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Retroelements as controlling elements in mammalsThomson, Gabrielle Anne, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW January 2006 (has links)
Retroelements are genomic parasites which make up ~42% of the human genome and 38% of the mouse genome. Most are degenerate, but a large number have relatively intact promoter elements, suggesting that they are capable of transcription. Transcriptionally active retroelements can perturb normal transcription units in their vicinity through a variety of mechanisms, leading to phenotypic effects and in some cases disease. This phenomenon of transcriptional interference has been observed in organisms as diverse as maize, Drosophila, and the mouse. We analysed the extent of retroelement transcription in normal and diseased tissues, by searching the mouse and human EST databases for transcripts originating in retroelement promoters, and found a large number of transcripts from LINEs, SINEs and ERVs. Retroelement transcripts were found to be initiated in both sense and antisense orientations, and to be equally as common in normal and diseased tissue. Several of these transcripts were chimeric, appearing to initiate in retroelements and reading through to cellular genes, suggestive of transcriptional interference. We have used transposon display to identify and recover retroelement transcripts in the mouse. Transcripts initiated in LINE, SINE and ERV promoters are numerous, and many are chimeric with cellular genes. Although the numbers of recovered chimeric transcripts are too large to permit rigorous analysis of more than a small proportion, some of those we have studied further appear to be authentic transcripts that may represent interference with the canonical promoters of the genes in question. Our results suggest that transcriptional interference by retroelements may be a relatively common occurrence in mammals.
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TRANSCRIPTIONAL, EPIGENETIC, AND SIGNAL EVENTS IN ANTIFOLATE THERAPEUTICSRacanelli, Alexandra 24 June 2009 (has links)
A targeted approach to the development of antifolate therapies has been sought for many years. Central to the success of such development is an understanding of the molecular mechanisms dictating the sensitivity of cells to antifolates and the fundamental differences of these processes between normal and neoplastic phenotypes. This dissertation addressed transcriptional mechanisms and cell-signaling events responsible for the efficacy of antifolate therapies. Transcriptional processes and cell signaling pathways are often aberrant in neoplastic tissues, providing a potential point of distinction between a normal and neoplastic cellular state. Folylpolyglutamate synthetase (FPGS) catalyzes the formation of poly-γ-glutamate derivatives of folates and antifolates, which permits intracellular retention and accumulation of these compounds. The mouse fpgs gene uses two distant promoters to produce functionally distinct isozymes in a tissue-specific pattern. We questioned how the two promoters were differentially controlled. An analysis of DNA methylation and histone post-translational modifications across the length of the mouse fpgs gene showed that epigenetic mechanisms contributed to the tissue-specific control of the upstream (P1), but not the downstream (P2) fpgs promoter. RNAPII complexes and general transcription factors were present over P1 only when P1 was transcribed, but these components were present over P2 in most tissues, and promoter-proximal pausing was evident in brain. Clear promoter occlusion was found over P2 in liver. These studies concluded that tissue-specific coordination of dual promoters required multiple interacting controls. The mammalian target of rapamycin (mTOR) controls protein translation initiation, and is central to a cell-signaling pathway rich in tumor suppressor and oncogenic proteins. mTOR dysregulation is a common feature of several human cancers and inhibition of this protein has been sought as an ideal cancer drug target. We have determined that antifolates inhibiting the two folate-dependent steps of purine synthesis (GART or AICART) activate AMP-dependent protein kinase (AMPK) and inhibit mTOR. The mechanism of AMPK stimulation appears to be mediated by either nucleotide depletion (GART inhibitors), or ZMP accumulation (AICART inhibitors). These studies discovered a new mechanism for antifolates that surprisingly defines them as molecularly targeted therapeutics.
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Influencia de la cromatina en el lugar de integración sobre la actividad del promotor del virus de la immunodeficiencia humana y el establecimiento de la latencia viralGallastegui Calvache, Edurne 18 June 2010 (has links)
El establecimiento de un reservorio latente del virus del HIV en células T CD4+ es la mayor barrera contra la erradicación de esta enfermedad. Para lograr su erradicación, se necesitaría combinar la terapia antirretroviral HAART con drogas capaces de reactivar los virus durmientes. El objetivo principal de este estudio es entender cómo se establece la latencia tras la integración del virus en el genoma, con el propósito de identificar factores involucrados que pudieran ser dianas de una nueva terapia. Hemos generado una librería de clones que contienen un minigenoma latente del virus que expresa GFP como reportero cuando se reactiva. Esta librería permite estudiar la posible relación existente entre estado de la cromatina en el lugar de integración y actividad del promotor. También hemos estudiado la implicación de la interferencia transcripcional en el establecimiento de la latencia en los clones cuya integración del HIV ha tenido lugar en genes transcripcionalmente activos. Para investigar el mecanismo de represión durante la latencia, se han llevado a cabo depleciones de factores relacionados con el reensamblaje de la cromatina y proteínas relacionadas con represión transcripcional. Finalmente, hemos buscado drogas que puedan reactivar el virus latente como posible terapia a combinar con la terapia antiretroviral. / The establishment of a latent HIV reservoir in CD4+ T cells is the main barrier to prevent the eradication of the virus and converts its infection in a chronic disease. To achieve its eradication, it would be needed to combine HAART with drugs able to reactivate the dormant viruses. The main objective of this study is to understand how latency is established after proviral integration into the genome, with the aim of identifying factors involved that could be targeted by new therapeutic approaches. We have generated a library of clones containing a latent HIV minigenome that expresses GFP as a reporter only when reactivated. This library allows the study of the relationship between the chromatin state at the site of integration and HIV promoter activity. We have also studied the implication of transcriptional interference in the establishment of latency in those clones where HIV has integrated in transcriptionally active genes. To further investigate the mechanism of transcriptional repression in latency we have performed knockdowns of known chromatin reassembly factors and repression-related proteins by using shRNA expression. Finally we have searched drugs that can reactivate the latent HIV as a possible therapy to combine with HAART.
