Abstract

Microbiomes are an extremely vast and complex network of microorganisms. Bacteriophages are a key factor in the microbial health of an ecological system and impact the evolution of pathogenic bacterial strains. Bacteria and the phages that infect them have an intricate relationship due to the dependency on the bacterial host for phage replication, the ability of the phage to lyse and kill its host, and the horizontal gene transfer between the host and phage. This thesis aimed to understand how bacteria and the bacteriophages that infect them impact an ecological system, with a focus on disease states. By analyzing all bacteriophages targeting a specific host, genomic properties, physical similarities and differences a better understanding of how a group of tailed phages have evolved numerous mechanisms and tools to infect host bacteria was understood. The microbiome study of the Western honey bee Apis mellifera, comparing the microbial communities of colonies infested with the external parasite Varroa destructor against those not infested revealed a need for more directed treatment of Varroa infestations. Through our study we discovered that the honey bee microbiome is much more complex than previously reported, consisting of hundreds of bacterial species. In addition, through comparing infested and healthy colonies, we discovered that infestation of Varroa destructor mites negatively impact the colony microbiome in part by reducing microbes key in digestion and immune health of honey bees. Results in this thesis indicate that two microbes which have not been previously established as part of the key microbes in honey bee guts, Xenorhabdus and Sodalis, may in fact be key to honey bee health as they were both effected negatively by the presence of Varroa mite infestations. These bacteria have been shown to be involved in immune health in other insects, supporting this hypothesis. The final stage of this thesis involved the development of an acaricide bacteriophage therapy designed to target key microbes in the gut of V. destructor. Our therapy was shown to safely treat honey bee colonies infested with this parasite. It can be concluded that while phages are a normal part of the microbial ecosystem of the intestinal tract of organisms, altering that balance by increasing the phage load on the microbiome to target specific beneficial microbes drastically reduces the overall fitness of the organism. Results from this study indicate that multi-target cocktail and single-target phage therapy are an effective low impact biological Varroacide. The discovery of an effective therapy is important and to better understand the results of this thesis, further investigation is required, including a study of the impact of the phage therapy on the mite microbiome, as well as the safety of the therapy to humans.

Degree

PhD

College and Department

Life Sciences; Microbiology and Molecular Biology

Rights

https://lib.byu.edu/about/copyright/

Date Submitted

2022-07-07

Document Type

Dissertation

Handle

http://hdl.lib.byu.edu/1877/etd12853

Keywords

Bacteriophage, microbiome, honey bee, varroa destructor

Language

english

Included in

Life Sciences Commons

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