Global ETD Search

31	Three-dimensional Folding of Eukaryotic Genomes Hsieh, Tsung-Han S. 15 May 2017 (has links) Chromatin packages eukaryotic genomes via a hierarchical series of folding steps, encrypting multiple layers of epigenetic information, which are capable of regulating nuclear transactions in response to complex signals in environment. Besides the 1-dimensinal chromatin landscape such as nucleosome positioning and histone modifications, little is known about the secondary chromatin structures and their functional consequences related to transcriptional regulation and DNA replication. The family of chromosomal conformation capture (3C) assays has revolutionized our understanding of large-scale chromosome folding with the ability to measure relative interaction probability between genomic loci in vivo. However, the suboptimal resolution of the typical 3C techniques leaves the levels of nucleosome interactions or 30 nm structures inaccessible, and also restricts their applicability to study gene level of chromatin folding in small genome organisms such as yeasts, worm, and plants. To uncover the “blind spot” of chromatin organization, I developed an innovative method called Micro-C and an improved protocol, Micro-C XL, which enable to map chromatin structures at all range of scale from single nucleosome to the entire genome. Several fine-scale aspects of chromatin folding in budding and fission yeasts have been identified by Micro-C, including histone tail-mediated tri-/tetra-nucleosome stackings, gene crumples/globules, and chromosomally-interacting domains (CIDs). CIDs are spatially demarcated by the boundaries, which are colocalized with the promoters of actively transcribed genes and histone marks for active transcription or turnover. The levels of chromatin compaction are regulated via transcription-dependent or transcription-independent manner – either the perturbations of transcription or the mutations of chromatin regulators strongly affect the global chromatin folding. Taken together, Micro-C further reveals chromatin folding behaviors below the sub-kilobase scale and opens an avenue to study chromatin organization in many biological systems. Chromatin Nucleosome 3D genome Histone modifications Biotechnology Genetics Genomics Molecular Biology
32	Identification Of Histone Demthylases In Budding Yeast And DNA Binding Motifs Of Human Demethylase RBP2 Tu, Shengjiang 20 August 2008 (has links) No description available. Biochemistry epigenetics histone modifications histone demethylases NMR structure RBP2 Rph1 Jhd2 Jhd1 Gis1 Ecm5
33	Epigenetic regulation of osteoblast differentiation Najafova, Zeynab 09 August 2016 (has links) No description available. 570 Bone remodeling Enhancers Epigenetic Transcription factors H2B monoubiquitination Histone modifications Bone remodeling BRD4 Osteoblast Biologie (PPN619462639)
34	Sierra platinum Müller, Lydia, Gerighausen, Daniel, Farman, Mariam, Zeckzer, Dirk 19 December 2016 (has links) (PDF) Background: Histone modifications play an important role in gene regulation. Their genomic locations are of great interest. Usually, the location is measured by ChIP-seq and analyzed with a peak-caller. Replicated ChIP-seq experiments become more and more available. However, their analysis is based on single-experiment peak-calling or on tools like PePr which allows peak-calling of replicates but whose underlying model might not be suitable for the conditions under which the experiments are performed. Results: We propose a new peak-caller called \"Sierra Platinum\" that allows peak-calling of replicated ChIP-seq experiments. Moreover, it provides a variety of quality measures together with integrated visualizations supporting the assessment of the replicates and the resulting peaks, as well as steering the peak-calling process. Conclusion: We show that Sierra Platinum outperforms currently available methods using a newly generated benchmark data set and using real data from the NIH Roadmap Epigenomics Project. It is robust against noisy replicates. ChIP-Seq Histonmodifikation Replikation ChIP-seq peak-caller histone modifications replicate analysis ddc:530 ddc:004
