Investigation of flagellotropic phage interactions with their motile host bacteria

Gonzalez, Floricel

21 June 2021

Bacteriophages cohabit with their bacterial hosts and shape microbial communities. To initiate infection, phages use bacterial components as receptors to recognize and attach to hosts. Flagellotropic phages utilize bacterial flagella as receptors. Studies focused on uncovering mechanistic details of flagellotropic phage infection are lacking. As the number of phage-based applications grows, it is important to understand these details to predict the potential outcomes of phage therapy. To this end, we studied two flagellotropic phages: Agrobacterium phage 7-7-1 and bacteriophage χ. Phage 7-7-1 infects Agrobacterium spp., while bacteriophage χ infects Salmonella and Escherichia coli. Chapter 1 consists of a literature review. Chapter 2 addresses factors underlying phage-bacteria coexistence. We document the emergence of a sector-shaped lysis pattern following co-inoculation of phage χ and one of its Salmonella hosts on swim plates. We propose that this pattern serves as a reporter for balanced phage-bacteria coexistence. Using a combined experimental and mathematical modelling approach, we discovered that variations to intrinsic factors (i.e., bacterial motility, phage adsorption) skews the pattern towards either bacterial or phage predominance. Thus, this computational model may be used to predict phage therapy application outcomes. Chapter 3 details the identification of cell surface receptors essential for phage 7-7-1 infection using a transposon mutagenesis approach. We identified three Agrobacterium sp. H13-3 genes involved in phage 7-7-1 infection. Using mass spectrometry and other analyses, we determined that the LPS profiles of strains lacking these genes varied compared to the wild type. Thus, LPS is a secondary cell surface receptor for phage 7-7-1. Chapter 4 focuses on the discovery of phage encoded receptor binding proteins (RBPs) in Agrobacterium phage 7-7-1. Using an RBP screen, we discovered three candidate RBPs. We learned that our top candidate, Gp4, inhibits the growth of Agrobacterium sp. H13-3 cells in a motility and glycan dependent manner. Because of its bacteriostatic activities, this protein is a promising candidate for therapeutic use. Overall, the described works contribute to a deepened understanding of flagellotropic phage infection and the factors influencing their coexistence with motile bacteria. These works will contribute towards the development of phage therapies using whole phage or their components. / Doctor of Philosophy / Bacteriophages, or phages for short, are the natural killers of bacteria. Like antibiotics, they can also be used as medicines to treat bacterial infections. Their attack on bacteria begins by recognizing specific parts of the bacterial cell and attaching to them. These parts are called receptors. To use phages as medicines it is important to understand how they recognize and kill bacteria. This information is helpful when deciding which phage should be given to treat a bacterial infection and to predict the outcomes of these treatments. In this work, we focused on two phages to answer different questions. Both phages use long helical thread-like structures, called flagella, as receptors. Flagella help the bacteria to move through the environment and reach new areas with more nutrients. One of these flagella-dependent phages, called phage 7-7-1, infects plant pathogens that cause tumor-like growth in plants. We found that this phage uses two very different host cell components during infection and identified one of the phage proteins that interacts with these receptors. This protein prevents the growth of the plant pathogen, which makes it a promising candidate for therapeutic use. We also investigated how another bacterial virus, bacteriophage χ, is spread throughout the environment and co-exists with its motile bacterial host. We built a computational model that can predict how altering different variables affects phage-bacteria coexistence. With additional research, this model will be a useful tool for predicting the outcomes following phage treatment.

phage

receptors

Agrobacterium

Salmonella

flagellotropic

Biophysics of helices : devices, bacteria and viruses

Katsamba, Panayiota

January 2018

A prevalent morphology in the microscopic world of artificial microswimmers, bacteria and viruses is that of a helix. The intriguingly different physics at play at the small scale level make it necessary for bacteria to employ swimming strategies different from our everyday experience, such as the rotation of a helical filament. Bio-inspired microswimmers that mimic bacterial locomotion achieve propulsion at the microscale level using magnetically actuated, rotating helical filaments. A promising application of these artificial microswimmers is in non-invasive medicine, for drug delivery to tumours or microsurgery. Two crucial features need to be addressed in the design of microswimmers. First, the ability to selectively control large ensembles and second, the adaptivity to move through complex conduit geometries, such as the constrictions and curves of the tortuous tumour microvasculature. In this dissertation, a mechanics-based selective control mechanism for magnetic microswimmers is proposed, and a model and simulation of an elastic helix passing through a constricted microchannel are developed. Thereafter, a theoretical framework is developed for the propulsion by stiff elastic filaments in viscous fluids. In order to address this fluid-structure problem, a pertubative, asymptotic, elastohydrodynamic approach is used to characterise the deformation that arises from and in turn affects the motion. This framework is applied to the helical filaments of bacteria and magnetically actuated microswimmers. The dissertation then turns to the sub-bacterial scale of bacteriophage viruses, 'phages' for short, that infect bacteria by ejecting their genetic material and replicating inside their host. The valuable insight that phages can offer in our fight against pathogenic bacteria and the possibility of phage therapy as an alternative to antibiotics, are of paramount importance to tackle antibiotics resistance. In contrast to typical phages, flagellotropic phages first attach to bacterial flagella, and have the striking ability to reach the cell body for infection, despite their lack of independent motion. The last part of the dissertation develops the first theoretical model for the nut-and-bolt mechanism (proposed by Berg and Anderson in 1973). A nut being rotated will move along a bolt. Similarly, a phage wraps itself around a flagellum possessing helical grooves, and exploits the rotation of the flagellum in order to passively travel along and towards the cell body, according to this mechanism. The predictions from the model agree with experimental observations with respect to directionality, speed and the requirements for succesful translocation.