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Regulation of Pluripotency and Differentiation by Chromatin Remodeling FactorsEe, Ly-Sha 08 August 2017 (has links)
Central to the control of virtually all cellular activity is the regulation of gene expression. In eukaryotes, this regulation is greatly influenced by chromatin structure, which is itself regulated by numerous chromatin-remodeling complexes. These are typically large protein complexes with interchangeable subunits that allow for highly specialized functions in different cell types. Moreover, additional specificity can be gained through complexes formed from different subunit isoforms. Histone modifications also regulate chromatin by recruiting remodeling complexes to particular genomic regions.
In this thesis we characterize MBD3C, an isoform of the Nucleosome Remodeling and Deacetylase (NuRD) complex subunit MBD3. MBD3 is essential for pluripotency and development, but MBD3C appears to be expressed only in embryonic stem cells (ESCs), and whether it forms a distinct NuRD complex, how its expression is regulated, and its precise function(s) remain unknown. We show that MBD3C forms a complete NuRD complex that functions redundantly with the other MBD3 isoforms in ESC gene regulation. Furthermore, MBD3C binds the SET/MLL complex subunit WDR5 through a conserved motif within its unique N-terminal region, and this interaction is necessary for the regulation of >2,000 ESC genes. Together, these findings indicate that ESCs can utilize isoforms of the same protein to achieve similar functions through diverse mechanisms.
The second part of this thesis focuses on the role of the histone modification H3.3K56ac in pluripotency and differentiation. Although H3K56ac is well-studied in yeast, in mammalian cells it is far less abundant and its functions are largely unknown. Our data indicate that the H3.3K56R mutant is largely normal for ESC maintenance and loss of pluripotency markers during differentiation, but H3.3K56ac is necessary for proper lineage commitment. Ongoing studies will characterize the H3.3K56Q phospho-mimetic mutant during differentiation, and examine H3.3K56ac function at lineage-specific genes.
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Mechanistic Basis for Control of Early Embryonic Development by a 5’ tRNA FragmentBing, Xin Y. 08 July 2019 (has links)
Ancestral environmental conditions can instruct offspring development, although the mechanism(s) underlying such transgenerational epigenetic inheritance is unclear. In murine models focused on paternal dietary effects, we and others have identified tRNA fragments (tRFs) in mature sperm as potential carriers of epigenetic information. In our search for molecular targets of specific tRFs, we observed that altering the level of 5’-tRF Glycine-GCC (tRF-GG) in mouse embryonic stem cells (mESCs) and preimplantation embryos modulates the expression of the endogenous retrovirus MERV-L and genes regulated by MERV-L. Intriguingly, transient derepression of MERV-L is associated with totipotency of two-cell stage embryos and a subset of two-cell-like mESCs.
Here, I reveal the mechanistic basis for tRF-GG regulation of MERV-L. I show that tRF-GG supports the production of numerous small nuclear RNAs associated with the Cajal body, in mouse and human embryonic stem cells. In particular, tRF-GG modulates the levels of U7 snRNA to ensure an adequate supply of histone proteins. This in turn safeguards heterochromatin-mediated transcriptional repression of MERV-L elements. Importantly, tRF-GG effects on histone mRNA levels, activity of a histone 3’UTR reporter, and expression of MERV-L associated transcripts can all be suppressed by appropriate manipulation of U7 RNA levels. I also show that hnRNPF and H bind directly to tRF-GG, and display a stark overlap of in vivo functions to tRF-GG. Together, this data uncovers a conserved mechanism for a 5’ tRNA fragment in the fine-tuning of a regulatory cascade to modulate global chromatin organization during pre-implantation development.
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Maelstrom Represses Canonical RNA Polymerase II Transcription in Drosophila Dual-Strand piRNA ClustersChang, Timothy H. 20 April 2018 (has links)
Transposons constitute much of the animal genome. While many transposons are ancient and inactivated, numerous others are intact and must be actively repressed. Uncontrolled transposons can cause genomic instability through DNA damage or mutations and must be carefully silenced in the germline or risk sterility or mutations that are passed on to offspring.
