Anti-biofouling
has been improved by passive or active ways. Passive
antifouling strategies aim to prevent the initial adsorption of foulants,
while active strategies aim to eliminate proliferative fouling by
destruction of the chemical structure and inactivation of the cells.
However, neither passive antifouling strategies nor active antifouling
strategies can solely resist biofouling due to their inherent limitations.
Herein, we successfully developed multimodal antibacterial surfaces
for waterborne and airborne bacteria with the benefit of a combination
of antiadhesion (passive) and bactericidal (active) properties of
the surfaces. We elaborated multifunctionalizable porous amine-reactive
(PAR) polymer films from poly(pentafluorophenyl acrylate) (PPFPA).
Pentafluorophenyl ester groups in the PAR films facilitate creation
of multiple functionalities through a simple postmodification under
mild condition, based on their high reactivity toward various primary
amines. We introduced amine-containing poly(dimethylsiloxane) (amine-PDMS)
and dopamine into the PAR films, resulting in infusion of antifouling
silicone oil lubricants and formation of bactericidal silver nanoparticles
(AgNPs), respectively. As a result, the PAR film-based lubricant-infused AgNPs-incorporated
surfaces demonstrate outstanding antibacterial effects toward both
waterborne and airborne Escherichia coli, suggesting
a new door for development of an effective multimodal anti-biofouling
surface.
Clostridium perfringens is one of the most common causes of food-borne illness. The increasing prevalence of multidrug-resistant bacteria requires the development of alternatives to typical antimicrobial treatments. Here, we isolated and characterized a C. perfringens-specific virulent bacteriophage CPS2 from chicken feces. The CPS2 phage contains a 17,961 bp double-stranded DNA genome with 25 putative ORFs, and belongs to the Picovirinae, subfamily of Podoviridae. Bioinformatic analysis of the CPS2 genome revealed a putative endolysin, LysCPS2, which is homologous to the endolysin of Clostridium phage phiZP2 and phiCP7R. The enzyme showed strong lytic activity against C. perfringens with optimum conditions at pH 7.5–10, 25–65 °C, and over a broad range of NaCl concentrations. Interestingly, LysCPS2 was found to be highly thermostable, with up to 30% of its lytic activity remaining after 10 min of incubation at 95 °C. The cell wall binding domain in the C-terminal region of LysCPS2 showed a binding spectrum specific to C. perfringens strains. This is the first report to characterize highly thermostable endolysin isolated from virulent C. perfringens bacteriophage. The enzyme can be used as an alternative biocontrol and detection agent against C. perfringens.
Clostridium perfringens is a Gram-positive, anaerobic, and spore forming bacterium that is widely distributed in the environment and one of the most common causes of foodborne illnesses. Bacteriophages are regarded as one of the most promising alternatives to antibiotics in controlling antibiotic-resistant pathogenic bacteria. Here we isolated a virulent C. perfringens phage, CPS1, and analysis of its whole genome and morphology revealed a small genome (19 kbps) and a short noncontractile tail, suggesting that CPS1 can be classified as a member of Picovirinae, a subfamily of Podoviridae. To determine the host receptor of CPS1, the EZ-Tn5 random transposon mutant library of C. perfringens ATCC 13124 was constructed and screened for resistance to CPS1 infection. Analysis of the CPS1-resistant mutants revealed that the CPF_0486 was disrupted by Tn5. The CPF_0486 was annotated as galE, a gene encoding UDP-glucose 4-epimerase (GalE). However, biochemical analyses demonstrated that the encoded protein possessed dual activities of GalE and UDP-N-acetylglucosamine 4-epimerase (Gne). We found that the CPF_0486::Tn5 mutant produced a reduced amount of capsular polysaccharides (CPS) compared with the wild type. We also discovered that glucosamine and galactosamine could competitively inhibit host adsorption of CPS1. These results suggest that CPS acts as a receptor for this phage.
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