Spelling suggestions: "subject:"demethylation""
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Development of biochemical tools to characterise human H3K27 histone demethylase JmjD3Che, Ka Hing January 2013 (has links)
Covalent modifications of histone tails play essential roles in mediating chromatin structure and epigenetic regulation. JmjD3 is a JumonjiC domain containing histone demethylase, belongs to the KDM6 subfamily, and catalyses the removal of methyl groups on methylated lysine 27 on histone 3 (H3K27), a critical mark to promote polycomb mediated repression and gene silencing. The importance of JmjD3 has been implicated in development, cancer biology and immunology. In this thesis, I report the recombinant production of active human JmjD3, development of two in vitro screening assays, a cell-based assay, and structural determination of JmjD3 in complex with the inhibitor 8-hydroxy-5-carboxyquinoline (8HQ). A highly selective and potent small molecule inhibitor GSK-J1 was subsequently identified. The inhibitor is active in HeLa cells and promotes a dose-dependent increase of global H3K27 methylation. The inhibitor GSK-J1 was used in two different cell assay systems related to inflammation and differentiation, to understand how H3K27 demethylation controls cellular functions. By inhibiting H3K27me3 demethylation, it is demonstrated that tumor necrosis factor (TNF) and other pro-inflammatory cytokines are regulated by H3K27 demethylase inhibition in M1- type macrophages derived from healthy volunteers and rheumatoid arthritis patients. It is also shown that inhibition of H3K27me3 demethylation abrogates cellular fusion of M2- type macrophages. During RANKL induced osteoclast differentiation, JmjD3 is up-regulated and promotes the expression of the key transcription factor NFATc1. By inhibiting JmjD3, NFATc1 expression is reduced and osteoclastogenesis is inhibited. This mechanism demonstrates a novel anti-resorptive principle of potential utility in conditions of excess bone resorption such as osteoporosis, bone erosion in inflammatory arthritis or cancer of the bone. These experiments further resolve the ambiguity between scaffold and catalytic function associ- ated with the H3K27 demethylase in these biological systems, and demonstrate that its enzymatic activity is crucial for epigenetic regulation of macrophage and osteoclast function.
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Biological and clinical relevance of epigenetic modifications in human breast cancersDedeurwaerder, Sarah 25 February 2011 (has links)
It is increasingly recognized by the scientific community that the field of epigenetics is a key step for a better understanding of human biology in both normal and pathological states. Its implication in cancer, and in particular in breast cancer, is now well accepted. Breast cancer, responsible for more than 450,000 deaths worldwide yearly, is a heterogenous disease at the histological and clinical levels as well as at the molecular level. Despite considerable efforts to develop new treatments and improve patient management, patients with a same “profile” of breast cancer can respond differently to therapies and have completely different clinical outcomes. There is therefore a critical need to improve our understanding of breast cancer biology and diversity, in order to find new markers that should provide a better management of patients and the development of new therapies. An increasing number of biologists, pathologists as well as clinicians are currently working towards these goals. During my PhD, we have conducted two studies in order to gain new insights into the contribution of epigenetics in breast cancer biology.<p>In the first study, by performing large genome-scale DNA methylation profiling of numerous breast tumors as well as of normal breast tissues, we first revealed the existence of six groups of breast tumors based on their DNA methylation profiles. Three of these groups showed a strong association with the basal-like, HER2 and luminal A breast cancer subtypes, previously identified by gene expression profiling. Interestingly, the three other groups were found to be a mixture of several gene expression-based subtypes, thus revealing the capacity of DNA methylation profiling to improve breast tumor taxonomy. Second, our study suggests that the establishment of DNA methylation patterns of breast tumors might help to determine their cell type of origin. Finally, we also showed that DNA methylation profiling can reflect the cell type composition of the tumor microenvironment and that a signature of T cell tumoral infiltration is associated with a good prognosis in particular categories of breast cancer patients. <p>In the second study, we revealed the clinical relevance of the KDM5 histone demethylases in breast cancer. The expression of these histone demethylases was deregulated in the analyzed breast tumors as well as in the pre-invasive samples as compared to normal breast samples. This suggests that KDM5 enzymes might be good markers for early diagnosis of breast cancer. Moreover, we showed a prognostic value of the KDM5C histone demethylase.<p>In conclusion, the above data should provide a better understanding of breast cancer biology and diversity, and this should bring new insights to improve breast cancer patient management.<p> / Doctorat en Sciences biomédicales et pharmaceutiques / info:eu-repo/semantics/nonPublished
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Identifying Novel In Vivo Epigenetic Dependencies in GlioblastomaMiller, Tyler Eugene 13 September 2016 (has links)
No description available.