In Drosophila melanogaster, 23–30 nt long piRNAs direct transposon silencing by serving as guides for Aubergine, Argonaute3, and Piwi, the three fly PIWI proteins. piRNAs derive from piRNA clusters—large heterochromatic DNA loci comprising transposons and transposon fragments. piRNAs are loaded into PIWI proteins via the ping-pong cycle which serves to amplify guide piRNAs. Loaded Piwi then enters the nucleus to transcriptionally repress transposons by establishing heterochromatin. Therefore, to silence transposons, transposon sequences must also be expressed. To bypass this paradox, the HP1 homolog Rhino (Rhi) allows non-canonical, promoter-independent, transcription of transposons embedded in heterochromatin. Transposon RNAs produced in this manner are “incoherent” and have little risk of being translated into transposon-encoded proteins required for transposition.
This thesis focuses on understanding how piRNA clusters permit non-canonical transcription yet restrict canonical transcription. We found that although Rhi promotes non-canonical transcription in piRNA clusters, it also creates a transcriptionally permissive environment that is amenable to canonical transcription. In addition, we discovered that the conserved protein, Maelstrom, is required to repress promoter-driven transcription of individual, potentially active, transposons within piRNA clusters and allows Rhi to transcribe such transposon sequences into incoherent piRNA precursors.
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The ADA/GCN5 Containing Acetyltransferase Complexes of <em>Saccharomyces cerevisiae</em>: Roles in Antagonizing Chromatin Mediated Transcriptional Repression: A DissertationPollard, Kerri Jeanne 30 October 1998 (has links)
The compaction of the eukaryotic genome into a complex, highly folded chromatin structure necessitates cellular mechanisms for allowing access of regulatory proteins to the DNA template. Recent advances have led to the identification of two distinct families of chromatin remodeling enzymes--multi-subunit complexes that harbor a SWI2/SNF2 ATPase family member, and the nuclear acetyltransferases. The Saccharomyces cerevisiae SWI/SNF complex, the prototype for the ATP-dependent chromatin remodeling machines, is required for expression of a subset of genes in yeast. This 2MDa multimeric assembly is believed to facilitate transcriptional enhancement by antagonizing chromatin-mediated transcriptional repression through disruption of histone-DNA contacts. In an attempt to identify components or regulators of the SWI/SNF complex, we have cloned three previously identified genes, ADA2, ADA3, and GCN5, that encode subunits of a complex distinct from SWI/SNF. During the course of this thesis work, one of these gene products, GCN5, was identified as the first catalytic nuclear histone acetyltransferase. The goal of this thesis work was to determine the role of the ADA/GCN5 complex in transcriptional activation in Saccharomyces cerevisiae.
Using in vivo functional and genetic analysis, we have found that mutations in ADA2, ADA3, and GCN5 cause phenotypes strikingly similar to those of swi/snf mutants. ADA2, ADA3, and GCN5 are required for full expression of all SWI/SNF-dependent genes tested, including HO, SUC2, INO1, and Ty elements. Furthermore, mutations in the SIN1 gene, which encodes a non-histone chromatin component, or mutations in histones H3 or H4, alleviate the transcriptional defects caused by ada/gcn5 or swi/snf mutations. We have also found that ada2 swi1, ada3 swi1, and gcn5 swi1 double mutants are inviable and that mutations in SIN1 allow viability of these double mutants.
To determine the biochemical activities of the native GCN5-containing complex in yeast, we have partially purified three chromatographically distinct GCN5-dependent acetyltransferase activities. We have found that these three acetyltransferase complexes demonstrate unique substrate specificities for free histones and histones assembled into nucleosomal arrays. Additionally, we found that these enzymes not only acetylate histones, but also purified yeast Sin1 protein, a non-histone chromatin component that resembles HMG1.
We have also established a functional relationship between GCN5-dependent histone acetylation and polyamine-dependent chromatin condensation. We have found that depletion of cellular polyamines alleviates transcriptional defects caused by inactivation of the GCN5 histone acetyltransferase. In contrast, polyamine depletion does not alter the transcriptional requirements for the SWI/SNF chromatin remodeling complex. We have also found that polyamines facilitate oligomerization of nucleosomal arrays in vitro. Furthermore, this polyamine-mediated condensation reaction requires intact N-terminal domains of the core histones, and is inhibited by hyperacetylation of these domains.