35	Modulação do trofoblasto bovino na gestação de embriões clonados / Modulation of bovine trophoblast in cloned pregnancy Barreto, Rodrigo da Silva Nunes 24 August 2015 (has links) O sucesso da gestação, e nascimento da prole saudável, depende da adequada formação, desenvolvimento e funcionamento da placenta. Entretanto, são observadas altas perdas durante o primeiro terço da gestação de embriões bovinos produzidos por transferência de núcleo de célula somática (TNCS), principalmente causadas por alterações placentárias, decorrentes da incompleta reprogramação epigenética no desenvolvimento embrionário. Normalmente, após a fecundação, o DNA paterno é desmetilado durante as primeiras horas do desenvolvimento, enquanto o DNA materno é desmetilado de forma passiva. Entretanto nos embriões TNCS a desmetilação do DNA é tardia e incompleta, resultando numa alteração do padrão epigenético, principalmente nos níveis de metilação (5mC) e hidroximetilação (5hmC) do DNA e nas histonas. Além disso, na gestação TNCS há expressão precoce das moléculas do complexo de histocompatibilidade principal de classe I (MHC-I), associada ao aumento de infiltrados inflamatórios na placenta e à rejeição imunológica ao feto. O objetivo desse trabalho foi de verificar, na placenta bovina TNCS e controle, os níveis globais de 5mC e 5hmC, e de algumas modificações de histonas importantes na formação do trofectoderma ou por serem modificações clássicas, além de imunolocalizar moléculas de MHC-I. Para tanto foram utilizadas amostras de placentônio TNCS no primeiro (n = 5) e terceiro (n = 6) terço gestacional; e como controle, placentônios com controle no primeiro (n = 6) e terceiro (n = 6). Foram realizadas reações de imunohistoquímica para modificações no DNA (5mC, 5hmC) e nas histonas (H3K4me3, H3K27me3, H3K9ac, H3K9me2/3) e para MHC-I (Qa-2 e IL-A88); além de reações de PCR quantitativo para enzimas responsáveis pelas modificações no DNA (DNMT1, TET1, TET3), para alguns genes relacionados com o desenvolvimento da placenta (PAG9, PHDLA2, SNRPN e TSSC4) e para isoformas de MHC-I (NC1-4 e JSP-1). Houve aumento dos níveis globais de metilação, e diminuição de hidroximetilação, na placenta TNCS durante o primeiro trimestre gestacional. Os níveis de H3K4me3 foram estáveis na placenta controle e crescentes na placenta TNCS, enquanto que a H3K27me3 decresceu na placenta controle e foi estável na placenta TNCS. Na placenta TNCS, aos 60 dias, foram observados os menores níveis globais H3K9ac, porém H3K9me2/3 não diferiram entre as idades e tipos gestacionais estudados. Foi identificado MHC-I no trofoblasto do placentônio bovino nas idades analisadas, com variações de intensidade dependendo da isoforma detectada, além de que a placenta controle e a TNCS apresentam padrões diferentes na expressão de MHC-I. De modo geral, o menores níveis de metilação do DNA encontrados na placenta TNCS aos 60 dias de gestação, indica ser um mecanismo compensatório para ativar a expressão gênica. Visto que a as modificações de histona levam a um estado repressivo da expressão gênica, já que a bivalência entre H3K4me3 e H3K27me3 e os níveis de H3K9ac estão diminuídos. Ainda na placenta TNCS aos 60 dias, há uma alta expressão de MHC-I, levando a resposta imune do sistema materno contra os tecidos fetais. Portanto vários eventos são presentes e parecem contribuir para instabilidade da gestação inicial em clones, coincidindo com a alta taxa de perdas gestacionais nessa fase / Pregnancy success depends of adequate placental formation, development and function. Therefore, the highest loses rates are found during first trimester pregnancies of bovine embryos produced by somatic cell nuclear transfer (NT), majorly by placental alterations, due to incomplete epigenetic reprogramming during embrionary development. Normally, after fecundation, paternal DNA is actively demethylated at first hours of development; where as maternal DNA is passively demethylated. However in NT embryos the DNA demethylation is late and incomplete, resulting in changes of epigenetic patterns, majorly in methylation (5mC), hydroxymethylation (5hmC) and histone levels. Furthermore, in NT pregnancy there is premature expression of class I major histocompatibility complex (MHC-I), associated with inflammatory infiltrates increases and immunological rejection against fetus. The aim of this work was to evaluate global levels of 5mC, 5hmC and some posttranslational histone modifications and MHC-I molecules expression of bovine placenta in NT and control models. For this, NT and control bovine placentome were collected at first (n = 6) and third (n = 6) trimester of pregnancy. Immunohistochemistry reactions were performed to assay DNA methylation (5mC) and (5hmC) and posttranslational histone modifications (H3K4me3, H3K27me3, H3K9ac, H3K9me2/3) and MHC-I molecules (Qa-2 e IL-A88). Quantitative PCR reactions were performed to evaluate the expression of DNA modifications related enzymes (DNMT1, TET1 and TET2), MHC-I classical (JSP-1) and non-classical (NC1-4) isoforms, and imprinted genes expression (SNRPN, TSSC4 and PHDLA2). In the NT placenta there was an increase in the global methylation and decreased