Appelmans Protocol for<i>in vitro Klebsiella pneumoniae</i>phage host range expansion leads to induction of a novel temperate linear plasmid prophage<i>vB_KpnS-KpLi5</i>

Jakob, Nadine; Hammerl, Jens A; Swierczewski, Brett E; Würstle, Silvia; Bugert, Joachim J

doi:10.1101/2023.08.05.552120

Cited by 2 publications

References 13 publications

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Evolutionary strategies ofKlebsiellaphages in a host-diverse environment

Ferriol-González,

Domingo-Calap

2024

Preprint

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Phage-host interactions have been studied using one or a few phages and hosts in simple, controlled systems. Here, we implemented an experimental design to evolve a 12-phage cocktail in a highly diverse environment, including a combination of 39 Klebsiella spp. capsular types. Our results showed how phages modulate their host range through different strategies, adopting a more generalist lifestyle or maintaining their host specificity, depending on the versatility of receptor binding proteins. Some of these proteins were mutational hotspots during the evolution experiment, mainly due to their intrinsic versatility, allowing a broader or narrower host range, and host diversity in the environment. Other mutations found in evolved phages were associated with evading bacterial defense systems or improving fitness on current hosts. Ecological dynamics between phages and hosts, including prophage activation and recombination events, also determined the fate of phage populations. In addition, single phage evolution experiments were performed to validate the results, allowing a model of receptor binding protein evolution and host range modulation to be proposed. This work is a step forward in the understanding of phage-host interactions and the appropriate implementation of phages as biomedical tools, providing insights into their impact in complex environments such as the human microbiota.

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Evolutionary strategies ofKlebsiellaphages in a host-diverse environment

Ferriol-González,

Domingo-Calap

2024

Preprint

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Directed evolution of bacteriophages: thwarted by prolific prophage

Peters,

Schow,

Spencer

et al. 2024

Appl Environ Microbiol

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Various directed evolution methods exist that seek to procure bacteriophages with expanded host ranges, typically targeting phage-resistant or non-permissive bacterial hosts. The general premise of these methods involves propagating phage(s) on multiple bacterial hosts, pooling the lysate, and repeating this process until phage(s) can form plaques on the target host(s). In theory, this produces a lysate containing input phages and their evolved phage progeny. However, in practice, this lysate can also include prophages originating from bacterial hosts. Here, we describe our experience implementing one directed evolution method, the Appelmans protocol, to study phage evolution in the Pseudomonas aeruginosa phage–host system, where we observed rapid host-range expansion of the phage cocktail. Further experimentation and sequencing revealed that the observed host-range expansion was due to a Casadabanvirus prophage originating from a lysogenic host that was only included in the first three rounds of the experiment. This prophage could infect five of eight bacterial hosts initially used, allowing it to persist and proliferate until the termination of the experiment. This prophage was represented in half of the sequenced phage samples isolated from the Appelmans experiment, but despite being subjected to directed evolution conditions, it does not appear to have evolved. This work highlights the impact of prophages in directed evolution experiments and the importance of genetically verifying output phages, particularly for those attempting to procure phages intended for phage therapy applications. This study also notes the usefulness of intraspecies antagonism assays between bacterial host strains to establish a baseline for inhibitory activity and determine the presence of prophage. IMPORTANCE Directed evolution is a common strategy for evolving phages to expand the host range, often targeting pathogenic strains of bacteria. In this study, we investigated phage host-range expansion using directed evolution in the Pseudomonas aeruginosa system. We show that prophages are active players in directed evolution and can contribute to observation of host-range expansion. Since prophages are prevalent in bacterial hosts, particularly pathogenic strains of bacteria, and all directed evolution approaches involve iteratively propagating phage on one or more bacterial hosts, the presence of prophage in phage preparations is a factor that needs to be considered in experimental design and interpretation of results. These results highlight the importance of screening for prophages either genetically or through intraspecies antagonism assays during selection of bacterial strains and will contribute to improving the experimental design of future directed evolution studies.

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Appelmans Protocol forin vitro Klebsiella pneumoniaephage host range expansion leads to induction of a novel temperate linear plasmid prophagevB_KpnS-KpLi5

Cited by 2 publications

References 13 publications

Evolutionary strategies ofKlebsiellaphages in a host-diverse environment

Evolutionary strategies ofKlebsiellaphages in a host-diverse environment

Directed evolution of bacteriophages: thwarted by prolific prophage

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