Global ETD Search

181	Avaliação dos efeitos antineoplásicos da Zebularina em meduloblastoma / Evaluation of antineoplastic effects of Zebularine in medulloblastoma Andrade, Augusto Faria 07 April 2016 (has links) O meduloblastoma (MB) é um câncer do sistema nervoso central, de origem embrionária, que surge no cerebelo. É o tumor maligno cerebral mais frequente na infância e corresponde a aproximadamente 20% de todos os tumores intracranianos pediátricos. Atualmente, o tratamento é realizado com cirurgia, quimioterapia e radioterapia e está relacionado com diversos efeitos colaterais em médio e longo prazo. Diversos fatores contribuem para o seu desenvolvimento e progressão, entre estes, alterações nas vias de sinalização, como a Sonic Hedgehog (SHH) e Wingless. As modificações nos padrões epigenéticos, como a metilação do DNA, tem também um papel central na biologia deste tumor. Tais alterações comprometem funções básicas da célula como o controle da proliferação, sobrevivência celular e apoptose. Drogas epigenéticas como os inibidores de DNA metiltransferases (DNMTs) têm demonstrado efeitos antineoplásicos e resultados promissores para terapia do câncer. A Zebularina é um inibidor de DNMTs, que consequentemente reduz a metilação do DNA, e tem se mostrado uma importante droga antitumoral, com baixa toxicidade e atividade adjuvante à quimioterapia em tumores quimio-resistentes. Diversos estudos têm descrito seus efeitos em diferentes tipos de neoplasias, entretanto, não há relatos da sua ação em MB. Sendo assim, o presente trabalho teve como objetivo analisar os potenciais efeitos antineoplásicos da Zebularina em quatro linhagens de MB pediátrico (DAOY, ONS-76, UW402 e UW473). Foi observado que o tratamento com a Zebularina promoveu inibição da proliferação celular e da capacidade clonogênica, aumentou o número de células apoptóticas e células na fase S do ciclo celular (p<0,05). Adicionalmente, o tratamento induziu um aumento na expressão proteica de p53, p21 e Bax e uma diminuição da ciclina A, Bcl-2 e Survivina. Além disso, quando combinada com o quimioterápico vincristina agiu de modo sinérgico; e de modo antagônico quando combinada com a cisplatina. Através de análises de expressão gênica em larga escala (plataforma Agilent de microarray), foi encontrada diferentes vias moduladas pela droga, incluindo a dos Receptores Toll-Like e o aumento dos genes SUFU e BATF2. Aqui, foi encontrado que a Zebularina pode modular a ativação da via SHH, reduzindo os níveis de SMO, de GLI1 e de um de seus alvos, o PTCH1; contudo sem alterar os níveis de SUFU. Confirmou-se que o gene BATF2 é induzido pela Zebularina e possui regiões ricamente metiladas. Além disso, a baixa expressão do gene BATF2 está associada à um pior prognóstico em MB. Todos esses dados sugerem que a Zebularina pode ser uma droga em potencial para o tratamento adjuvante do MB / Medulloblastoma (MB) is an embryonal cerebellum tumor. It is the most common brain malignancy in children and accounts for approximately 20% of all pediatric intracranial tumors. Currently, treatment consists of surgery, chemotherapy and radiation and is associated to medium- and long-term side effects. Several factors contribute to the development and progression of MB, for instance, alterations in signaling pathways, such as Sonic Hedgehog (SHH) and Wingless. Epigenetic changes in DNA methylation patterns also play a central role in the biology of this tumor. Such changes are able to alter basic cell functions, controlling cell proliferation, survival and apoptosis. Epigenetic drugs as DNA methyltransferases (DNMTs) inhibitors have shown anticancer effects and promising results for cancer therapy. Zebularine is a low toxicity DNMTs inhibitor that induces DNA demethylation and has been reported as an important antitumor drug with adjuvant activity to chemotherapy in chemoresistant tumors. Studies have described its effects on different types of cancer, however, there are not data concerning its action in MB. Therefore, this study aimed to analyze the potential anticancer effects of Zebularine in four pediatric MB lines (UW402, UW473, ONS- 76 and DAOY). It was observed that treatment with Zebularine promoted inhibition of cell proliferation and clonogenic capacity, increased the number of apoptosis rate and cells in S phase of the cycle (p <0.05). In addition, the treatment induced an increasing in the protein expression of p53, p21 and Bax and a decreasing in cyclin A, Survivin and Bcl-2. Also, when combined with the chemotherapeutic agent vincristine acted synergistically but resulted in antagonism when combined with cisplatin. Through large-scale gene expression analysis (Agilent microarray platform), it was found different pathways modulated by Zebularine, including the Toll-Like Receptors pathway and the overexpression of SUFU and BATF2 genes. Zebularine was able to modulate SHH pathway activation, by reducing levels of SMO, GLI1 and one of its targets, PTCH1, whereas there were no changes in SUFU levels. It was confirmed that the gene BATF2 is induced by Zebularine and contains regions richly methylated. In addition, BATF2 low expression is associated with a worse prognosis in MB. All these data suggest that Zebularine may be a potential drug for the adjuvant treatment of MB DNA methyltransferases DNA metiltransferases Epigenética Epigenetics Medulloblastoma Meduloblastoma Zebularina Zebularine
