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Browsing by Author "Gonzalez, Floricel"

Now showing 1 - 4 of 4
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    Formation of phage lysis patterns and implications on co-propagation of phages and motile host bacteria
    Li, Xiaochu; Gonzalez, Floricel; Esteves, Nathaniel; Scharf, Birgit E.; Chen, Jing (2020-03)
    Coexistence of bacteriophages, or phages, and their host bacteria plays an important role in maintaining the microbial communities. In natural environments with limited nutrients, motile bacteria can actively migrate towards locations of richer resources. Although phages are not motile themselves, they can infect motile bacterial hosts and spread in space via the hosts. Therefore, in a migrating microbial community coexistence of bacteria and phages implies their co-propagation in space. Here, we combine an experimental approach and mathematical modeling to explore how phages and their motile host bacteria coexist and co-propagate. When lytic phages encountered motile host bacteria in our experimental set up, a sector-shaped lysis zone formed. Our mathematical model indicates that local nutrient depletion and the resulting inhibition of proliferation and motility of bacteria and phages are the key to formation of the observed lysis pattern. The model further reveals the straight radial boundaries in the lysis pattern as a telltale sign for coexistence and co-propagation of bacteria and phages. Emergence of such a pattern, albeit insensitive to extrinsic factors, requires a balance between intrinsic biological properties of phages and bacteria, which likely results from coevolution of phages and bacteria. Author summary Coexistence of phages and their bacterial hosts is important for maintaining the microbial communities. In a migrating microbial community, coexistence between phages and host bacteria implies that they co-propagate in space. Here we report a novel phage lysis pattern that is indicative of this co-propagation. The corresponding mathematical model we developed highlights a crucial dependence of the lysis pattern and implied phage-bacteria co-propagation on intrinsic properties allowing proliferation and spatial spreading of the microbes. In contrast, extrinsic factors, such as overall nutrient level, do not influence phage-bacteria coexistence and co-propagation. Findings from this work have strong implications for dispersal of phages mediated by motile bacterial communities, which will provide scientific basis for the fast-growing applications of phages.
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    Identification of Receptor Binding Proteins in Flagellotropic Agrobacterium Phage 7-7-1
    Gonzalez, Floricel; Scharf, Birgit E. (MDPI, 2021-06-29)
    The rapid discovery of new and diverse bacteriophages has driven the innovation of approaches aimed at detailing interactions with their bacterial hosts. Previous studies on receptor binding proteins (RBPs) mainly relied on their identification in silico and are based on similarities to well-characterized systems. Thus, novel phage RBPs unlike those currently annotated in genomic and proteomic databases remain largely undiscovered. In this study, we employed a screen to identify RBPs in flagellotropic Agrobacterium phage 7-7-1. Flagellotropic phages utilize bacterial flagella as receptors. The screen identified three candidate RBPs, Gp4, Gp102, and Gp44. Homology modelling predicted that Gp4 is a trimeric, tail associated protein with a central β-barrel, while the structure and function of Gp102 and Gp44 are less obvious. Studies with purified Gp41-247 confirmed its ability to bind and interact with host cells, highlighting the robustness of the RBP screen. We also discovered that Gp41-247 inhibits the growth of host cells in a motility and lipopolysaccharide (LPS) dependent fashion. Hence, our results suggest interactions between Gp41-247, rotating flagellar filaments and host glycans to inhibit host cell growth, which presents an impactful and intriguing focus for future studies.
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    Investigation of flagellotropic phage interactions with their motile host bacteria
    Gonzalez, Floricel (Virginia Tech, 2021-06-21)
    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.
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    More than Rotating Flagella: Lipopolysaccharide as a Secondary Receptor for Flagellotropic Phage 7-7-1
    Gonzalez, Floricel; Helm, Richard F.; Broadway, Katherine M.; Scharf, Birgit E. (2018-10)
    Bacteriophage 7-7-1, a member of the family Myoviridae, infects the soil bacterium Agrobacterium sp. strain H13-3. Infection requires attachment to actively rotating bacterial flagellar filaments, with flagellar number, length, and rotation speed being important determinants for infection efficiency. To identify the secondary receptor(s) on the cell surface, we isolated motile, phage-resistant Agrobacterium sp. H13-3 transposon mutants. Transposon insertion sites were pinpointed using arbitrary primed PCR and bioinformatics analyses. Three genes were recognized, whose corresponding proteins had the following computationally predicted functions: AGROH133_07337, a glycosyltransferase; AGROH133_13050, a UDP-glucose 4-epimerase; and AGROH133_08824, an integral cytoplasmic membrane protein. The first two gene products are part of the lipopolysaccharide (LPS) synthesis pathway, while the last is predicted to be a relatively small (13.4-kDa) cytosolic membrane protein with up to four transmembrane helices. The phenotypes of the transposon mutants were verified by complementation and site-directed mutagenesis. Additional characterization of motile, phage-resistant mutants is also described. Given these findings, we propose a model for Agrobacterium sp. H13-3 infection by bacteriophage 7-7-1 where the phage initially attaches to the flagellar filament and is propelled down toward the cell surface by clockwise flagellar rotation. The phage then attaches to and degrades the LPS to reach the outer membrane and ejects its DNA into the host using its syringe-like contractile tail. We hypothesize that the integral membrane protein plays an important role in events following viral DNA ejection or in LPS processing and/or deployment. The proposed two-step attachment mechanism may be conserved among other flagellotropic phages infecting Gram-negative bacteria.