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Transcriptional Network Analysis During Early Differentiation Reveals a Role for Polycomb-like 2 in Mouse Embryonic Stem Cell CommitmentWalker, Emily 11 January 2012 (has links)
We used mouse embryonic stem cells (ESCs) as a model to study the mechanisms that regulate stem cell fate. Using gene expression analysis during a time course of differentiation, we identified 281 candidate regulators of ESC fate. To integrate these candidate regulators into the known ESC transcriptional network, we incorporated promoter occupancy data for OCT4, NANOG and SOX2. We used shRNA knockdown studies followed by a high-content fluorescence imaging assay to test the requirement of our predicted regulators in maintaining self-renewal. We further integrated promoter occupancy data for Polycomb group (PcG) proteins, EED and PHC1 to identify 43 transcriptional networks in which we predict that OCT4 and NANOG co-operate with EED and PHC1 to influence the expression of multiple developmental regulators. Next, we turned our focus to the PcG protein PCL2 which we identified as being bound by both OCT4 and NANOG and down-regulated during differentiation. PcG proteins are conserved epigenetic transcriptional repressors that control numerous developmental gene expression programs. Using multiple biochemical strategies, we demonstrated that PCL2 associates with Polycomb Repressive Complex 2 (PRC2) in mouse ESCs, a complex that exerts its effect on gene expression through H3K27me3. Although PCL2 was not required for global histone methylation, it was required at specific target regions to maintain proper levels of H3K27me3. Knockdown of Pcl2 in ESCs resulted in heightened self-renewal characteristics and defects in differentiation. Integration of global gene expression and promoter occupancy analyses allowed us to identify PCL2 and PRC2 transcriptional targets and draft regulatory networks. We describe the role of PCL2 in both modulating transcription of ESC self-renewal genes in undifferentiated ESCs as well as developmental regulators during early commitment and differentiation.
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Transcriptional Network Analysis During Early Differentiation Reveals a Role for Polycomb-like 2 in Mouse Embryonic Stem Cell CommitmentWalker, Emily 11 January 2012 (has links)
We used mouse embryonic stem cells (ESCs) as a model to study the mechanisms that regulate stem cell fate. Using gene expression analysis during a time course of differentiation, we identified 281 candidate regulators of ESC fate. To integrate these candidate regulators into the known ESC transcriptional network, we incorporated promoter occupancy data for OCT4, NANOG and SOX2. We used shRNA knockdown studies followed by a high-content fluorescence imaging assay to test the requirement of our predicted regulators in maintaining self-renewal. We further integrated promoter occupancy data for Polycomb group (PcG) proteins, EED and PHC1 to identify 43 transcriptional networks in which we predict that OCT4 and NANOG co-operate with EED and PHC1 to influence the expression of multiple developmental regulators. Next, we turned our focus to the PcG protein PCL2 which we identified as being bound by both OCT4 and NANOG and down-regulated during differentiation. PcG proteins are conserved epigenetic transcriptional repressors that control numerous developmental gene expression programs. Using multiple biochemical strategies, we demonstrated that PCL2 associates with Polycomb Repressive Complex 2 (PRC2) in mouse ESCs, a complex that exerts its effect on gene expression through H3K27me3. Although PCL2 was not required for global histone methylation, it was required at specific target regions to maintain proper levels of H3K27me3. Knockdown of Pcl2 in ESCs resulted in heightened self-renewal characteristics and defects in differentiation. Integration of global gene expression and promoter occupancy analyses allowed us to identify PCL2 and PRC2 transcriptional targets and draft regulatory networks. We describe the role of PCL2 in both modulating transcription of ESC self-renewal genes in undifferentiated ESCs as well as developmental regulators during early commitment and differentiation.
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Histone Crosstalks involving H3 Phosphorylation and their Role in Transcriptional RegulationLau, Nga Ieng 08 August 2013 (has links)
Histone phosphorylation is often a direct outcome of activated intracellular signaling pathways, and functions to translate extracellular signals into appropriate biological outputs such as changes in gene expression. Growth factors and cellular stress trigger rapid and transient expression of immediate-early genes (such as c-fos, c-jun) in mammalian cells, and their induction strongly correlates with a transient phosphorylation of S10 and S28 on histone H3. While many signaling cascades that lead to H3 phosphorylation have been mapped out, mechanistic details of the downstream events and how H3 phosphorylation contributes to transcriptional activation are still poorly defined.
To investigate the direct effects of H3 phosphorylation on transcription, we targeted the H3 kinase MSK1 to endogenous c-fos promoter, and found that this is sufficient to activate its expression. Moreover, targeting MSK1 to the tissue-specific -globin gene induces H3S28 phosphorylation and reactivates expression of this polycomb-silenced gene. Mechanistically, H3S28 phosphorylation not only disrupts binding of polycomb repressive complexes, but also induces a methyl-acetylation switch of the adjacent K27 residue. This provides the first indication that H3 phosphorylation is involved in antagonizing polycomb silencing.