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Rôle de la transcription pervasive antisens chez Saccharomyces cerevisiae dans la régulation de l'expression des gènes / Role of pervasive transcription in gene expression regulation in Saccharomyces cerevisiaeChery, Alicia 04 October 2017 (has links)
L'expression des gènes est finement régulée dans la cellule et soumise à de multiples contrôles-qualité. Cette régulation intervient à différents niveaux, de façon à garantir une synthèse efficace des produits fonctionnels de l'expression génique, et pour assurer une adaptation à un changement environnemental. Notamment, les régulations transcriptionnelles sont cruciales pour contrôler la cinétique et le niveau d'expression des gènes. La transcription pervasive est une transcription généralisée non-codante et instable qui fut révélée chez la levure Saccharomyces cerevisiae. Bien que son potentiel régulateur ait été démontré de façon ponctuelle, la question de sa fonctionnalité globale restait ouverte. Lors de ma thèse, j'ai pu montrer l'existence de phénomènes multiples d'interférence transcriptionnelle liés à la transcription pervasive, pour co-réguler un ensemble de gènes entre la phase exponentielle et la quiescence. En effet, la transcription non-codante en antisens des gènes concernés conduit à leur répression, dans des conditions où ils ne doivent pas être exprimés. Le mécanisme de répression fait intervenir des modifications de la chromatine. La levure bourgeonnante, dépourvue de la machinerie d'ARN interférence, présente donc un système fin de régulation de l'expression génique utilisant la transcription pervasive. / In the cell, gene expression is finely tuned and is submitted to different quality-controls. Gene are regulated at different expression levels in order to guarantee a proper synthesis of functional products, and to ensure an optimal adaptation to environmental changes. In particular, transcriptional regulations are critical for gene expression level and kinetics.Pervasive transcription, defined as a generalized non-coding and unstable transcription, was discovered in the yeast Saccharomyces cerevisiae. Although its regulatory potential was punctually shown, the question of its global functionality still remained. During my PhD, I could show the existence of numerous transcriptional interference mechanisms involved in the co-regulation of a group of genes between exponential phase and quiescence. Indeed, non-coding transcription in antisense to genes promoter leads to its repression in conditions where they have to be switched off. The repression mechanism is allowed by chromatin modifications.Hence, budding yeast that lacks RNA interference machinery has developed a fine regulation system using pervasive transcription.
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OperomeDB: database of condition specific transcription in prokaryotic genomes and genomic insights of convergent transcription in bacterial genomesChetal, Kashish 27 October 2014 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / My thesis comprises of two individual projects: 1) we have developed a database for operon prediction using high-throughput sequencing datasets for bacterial genomes. 2) Genomics and mechanistic insights of convergent transcription in bacterial genomes.
In the first project we developed a database for the prediction of operons for bacterial genomes using RNA-seq datasets, we predicted operons for bacterial genomes. RNA-seq datasets with different condition for each bacterial genome were taken into account and predicted operons using Rockhopper. We took RNA-seq datasets from NCBI with distinct experimental conditions for each bacterial genome into account and analyzed using tool for operon prediction. Currently our database contains 9 bacterial organisms for which we predicted operons. User interface is simple and easy to use, in terms of visualization, downloading and querying of data. In our database user can browse through reference genome, genes present in that genome and operons predicted from different RNA-seq datasets.
Further in the second project, we studied the genomic and mechanistic insights of convergent transcription in bacterial genomes. We know that convergent gene pairs with overlapping head-to-head configuration are widely spread across both eukaryotic and prokaryotic genomes. They are believed to contribute to the regulation of genes at both transcriptional and post-transcriptional levels, although factors contributing to their abundance across genomes and mechanistic basis for their prevalence are poorly understood. In this study, we explore the role of various factors contributing to convergent overlapping transcription in bacterial genomes. Our analysis shows that the proportion of convergent overlapping gene pairs (COGPs) in a genome is affected due to endospore formation, bacterial habitat, oxygen requirement, GC content and the temperature range. In particular, we show that bacterial genomes thriving in specialized habitats, such as thermophiles, exhibit a high proportion of COGPs. Our results also conclude that the density distribution of COGPs across the genomes is high for shorter overlaps with increased conservation of distances for decreasing overlaps. Our study further reveals that COGPs frequently contain stop codon overlaps with the middle base position exhibiting mismatches between complementary strands. Further, for the functional analysis using cluster of orthologous groups (COGs) annotations suggested that cell motility, cell metabolism, storage and cell signaling are enriched among COGPs, suggesting their role in processes beyond regulation. Our analysis provides genomic insights into this unappreciated regulatory phenomenon, allowing a refined understanding of their contribution to bacterial phenotypes.
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