Publication Search Results

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  • (2021) Begik, Oguzhan
    RNA modifications, collectively referred to as the ‘epitranscriptome’, are not mere decorations of RNA molecules, but can be dynamically regulated upon environmental queues and changes in cellular conditions. This dynamic behaviour is achieved through the RNA modification machinery, which comprises “writer”, “reader” and “eraser” proteins that modify, recognize and remove the modification, respectively. Chapter1 presents a comprehensive analysis of the RNA modification machinery (readers, writers and erasers) across species, tissues and cancer types, revealing gene duplications during eukaryotic evolution, changes in substrate specificity and tissue- and cancer-specific expression patterns. Chapters 2 and 3 presents the exploration and development of novel methods to map and analyze RNA modifications transcriptome-wide. Nanopore direct-RNA sequencing technology was used to provide RNA modification maps in full-length native RNA molecules. Firstly, it is shown that RNA modifications can be detected in the form of base-calling ‘errors’, thus allowing us to train Support Vector Machine models that can distinguish m6A-modified from unmodified sites, both in vitro and in vivo. Secondly, it is demonstrated that distinct RNA modification types have unique base-calling ‘error’ signatures, allowing us to exploit these signatures to distinguish different RNA modification types. It is found that pseudouridine has one of the most distinct signatures, appearing in the form of C-to-U mismatches. Finally, this information was used to predict novel pseudouridine sites on ncRNAs and mRNAs transcriptome-wide, as well as to obtain quantitative measurements of the stoichiometry of modified sites. Chapter 4 presents the development of a novel nanopore-based method, which is termed ‘Nano3P-seq’, to simultaneously quantify RNA abundance and tail length dynamics in individual molecules in both the coding and non-coding transcriptome, from cDNA reads. It is demonstrated that Nano3P-seq offers a simple approach to study the coding and non-coding transcriptome at single molecule resolution regardless of the tail ends. Together, this work provides a comprehensive framework for the study of RNA modifications and polyA tail dynamics using third generation sequencing technologies, opening novel avenues for future works that aim to characterize their dynamics and biological roles both in health and in disease.

  • (2022) Young, Clara
    A breakdown in B cell self-tolerance can lead to antibody-mediated autoimmune disease. This thesis aims to explore how B cell tolerance can be broken in two distinct, but complementary projects within the context of the Goodnow somatic mutation hypothesis. In both scenarios, B cells that escape self-tolerance and generate autoantibodies are referred to as “rogue” B cells. First, this thesis aimed to elucidate the precise steps undertaken by expanded rogue B cell clones in patients with chronic Hepatitis C virus (HCV)-associated cryoglobulinemic vasculitis, an autoimmune disease characterised by the production of a rheumatoid factor cryoglobulin autoantibody. The rogue B cell clones in the HCV cryoglobulinemic vasculitis patients were confirmed to be the source of the autoantibody. The rogue B cell clone precursor antibodies failed to bind the HCV envelope glycoprotein E2, yet bound multimerised self-antigen IgG relative to membrane IgM density. These findings disfavour a molecular mimicry hypothesis, and instead indicate IgG immune complexes may be sufficient to drive recruitment of the rogue B cell clone precursors. Finally, the rogue B cells clones were found to carry somatic lymphoma-associated, non-immunoglobulin gene mutations and chromosomal aberrations, predicted to cause hyperactivation of the NF-kB signalling pathway and escape of B cell tolerance. This finding provides additional evidence in support of the Goodnow somatic mutation hypothesis. Second, this thesis examined rogue germinal centre (GC) B cells that arise in the absence of the receptor FAS. Rogue GC B cells loose specificity for the foreign antigen and incidentally generate autoantibodies. However, the accumulation of rogue GC B cells cannot be explained by our current understanding of affinity-based selection in the GC. This work revealed rogue GC B cells, unlike “conventional” GC B cells undergoing affinity maturation to the foreign antigen, can be identified by low expression of CD21 and high expression of B220 (CD21loB220hi). Moreover, rogue GC B cells were found to be rapidly entering cell cycle, enriched for a dark zone phenotype and T-cell dependent, reminiscent of positively selected GC B cells. Thus, rogue GC B cells typically removed by FAS, likely persist in the competitive GC microenvironment despite their loss of BCR specificity to foreign antigen, because they retain the capacity to undergo T-cell dependent positive GC selection.