Abstract
BackgroundBacterial drug resistance is one of the most significant challenges to human health today. In particular, effective antibacterial agents against methicillin-resistant Staphylococcus aureus (MRSA) are urgently needed. A causal relationship between nasal commensal S. aureus and infection has been reported. Accordingly, elimination of nasal S. aureus reduces the risk of infection. Enzymes that degrade bacterial cell walls show promise as antibacterial agents. Bacteriophage-encoded bacterial cell wall-degrading enzymes exhibit intrinsic bactericidal activity. P128 is a chimeric protein that combines the lethal activity of the phage tail-associated muralytic enzyme of Phage K and the staphylococcal cell wall targeting-domain (SH3b) of lysostaphin.Here we report results of in vitro studies evaluating the susceptibility of staphylococcal strains to this novel protein.ResultsUsing the broth microdilution method adapted for lysostaphin, we found that P128 is effective against S. aureus clinical strains including MRSA, methicillin-sensitive S. aureus (MSSA), and a mupirocin-resistant S. aureus. Minimum bactericidal concentrations and minimum inhibitory concentrations of P128 (1-64 μg/mL) were similar across the 32 S. aureus strains tested, demonstrating its bactericidal nature.In time-kill assays, P128 reduced colony-forming units by 99.99% within 1 h and inhibited growth up to 24 h.In an assay simulating topical application of P128 to skin or other biological surfaces, P128 hydrogel was efficacious when layered on cells seeded on solid media. P128 hydrogel was lethal to Staphylococci recovered from nares of healthy people and treated without any processing or culturing steps, indicating its in situ efficacy. This methodology used for in vitro assessment of P128 as an agent for eradicating nasal carriage is unique.ConclusionsThe novel chimeric protein P128 is a staphylococcal cell wall-degrading enzyme under development for clearance of S. aureus nasal colonization and MRSA infection. The protein is active against globally prevalent antibiotic-resistant clinical isolates and other clinically significant staphylococcal species including S. epidermidis. The P128 hydrogel formulation was bactericidal against Staphylococci including S. aureus recovered from the nares of 31 healthy people, demonstrating its in situ efficacy.
Highlights
Bacterial drug resistance is one of the most significant challenges to human health today
We found that P128 reduced the staphylococcal viable count (CFU) by five orders of magnitude in simulated nasal fluid (SNF), comparable to the activity observed in case of P128 in physiological saline
We evaluated the bactericidal activity of P128 on S. aureus and other staphylococcal species recovered from human nares
Summary
Bacterial drug resistance is one of the most significant challenges to human health today. Enzymes that degrade bacterial cell walls show promise as antibacterial agents. Bacteriophage-encoded bacterial cell wall-degrading enzymes exhibit intrinsic bactericidal activity. Bactroban Nasal (Mupirocin ointment) has been approved for nasal clearance of S. aureus and significantly reduces the risk of postoperative staphylococcal infection in carriers [9]. Bacteriophages have been used for human therapy in several Eastern European countries for decades [17] They have not been used in clinical applications in Western countries, the United States Food and Drug Administration recently approved the use of bacteriophages to prevent bacterial contamination in meat [18]. Bacteriophages are a good source of cell wall-degrading enzymes, which have been evaluated as antibacterial agents [19,20,21]
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