Global ETD Search

31	Atomic Force Microscopy for Chromatin Structure Study January 2010 (has links) abstract: In eukaryotes, DNA is packed in a highly condensed and hierarchically organized structure called chromatin, in which DNA tightly wraps around the histone octamer consisting of one histone 3-histone 4 (H3-H4) tetramer and two histone 2A- histone 2B (H2A-H2B) dimers with 147 base pairs in an almost two left handed turns. Almost all DNA dependent cellular processes, such as DNA duplication, transcription, DNA repair and recombination, take place in the chromatin form. Based on the critical importance of appropriate chromatin condensation, this thesis focused on the folding behavior of the nucleosome array reconstituted using different templates with various controllable factors such as histone tail modification, linker DNA length, and DNA binding proteins. Firstly, the folding behaviors of wild type (WT) and nucleosome arrays reconstituted with acetylation on the histone H4 at lysine 16 (H4K16 (Ac)) were studied. In contrast to the sedimentation result, atomic force microscopy (AFM) measurements revealed no apparent difference in the compact nucleosome arrays between WT and H4K16 (Ac) and WT. Instead, an optimal loading of nucleosome along the template was found necessary for the Mg2+ induced nucleosome array compaction. This finding leads to the further study on the role of linker DNA in the nucleosome compaction. A method of constructing DNA templates with varied linker DNA lengths was developed, and uniformly and randomly spaced nucleosome arrays with average linker DNA lengths of 30 bp and 60 bp were constructed. After comprehensive analyses of the nucleosome arrays' structure in mica surface, the lengths of the linker DNA were found playing an important role in controlling the structural geometries of nucleosome arrays in both their extended and compact forms. In addition, higher concentration of the DNA binding domain of the telomere repeat factor 2 (TRF2) was found to stimulate the compaction of the telomeric nucleosome array. Finally, AFM was successfully applied to investigate the nucleosome positioning behaviors on the Mouse Mammary Tumor Virus (MMTV) promoter region, and two highly positioned region corresponded to nucleosome A and B were identified by this method. / Dissertation/Thesis / Ph.D. Chemistry 2010 Biochemistry Biophysics Chemistry Atomic Force Microscopy Chromatin DNA Nucleosome
32	Chemical and Biological Studies on Photoinduced DNA Damage and Repair and Subnucleosome Structures / 光照射に起因するDNA損傷と修復、およびサブヌクレオソーム構造体に関するケミカルバイオロジー Hashiya, Fumitaka 25 March 2019 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第21597号 / 理博第4504号 / 新制\|\|理\|\|1647(附属図書館) / 京都大学大学院理学研究科化学専攻 / (主査)教授杉山弘, 教授秋山芳展, 准教授竹田一旗 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM Photoreaction 5-Bromouracil Chem-seq TFAM Sub-nucleosome structure 400
33	Controllable cell delivery and chromatin structure observation using DNA nanotechnology / DNAナノテクノロジーを用いた細胞制御法の開拓とクロマチン構造の観察 FENG, YIHONG 23 September 2020 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第22719号 / 理博第4628号 / 新制\|\|理\|\|1665(附属図書館) / 京都大学大学院理学研究科化学専攻 / (主査)教授杉山弘, 教授深井周也, 教授秋山芳展 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM DNA nanotechnology cell uptake nucleosome chromatin AFM 400
34	The Role of the Nucleosomal Acidic Patch in Histone Dimer Exchange Gioacchini, Nathan 07 January 2022 (has links) Eukaryotes organize their genomes by wrapping DNA around positively charged proteins called histones to form a structure known as chromatin. This structure is ideal for keeping the genome safe from damage, but also becomes an obstacle for the transcriptional machinery to access information stored in the DNA. To facilitate a balance between storage and accessibility, eukaryotes utilize a family of enzymes known as ATP-dependent chromatin remodelers to directly manipulate chromatin structure. The diverse activities of these chromatin remodeling enzymes range from simply sliding nucleosomes to reveal transcription start sites, to editing the composition of a nucleosome by exchanging canonical histones for histone variants. Chromatin remodeling enzymes recognize features of the nucleosome that activate their ATPase domains and enable proper remodeling function. One nuclear epitope that has been extensively studied is the nucleosomal acidic patch. This negatively charged region on the face of the nucleosome