The Role of Bacterial Genotype in the Persistence of the Microbiota of Drosophila melanogaster

Gottfredson, Sarah J.

18 April 2022

In this work we use the fruit fly Drosophila melanogaster as a model to identify bacterial genes that help bacteria to persist in their animal hosts. Early work on this model system established that dietary replenishment drives the composition of the D. melanogaster gut microbiota, and subsequent research has shown that some bacterial strains can colonize the fly for much longer than the flow of bulk diet through the gut. In this work we reveal that bacterial genes influence bacterial persistence by studying the correlation between bacterial genotype and persistence in the D. melanogaster gut microbiota. We performed an initial assay with 7 bacterial strains to establish that different bacterial strains persist differently independent of ingestion in the fly. We then repeated the assay with 41 different strains of bacteria in order to perform a metagenome wide association (MGWA) to find distinct bacterial genes that are significantly correlated with persistence. Based on the MGWA, we tested if 44 mutants from 6 gene categories affect bacterial persistence in the flies. We identified that transposon insertions in four flagellar genes (fliF, flgH, fliI, and flgE), one urea carboxylase gene, one phosphatidyl inositol gene, one bacterial secretion gene, and one antimicrobial peptide (AMP) resistance gene each significantly lowered colonization forming units (CFUs) that resulted from plating the gut content in Drosophila melanogaster. Follow-up experiments with the flagellar gene mutants revealed that each significant flagellar mutant was non-motile compared with the wild type. Taken together, these results reveal that there are bacterial genes that are involved in mechanisms, like bacterial motility, that help bacteria to persist in the fly gut.

microbiome

microbiota

flagella

persistence

colonization

drosophila

Arts and Humanities

The interplay between pathogenic bacteria and bacteriophage Chi: New directions in motility and phage-host interactions in Enterobacterales

Esteves, Nathaniel Carlos

15 April 2024

The bacterial flagellum is a rotary motor that propels motile bacteria through their surroundings via swimming motility, or on surfaces via swarming motility. The flagellum is a key virulence factor for motile pathogenic bacteria. Viruses that infect bacteria via this appendage are known as flagellotropic or flagellum-dependent bacteriophages. Much like other phages, flagellotropic phages are of interest for clinical applications as antibacterial agents, particularly against multidrug resistant (MDR) bacteria. Bacteriophage χ is a flagellotropic phage that infects multiple species of motile pathogens. In the projects described below, we characterized several aspects of the complex interactions between χ and two of its hosts: Salmonella enterica and Serratia marcescens. In Chapter I, we describe in detail the existing knowledge on flagellum-dependent bacteriophages, pathogenic bacteria, and the flagellar motility system. We also expand significantly on flagellotropic phage χ. In Chapter II, we describe our discovery of S. enterica cellular components other than motility that are crucial for bacteriophage χ infection, making the key discovery that the AcrABZ-TolC multi-drug efflux system is required for infection to proceed. We additionally found that the host molecular chaperone trigger factor is important for the χ phage lifecycle. In Chapter III, we outline our characterization of the initial binding interaction between χ and the flagellum, determining that of flagellin's seven domains, C-terminal domain D2 is the most important for χ adsorption. In Chapter IV, we expand on this by discussing our work that determined that the χ tail fiber protein is encoded by the gene CHI_31, purification of this recombinantly-expressed protein, and demonstration of its direct interaction with the flagellar filament. Lastly, in Chapter V, our findings indicate that S. marcescens is able to detect χ infection and lysis in the surroundings and alter gene expression, resulting in an increase in the production of the red pigment prodigiosin. Overall, our hypothetical model for χ infection is as follows: χ binds to the flagellum of its host using its single tail fiber, composed of monomers of the CHI_31 gene product gp31. This tail fiber interacts with CTD2 of flagellin, and the rotation of the flagellum brings the phage to the cell surface, where it interacts with AcrABZ-TolC to inject its genetic material into the host cytoplasm. At some point during the process of production of phage particles and subsequent cell lysis, the host molecular chaperone trigger factor likely assists with proper folding of χ proteins. After cell lysis, cells in the surroundings are capable of detecting lysis and responding accordingly, at least in the case of S. marcescens. This research is clinically relevant for a number of reasons. Phage therapy, the use of bacteriophages as antibacterial agents, requires knowledge of phage infection pathways for optimal implementation. The fact that the flagellum and a complex mediating MDR are both essential for χ infection leads to particular interest in χ for this application. Knowledge of the host-determining factors between χ and Salmonella may lead to the ability to alter the χ phage genome to target specific pathogenic Salmonella or Escherichia coli strains while avoiding disruption of beneficial bacterial communities. / Doctor of Philosophy / Bacteriophages (phages) are viruses that only infect bacteria. They do not harm animal cells or the human body, despite being highly effective predators of bacteria. As such, they have applications in the medical field as antibacterial agents, similar to antibiotics. Phages that infect pathogenic bacteria like Salmonella are of particular interest for scientific research. Bacteriophage χ (Chi) infects bacteria by binding to their flagella, propeller-like appendages that a bacterial cell uses to swim through its surroundings. In many bacterial species, flagella and the ability to swim are closely involved in human infection. Due to this, flagellotropic (flagellum-dependent) phages like χ may be particularly useful as antibiotics. Throughout this project, we characterized the χ phage infection process, including exploring how it attaches to flagella, interactions it has on the surface of and inside Salmonella cells, and the largely unexplored relationship with Serratia marcescens, another bacterial species that causes illness in humans and is highly antibiotic resistant. Overall, our research contributes to the medical field, and indicates that χ may serve as a highly effective antibacterial treatment.

