections. S. aureus-specific phage Sb-1 has been widely used in Georgia to treat a variety of human S. aureus infections. Sb-1 has a broad host range within S. aureus, including MRSA strains, and its host range can be further expanded by adaptation to previously resistant clinical isolates. The susceptibilities of a panel of 25 genetically diverse clinical MRSA isolates to Sb-1 phage were tested, and the phage had lytic activity against 23 strains (92%). The adapted phage stock (designated Sb-1A) was tested in comparison with the parental phage (designated Sb-1P). Sb-1P had lytic activity against 78/90 strains (87%) in an expanded panel of diverse global S. aureus isolates, while eight additional strains in this panel were susceptible to Sb-1A (lytic against 86/90 strains [96%]). The Sb-1A stock was shown to be a mixed population of phage clones, including approximately 4% expanded host range mutants, designated Sb-1M. In an effort to better understand the genetic basis for this host range expansion, we sequenced the complete genomes of the parental Sb-1P and two Sb-1M mutants. Comparative genomic analysis revealed a hypervariable complex repeat structure in the Sb-1 genome that had a distinct allele that correlated with the host range expansion. This hypervariable region was previously uncharacterized in Twort-like phages and represents a novel putative host range determinant.IMPORTANCE Because of limited therapeutic options, infections caused by methicillin-resistant Staphylococcus aureus represent a serious problem in both civilian and military health care settings. Phages have potential as alternative antibacterial agents that can be used in combination with antibiotic drugs. For decades, phage Sb-1 has been used in former Soviet Union countries for antistaphylococcal treatment in humans. The therapeutic spectrum of activity of Sb-1 can be increased by selecting mutants of the phage with expanded host ranges. In this work, the host range of phage Sb-1 was expanded in the laboratory, and a hypervariable region in its genome was identified with a distinct allele state that correlated with this host range expansion. These results provide a genetic basis for better understanding the mechanisms of phage host range expansion.

Bacteriophages as Potential Treatment for Urinary Tract Infections.

BACKGROUND: Urinary tract infections (UTIs) are among the most prevalent microbial diseases and their financial burden on society is substantial. The continuing increase of antibiotic resistance worldwide is alarming so that well-tolerated, highly effective therapeutic alternatives are urgently needed. OBJECTIVE: To investigate the effect of bacteriophages on Escherichia coli and Klebsiella pneumoniae strains isolated from the urine of patients suffering from UTIs. MATERIAL AND METHODS: Forty-one E. coli and 9 K. pneumoniae strains, isolated from the urine of patients suffering from UTIs, were tested in vitro for their susceptibility toward bacteriophages. The bacteriophages originated from either commercially available bacteriophage cocktails registered in Georgia or from the bacteriophage collection of the George Eliava Institute of Bacteriophage, Microbiology and Virology. In vitro screening of bacterial strains was performed by use of the spot-test method. The experiments were implemented three times by different groups of scientists. RESULTS: The lytic activity of the commercial bacteriophage cocktails on the 41 E. coli strains varied between 66% (Pyo bacteriophage) and 93% (Enko bacteriophage). After bacteriophage adaptation of the Pyo bacteriophage cocktail, its lytic activity was increased from 66 to 93% and only one E. coli strain remained resistant. One bacteriophage of the Eliava collection could lyse all 9 K. pneumoniae strains. CONCLUSIONS: Based on the high lytic activity and the potential of resistance optimization by direct adaption of bacteriophages as reported in this study, and in view of the continuing increase of antibiotic resistance worldwide, bacteriophage therapy is a promising treatment option for UTIs highly warranting randomized controlled trials.