has been shown to be essential for remodeling enzymes like Chd1, ISWI, and INO80C. The chromatin remodeler SWR1C edits nucleosomes by removing the canonical histone H2A from nucleosomes and exchanges it for the histone variant H2A.Z, but the role of the acidic patch in this process has not been investigated. In this work, I showed that SWR1C has normal binding affinity to acidic patch mutant nucleosomes and retains ATPase stimulation but can no longer exchange dimers on this substrate. This work also identified a novel arginine anchor on the essential SWR1C subunit, Swc5, that binds specifically to the nucleosomal acidic patch. The data in this work suggest a mechanism where SWR1C engages nucleosomes and uses the Swc5 subunit to recognize the nucleosomal acidic patch to couple ATPase activity to histone dimer exchange. Chromatin Remodeling Histone Variants Nucleosome Acidic Patch Biochemistry
35	Elucidating Mechanisms of Chromatin Crosstalk Using ‘Designer’ Nucleosomes Yerkesh, Zhadyra 04 1900 (has links) The molecular target of epigenetic signaling is chromatin. Histones are extensively post-translationally modified (PTM), and many of these individual modifications have been studied in depth. As PTMs occur at multiple positions within histones, the degree to which these modifications might influence each other remains one of the major challenges of chromatin biology. Although major discoveries in understanding the complex repertoire of histone modifications were achieved using reductionist experimental systems with synthetic histone peptides, they do not explain the role of putative PTM cross-talks in a chromatin context. However, generating chromatin substrates of defined modification status has proved to be a technically challenging task. In this thesis, I first demonstrate our work on establishing a novel approach to produce libraries of modified nucleosomes. We employed protein trans-splicing and sortase-mediated ligation strategies to incorporate chemical modifications on histone tails of ‘ligation-ready’ nucleosomes. Subsequently, the ‘designer’ nucleosome libraries were used for testing the binding of heterochromatin protein 1 (HP1) and elucidated the previously uncharacterized crosstalk of H3K9me2 and S28ph marks. Further investigations explained the mechanism of this crosstalk and highlighted the importance of developing chemical biology tools for elucidating complex chromatin signaling. Second, I describe our reconstitution systems for the assembly of semisynthetic recombinant chromatin carrying methylation marks on DNA and distinct modifications on histones, e.g. H3K9me3. I aimed to understand the mechanisms of the interplay between chromatin and one of the DNA maintenance methylation factors, UHRF1. I showed that UHRF1 strongly interacts with nucleosomes containing linker DNA. However, it exerts only residual enzymatic activity in this context. Based on functional H3 ubiquitylation assays in vitro, I found that hemi-methylated nucleosomes stimulate enzymatic activity of UHRF1, suggesting that the protein’s chromatin targeting and activation are a two-step process. The positioning of hemi-methylated CpG on nucleosome regulates UHRF1 target selectivity. Further, mutational analysis revealed that the PHD domain of the factor is indispensable for H3 binding and that its SRA domain is required for catalytic activation. Overall, our work adds a new layer of positional complexity to the me½CpG-dependent regulation of UHRF1 and expands the current model of DNA methylation maintenance. nucleosome post-translational modifications chromatin designer chromatin UHRF1 DNA methylation
36	Mécanisme d'action d'un facteur potentiellement pionnier dans la différenciation des cellules souches végétales / Role of a potential pioneer factor in the differentiation of plant stem cells Brun Hernández, Eugenia 27 April 2018 (has links) LFY est un facteur de transcription clé dans le développement des plantes, et en particulier dans la floraison des angiospermes. Il a un rôle important, d'abord, dans l'établissement des méristèmes floraux et plus tard, dans la spécification de leurs identités d'organes floraux. Cette activité implique des réarrangements majeurs de la chromatine dans le noyau des cellules. Des loci cibles doivent passer d'un état fermé à un état ouvert. Au cours des deux dernières décennies, les Facteurs de Transcription Pionniers (PTF) ont été étudiés car ils peuvent lier