phage

flagella

motility

pathogenic bacteria

virulence

phage therapy

Motility studies and taxonomy of a rod-shaped bacterium with unusual flagellar fascicles, Aquaspirillum fasciculus sp. nov.

Isani, Bilquis

January 1975

In 1971 Strength and Krieg reported the isolation of a floe-forming gram-negative freshwater rod which exhibited large bipolar flagellar fascicles. Despite the intense activity of the fascicles, the organism had appeared unable to swim. However, free-swimming has now been demonstrated within the highly viscous floes formed by the organisms in viscous solutions of gelatin, DNA and methyl cellulose. With each of these viscous agents there existed an optimum concentration for motility. Higher or lower concentrations led to a decrease in motility. In methyl cellulose, strain XI exhibited optimum motility at a viscosity of 200 cp, while strains X and XI were optimal at 10 cp. Nitrogenase activity was demonstrated by the use of the semisolid medium of Döbereiner and Day. No nitrogenase activity occurred when liquid medium was used, and the organisms were obligately microaerophilic in nitrogen-free medium. When (NH₄)₂SO₄ was supplied, no nitrogenase activity occurred and the organism grew best aerobically. The characteristics of strains X, XI and XII indicated that the organisms should be assigned to genus Aquaspirillum. This decision was based on the following considerations: large bipolar fascicles of flagella, a strictly respiratory metabolism, inability to attack carbohydrates, presence of intracellular poly-β-hydroxybutyrate granules, positive reactions for catalase, oxidase and phosphatase, lack of tolerance to 3% NaCl, occurrence of a "polar membrane" in thin sections, and a DNA base composition of 62 to 65% G+C. The strains have been placed in the species Aquaspirillum fasciculus sp. nov. / M.S.

LD5655.V855 1975.I83

Bacteria -- Motility

Flagella (Microbiology)

Molecular interaction of flagellar export chaperone FliS and its interacting partner HP1076 in Helicobacter pylori. / CUHK electronic theses & dissertations collection