182	Systematically Mapping the Epigenetic Context Dependence of Transcription Factor Binding Kribelbauer, Judith Franziska January 2018 (has links) At the core of gene regulatory networks are transcription factors (TFs) that recognize specific DNA sequences and target distinct gene sets. Characterizing the DNA binding specificity of all TFs is a prerequisite for understanding global gene regulatory logic, which in recent years has resulted in the development of high-throughput methods that probe TF specificity in vitro and are now routinely used to inform or interpret in vivo studies. Despite the broad success of such methods, several challenges remain, two of which are addressed in this thesis. Genomic DNA can harbor different epigenetic marks that have the potential to alter TF binding, the most prominent being CpG methylation. Given the vast number of modified CpGs in the human genome and an increasing body of literature suggesting a link between epigenetic changes and genome instability, or the onset of disease such as cancer, methods that can characterize the sensitivity of TFs to DNA methylation are needed to mechanistically interpret its impact on gene expression. We developed a high-throughput in vitro method (EpiSELEX-seq) that probes TF binding to unmodified and modified DNA sequences in competition, resulting in high-resolution maps of TF binding preferences. We found that methylation sensitivity can vary between TFs of the the same structural family and is dependent on the position of the 5mCpG within the TF binding site. The importance of our in vitro profiling of methylation sensitivity is demonstrated by the preference of human p53 tetramers for 5mCpGs within its binding site core. This previously unknown, stabilizing effect is also detectable in p53 ChIP-seq data when comparing methylated and unmethylated sites genome-wide. A second impediment to predicting TF binding is our limited understanding of i) how cooperative participation of a TF in different complexes can alter their binding preference, and ii) how the detailed shape of DNA aids in creating a substrate for adaptive multi-TF binding. To address these questions in detail, we studied the in vitro binding preferences of three D. melanogaster homeodomain TFs: Homothorax (Hth), Extradenticle(Exd) and one of the eight Hox proteins. In vivo, Hth occurs in two splice forms: with (HthFL) and without (HthHM) the DNA binding domain (DBD). HthHM-Exd itself is a Hox cofactor that has been shown to induce latent sequence specificity upon complex formation with Hox proteins. There are three possible complexes that can be formed, all potentially having specific target genes: HthHM-Exd-Hox, HthFL-Exd-Hox, and HthFL-Exd. We characterized the in vitro binding preferences of each of these by developing new computational approaches to analyze high-throughput SELEX-seq data. We found distinct orientation and spacing preference for HthFL-Exd-Hox, alternative recognition modes that depend on the affinity class a sequence falls into, and a strong preference for a narrow DNA minor grove near Exd's N-terminal DBD. Strikingly, this shape readout is crucial to stabilize the HthHM-Exd-Hox complex in the absence of a Hth DBD and can thus be used to distinguish HthHM from HthFL isoform binding. Mutating the amino acids responsible for the shape readout by Exd and reinserting the engineered protein into the fly genome allowed us to classify in vivo binding sites based on ChIP-seq signal comparison between “shape-mutant” and wild-type Exd. In summary, the research presented here has investigated TF binding preferences beyond sequence context by combining novel high-throughput experimental and computational methods. This interdisciplinary approach has enabled us to study binding preferences of TF complexes with respect to the epigenetic landscape of their cognate binding sites. Our novel mechanistic insights into DNA shape readout have provided a new avenue of exploiting guided protein engineering to probe how specific TFs interact with their co-factors in a cellular context, and how flanking genomic sequence helps determine which multi-TF complexes will form and which binding mode a complex adopts. Biochemistry Bioinformatics Biophysics Transcription factors Gene regulatory networks Epigenetics