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Identification and characterisation of epigenetic mechanisms in osteoblast differentiation of human mesenchymal stem cellsKramm, Anneke January 2014 (has links)
A major therapeutic challenge in musculoskeletal regenerative medicine is how to effectively replenish bone tissue lost due to pathological conditions such as fracture, osteoporosis, or rheumatoid arthritis. Mesenchymal stem cells are currently investigated for applications in bone-tissue engineering and human bone marrow-derived mesenchymal stem cells (hMSCs) could be a promising source for generation of tissue-engineered bone. However, the therapeutic potential of MSCs has not been fully exploited due to a lack of knowledge regarding the identity, nature, and differentiation of hMSCs. Epigenetic mechanisms regulating the chromatin structure as well as specific gene transcription are crucial in determination of stem cell differentiation. With the aim to systematically identify epigenetic factors that modulate MSC differentiation, the work in this thesis encompasses an approach to identify epigenetic mechanisms underlying, initiating, and promoting osteoblast differentiation, and the investigation of individual epigenetic modulators. Various osteogenic inducers were validated for differentiation of MSCs and an assay allowing assessment of differentiation outcome was developed. This assay was subsequently employed in knockdown experiments with lentiviral short hairpin RNAs and inhibitor screens with small molecules targeting putative druggable epigenetic modulator classes. This approach identified around 100 epigenetic modulator candidates involved in osteoblast differentiation, of these candidates approximately 2/3 downregulated and 1/3 upregulated alkaline phosphatase (ALP) activity. Serving as a proof-of-concept, orthogonal validation experiments employing locked nucleic acid (LNA) knockdown were performed to validate a subset of candidates. Two identified target genes were selected for further investigation. Bromodomain-containing protein 4 (BRD4) was identified as one component of epigenetic regulation; its inhibition led to a decrease in ALP expression, downregulation of key osteoblast transcription factors Runx2 and Osterix, as well as impaired bone matrix formation. Knockdown of lysine (K)-specific demethylase 1A (KDM1A/LSD1) upregulated ALP activity and treatment with a small molecule inhibitor targeting KDM1A led to an increase in ALP, RUNX2, and bone sialoprotein expression. Intriguingly, in a transgenic mouse model overexpressing Kdm1a a decrease in bone volume and bone mineral density was observed, thus supporting the hypothesis that KDM1A is a central regulator of osteoblast differentiation.
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Chemical and biological studies on human oxygenasesThinnes, Cyrille Christophe January 2014 (has links)
As depicted in Chapter I, 2-oxoglutarate- (2OG) dependent oxygenases are ubiquitous in living systems and display a wide range of cellular functions, spanning metabolism, transcription, and translation. Although functionally diverse, the 2OG oxygenases share a high degree of structural similarities between their catalytic sites. From a medicinal chemistry point of view, the combination of biological diversity and structural similarity presents a rather challenging task for the development of selective small molecules for functional studies in vivo. The non-selective metal chelator 8-hydroxyquinoline (8HQ) was used as a template for the generation of tool compound <b>I</b> for the KDM4 subfamily of histone demethylases via application of the Betti reaction. Structural analogue <b>II</b> was used as the corresponding negative control (Figure A). These compounds were characterised in vitro against a range of 2OG oxygenases and subsequently used for studies in cells. <b>I</b> displays selectivity for KDM4 and increases the level of the H3K9me3 histone mark in cells. It has an effect on the post-translational modification pattern of histone H3, but not other histones, and reduces the viability of lung cancer cells, but not normal lung cells, derived from the same patient. <b>I</b> also stabilises hypoxia-inducable factor HIF in cells via a mechanism which seems to be independent from prolyl hydroxylase inhibition. This work is described in Chapters II and III. The chemical biology research in epigenetics is complemented by qualitative analysis conducted in the social sciences at Said Business School. With a global view on how innovation occurs and may actively be fostered, Chapter IV focuses on the potential of epigenetics in drug discovery and how this process may actively be promoted within the framework of open innovation. Areas of focus include considerations of incremental and disruptive technology; how to claim, demarcate, and control the market; how knowledge brokering occurs; and insights about process, management, organisation, and culture of open innovation. In contrast to the open-skies approach adopted for the development of a tool compound in Chapters II and III, a focused-library approach was taken for the generation of a tool compound for the OGFOD1 ribosomal prolyl hydroxylase. The development of a suitable in vitro activity assay for OGFOD1 in Chapter V enabled the development of lead compound <b>III</b> in Chapter VI. <b>III</b> is selective for OGFOD1 against the structurally closely related prolyl hydroxylase PHD2.
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