Microbiology & Immunology - Theses

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End date: 2020 × Start date: 2020 × Type: Masters Research thesis ×

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    Investigation of rare actinomycetes for novel antimicrobials
    Byrne, Janet ( 2020)
    Nocardia are a genus of ubiquitous environmental bacteria belonging to the phylum Actinobacteria. Genomics has revealed that Nocardia species are endowed with extensive and varied arrays of secondary metabolite biosynthetic gene clusters with the potential to produce natural products that have antibiotic properties. Furthermore, the abundance of such gene clusters within the Nocardia rivals that of Streptomyces, the signature genus among the Actinobacteria, owed to the fact that Streptomyces species have yielded many clinically used antibiotics. This project aimed to address the current antibiotic resistance crisis and the shortfall in new compounds within the drug discovery pipeline. A range of natural product discovery techniques were utilised amongst different Actinobacteria with a particular focus on a collection of species within the generally overlooked genus Nocardia. This study had three primary objectives, the first was to use a traditional, high-throughput, empirical screen of 169 pathogenic actinomycetes predominantly from the genus Nocardia. These isolates were screened for antibiotic activity on 19 distinct growth media against a panel of five highly prevalent, multidrug resistant pathogens (Escherichia coli, Klebsiella pneumoniae, Staphylococcus aureus, Enterococcus faecium and Acinetobacter baumannii). Secondly, whole genome sequencing and bioinformatic interrogation of 100 Nocardia species was conducted to assess their genetic potential to biosynthesise natural products. This facilitated the selection of a single Nocardia isolate which possessed a non-ribosomal peptide synthetase locus that appeared to be unique amongst other Nocardia species. The locus was also transcriptionally silent. Bioengineering using promoter refactoring was employed to activate expression of this gene cluster, the product of which might have potential as a novel antimicrobial. Thirdly, by utilisation of liquid chromatography-mass spectrometry (LC-MS), bioinformatics and molecular networking, a metabolomic approach was employed to gain a global secondary metabolic footprint of ten predicted “biosynthetically talented" Nocardia species grown on five distinct media types. This project identified: (i) A Nocardia sp. with activity against multidrug resistant Acinetobacter baumannii. (ii) Two Streptomyces isolates (Streptomyces cacaoi and Streptomyces sp.) which exhibited antimicrobial activity against multidrug resistant Escherichia coli and Acinetobacter baumannii respectively. Secondary metabolite extracts from each of these producing isolates were investigated by LC-MS/MS and the resulting spectra was assessed for uniqueness through a dereplication data platform developed specifically for bacterial natural product identification. No hits for previously discovered metabolites were obtained suggesting that the antimicrobials discovered within this project appear to be unique and have potential as new drug leads for today’s ever-decreasing antibiotic discovery pipeline. (iii) Four distinct families of bioactive secondary metabolites that were produced by multiple Nocardia species following LC-MS/MS and molecular network analysis. The identified secondary metabolites were correlated with genome sequence data to identify their probable biosynthetic origin in Nocardia species.
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    The dynamics of the B cell response during influenza A virus infection
    Lee, Hoi Yee ( 2020)
    Although vaccination remains the most effective method of managing influenza epidemics, there is still much that remains to be characterized about humoral immunity against the varying contexts in which influenza infection can occur. With the continuous subversion of humoral immunity by seasonal influenza through antigenic drift and the potential of zoonotic influenza viruses adapting and spreading through human populations through antigenic shift, improving our understanding of B cell immunity against different types of influenza infection could provide important insights into improving management of epidemics and vaccine formulations. In order to understand B cell responses during influenza infection, the well-characterized C57BL/6 mouse model was used to investigate and compare humoral responses in the context of different influenza infection histories. Markers that identified specific B cell subsets such as germinal centre (GC) B cells and plasmablasts were analysed by flow cytometry paired with influenza virus-specific B cell ELISPOT assays to investigate strain-specific antibody secreting responses within the same experiment. As the surface glycoprotein HA is thought to be the immunodominant response for B cell responses against influenza virus, the prediction is that the greater the antigenic differences between the HA of the first and second infecting strains, the more primary-like the response to the second strain would be. Primary and homologous secondary B cell responses in the mediastinal lymph node (MLN) and spleen were first characterized using this model to establish baseline responses against influenza virus before heterosubtypic infection was studied through infection of mice with H1N1A/Puerto Rico/8/34 (PR8) virus followed by H3N2 A/Udorn/305/72 (Udorn) virus 7 weeks later. Unexpectedly, a secondary-like plasmablast, GC B cell and Udorn-specific antibody secreting cells was observed during heterosubtypic infection, with earlier and higher magnitude B cell responses. These findings suggested a possible role for cross-subtype T cell memory in modulating B cell responses. The effect of antigenic drift on the B cell responses during influenza infection was then analysed with the same model. Mice were infected with H3N2 strains isolated between 1972 and 1979, representing different antigenic distance from a virus isolated in 1982 (Ph82). Seven weeks post infection mice were reinfected with Ph82 and the B cell response over the course of infection examined. It was found that infection of strains up to 10 years apart appeared to induce a secondary-like B cell response in the secondary lymphoid organs when compared to baseline primary and secondary responses against Ph82 virus. Prior infection with any H3N2 strain also resulted in minimal viral replication during the secondary challenge when compared to primary infection groups. However, data from both primary antibody inhibition and HA-specific B cell responses appears to suggest a narrower threshold of recognition, around a maximum of 3 years drift before serum and HA-specific responses cease to bind with other strains. Taken together, secondary-like B cell responses in both heterosubtypic and drift models of infection and in the case of drift responses, irrespective of reactivity of HA-specific B cells, appear to refute the hypothesis that virus-specific B cell responses would reflect antigenic relatedness between the HA of the infecting strains. Overall, data from this study identifies the diversity of the overall B cell response against influenza infection in the context of prior exposure to strains of different antigenic properties. Further study into the reactivity of these B cells against different influenza virus components and the role of memory T cells in the observed responses may provide important insights into the nature of host immunity against the ever-shifting target of influenza virus.