183	Combinação de moduladores epigenéticos com ativação de receptor retinoide em neuroblastoma : efeitos sobre proliferação e diferenciação celular Almeida, Viviane Rösner January 2016 (has links) Neuroblastoma (NB) é a forma mais indiferenciada de tumores neuroblásticos e a principal causa de morte por câncer pediátrico. Alterações epigenéticas interagem em todas as etapas do desenvolvimento do câncer, promovendo a progressão tumoral. A remodelação da cromatina é influenciada pela acetilação de histonas e a metilação de DNA. Acetiltransferases de histona (HATs), desacetilases de histonas (HDAC) e metiltransferase de DNA (DNMTs) são alvos de estratégias terapêuticas em tumores. Os retinoides agem nas vias de diferenciação celular, anti-proliferação e pró-apoptose. Nesse trabalho, é proposto que a combinação desses moduladores epigenéticos e de diferenciação em linhagens de células de NB humano é mais efetiva que os agentes isolados. Os tratamentos induziram mudanças na expressão de marcadores de diferenciação e indiferenciação, como c-Myc, β-3tubulina, NeuN e Bmi1, e alterações morfológicas nas duas linhagens celulares utilizadas, SK-N-BE(2) e SH-SY5Y. Os dados encontrados podem contribuir para uma melhor compreensão dos mecanismos moleculares dos moduladores retinoides e epigenéticos em NB capazes de acrescentar melhorias nas atuais estratégias terapêuticas. / Neuroblastoma (NB) is the most undifferentiated form of neuroblastic tumors and the leading cause of death from pediatric cancer. Epigenetic changes interact at all stages of cancer development, promoting tumor progression. Chromatin remodeling is influenced by histone acetylation and DNA methylation. Histone acetyltransferases (HATs), histone deacetylases (HDAC), and DNA methyltransferase (DNMTs) are targets for therapeutic strategies in cancer. Retinoids act on cell differentiation pathways and display anti-proliferation and pro-apoptotic actions. In the present research we examined the effects of combining epigenetic modulators and a retinoid receptor agonist in human NB cells. The retinoid all trans-retinoic acid (ATRA) combined with inhibitors of either histone deacetylases (HDACs) or DNA methyltransferase was more effective than any drug given alone in impairing the proliferation of SH-SY5Y and SK-N-BE(2) NB cells. In addition, the treatments induced differential changes in the expression of differentiation markers including c-Myc, β-3tubulin, NeuN and Bmi1, and morphological changes in SK-N-BE(2) e SH-SY5Y cell lines. The data contribute to a better understanding of the molecular mechanisms of retinoid modulators and epigenetic in NB able to add improvements in current therapeutic strategies. Diferenciação celular Neuroblastoma Cancer infantil Neuroblastoma Epigenetics Retinoids Cell differentiation
184	DNA Repair Capacity as a Marker of Breast Cancer Susceptibility Kappil, Maya January 2014 (has links) Introduction: The wide-ranging prognostic implications of a breast cancer diagnosis highlight the need to better enable women to make informed decisions regarding screening and treatment options. As several cancer susceptibility syndromes have been linked to germline mutations resulting in defective DNA repair, including the predisposition to breast cancer due to BRCA1 and BRCA2 mutations, more subtle defects in DNA repair capacity may contribute to the components driving differential susceptibility within the general population. Hence, understanding the role of DNA repair capacity in breast cancer onset may aid in the development of a more comprehensive risk profile, thereby furthering the effort to target relevant populations for early screening. In the studies undertaken for this dissertation, we employed various methodologies capturing endpoints across different repair pathways detectable in blood to both further elucidate the etiologic basis of breast cancer development and leverage the information into the potential development of a screening biomarker. Methods: For the phenotypic assessment of nucleotide excision repair (NER) capacity, we developed an ELISA-based method to determine benzo(a)pyrene diolepoxide (BPDE)-DNA adduct capacity in lymphoblastoid cell lines. Gene expression levels were assessed with pre-designed Taqman kits in RNA-derived cDNAs from mononuclear cells using a real-time PCR-based platform. Methylation analysis was conducted with in-house designed assays on bisulfite-converted DNA from mononuclear cells using a pyrosequencing platform. Finally, single nucleotide polymorphisms (SNP) genotyping was assessed in DNA derived from white blood cells with pre-designed Taqman SNP genotyping assays using a real-time PCR-based platform. All studies were conducted in sister-sets enrolled in the New York site within the Breast Cancer Family Registry and all statistical analysis was conducted using the R Foundation for Statistical Computing (2011). Results: We did not detect an association