leurs sites cibles à l'ADN nucléosomique, ils peuvent surmonter les contraintes stériques des nucléosomes et établir un état «compétent» dans une région particulière pour qu’il puisse être davantage régulé par d'autres partenaires (Iwafuchi-Doi & Zaret, 2014). Il a été démontré que LFY interagit physiquement et génétiquement avec deux ATPases appartenant à des complexes de remodelage de la chromatine ATP-dépendants, SYD et BRM (Wu et al., 2012). En outre, des analyses de données à l'échelle du génome suggèrent fortement que son domaine d'oligomérisation N-terminal, confère à LFY un accès à des régions fermées de la chromatine (Sayou et al., 2016). De cette manière, LFY présente des caractéristiques communes avec les PTF. Nous avons travaillé afin de mieux comprendre le mode d'action de LFY par rapport aux ATPases mentionnées ainsi qu'à la chromatine.Au chapitre I, à travers des expériences in vitro, l'interaction potentielle de LFY avec les nucléosomes a été évaluée. Nous avons reconstitué des nucléosomes, en identifiant des régions enrichies en nucléosomes dans le génome d'Arabidopsis, ciblées efficacement par LFY. Ces régions ont été sélectionnées à partir des données génomiques de ChIP-seq de LFY dans les lignes de surexpression ainsi que des données de DNAse-seq et de MNase-seq, qui ont été utiles pour analyser le paysage chromatinien (T. Zhang, Zhang, & Jiang, 2015; W. Zhang, Zhang, Wu, & Jiang, 2012). Une liaison forte mais non-spécifique de LFY de la gymnosperme Ginkgo biloba aux nucléosomes a été observée. Cependant, LFY d'Arabidopsis thaliana a montré une faible liaison aux nucléosomes.Au chapitre II, l'objectif était de cartographier les domaines d'interaction minimale nécessaires de LFY et les ATPases SYD et BRM. En utilisant la technique HTRF, nous avons montré que le domaine C-terminal de LFY interagit avec le domaine HSA de BRM. De plus, grâce à une approche in vivo, nous avons observé la perte du phénotype 35S:LFY dans les plantes F1 de chacun des trois croisements: 35S:LFY syd-5, 35S:LFY brm-1 et 35S:LFY brm-3. Cela suggère une interaction forte, ce qui signifie que lorsque BRM ou SYD ne sont pas fonctionnels, la fonction de LFY est affectée et aucune fleur ectopique n'est formée. / LFY is a key transcription factor in plant development, and especially in flowering for angiosperms. It has an important role, first, in the establishment of floral meristems and later, in the specification of their floral organ identities. This activity implicates on cells’ nucleus major chromatin rearrangements. Target loci need to pass from a closed to an opened state. In the last two decades, Pioneer Transcription Factors (PTFs) have been studied because they can bind their target sites at nucleosomal DNA, they are able to overcome the steric constraints of nucleosomes and establish a “competent state” in a particular region, so it can be further regulated by other partners (Iwafuchi-Doi & Zaret, 2014). LFY has been demonstrated to physically and genetically interact with two ATPases belonging to ATP-dependent chromatin remodeling complexes, SYD and BRM (Wu et al., 2012). Besides, genome-wide data analyses strongly suggest that its N-terminal oligomerization domain, confers LFY access to closed regions of chromatin (Sayou et al., 2016). In this way, LFY presents common features with PTFs. We worked in order to better understand LFY’s mode of action in relation to the mentioned ATPases as well as with chromatin.In Chapter I, through in vitro experiments, LFY’s potential interaction with nucleosomes, was assessed. We performed reconstituted nucleosomes by identifying nucleosome-enriched regions in Arabidopsis genome, efficiently targeted by LFY. These regions were selected used genome-wide data from ChIP-seq of LFY in overexpressing lines and DNAse-seq as well as MNase-seq data, which was useful to analyze chromatin landscape (T. Zhang, Zhang, & Jiang, 2015; W. Zhang, Zhang, Wu, & Jiang, 2012). A strong but non-specific binding of LFY from the gymnosperm Ginkgo biloba to nucleosomes was observed. However, LFY from Arabidopsis thaliana, showed a weak binding to nucleosomes.In Chapter II, the aim was to map the minimal necessary interacting domains of LFY and the ATPases SYD and BRM. Using the HTRF technique, LFY’s C-terminal domain was shown to interact with BRM’s HSA domain. In addition, through an in vivo approach, we observed the loss of the 35S:LFY phenotype in the F1 plants from each of the three crosses: 35S:LFY syd-5, 35S:LFY brm-1 and 35S:LFY brm-3. This suggested a strong interaction, meaning that when BRM or SYD are not functional, LFY’s function is affected and no ectopic flowers are formed. Leafy Facteur pionnier Nucléosome Leafy Pioneer factor Nucleosome 570