To further identify post-translational modifications (PTMs) that function together with MSK1-mediated H3 phosphorylation, I developed a novel nucleosome purification approach called Biotinylation-assisted Isolation of CO-modified Nucleosomes (BICON). This technique combines in vivo biotinylation by BirA and H3 phosphorylation by MSK1, allowing enrichment of phosphorylated nucleosomes using streptavidin. I found that MSK1-phosphorylated nucleosomes are hyper-acetylated on H3 and H4, and importantly, I identified a trans-tail crosstalk between H3 phosphorylation and H4 acetylation on K12. This proof-of-principle study demonstrates that BICON can be further adapted to study PTMs and crosstalks associated with other histone-modifying enzymes.
Taken together, work described in this thesis shows that histone H3 phosphorylation can initiate additional PTM changes on other residues within the nucleosome, and such crosstalk plays an important role in regulating gene expression.
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Histone Crosstalks involving H3 Phosphorylation and their Role in Transcriptional RegulationLau, Nga Ieng 08 August 2013 (has links)
Histone phosphorylation is often a direct outcome of activated intracellular signaling pathways, and functions to translate extracellular signals into appropriate biological outputs such as changes in gene expression. Growth factors and cellular stress trigger rapid and transient expression of immediate-early genes (such as c-fos, c-jun) in mammalian cells, and their induction strongly correlates with a transient phosphorylation of S10 and S28 on histone H3. While many signaling cascades that lead to H3 phosphorylation have been mapped out, mechanistic details of the downstream events and how H3 phosphorylation contributes to transcriptional activation are still poorly defined.
To investigate the direct effects of H3 phosphorylation on transcription, we targeted the H3 kinase MSK1 to endogenous c-fos promoter, and found that this is sufficient to activate its expression. Moreover, targeting MSK1 to the tissue-specific -globin gene induces H3S28 phosphorylation and reactivates expression of this polycomb-silenced gene. Mechanistically, H3S28 phosphorylation not only disrupts binding of polycomb repressive complexes, but also induces a methyl-acetylation switch of the adjacent K27 residue. This provides the first indication that H3 phosphorylation is involved in antagonizing polycomb silencing.
To further identify post-translational modifications (PTMs) that function together with MSK1-mediated H3 phosphorylation, I developed a novel nucleosome purification approach called Biotinylation-assisted Isolation of CO-modified Nucleosomes (BICON). This technique combines in vivo biotinylation by BirA and H3 phosphorylation by MSK1, allowing enrichment of phosphorylated nucleosomes using streptavidin. I found that MSK1-phosphorylated nucleosomes are hyper-acetylated on H3 and H4, and importantly, I identified a trans-tail crosstalk between H3 phosphorylation and H4 acetylation on K12. This proof-of-principle study demonstrates that BICON can be further adapted to study PTMs and crosstalks associated with other histone-modifying enzymes.
Taken together, work described in this thesis shows that histone H3 phosphorylation can initiate additional PTM changes on other residues within the nucleosome, and such crosstalk plays an important role in regulating gene expression.
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Cell Fate Maintenance and Presynaptic Development in the Drosophila EyeFinley, Jennifer 03 October 2013 (has links)
Neurons in the central nervous system are typically not replaced and must therefore maintain their choice of fate and their synaptic connections throughout the life of an organism. I have used Drosophila genetics to analyze genes that prevent neurons from switching fates and allow them to form synapses onto target neurons. The Drosophila fly eye is composed of approximately 750 ommatidia, each comprising eight photoreceptor neurons (R1-R8) surrounded by non-neuronal accessory cells. These photoreceptor neurons undergo a well-defined developmental specification process and form synapses at defined locations in the brain. I have taken advantage of this system to investigate two questions: 1) how do neurons maintain their fate after specification? and 2) how do neurons form stable synapses? For the first half of my dissertation, I have focused my research on a gene, Sce, that I have shown is essential to prevent R7 neurons from undergoing a late switch in cell fate. Sce is an integral component of the Polycomb Group (PcG) complex that is essential for maintaining repression of multiple genes throughout the genome. I found that PcGs are required to prevent R7s from derepression of the R8-specific transcription factor Senseless. For the second half of my dissertation, I focused on the gene syd-1 that was identified to be required for proper presynaptic formation of R7 neurons. Previous studies in Caenorhabditis elegans suggested that Syd-1 acts upstream of Liprin-α and that Liprin-α promotes presynaptic development by binding the kinesin Kif1a to promote axon transport. I used live image analysis to show that, unlike Liprin-α, Syd-1 is not necessary to promote axon transport. Instead, we show that in R7s, Syd-1 acts upstream of Trio, and our results suggest that Syd-1's function is to promote Trio activity.
This dissertation includes both my previously published and co-authored materials. / 10000-01-01
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Vztah vyšších chromatinových struktur a genové umlčování / The relationship between higher order chromain structure and gene silencingŠmigová, Jana January 2012 (has links)
No description available.
