Relevance of the bacteriophage adherence to mucus model for Pseudomonas aeruginosa phages

infections are getting increasingly serious as antimicrobial resistance spreads. Phage therapy may be a solution to the problem, especially if improved by current advances on phage-host studies. As a mucosal pathogen, we hypothesize that and its phages are linked to the bacteriophage adherence to mu...

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Published in:Microbiology spectrum 2024-08, Vol.12 (8), p.e0352023
Main Authors: Almeida, Gabriel Magno de Freitas, Ravantti, Janne, Grdzelishvili, Nino, Kakabadze, Elene, Bakuradze, Nata, Javakhishvili, Elene, Megremis, Spyridon, Chanishvili, Nina, Papadopoulos, Nikolaos, Sundberg, Lotta-Riina
Format: Article
Language:English
Subjects:
bacteriophage
Bacteriophages
BAM model
mucus
Pseudomonas
Research Article
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Summary:infections are getting increasingly serious as antimicrobial resistance spreads. Phage therapy may be a solution to the problem, especially if improved by current advances on phage-host studies. As a mucosal pathogen, we hypothesize that and its phages are linked to the bacteriophage adherence to mucus (BAM) model. This means that phage-host interactions could be influenced by mucin presence, impacting the success of phage infections on the host and consequently leading to the protection of the metazoan host. By using a group of four different phages, we tested three important phenotypes associated with the BAM model: phage binding to mucin, phage growth in mucin-exposed hosts, and the influence of mucin on CRISPR immunity of the bacterium. Three of the tested phages significantly bound to mucin, while two had improved growth rates in mucin-exposed hosts. Improved phage growth was likely the result of phage exploitation of mucin-induced physiological changes in the host. We could not detect CRISPR activity in our system but identified two putative anti-CRISPR proteins coded by the phage. Overall, the differential responses seen for the phages tested show that the same bacterial species can be targeted by mucosal-associated phages or by phages not affected by mucus presence. In conclusion, the BAM model is relevant for phage-bacterium interactions in , opening new possibilities to improve phage therapy against this important pathogen by considering mucosal interaction dynamics.IMPORTANCESome bacteriophages are involved in a symbiotic relationship with animals, in which phages held in mucosal surfaces protect them from invading bacteria. is one of the many bacterial pathogens threatening humankind during the current antimicrobial resistance crisis. Here, we have tested whether and its phages are affected by mucosal conditions. We discovered by using a collection of four phages that, indeed, mucosal interaction dynamics can be seen in this model. Three of the tested phages significantly bound to mucin, while two had improved growth rates in mucin-exposed hosts. These results link and its phages to the bacteriophage adherence to the mucus model and open opportunities to explore this to improve phage therapy, be it by exploiting the phenotypes detected or by actively selecting mucosal-adapted phages for treatment.
ISSN:2165-0497
2165-0497
DOI:10.1128/spectrum.03520-23