hydromethylation level at first trimester. Levels of H3K4me3 were constant at control placenta while increased in NT placenta. For H3K27me3, the levels decreased in control placenta and were stable at NT counterparts. At 60 days of pregnancy in NT placenta, were observed low levels of global H3K9ac, but no differences of H3K9me2/3 levels were found between pregnancy ages or type. We identified MHC-I at bovine placentomal trophoblast in all ages analyzed, with intensity variation of different isoforms. In general, low levels of DNA methylation at day 60 of pregnancy of TNCS placenta, indicates a compensatory mechanism to active genic expression. Since histone modifications, in this period, leads to repressive status, because bivalence of H3K4me3 and H3K27me3 and levels of H3K9ac were diminished. Also at day 60 of pregnancy of TNCS placenta, MHC-I is highly expressed and leads to maternal immune response against fetus tissue. In conclusion, several events are present and apparently contribute to early clone pregnancy instability, coinciding with high pregnancy losses in that phase Bovine placenta DNA methylation Histone modifications Metilação do DNA MHC MHC Modificações de histona Nuclear transfer Placenta bovina Transferência nuclear
36	Decoding the Structural Layer of Transcriptional Regulation : Computational Analyses of Chromatin and Chromosomal Aberrations Andersson, Robin January 2010 (has links) Gene activity is regulated at two separate layers. Through structural and chemical properties of DNA – the primary layer of encoding – local signatures may enable, or disable, the binding of proteins or complexes of them with regulatory potential to the DNA. At a higher level – the structural layer of encoding – gene activity is regulated through the properties of higher order DNA structure, chromatin, and chromosome organization. Cells with abnormal chromosome compaction or organization, e.g. cancer cells, may thus have perturbed regulatory activities resulting in abnormal gene activity. Hence, there is a great need to decode the transcriptional regulation encoded in both layers to further our understanding of the factors that control activity and life of a cell and, ultimately, an organism. Modern genome-wide studies with those aims rely on data-intense experiments requiring sophisticated computational and statistical methods for data handling and analyses. This thesis describes recent advances of analyzing experimental data from quantitative biological studies to decipher the structural layer of encoding in human cells. Adopting an integrative approach when possible, combining multiple sources of data, allowed us to study the influences of chromatin (Papers I and II) and chromosomal aberrations (Paper IV) on transcription. Combining chromatin data with chromosomal aberration data allowed us to identify putative driver oncogenes and tumor-suppressor genes in cancer (Paper IV). Bayesian approaches enabling the incorporation of background information in the models and the adaptability of such models to data have been very useful. Their usages yielded accurate and narrow detection of chromosomal breakpoints in cancer (Papers III and IV) and reliable positioning of nucleosomes and their dynamics during transcriptional regulation at functionally relevant regulatory elements (Paper II). Using massively parallel sequencing data, we explored the chromatin landscapes of human cells (Papers I and II) and concluded that there is a preferential and evolutionary conserved positioning at internal exons nearly unaffected by the transcriptional level. We also observed a strong association between certain histone modifications and the inclusion or exclusion of an exon in the mature gene transcript, suggesting a functional role in splicing. Chromatin Nucleosome positioning Histone modifications Chromosomal aberrations Transcriptional regulation Array-CGH Next generation sequencing ChIP-chip Bioinformatics Bioinformatik
37	Early Epigenetic Regulation of the Adaptive Immune Response Gene CIITA Mehta, Ninad T 01 December 2010 (has links) The precise regulation of Major Histocompatibility class II (MHC-II) genes plays an important role in the control of the adaptive immune response. MHC-II genes are expressed constitutively in only a few cell types, but their expression can be induced by the inflammatory response cytokine interferon gamma (INF-γ). The regulation of MHC-II is controlled by a Master Regulator, the class II transactivator (CIITA). Multiple studies have shown that CIITA regulated expression of MHC-II is controlled and induced by INF-γ. It has been also shown that a functional CIITA gene is necessary for the