January 2010

A HP1076 null mutant has been constructed to provide a better understanding of the biological significance of HP1076 in H. pylori . The DeltaHP1076 mutant displays impaired motility and resistance to the antibiotic drug metronidazole. Using a proteomic study, an overall of 40 differentially expressing proteins involved in metabolism and pH homeostasis for bacterial survival, adhesion for colonization, virulence factor to gastric epithelial cells and antigenic proteins have been identified. The virulence factor, Cag pathogenicity island protein (Cag 26) and urease UreA and UreB are confirmed to have enhanced and reduced expression in null mutants. These findings may provide new insight into the infection of H. pylori. / FliS is an export chaperone that binds to flagellin molecules in cytosol in order to prevent pre-mature polymerization. Disruption of FliS would result in formation of shorter flagella and impaired adhesion ability to epithelial cells. Previous yeast two-hybrid study has identified various FliS associated proteins in H. pylori, but with no known implications. Here, we have demonstrated the interaction of FliS and a hypothetical protein HP1076 by biochemical and biophysical methods. Moreover, HP1076 possesses anti-aggregation ability on insoluble FliS-mutants and chaperone activity. Thus, HP1076 is proposed to be a co-chaperone that promotes the folding and chaperone activity of FliS. FliS is demonstrated to have a broad range of substrate specificity that binds to flagellin and flagellar related proteins which may play a key role in flagellar export system different from other flagellated bacteria. / Helicobacter pylori is a pathogenic bacterium and adheres to the gastric mucosal cells. Chronic infection would lead to gastritis or peptic ulceration and is one of the leading causes of gastric cancer. Formation of functional flagella is essential for infection, that it aids in motility of bacteria and colonization on gastric epithelial cells. The process is complex and involves more than 50 proteins in assembly of structural proteins, regulatory proteins, an export apparatus, a motor and a sensory system. Cytosolic chaperones are required to bind to exported proteins in order to facilitate the export or prevent the aggregation of proteins in cytosol. Divergence is found in flagellar system H. pylori that may account for survival inside gastric environment. / The crystal structures of FliS, HP1076 fragment and FliS/HP1076 complex are determined at 2.7A, 1.8A and 2.7A resolution respectively to provide better understanding of their molecular interactions. FliS consists of four helices and HP1076 consists of helical rich bundle structure with three helices and three beta strands that share similar fold to that of a flagellin homologue, hook-associated protein and FliS, suggesting HP1076 is involved in flagellar system. The FliS/HP1076 complex reveals an extensive electrostatic and hydrophobic binding interface which is distinct from the flagellin binding pocket on FliS. HP1076 stabilizes two alpha helices of FliS and therefore the overall bundle structure. Our findings provide new insights into the flagellar export chaperones and other secretion chaperones in Type III secretion system. / Lam, Wai Ling. / Adviser: An Wing-Ngor. / Source: Dissertation Abstracts International, Volume: 73-02, Section: B, page: . / Thesis (Ph.D.)--Chinese University of Hong Kong, 2010. / Includes bibliographical references (leaves 223-243). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. [Ann Arbor, MI] : ProQuest Information and Learning, [201-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract also in Chinese.

Bacterial proteins

Flagella (Microbiology)

