Abstract
Bacteriophage therapeutic development will clearly benefit from understanding the fundamental dynamics of in vivo phage-bacteria interactions. Such information can inform animal and human trials, and much can be ascertained from human cell-line work. We have developed a human cell-based system using Clostridium difficile, a pernicious hospital pathogen with limited treatment options, and the phage phiCDHS1 that effectively kills this bacterium in liquid culture. The human colon tumorigenic cell line HT-29 was used because it simulates the colon environment where C. difficile infection occurs. Studies on the dynamics of phage-bacteria interactions revealed novel facets of phage biology, showing that phage can reduce C. difficile numbers more effectively in the presence of HT-29 cells than in vitro. Both planktonic and adhered Clostridial cell numbers were successfully reduced. We hypothesise and demonstrate that this observation is due to strong phage adsorption to the HT-29 cells, which likely promotes phage-bacteria interactions. The data also showed that the phage phiCDHS1 was not toxic to HT-29 cells, and phage-mediated bacterial lysis did not cause toxin release and cytotoxic effects. The use of human cell lines to understand phage-bacterial dynamics offers valuable insights into phage biology in vivo, and can provide informative data for human trials.
Highlights
The increase in antibiotic resistance found within multiple pathogenic bacteria has motivated an interest in the use of phages to control and treat bacterial pathogens[1,2,3,4,5,6]
We examined dynamics of the phage phiCDHS1 when used to treat HT-29 cells infected with C. difficile ribotype ribotype 027 (R027) strain
We propose that our model will be a useful tool for phage therapy development and can be adapted to study other bacteria-phage interactions with suitable human cell lines
Summary
The increase in antibiotic resistance found within multiple pathogenic bacteria has motivated an interest in the use of phages to control and treat bacterial pathogens[1,2,3,4,5,6]. A major strength of human cell lines as a tool to study phages is that in vivo data on the mechanisms of interactions between bacteria and phages can be obtained. We propose that our model will be a useful tool for phage therapy development and can be adapted to study other bacteria-phage interactions with suitable human cell lines.
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