37	Chemical Biology Study on DNA Epigenetic Modifications / DNAエピジェネティック修飾に関するケミカルバイオロジー研究 Kizaki, Seiichiro 23 March 2017 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第20195号 / 理博第4280号 / 新制\|\|理\|\|1615(附属図書館) / 京都大学大学院理学研究科化学専攻 / (主査)教授杉山弘, 教授三木邦夫, 教授秋山芳展 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM methylcytosine hydroxymethylcytosine Tet protein active demethylation nucleosome 400
38	Chemical Biology Approaches for Investigating Nucleosome Structure and Accessibility / ケミカルバイオロジー的アプローチによるヌクレオソーム構造とアクセシビリティの研究 Zou, Tingting 26 March 2018 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第20936号 / 理博第4388号 / 新制\|\|理\|\|1630(附属図書館) / 京都大学大学院理学研究科化学専攻 / (主査)教授杉山弘, 教授三木邦夫, 教授秋山芳展 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM Nucleosome Reactivity Structure Chemical assay Gene expression regulation 400
39	Development of Multivalent DNA-Peptide Nucleosome Mimetics and Multi-Domain Protein Inhibitors That Directly or Indirectly Target the E3 Ligase UHRF1 Gu, Li 01 January 2023 (has links) (PDF) UHRF1 is an E3 ubiquitin ligase and a key epigenetic regulator establishing a crosstalk between DNA methylation and histone modification. Despite the important biochemical role of UHRF1 in cells, its overexpression has been found in almost all primary cancer types including breast cancer, lung cancer and so on. Numerous evidence indicates a strong link between tumorigenesis and UHRF1 overexpression, supporting its potential as a universal biomarker for cancer. However, UHRF1 is “yet-to-be drugged” and no highly potent chemical probes have been developed to target UHRF1 to date. In this study, we proposed two drug design approaches for UHRF1. The first approach is to construct multivalent DNA-peptide nucleosome mimetics that can target UHRF1 directly. For UHRF1 to promote DNA methylation, the interaction with nucleosomes, both through a DNA-binding (SRA) and histone-binding domain (TTD-PHD), and ubiquitylation of histone H3 are necessary to recruit DNA methyltransferase. We utilized the natural binding activity between UHRF1 and nucleosome in cells to develop a DNA-peptide hybrid that mimics UHRF1’s interaction with nucleosomes, thereby inhibiting UHRF1-dependent histone ubiquitylation and impairing its function in controlling DNA methylation. Here, we described the synthesis of the DNA-peptide hybrids using different lengths of PEG linkers including PEG2, 6, 8, 16 and 24. We purified and characterized the molecules with RP-HPLC and ESI-MS. Biophysical assays such as ITC and METRIS were conducted to study about the binding affinities of these DNA-peptide hybrids. In vitro UHRF1 ubiquitylation assays were performed to investigate the inhibition efficacy of these inhibitors, and pull-down assays were conducted to study their selectivity. In addition, mass photometry assays were used to study the stoichiometry of the binding between UHRF1 and the DNA-peptide hybrids. We demonstrated that multivalent DNA-peptide hybrids possess high affinity for UHRF1 and can inhibit histone ubiquitylation. Among them, In16 can form a 1:1 binding complex with UHRF1, substantiating its ability to be used as a molecular tool for structural analysis of UHRF1. In the second approach, we designed and constructed three generations of multi-domain protein inhibitors of E2 enzyme Ube2D, including RING-UBL (RU), UBOX-UBL (UU) and UBOX-UbvD1.1 short/long (UD1 and UD2). Through targeting both the RING- and backside-binding sites on Ube2D, UHRF1 enzymatic function can be indirectly inhibited as Ube2D is the only cognate E2 enzyme that cooperates with UHRF1 for histone H3 ubiquitylation. In this study, ITC was used to measure the binding affinities of these inhibitors, showing an increasing affinity from the first inhibitor RU to the last one UD2, ranging from 10-6 M to biochemistry Cancer Inhibitor Nucleosome Ube2d Ubiquitylation UHRF1 Biochemistry
40	Nucleosome Remodeling by hMSH2-hMSH6 Javaid, Sarah January 2010 (has links) No description available. Biophysics mismatch repair hMSH2-hMSH6 nucleosome disassembly post-translational modifications

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