Molecular chaperones

Bacterial Proteins

Flagella--genetics

Helicobacter pylori--pathogenicity

Molecular Chaperones

The centriole in evolution : from motility to mitosis

Smith, Amy Elisabeth

January 2013

Centrioles and basal bodies with their characteristic 9+2 structure are found in all major eukaryotic lineages. The correlation between the occurrence of centrioles and the presence of cilia/flagella, but not centrosome-like structures, suggests that the ciliogenesis function of centrioles is ancestral. Here, it is demonstrated that the centriole domain of centrosomes emerged within the Metazoa from an ancestral state of possessing a centriole with basal body function but no functional association with a centrosome. Centrosome structures involving a centriole are metazoan innovations. When an axoneme is still present but no longer fully functional, such as the sensory cilia of Caenorhabditis elegans or, as depicted here, the flagellum of the intracellular amastigote stage of the Leishmania mexicana parasite, the basal body structure is less constrained and can depart from the canonical structure. A general view has emerged that classifies axonemes into canonical motile 9+2 and noncanonical, sensory 9+0 structures. This study reveals this view to be overly simplistic, and additional axonemal architectures associated with potential sensory structures should be incorporated into prevailing models. Here, a striking similarity between the axoneme structure of Leishmania amastigotes and vertebrate primary cilia is revealed. This striking conservation of ciliary structure, despite the evolutionary distance between Leishmania and mammalian cells, suggests a sensory function for the amastigote flagellum. Adding weight to a sensory hypothesis, close examination of Leishmania positioning inside the parasitophorous vacuole revealed frequent contact between the flagellum tip and the vacuole membrane. A sensory function could also explain the retention of a flagellum in Trypanosoma cruzi amastigotes, an intracellular stage that, as shown in this study, emerged independently to the Leishmania amastigote. Basal body appendages, such as pro-basal bodies and microtubule rootlets, also vary widely in their structure. Choanoflagellates, a sister group to the Metazoa, posses an extensive microtubule rootlet system that provides support for their characteristic collar tentacles. This atypical structure is reflected in the underlying molecular components of the choanoflagellate basal body. The importance of choanoflagellates as the closest known relative of metazoans was first revealed by their similarity to choanocytes, the feeding cells of sponges. Although phylogenetic analyses leave little doubt that choanoflagellates are a sister group of animals, comparisons of molecular and structural components of appendages associated with the collar tentacles highlight significant differences and questions the extent to which the collar structures of choanoflagellates and choanocytes can be assumed to be homologous. Finally, the confinement of a centriole-based centrosome to the Metazoa provides little support for the flagellar synthesis constraint as an explanation for the origin of multicellularity. There is, indeed, an apparent constraint; no flagellated or ciliated metazoan cell ever divides. This constraint, however, did not arise until after the incorporation of centrioles into the centrosome in the metazoan lineage and the co-option of centrioles as a structural and functional component of the centrosome. The flagellar synthesis constraint is therefore not an explanation for the origin of multicellularity but a consequence of it.

571.8

Characterisation of the structure and function of the Salmonella flagellar export gate protein, FlhB

Bergen, Paul Michael

January 2017

Flagella, the helical propellers that extend from the bacterial cell surface, illustrate how complex nanomachines assemble outside the cell. The sequential construction of the flagellar rod, hook, and filament requires export of thousands of structural subunits across the cell membrane and this is achieved by a specialised flagellar Type III Secretion System (fT3SS) located at the base of each flagellum. The fT3SS imposes a crude ordering of subunits, with filament subunits only exported once the rod and hook are complete. This “export specificity switch” is controlled by the FlhB component of the fT3SS export gate in response to a signal from the exported molecular ruler FliK, which monitors the length of the growing hook. This study seeks to clarify how rod and hook subunits interact with FlhB, and how FlhB switches export specificity. Rod and hook subunits possess a conserved gate recognition motif (GRM; Fxxxφ, with φ being any hydrophobic residue) that is proposed to bind a surface-exposed hydrophobic patch on the FlhB cytosolic domain. Mutation of the GRM phenylalanine and the final hydrophobic residue resulted in impaired subunit export and decreased cell motility. Isothermal titration calorimetry was performed to assess whether subunit export order is imposed at FlhB. These experiments showed that rod and hook subunits bind to FlhB with micromolar dissociation constants (5-45 μM), suggesting transient interactions. There was no clear correlation between subunit affinity for FlhB and the order of subunit assembly in the nascent flagellum. Solution-state nuclear magnetic resonance (NMR) spectroscopy supported prior data showing that rod and hook subunits interact with FlhB’s surface-exposed hydrophobic patch. NMR also indicated that residues away from the patch undergo a conformational change on subunit binding. FlhB autocleaves rapidly in its cytosolic domain, and the resulting polypeptides (FlhBCN and FlhBCC) are held together by non-covalent interactions between b-strands that encompass the autocleavage site. The autocleavage event is a prerequisite for the export specificity switch, but its function is unclear. Analysis of the cellular localization of FlhBCN and FlhBCC revealed that FlhBCC dissociated from the membrane export machinery, but only in the presence of FliK. Biochemical and biophysical studies of FlhB variants that undergo export specificity switching in the absence of FliK showed that these FlhB “autonomous switchers” were less stable than wildtype FlhB and their FlhBCC domain could dissociate from the export machinery in the absence of FliK. The results suggest that the export specificity switch involves a FliK-dependent loss of FlhBCC from the export machinery, eliminating the binding site for rod and hook subunits.