between the ELISA-based phenotypic assessment of NER capacity in the lymphoblastoid cells lines of the sister-sets (n=246, 114 sister-sets) and breast cancer risk (OR = 1.0, 95%CI=0.95, 1.04). Furthermore, we did not observe a correlation with previously determined NER capacity in the same population using an immunohistochemical-based method (r= -0.01, p=0.86). In our gene expression study (n=569, 218 sister-sets), women in the lowest tertile of ATM expression had a heightened risk of breast cancer compared to women in the highest tertile of expression, adjusted for age at blood draw and smoking status (OR=2.12, 95%CI=1.09, 4.12). This association was largely restricted to women with an extended family history of breast cancer (pinteraction = 0.06). Additionally, women in the lowest tertile of MSH2 expression also had a heightened risk of breast cancer compared to women in the highest tertile of expression, adjusted for age at blood draw and smoking status (OR=2.75, 95%CI=1.31, 5.79). The association observed between reductions in ATM expression level and breast cancer risk was lost upon incorporating previously determined end-joining capacity of EcoRI-generated sticky end substrates (OR=1.28, 95%CI=0.15, 11.2) and HincII-generated blunt end substrates (OR=1.55, 95%CI=0.15, 15.5) into the model, suggesting that the impact on risk due to reductions in ATM expression maybe partially driven by the reduction in double strand break repair capacity. In our study investigating breast cancer risk due to the impact of epigenetic modulation on DNA repair gene activity (n=569, 218 sister-sets), no association with risk was observed due to differential promoter methylation levels of BRCA1 (OR=1.09, 95%CI=0.98, 1.20), MLH1 (OR=1.19, 95%CI=0.91, 1.55) or MSH2 (OR=0.89, 95%CI=0.48, 1.64). Furthermore, no correlation between BRCA1 and expression (r=-0.05, p=0.39) or MSH2 methylation and expression (r=-0.04, p=0.39) was observed. Finally, our mismatch repair genotyping study (n=714, 313 sister-sets) indicated an association between the variant MutY_rs3219489 (OR=2.23, 95%CI=1.10, 4.52) and breast cancer risk, as well as a borderline association with risk due to the variant MSH2_rs2303428 (OR=1.71, 95%CI=0.99, 2.95). Furthermore, a protective effect was observed due to the variant MLH3_rs175080, restricted to women without an extended family history of breast cancer (pinteraction = 0.03). Conclusion: These studies suggest that the deregulation of targets spanning various DNA repair pathways contribute to the risk of familial breast cancer. Molecular biology Epigenetics Breast--Cancer--Etiology DNA repair Gene expression
185	Mechanisms of transcriptomic and epigenetic responses to industrial pollutants in fish Laing, Lauren Victoria January 2017 (has links) Thousands of chemical pollutants enter the environment continuously, each with the potential to cause adverse effects in both terrestrial and aquatic organisms. As a result, organisms are often exposed to a mixture of stressors within their habitat. Populations of fish inhabiting most aquatic environments are exposed to time-varying or repeated pulses of exposure, driven by run-off events or spills, or due to their mobility between polluted and clean waters. Therefore, the sustainability of fish populations is critically dependent on their ability to adapt to frequent changes in their local environment. Despite this, legislation to protect the environment from chemical contamination are generally based on toxicological measurements following exposures to single stressors, conducted under optimal laboratory conditions, and that do not take into account the variation in susceptibility of wild populations, or the potential consequences of exposure for the susceptibility of the population during future exposures, including across generations. Increasing evidence is suggesting that a number of chemicals may interact with the epigenome, and that differential responses to pollutants may be modulated, at least in part, via epigenetic mechanisms. However, our understanding of the role of epigenetic mechanisms in normal development in fish models or its susceptibility to exposure to environmental stressors is currently very limited. This thesis aimed to document the mechanisms of genetic and epigenetic responses to industrial pollutants in fish, and to explore the extent to which differential responses can be induced in the lab following exposure during the critical window of embryonic development or in adults. To address these objectives, I performed a series of experiments using both the zebrafish (Danio rerio) and the three-spined stickleback (Gasterosteus aculeatus) as fish models. I first used the zebrafish (Danio rerio) model to investigate the sex-specific transcription and DNA methylation profiles for genes involved in the regulation of reproduction and in epigenetic signalling