expression of MHC-II genes. CIITA is thus a general regulator of both constitutive and inducible MHC-II expression. Although much is known about the transcription factors necessary for CIITA expression, there is little information as to the epigenetic modifications and the requisite enzymes needed to provide these transcription factors access to DNA. Previous studies in the Greer lab have shown that increased levels of acetylation of histones H3 upon INF-γ stimulation, as does tri-methylation of H3K4 upon prolonged cytokine stimulation. Similar observations were made at early time points post IFN-γ stimulation, where there is an instantaneous increase in the levels of H3K18ac and H3K4me3. In contrast to this, the levels of silencing modifications begin to drop with in the first 20 minutes of IFN-γ stimulation. The binding of STAT1 reaches its peak at about 60 minutes and the first transcripts for the protein start to appear as early as 40 minutes post the cytokines stimulation. Our study is the first to link the rapidly occurring epigenetic changes at the CIITA promoter pIV to EZH2 Transcriptional regulation Epigenetics Histone modifications Histone remodeling enzymes Class II transactivator Biology, general
38	The role of H2B monoubiquitination in cellular differentiation Karpiuk, Oleksandra 05 November 2012 (has links) No description available. 570 H2B monoubiquitination RNF20 RNF40 differentiation mesenchymal stem cells cyclin-dependent kinase 9 histone modifications epigenetics Biologie (PPN619462639)
39	Modulação do trofoblasto bovino na gestação de embriões clonados / Modulation of bovine trophoblast in cloned pregnancy Rodrigo da Silva Nunes Barreto 24 August 2015 (has links) O sucesso da gestação, e nascimento da prole saudável, depende da adequada formação, desenvolvimento e funcionamento da placenta. Entretanto, são observadas altas perdas durante o primeiro terço da gestação de embriões bovinos produzidos por transferência de núcleo de célula somática (TNCS), principalmente causadas por alterações placentárias, decorrentes da incompleta reprogramação epigenética no desenvolvimento embrionário. Normalmente, após a fecundação, o DNA paterno é desmetilado durante as primeiras horas do desenvolvimento, enquanto o DNA materno é desmetilado de forma passiva. Entretanto nos embriões TNCS a desmetilação do DNA é tardia e incompleta, resultando numa alteração do padrão epigenético, principalmente nos níveis de metilação (5mC) e hidroximetilação (5hmC) do DNA e nas histonas. Além disso, na gestação TNCS há expressão precoce das moléculas do complexo de histocompatibilidade principal de classe I (MHC-I), associada ao aumento de infiltrados inflamatórios na placenta e à rejeição imunológica ao feto. O objetivo desse trabalho foi de verificar, na placenta bovina TNCS e controle, os níveis globais de 5mC e 5hmC, e de algumas modificações de histonas importantes na formação do trofectoderma ou por serem modificações clássicas, além de imunolocalizar moléculas de MHC-I. Para tanto foram utilizadas amostras de placentônio TNCS no primeiro (n = 5) e terceiro (n = 6) terço gestacional; e como controle, placentônios com controle no primeiro (n = 6) e terceiro (n = 6). Foram realizadas reações de imunohistoquímica para modificações no DNA (5mC, 5hmC) e nas histonas (H3K4me3, H3K27me3, H3K9ac, H3K9me2/3) e para MHC-I (Qa-2 e IL-A88); além de reações de PCR quantitativo para enzimas responsáveis pelas modificações no DNA (DNMT1, TET1, TET3), para alguns genes relacionados com o desenvolvimento da placenta (PAG9, PHDLA2, SNRPN e TSSC4) e para isoformas de MHC-I (NC1-4 e JSP-1). Houve aumento dos níveis globais de metilação, e diminuição de hidroximetilação, na placenta TNCS durante o primeiro trimestre gestacional. Os níveis de H3K4me3 foram estáveis na placenta controle e crescentes na placenta TNCS, enquanto que a H3K27me3 decresceu na placenta controle e foi estável na placenta TNCS. Na placenta TNCS, aos 60 dias, foram observados os menores níveis globais H3K9ac, porém H3K9me2/3 não diferiram entre as idades e tipos gestacionais estudados. Foi identificado MHC-I no trofoblasto do placentônio bovino nas idades analisadas, com variações de intensidade dependendo da isoforma detectada, além de que a placenta controle e a TNCS apresentam padrões diferentes na expressão de MHC-I. De modo geral, o menores níveis de metilação do DNA encontrados na placenta TNCS aos 60 dias de gestação, indica ser um mecanismo compensatório para ativar a expressão gênica. Visto que a as modificações de histona levam a um estado repressivo da expressão gênica, já que a bivalência entre H3K4me3 e H3K27me3 e os níveis de H3K9ac estão diminuídos. Ainda