616.9

Clostridium difficile : étude du processus de colonisation et d’hypervirulence de la souche épidémique 027 / Clostridium difficile : study of the colonization process and the hypervirulence of an epidemic 027 strain

Barketi-Klai, Amira

12 October 2012

Clostridium difficile est une bactérie entéropathogène responsable de diarrhées nosocomiales post-antibiotiques et de colites pseudomembraneuses. Ces dernières années, l'incidence et la gravité des infections à C. difficile ont significativement augmenté en Amérique et en Europe. Cette évolution semble être liée à l'émergence puis à la dissémination très rapide d'un clone particulièrement virulent de PCR-ribotype 027. Les facteurs de virulence majeurs de C. difficile sont les toxines TcdA et TcdB qui sont responsables des lésions intestinales. Cependant, l’étape de colonisation de l’intestin par la bactérie est considérée comme un pré-requis à l’infection. Afin de mieux comprendre les mécanismes d’hypervirulence de la souche 027, nous nous sommes focalisés sur l’étude du processus de colonisation intestinal de cette souche en le comparant à celui de la souche non épidémique 630∆erm. Dans un premier temps, nous avons étudié le rôle de la protéine de liaison à la fibronectine FbpA. La caractérisation in vitro et in vivo d’un mutant d’inactivation de fbpA, nous a permis de montrer l’implication de cette protéine dans le processus de colonisation de la souche non épidémique 630∆erm. La difficulté à obtenir un mutant dans la souche épidémique 027 R20291 ne nous a pas permis de comparer les propriétés adhésives de FbpA entre les deux souches. Dans un deuxième temps, nous avons étudié les caractéristiques des protéines flagellaires FliC, FliD, FlgE et MotB. Nous avons montré que les flagelles agissent en tant qu’adhésines chez la souche 027 et que ce rôle est moins important chez la souche 630∆erm. Nous avons également montré que les flagelles sont impliqués dans des processus cellulaires autres que l’adhésion et la colonisation. Selon une étude transcriptomique d’un mutant ∆FliC de la souche 027 R20291, il s’est avéré que la flagelline est aussi impliquée dans la production de toxines, la sporulation et dans l’adaptation de la bactérie aux conditions de stress. Une étude complémentaire serait nécessaire afin de mieux comprendre le système de régulation qui régi ces différents processus cellulaires.Finalement, nous avons effectué une analyse transcriptomique de la cinétique de colonisation in vivo de la souche 027. L’étude a révélé l’expression précoce des gènes de toxines et de sporulation au cours du processus d’infection. Elle nous a également permis d’identifier des gènes spécifiques à la souche 027 qui sont exprimés lors du processus infectieux. Ces gènes pourraient éventuellement être impliqués dans la virulence de C. difficile 027 et pourraient constituer de nouvelles pistes d’étude. / Clostridium difficile is an enteropathogenic bacterium that causes post-antibiotic nosocomial diarrhea and pseudomembranous colitis. During the last decade, the incidence and the severity of C. difficile infections have significantly increased in America and Europe. This evolution seems to be related to the emergence and to the rapid dissemination of a particularly virulent clone of PCR-ribotype 027. The main virulence factors of C. difficile are the TcdA and TcdB cytotoxins which are responsible for intestinal lesions. However, the intestinal colonization by the bacterium is considered as an indispensible step for infection.To better understand the hypervirulence mechanisms of strain 027, we focused on the study of intestinal colonization process of this strain compared to the colonization process of the non-epidemic strain 630Δerm. First, we studied the role of the fibronectin binding protein FbpA. In vitro and in vivo characterization of a mutant FbpA showed the involvement of this protein in the colonization process of the non-epidemic strain 630Δerm. The difficulty of obtaining a mutant in the epidemic strain R20291 027 does not allow us to compare the adhesive properties of FbpA between the two strains.In a second step, we studied the characteristics of flagellar proteins FliC, FliD, FlgE and MotB. We showed that the flagella have a role in the adhesion and colonization of strain 027 and that this role is less important in strain 630Δerm. We also showed that flagella are involved in other cellular processes than adhesion and colonization. A transcriptomic study of a FliC mutant in 027 R20291 shows that flagellin is also involved in toxin production, sporulation and in the adaptation of bacteria to stress conditions. Further study should be performed to better understand the regulation system that governs these different cellular processes. Finally, we performed a transcriptomic analysis of the kinetic of in vivo colonization of the 027 R20291 strain. The study revealed a very early expression of toxin and sporulation genes during the first stages of the infection process. This analysis also allowed us to identify some genes, specific to 027 strains, which appeared regulated during the infection process. These genes could be involved in the virulence of C. difficile 027 strains and could provide new issues of study to better understand C. difficile virulence.