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Strukturně-funkční organizace buněčného jádra.Mikroskopická analýza jaderných subkompartmentů. / Structure-function organization of the cell nucleus.Microscopical analysis of nuclear subcompartments.Jůda, Pavel January 2015 (has links)
Pavel Jůda - Abstract The cell nucleus is a complex cellular organelle. The nucleus and nuclear processes are organized into functionally and morphologically separated nuclear subcompartments. This thesis is particularly concerned with the three following nuclear subcompartments: sites of DNA replication, Polycomb bodies and nuclear inclusions constituted of inosine monophosphate dehydrogenase 2 (IMPDH2). First, we examined the relationship between MCM proteins and DNA replication. Using immunofluorescent labeling of cells extracted prior fixation and applying cross-correlation function analysis, we showed that MCM proteins are present at the sites of active DNA synthesis. Our results contributed to the solving of the first part of so-called MCM paradox. Second, we studied the structural basis of the Polycomb bodies. Based on fluorescence microscopy studies, Polycomb bodies have been considered to be the nuclear subcompartments formed by the accumulation of Polycomb proteins in the interchromatin compartment. In our work, using correlative light electron microscopy and experimental changes in macromolecular crowding, we clearly showed that a Polycomb body is a chromosomal domain formed by an accumulation of heterochromatin structures, rather than a typical nucleoplasmic body. Third, we were interested in...
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Design and synthesis of inhibitors targeting methyllysine reader proteins belonging to the polycomb paralog familyMilosevich, Natalia 06 June 2019 (has links)
Methyl reader proteins recognize and bind to post-translationally methylated
residues and have functional roles in diverse cellular processes including gene regulation,
development and oncogenesis. The CBX polycomb paralog family of methyllysine
readers recognize trimethyllysine lysine residues on histone tail 3 and repress
transcription by compacting chromatin. The polycomb paralogs form multi-protein
complexes that silence the expression of tumour suppressor genes, and play important
roles in regulating cell cycle and differentiation. Each paralog is structurally similar, yet
has distinct functions, of which many are unknown.
My work has focused on the design and synthesis of CBX inhibitors and on the
development of new methodologies for the discovery of inhibitors targeting methyllysine
readers. In this work, I report on a series of potent peptidic inhibitors that selectively
target the CBX polycombs, as well as the first selective inhibitor for the family member
CBX6, and dual-active inhibitors that target CBX6/CBX8. The results demonstrate the
potential to achieve selectivity through interactions outside of the methyllysine binding
domain. Structural determinants in the binding pocket of each protein that differ within
the family and give rise to selectivity were discovered. I will also report on a series of
peptidomimetic CBX inhibitors that are active in cells. Cellular active inhibitors are
critical for understanding the biological role of each CBX protein and their potential as
therapeutic targets.
New high-throughput approaches are needed to efficiently target methyllysine
readers by chemical inhibition. I describe in this work a strategy for creating massive
libraries of phage-displayed peptidic inhibitors containing methyllysine mimics.
Synthetic optimization on cysteine-containing peptide phage constructs allowed for the
successful installation of Kme3 mimics. This is the first report of a post-translational
methylated peptide phage library. The methodology I developed can be used in a
synthetic chemistry-driven adaptation of traditional phage display for the screening of
millions of peptide-based compounds. Strategies that allow for diversity and high
throughput screening will aid in future efforts in targeting the highly similar CBX
proteins. / Graduate / 2021-06-01
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Strukturně-funkční organizace buněčného jádra.Mikroskopická analýza jaderných subkompartmentů. / Structure-function organization of the cell nucleus.Microscopical analysis of nuclear subcompartments.Jůda, Pavel January 2015 (has links)
Pavel Jůda - Abstract The cell nucleus is a complex cellular organelle. The nucleus and nuclear processes are organized into functionally and morphologically separated nuclear subcompartments. This thesis is particularly concerned with the three following nuclear subcompartments: sites of DNA replication, Polycomb bodies and nuclear inclusions constituted of inosine monophosphate dehydrogenase 2 (IMPDH2). First, we examined the relationship between MCM proteins and DNA replication. Using immunofluorescent labeling of cells extracted prior fixation and applying cross-correlation function analysis, we showed that MCM proteins are present at the sites of active DNA synthesis. Our results contributed to the solving of the first part of so-called MCM paradox. Second, we studied the structural basis of the Polycomb bodies. Based on fluorescence microscopy studies, Polycomb bodies have been considered to be the nuclear subcompartments formed by the accumulation of Polycomb proteins in the interchromatin compartment. In our work, using correlative light electron microscopy and experimental changes in macromolecular crowding, we clearly showed that a Polycomb body is a chromosomal domain formed by an accumulation of heterochromatin structures, rather than a typical nucleoplasmic body. Third, we were interested in...
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Vztah vyšších chromatinových struktur a genové umlčování / The relationship between higher order chromain structure and gene silencingŠmigová, Jana January 2012 (has links)
No description available.
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