in the livers and gonads. I provide evidence of the sex-specific transcription of genes involved in reproduction and their regulation by epigenetic signalling in this commonly used vertebrate model and highlight important considerations regarding the use of whole tissues comprised of multiple cell types in epigenetic and transcriptomic studies. I then investigated the potential for exposure to Bisphenol A (BPA) to cause adverse effects on reproduction and to disrupt the expression profiles and promotor DNA methylation of target genes important for reproductive function and epigenetic signalling in the zebrafish. To do this, I exposed breeding zebrafish to a range of BPA concentrations over 15 days and found that BPA disrupted reproductive processes in zebrafish, likely via estrogenic mechanisms, but only at high concentrations. Importantly, exposure to environmentally relevant concentrations of BPA resulted in altered transcription of key enzymes involved in DNA methylation maintenance, and caused changes in promoter DNA methylation. I also conducted a series of repeated exposures to copper in the three-spined stickleback to investigate the extent to which differential susceptibility can be induced in the lab. This work provides evidence that pre-exposure to copper results in differential responses in future exposure scenarios both when the initial exposure occurred in adults and during embryogenesis. For adults, fish appeared to recover completely from the initial exposure following a period of depuration of 30 days, but displayed decreased susceptibility upon re-exposure. In contrast, for fish exposed during the critical windows of embryonic development when epigenetic reprogramming are hypothesised to occur, differential copper accumulation was maintained throughout life. Importantly, the initial exposure caused increased tolerance in the offspring, which was inherited up to the F2 generation. This work provides valuable information regarding potential critical windows of development which may be more susceptible to effects associated with pre-exposure, highlighting that early life exposure to a low concentration of copper can induce differential responses to copper across generations. These data highlight the extent of differential responses to chemical stressors likely to be present in wild populations, and point towards the possibility that effective population management will likely require an in-depth understanding of the exposure history of a given population in order to manage restocking initiatives, and to inform conclusions drawn from toxicity testing studies conducted using individuals originating from wild populations. In addition, these data suggest that it is likely that both epigenetic and genetic changes can contribute to the adaptation of individual populations to their local environment. Finally, other vertebrates including humans have been shown to be exposed to the chemicals tested in this thesis. Therefore, this highlights the potential for these chemicals to also cause toxic effects in humans, potentially via (epi) genetic mechanisms, and advocate the testing of the potential for inheritable phenotypes, such as those described in this thesis, to occur in mammalian models. 571.9
186	Epigenetic Regulation of Muscle Stem and Progenitor Cells Addicks, Gregory Charles January 2018 (has links) Epigenetic mechanisms are of fundamental importance for resolving and maintaining cellular identity. The mechanisms regulating muscle stem and progenitor cell identity have ramifications for understanding all aspects of myogenesis. The epigenetic mechanisms regulating muscle stem cells are therefore important aspects for understanding the regulation of muscle regeneration and maintenance. Important roles for the trithorax H3K4 histone methyltransferase (HMT) MLL1 have been established for early embryogenesis, and for hematopoietic and neural identity. Here, using a conditional Mll1 knockout (KO), we find that in vivo, MLL1 is necessary for efficient muscle regeneration, and for maintenance and proliferation of muscle stem and progenitor cells. Loss of Mll1 in cultured myoblasts reveals an essential role for expression of the myogenic specification gene Pax7. Mll1 KO results in a minor decrease in Pax7 mRNA and a strong decrease of Pax7 protein. While MLL1 was found to bind the Pax7 promoter, Mll1 KO results in a minor decrease of H3K4me3 at Pax7, supporting a recognized non-HMT role for Mll1 at Pax7. Microarray analysis of mRNA expression in Mll1 KO myoblasts finds that Myf5 is the most strongly downregulated of all genes, unexpectedly, mRNA expression of previously identified MLL1 targets are unaffected by loss of MLL1 in myoblasts. Pax7 activates Myf5 expression through recruitment of a H3K4 HMT, and in Mll1 KO myoblasts expression of, and H3K4me3 at Myf5 is lost. Exogenous Pax7 rescues Myf5 expression