Browsing by Subject "RNA interference"
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Item Open Access Mechanisms of specificity in neuronal activity-regulated gene transcription.(2012) Lyons, Michelle RenéeIn the nervous system, activity-regulated gene transcription is one of the fundamental processes responsible for orchestrating proper brain development–a process that in humans takes over 20 years. Moreover, activity-dependent regulation of gene expression continues to be important for normal brain function throughout life; for example, some forms of synaptic plasticity important for learning and memory are known to rely on alterations in gene transcription elicited by sensory input. In the last two decades, increasingly comprehensive studies have described complex patterns of gene transcription induced and/or repressed following different kinds of stimuli that act in concert to effect changes in neuronal and synaptic physiology. A key theme to emerge from these studies is that of specificity, meaning that different kinds of stimuli up- and down regulate distinct sets of genes. The importance of such signaling specificity in synapse-to-nucleus communication becomes readily apparent in studies examining the physiological effects of the loss of one or more forms of transcriptional specificity – often, such genetic manipulations result in aberrant synapse formation, neuronal cell death, and/or cognitive impairment in mutant mice. The two primary loci at which mechanisms of signaling specificity typically act are 1) at the synapse – in the form of calcium channel number, localization, and subunit composition – and 2) in the nucleus – in the form of transcription factor expression, localization, and post-translational modification. My dissertation research has focused on the mechanisms of specificity that govern the activity-regulated transcription of the gene encoding Brain-derived Neurotrophic Factor(Bdnf). BDNF is a secreted protein that has numerous important functions in nervous system development and plasticity, including neuronal survival, neurite outgrowth, synapse formation, and long-term potentiation. Due to Bdnf’s complex transcriptional regulation by various forms of neural stimuli, it is well positioned to function as a transducer through which altered neural activity states can lead to changes in neuronal physiology and synaptic function. In this dissertation, I show that different families of transcription factors, and even different isoforms or splice variants within a single family, can specifically regulate Bdnf transcription in an age- and stimulus-dependent manner. Additionally, I characterize another mechanism of synapse-to-nucleus signaling specificity that is dependent upon NMDA-type glutamate receptor subunit composition, and provide evidence that the effect this signaling pathway has on gene transcription is important for normal GABAergic synapse formation. Taken together, my dissertation research sheds light on several novel signaling mechanisms that could lend specificity to the activity-dependent transcription of Bdnf exon IV. My data indicate that distinct neuronal stimuli can differentially regulate the Calcium-Response Element CaRE1 within Bdnf promoter IV through activation of two distinct transcription factors: Calcium-Response Factor (CaRF) and Myocyte Enhancer Factor 2 (MEF2). Furthermore, individual members of the MEF2 family of transcription factors differentially regulate the expression of Bdnf, and different MEF2C splice variants are unequally responsive to L-type voltage-gated calcium channel activation. Additionally, I show here for the first time that the NMDA-type glutamate receptor subunit NR3A (also known as GluN3A) is capable of exerting an effect on NMDA receptor-dependent Bdnf exon IV transcription, and that changes in the expression levels of NR3A may function to regulate the threshold for activation of synaptic plasticity-inducing transcriptional programs during brain development. Finally, I provide evidence that the transcription factor CaRF might function in the regulation of homeostatic programs of gene transcription in an age- and stimulus-specific manner. Together, these data describe multiple novel mechanisms of specificity in neuronal activity-regulated gene transcription, some of which function at the synapse, others of which function in the nucleus.Item Open Access Roles of RNA interference and DNA mismatch repair in maintaining genomic integrity in Cryptococcus pathogens(2022) Priest, Shelby JordanMicroorganisms must regulate genomic stability to strike a balance between excessive deleterious mutation and evolutionary stagnation to successfully compete and endure within their ecological niches. Two important mechanisms involved in maintaining genomic stability are RNA interference (RNAi) and DNA mismatch repair (MMR). RNAi defends the host genome by targeting double-stranded viral RNAs and aberrant endogenous RNAs for degradation. Endogenous sources of aberrant RNAs include transcripts derived from transposable elements and repetitive sequences as well as transcripts with inefficiently spliced introns. Transcription and translation of these endogenous aberrant RNAs is often considered deleterious to the host because transposable elements are capable of replicating and spreading throughout the genome, a process that can disrupt genes and destabilize chromosomes. The DNA MMR pathway canonically detects mismatches caused by DNA damage or errors during DNA replication. After recognizing mismatches, MMR pathway components recruit the appropriate proteins for removal and repair of the mismatched nucleotide. In addition to this role, MMR pathway components are also involved in the rejection of homeologous, or only partially homologous, meiotic recombination intermediates. This activity mediates a critical role in the maintenance of species boundaries, by inhibiting successful recombination between the genomes of two sufficiently divergent organisms, often preventing the production of viable or fertile progeny.The first chapter of this dissertation begins by introducing pathogenic Cryptococcus species, their ability to mediate disease in humans, and various aspects of their genomes and life cycles. Following the introduction to Cryptococcus, factors known to mediate genomic instability in fungi are described. In Chapter 2, the identification and characterization of two clinical Cryptococcus neoformans isolates with significantly increased mutation rates due to RNAi loss and rampant mobilization of a transposable element are detailed. Chapter 3 describes the impact of loss of a functional MMR pathway on the species boundary between C. neoformans and Cryptococcus deneoformans, sister species within the pathogenic Cryptococcus species complex. In Chapter 4, experimental procedures for conducting genetic crosses with Cryptococcus, isolating meiotic products, and many factors impacting these methods are presented. The conclusions of each preceding chapter are then summarized in Chapter 5, where I also put forth further questions and directions for each project. In Appendices A and B, two ongoing projects focused on the identification of additional RNAi-deficient C. neoformans strains as well as work to discover novel RNAi components are respectively described. Lastly, Appendices C and D include supplementary tables from Chapters 2 and 3, respectively.
Item Open Access Unfolded protein response genes regulated by CED-1 are required for Caenorhabditis elegans innate immunity.(2008) Haskins, Kylie AnneThe first line of defense against pathogens is the phylogenetically ancient innate immune system. This system consists of physical barriers and conserved signaling pathways are activated upon infection to produce effector molecules that mount a microbicidal response. Recently, C. elegans has been established as a model organism for the study of innate immunity due to C. elegans genetic tractability and origins predating the evolution of adaptive immunity. Conserved defense pathways essential for mammalian innate immunity have been identified in C. elegans. However, most receptors critical for the activation of the defense signaling pathways in C. elegans remain unknown. The goal of this work was to study CED-1 and its potential role as a cell-surface signaling receptor essential for C. elegans immune response. In this study, we performed a full-genome microarray analysis and discovered that CED-1 functions to activate the expression of pqn/abu unfolded protein response (UPR) genes. The unfolded protein response has been implicated in the normal physiology of immune defense and in several disorders including diabetes, cancer, and neurodegenerative disease. Here we show that ced-1 and pqn/abu genes are required for the survival of C. elegans exposed to live S. enterica. We also show that the overexpression of pqn/abu genes confers protection to pathogen-mediated killing. Taken together, these results indicate that the apoptotic receptor CED-1 and a network of PQN/ABU proteins involved in a non-canonical UPR response are required for proper defense to pathogen infection in Caenorhabditis elegans.