Controlling Recombination to Evolve Bacteriophages

Overview

Journal Cells

Publisher MDPI

Specialties Biochemistry
Biophysics
Cell Biology
Molecular Biology

Date 2024 Apr 12

PMID 38607024

Authors

James J Bull

Holly A Wichman

Stephen M Krone

Ian J Molineux

Affiliations

Soon will be listed here.

Abstract

Recombination among different phages sometimes facilitates their ability to grow on new hosts. Protocols to direct the evolution of phage host range, as might be used in the application of phage therapy, would then benefit from including steps to enable recombination. Applying mathematical and computational models, in addition to experiments using phages T3 and T7, we consider ways that a protocol may influence recombination levels. We first address coinfection, which is the first step to enabling recombination. The multiplicity of infection (MOI, the ratio of phage to cell concentration) is insufficient for predicting (co)infection levels. The force of infection (the rate at which cells are infected) is also critical but is more challenging to measure. Using both a high force of infection and high MOI (>1) for the different phages ensures high levels of coinfection. We also apply a four-genetic-locus model to study protocol effects on recombinant levels. Recombinants accumulate over multiple generations of phage growth, less so if one phage outgrows the other. Supplementing the phage pool with the low-fitness phage recovers some of this 'lost' recombination. Overall, fine tuning of phage recombination rates will not be practical with wild phages, but qualitative enhancement can be attained with some basic procedures.

Citing Articles

Isolation of phages infecting the zoonotic pathogen reveals novel structural and genomic characteristics.

Osei E, OHea R, Cambillau C, Athalye A, Hille F, Franz C bioRxiv. 2025; .

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Mathematical comparison of protocols for adapting a bacteriophage to a new host.

Bull J, Krone S Virus Evol. 2024; 10(1):veae100.

PMID: 39717707 PMC: 11665826. DOI: 10.1093/ve/veae100.

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