and H3K4me3 at Myf5 in the absence of MLL1, indicating that Myf5 expression is conditional on Pax7, but not MLL1. We also show that Myf5 DNA is methylated in non-myogenic cells, and in satellite stem cells that have never expressed Myf5, but is not methylated in satellite cells that are committed to the myogenic lineage, indicating that demethylation of Myf5 may be a fundamental step in myogenic commitment. Intriguingly, Myf5 promoter DNA becomes remethylated in Mll1 KO myoblasts. This work finds that Pax7 expression and myogenic identity is partly dependent on MLL1 expression. Further, evidence is uncovered that myogenic commitment is initiated by demethylation of Myf5. These findings add to the understanding of the epigenetic mechanisms that regulate and define muscle stem cells. Muscle Epigenetics Stem Cells Regeneration MLL1 DNA methylation Pax7 Myf5
187	Engineering and Delivery of Synthetic Chromatin Effectors January 2019 (has links) abstract: Synthetic manipulation of chromatin dynamics has applications for medicine, agriculture, and biotechnology. However, progress in this area requires the identification of design rules for engineering chromatin systems. In this thesis, I discuss research that has elucidated the intrinsic properties of histone binding proteins (HBP), and apply this knowledge to engineer novel chromatin binding effectors. Results from the experiments described herein demonstrate that the histone binding domain from chromobox protein homolog 8 (CBX8) is portable and can be customized to alter its endogenous function. First, I developed an assay to identify engineered fusion proteins that bind histone post translational modifications (PTMs) in vitro and regulate genes near the same histone PTMs in living cells. This assay will be useful for assaying the function of synthetic histone PTM-binding actuators and probes. Next, I investigated the activity of a novel, dual histone PTM binding domain regulator called Pc2TF. I characterized Pc2TF in vitro and in cells and show it has enhanced binding and transcriptional activation compared to a single binding domain fusion called Polycomb Transcription Factor (PcTF). These results indicate that valency can be used to tune the activity of synthetic histone-binding transcriptional regulators. Then, I report the delivery of PcTF fused to a cell penetrating peptide (CPP) TAT, called CP-PcTF. I treated 2D U-2 OS bone cancer cells with CP-PcTF, followed by RNA sequencing to identify genes regulated by CP-PcTF. I also showed that 3D spheroids treated with CP-PcTF show delayed growth. This preliminary work demonstrated that an epigenetic effector fused to a CPP can enable entry and regulation of genes in U-2 OS cells through DNA independent interactions. Finally, I described and validated a new screening method that combines the versatility of in vitro transcription and translation (IVTT) expressed protein coupled with the histone tail microarrays. Using Pc2TF as an example, I demonstrated that this assay is capable of determining binding and specificity of a synthetic HBP. I conclude by outlining future work toward engineering HBPs using techniques such as directed evolution and rational design. In conclusion, this work outlines a foundation to engineer and deliver synthetic chromatin effectors. / Dissertation/Thesis / Doctoral Dissertation Biological Design 2019 Bioengineering Chromatin Engineering Epigenetics PcTF Protein Engineering Synthetic Biology
188	Genome-wide DNA methylation investigation of stress: from a mouse model of chronic stress to humans exposed to glucocorticoids Braun, Patricia Rose 01 August 2018 (has links) Stress contributes to the development of major depressive disorder (MDD) and post-traumatic stress disorder (PTSD), and an intermediary factor between stress and psychiatric disorders may be epigenetics. Studies have shown altered DNA methylation (DNAm) in animal models of and humans with stress exposure and in individuals with PTSD and MDD. The availability of genome-wide experimental platforms has given us new tools to investigate DNAm, and in this dissertation these techniques have been used to further our current understanding of the epigenetics of stress. We performed a genome-wide investigation in mice exposed to chronic stress that exhibit depressive- and anxious-like behaviors, examining DNAm changes within the dentate gyrus, a sub-region of the hippocampus that contributes to the stress response. Using the Methyl-Seq method, an intergenic region of chromosome X was shown to be differentially methylated with chronic stress, and this finding replicated in two additional cohorts of mice. In postmortem brain tissue of humans with MDD, an increase in DNAm within this intergenic region was also found. Animal models do not fully capture the complexity of stress and psychiatric disorders in humans, but comparable studies in