Medical Biology - Theses

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Subject: Bioinformatics × Subject: Immunology ×

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    Identification of molecular pathways associated with susceptibility and immunity to severe dengue and malaria
    Studniberg, Stephanie Irene ( 2023-12)
    In this era of increasing globalisation, urbanisation, and worsening climate change, the geographical range of transmission-competent mosquito vectors is shifting. Mosquito-borne diseases such as malaria and dengue are gradually emerging in previously unaffected areas, and re-emerging in areas where they had once previously subsided. With alarming increases in dengue case incidence, and for the first time, a chapter addressing the influence of climate change on malaria transmission in the World Malaria Report, it is clear that these two important vector-borne diseases are of utmost global relevance. As per the World Health Organization (WHO) guidelines, individuals presenting with warning signs signifying progression to severe dengue are required to remain under hospital observation. However, these warning signs appear late in the disease course and are non-specific. Consequentially, hospitals become overwhelmed with patients admitted for in-patient observation, many of whom do not progress to severe dengue. Biomarkers to detect progression to severe dengue upon hospital presentation are much needed to improve patient triage and resource allocation. In malaria, despite the great achievement of the recommendation by the WHO for the use of the RTS,S and R21/Matrix-M vaccines in children living in endemic areas, reductions in malaria case incidence remain at a prolonged stall. It is clear that efficacious vaccines approved for children to adults are required to reduce the global malaria burden. Further elucidation of the molecular mechanisms underlying the immune response to dengue and malaria is imperative if these outcomes are to be achieved. To address these outstanding concerns, an integrative systems immunology approach was utilised to identify molecular pathways associated with susceptibility and immunity to severe dengue and malaria. The studies within this thesis have integrated data from single-cell mass cytometry, serology, and transcriptional profiling of peripheral blood mononuclear cells from individuals progressing to either dengue fever (DF) or dengue haemorrhagic fever (DHF), as well as individuals living in a malaria-endemic regions of Indonesia with either symptomatic or asymptomatic Plasmodium falciparum and Plasmodium vivax malaria. Integrative data analysis identified frequencies and transcriptional profiles of effector CD4+ and CD8+ T cells as important components of dengue immunity in individuals progressing to DF. Furthermore, high frequencies of defined populations of CD4+ non-classical monocytes were associated with increased odds of developing DHF. Our approach discovered a strong transcriptional phenotype of immunosuppression underlying asymptomatic P. falciparum malaria, suggesting that the carriage of these infections could preclude complete parasite clearance. Lastly, unlike symptomatic P. falciparum malaria that induced a highly inflammatory response, clinical P. vivax infection featured the upregulation of anti-inflammatory pathways and checkpoint receptors, providing a feedback loop to ameliorate symptomatic infection. Furthermore, gene set enrichment analysis revealed profound dysfunction of the blood monocyte compartment in both symptomatic and asymptomatic P. vivax malaria. Together, the findings in this thesis have critical implications for the deployment and efficacy of malaria vaccines, and for the development of diagnostic tools to predict disease outcomes for dengue patients at point-of-care.
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    The Purification, Identification, and Measurement Of RNA-Binding Proteins
    Smith, Jeffrey Michael ( 2021)
    RNA-binding proteins (RBPs) are classically regarded as facilitators of gene expression. In recent years, however, RNA-protein interactions have also emerged as a pervasive force in the regulation of homeostasis. The compendium of proteins with provable RNA-binding function has swelled from the hundreds to the thousands astride the partnership of MS-based proteomics and RNA Sequencing. At the foundation of these advances is the adaptation of RNA-centric capture methods that extract protein that has been crosslinked in its native environment. These methods reveal snapshots in time displaying an extensive network of regulation and a wealth of data that can be used for both the discovery of RNA-binding function and the molecular interfaces at which these interactions occur. This thesis describes the development of an extraction method that purifies RBP-RNA complexes. This method differentiates itself from other RBP-discovery protocols in that it 1) purifies these complexes so completely that RBP identification can be conducted qualitatively and without differential abundance analysis, 2) permits transcript-targeted capture with sequence-specific oligos, 3) permits global, sequence-agnostic capture 4) both RBP and its bound RNA are isolated intact and 5) can reliably interrogate RBPs at depths that exceed present methods without metabolic or molecular labelling. The performance of this method is first assessed with a census of proteins that directly interact with global, or targeted, RNA transcripts from model cell lines. These efforts are then extended to investigate how protein-RNA interactions change during transition from quiescence to proliferation and then contraction in primary murine CD8+ T cells. Finally, these studies demonstrate how cellular responses provoke different proteins to moonlight as RNA binders and sheds light on a network of complex, co-evolved molecular machines.