na placenta TNCS aos 60 dias, há uma alta expressão de MHC-I, levando a resposta imune do sistema materno contra os tecidos fetais. Portanto vários eventos são presentes e parecem contribuir para instabilidade da gestação inicial em clones, coincidindo com a alta taxa de perdas gestacionais nessa fase / Pregnancy success depends of adequate placental formation, development and function. Therefore, the highest loses rates are found during first trimester pregnancies of bovine embryos produced by somatic cell nuclear transfer (NT), majorly by placental alterations, due to incomplete epigenetic reprogramming during embrionary development. Normally, after fecundation, paternal DNA is actively demethylated at first hours of development; where as maternal DNA is passively demethylated. However in NT embryos the DNA demethylation is late and incomplete, resulting in changes of epigenetic patterns, majorly in methylation (5mC), hydroxymethylation (5hmC) and histone levels. Furthermore, in NT pregnancy there is premature expression of class I major histocompatibility complex (MHC-I), associated with inflammatory infiltrates increases and immunological rejection against fetus. The aim of this work was to evaluate global levels of 5mC, 5hmC and some posttranslational histone modifications and MHC-I molecules expression of bovine placenta in NT and control models. For this, NT and control bovine placentome were collected at first (n = 6) and third (n = 6) trimester of pregnancy. Immunohistochemistry reactions were performed to assay DNA methylation (5mC) and (5hmC) and posttranslational histone modifications (H3K4me3, H3K27me3, H3K9ac, H3K9me2/3) and MHC-I molecules (Qa-2 e IL-A88). Quantitative PCR reactions were performed to evaluate the expression of DNA modifications related enzymes (DNMT1, TET1 and TET2), MHC-I classical (JSP-1) and non-classical (NC1-4) isoforms, and imprinted genes expression (SNRPN, TSSC4 and PHDLA2). In the NT placenta there was an increase in the global methylation and decreased hydromethylation level at first trimester. Levels of H3K4me3 were constant at control placenta while increased in NT placenta. For H3K27me3, the levels decreased in control placenta and were stable at NT counterparts. At 60 days of pregnancy in NT placenta, were observed low levels of global H3K9ac, but no differences of H3K9me2/3 levels were found between pregnancy ages or type. We identified MHC-I at bovine placentomal trophoblast in all ages analyzed, with intensity variation of different isoforms. In general, low levels of DNA methylation at day 60 of pregnancy of TNCS placenta, indicates a compensatory mechanism to active genic expression. Since histone modifications, in this period, leads to repressive status, because bivalence of H3K4me3 and H3K27me3 and levels of H3K9ac were diminished. Also at day 60 of pregnancy of TNCS placenta, MHC-I is highly expressed and leads to maternal immune response against fetus tissue. In conclusion, several events are present and apparently contribute to early clone pregnancy instability, coinciding with high pregnancy losses in that phase Metilação do DNA MHC Modificações de histona Placenta bovina Transferência nuclear Bovine placenta DNA methylation Histone modifications MHC Nuclear transfer
40	The Interaction Between Sir3 and Sir4 is Dispensable for Silent Chromatin Spreading in Budding Yeast Gerson, Rosalind J. January 2015 (has links) In Saccharomyces cerevisiae, telomeric and HM silencing requires the histone deacetylase Sir2 and the chromatin binding proteins Sir3 and Sir4, which interact to form the SIR complex. Silent chromatin formation begins with a nucleation step, followed by spreading of Sir proteins along chromatin. Overexpression of Sir3 extends silent chromatin domains, however the role of Sir protein interactions within silent chromatin extensions remains unknown. Here, we generated the Sir3 mutant, Sir3-4A, which cannot interact with Sir4 but is capable of forming silent chromatin extensions when overexpressed. Within extended silent domains, Sir2 and Sir4 enrichments are similar whether Sir3 or Sir3-4A is overexpressed, suggesting that silent chromatin extensions require Sir4 but not the interaction between Sir3 and Sir4. Tethering Sir3-4A at an HMR silencer cannot nucleate silencing in the absence of Sir3, suggesting that in addition to Sir3 recruitment, the Sir3-Sir4 interaction has at least one other function during silent chromatin nucleation. Heterochromatin Silent chromatin Epigenetics Gene silencing Histone modifications Saccharomyces cerevisiae Sir2 Sir3 Sir4 Gene regulation H3K79 H4K16

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