Clostridium difficile

Colonisation

Hypervirulence

Flagelles

Protéine de liaison à la fibronectine

Clostridium difficile

Colonization

Hypervirulence

Flagella

Fibronectin binfing protein

Investigating Vibrio parahaemolyticus interactions with the Pacific oyster, Crassostrea gigas

Aagesen, Alisha M.

30 October 2012

Vibrio parahaemolyticus is a Gram-negative, halophilic, human pathogenic bacterium ubiquitous in the marine environment. Like many Vibrio species, V. parahaemolyticus commonly associates with shellfish, particularly oysters. Ingestion of a raw or under cooked oysters contaminated with V. parahaemolyticus can cause gastroenteritis, which is typically self-limiting and rarely causes death. Globally, oyster production is highly lucrative, especially on the West Coast of the United States where approximately 60% of oyster production occurs each year. Outbreaks of V. parahaemolyticus can result in a significant public health problem as well as an economic burden for the oyster farms implicated in the outbreak. With the increase in overall V. parahaemolyticus outbreaks, improved post-harvest processing strategies have been developed to reduce this natural contaminant. Depuration was developed to allow shellfish to purge contaminants from their tissues into the clean, flowing seawater where they are held. This post-harvest processing technique can typically reduce fecal contaminants from the oyster tissues but is relatively ineffective at eliminating V. parahaemolyticus and other Vibrio species.. Thus, improved methods for reducing this and other human pathogenic Vibrio are needed to effectively produce safer oysters for the consumer. To develop more effective and novel V. parahaemolyticus intervention strategies, first we must identify the factors that are involved in V. parahaemolyticus colonization of the oyster, allowing them toresist depuration. This study sought to investigate specific factors utilized by V. parahaemolyticus and, in the process, determined that various strains of V. parahaemolyticus have different alleles of the Type IV pili, mannose-sensitive hemagglutinin (MSHA)and chitin-regulated pilus (PilA). In addition, we expanded our investigations into the allelic diversity of MSHA and PilA from Vibrio cholerae and Vibrio vulnificus and found that V. cholerae strains that possess the Type IV toxin co-regulated pilus (TCP) maintained highly conserved MSHA and PilA sequences while strains of V. cholerae without TCP, and all of the V. vulnificus and V. parahaemolyticus strains examined, had highly divergent sequences with no discernable connection to isolation source or observed phenotype. Following that discovery, we determined that Type I, and Type IV pili, as well as polar and lateral flagellar systems contribute to V. parahaemolyticus persistence in the Pacific oyster during depuration, while Type III secretion systems and phase variation do not. Overall, we have identified factors involved in colonization of the Pacific oyster by V. parahaemolyticus. Future studies investigating conditions that affect pili and flagella production in V. parahaemolyticus may provide novel depuration conditions that could easily and effectively increase the efficiency of oyster depuration, ultimately reducing the risk of seafood-borne illness by V. parahaemolyticus associated with oysters. / Graduation date: 2013

Oyster

Vibrio parahaemolyticus

pili

flagella

Vibrio parahaemolyticus

Pacific oyster -- Microbiology

Pacific oyster -- Sanitation

Regulation of the flagellar specific sigma factor, sigma28, of Salmonella typhimurium by the anti-sigma factor FlgM /

Chadsey, Meggen Shepherd.

January 1998

Thesis (Ph. D.)--University of Washington, 1998. / Vita. Includes bibliographical references (leaves [176]-190).

The role of the primary cilium in energy and glucose metabolism

Davenport, James Robert.

January 2007

Thesis (Ph.D.)--University of Alabama at Birmingham, 2007. / Title from PDF title page (viewed on Sept. 15, 2009). Includes bibliographical references.