humans are limited by the difficulty of obtaining brain tissues. Instead, these studies have used peripheral tissues to examine DNAm changes related to stress and psychiatric disorders. To address the usefulness of these peripheral tissues, we employed the Illumina 450K and EPIC arrays to establish a resource that compares DNAm of the brain to that of blood, buccal, and saliva tissues. Glucocorticoids (GCs) play an essential role in the stress response, and their dysregulation is seen in individuals with MDD and PTSD. To determine the role of GCs in stress-mediated epigenetic changes, buccal samples were obtained before and after individuals were given GCs in the context of oral surgery, and DNAm was analyzed using the Illumina EPIC array. Five CpGs were altered following this exposure, to a genome-wide significant degree. Further analysis revealed FDR-significant CpG changes to be in genes involved in steroid hormone biosynthesis and in genes differentially expressed with GC exposure. Collectively, these results exemplify the complexity of DNAm changes associated with the stress response and provide potential avenues for elucidating their impact on psychiatric disorders. DNA methylation Epigenetics Genome-wide Glucocorticoids Stress Genetics
189	The effect of valproic acid on histone acetylation in FaDu-luc head and neck squamous cell carcinoma cells Pourian, Ali 01 July 2011 (has links) No description available. Epigenetics Head and Neck Cancer Valproic Acid Other Dentistry
190	Expression and function of Suppressor of zeste 12 in Drosophila melanogaster Chen, Sa January 2009 (has links) The development of animals and plants needs a higher order of regulation of gene expression to maintain proper cell state. The mechanisms that control what, when and where a gene should (or should not) be expressed are essential for correct organism development. The Polycomb group (PcG) is a family of genes responsible for maintaining gene silencing and Suppressor of zeste 12 (Su(z)12) is one of the core components in the PcG. The gene is highly conserved in organisms ranging from plants to humans, however, the specific function is not well known. The main tasks of this thesis was to investigate the function of Su(z)12 and its expression at different stages of Drosophila development. In polytene chromosomes of larval salivary glands, Su(z)12 binds to about 90 specific euchromatic sites. The binding along the chromosome arms is mostly in interbands, which are the most DNA de-condensed regions. The binding sites of Su(z)12 in polytene chromosomes correlate precisely with those of the Enhancer-of-zeste (E(z)) protein, indicating that Su(z)12 mainly exists within the Polycomb Repressive Complex 2 (PRC2). However, the binding pattern does not overlap well with Histone 3 lysine 27 tri-methylations (H3K27me3), the specific chromatin mark created by PRC2. The Su(z)12 binding to chromatin is dynamically regulated during mitotic and meiotic cell division. The two different Su(z)12 isoforms: Su(z)12-A and Su(z)12-B (resulting from alternative RNA splicing), have very different expression patterns during development. Functional analyses indicate that they also have different functions he Su(z)12-B form is the main mediator of silencing. Furthermore, a neuron specific localization pattern in larval brain and a giant larval phenotype in transgenic lines reveal a potential function of Su(z)12-A in neuron development. In some aspects the isoforms seem to be able to substitute for each other. The histone methyltransferase activity of PRC2 is due to the E(z) protein. However, Su(z)12 is also necessary for H3K27me3 methylation in vivo, and it is thus a core component of PRC2. Clonal over-expression of Su(z)12 in imaginal wing discs results in an increased H3K27me3 activity, indicating that Su(z)12 is a limiting factor for silencing. When PcG function is lost, target genes normally become de-repressed. The segment polarity gene engrailed, encoding a transcription factor, is a target for PRC2 silencing. However, we found that it was not activated when PRC2 function was deleted. We show that the Ultrabithorax protein, encoded by another PcG target gene, also acts as an inhibitor of engrailed and that de-regulation of this gene causes a continued repression of engrailed. The conclusion is that a gene can have several negative regulators working in parallel and that secondary effects have to be taken into consideration, when analyzing effects of mutants. PcG silencing affects very many cellular processes and a large quantity of knowledge is gathered on the overall mechanisms of PcG regulation. However, little is known about how individual genes are silenced and how cells “remember” their fate through cell generations. Epigenetics histone polycomb Drosophila Suppressor of zeste 12 Genetics Genetik

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