The results presented throughout this thesis support roles for the ADA/GCN5 products in antagonizing chromatin. In vivo analysis suggests a functional relationship between the ADA/GCN5 acetyltransferase complex (or complexes) and the SWI/SNF complex. These comp1exes may operate in concert at nucleosomes within specific promoters to facilitate activated transcription. Furthermore, our studies suggest that polyamines are repressors of transcription in vivo, and that an additional role of histone hyperacetylation is to antagonize the ability of polyamines to stabilize highly condensed states of chromosomal fibers.
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Three-dimensional Folding of Eukaryotic GenomesHsieh, 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.
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The Silencing of Endogenous and Exogenous Transposable Elements in ArabidopsisFultz, Dalen R. 03 August 2017 (has links)
No description available.
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Impact des mutations d'un modificateur chromatinien dans le développement du cervelet et le médulloblastome de groupe Sonic Hedgehog / Impact of Mutations of a Chromatin Modifier in Cerebellar Development and Sonic Hedgehog Group of MedulloblastomaMercier, Audrey 07 December 2018 (has links)
Le médulloblastome (MB), une tumeur formée à partir du cervelet en développement, est l’un des cancers pédiatriques malins les plus fréquents. Des profils d’expression géniques ont montré l’existence de quatre groupes distincts de MB qui présentent des profils moléculaires et des pronostics différents. Parmi ces groupes, l’un d’entre eux est caractérisé par une activation de la voie de signalisation Sonic Hedgehog (SHH). Ce groupe de MB provient des précurseurs de neurones en grain lors du développement cérébelleux. Les traitements actuels comprennent la chirurgie, la chimiothérapie ainsi que la radiothérapie, ce qui a pour effet d’altérer les capacités cognitives et sociales des survivants. Ainsi, des efforts considérables ont été mis en œuvre dans le but de trouver des cibles thérapeutiques afin de bloquer spécifiquement les mécanismes tumorigéniques sans affecter le développement normal. De récentes analyses à grande échelle ont révélé le rôle crucial de mécanismes épigénétiques, et en particulier dans le groupe SHH, dans lequel la perte de fonction d’un certain nombre de modificateurs chromatiniens a été identifiée. Ainsi, l'objectif principal de ma thèse est d'étudier l'implication de potentiels candidats modificateur chromatinien, à la fois au cours du développement cérébelleux et lors du MB SHH. Nous avons concentré notre étude sur plusieurs modificateurs de la chromatine qui ont été trouvés mutés dans les MB SHH humains. Nous avons commencé l’étude avec trois modificateurs chromatiniens sélectionnés selon (i) leur impact sur la survie, (ii) leur expression au cours du développement du cervelet, (iii) leur expression dans les MB SHH humains et nous sommes finalement concentré sur un.Afin d'étudier ce candidat, un objectif important de ma thèse a été de développer des outils fiables. Dans ce contexte, nous avons développé des modèles de souris knock-out conditionnelles et le système CRISPR-cas9 dans le développement cérébelleux postnatal afin d'étudier l'impact de la perte du candidat à la fois dans le développement du cervelet et dans le MB SHH. Ensuite, nous nous sommes intéressés aux mécanismes moléculaires contrôlés par ce modificateur de la chromatine. Plus précisément, nous avons défini (i) l’interactome, et (ii) des cibles transcriptionnelles spécifiques qui nous ont aidé à comprendre comment une protéine impliquée dans la modification de la chromatine peut favoriser l’état tumoral. En conclusion, ces travaux permettent de mettre en évidence comment la perte de la fonction de modificateur chromatinien spécifique peut différemment affecter le destin cellulaire dans le développement normal cérébelleux et dans le MB SHH et soulève la question d’une prise en charge plus personnalisée des patients atteints de MB SHH. / Medulloblastoma (MB), a tumor arising from the developing cerebellum, is one of the most common malignant pediatric brain tumors. Gene expression profiling showed the existence of four groups of MB with distinct molecular profiles and patient outcomes. Among these groups, one of them is associated with an activation of the Sonic Hedgehog (SHH) pathway.This specific group is thought to arise from cerebellar Granule Neuron Progenitors (GNPs) during cerebellar development. The actual treatment is heavy and consists of surgery, chemotherapy as well as radiotherapy impairing social and cognitive ability of survivors. Thus, considerable effort has been made in order to find drug targets that would specifically block tumorigenic mechanisms without affecting normal development.Recent large scale analysis revealed the crucial role of epigenetic mechanisms, and especially in the SHH group of MB in which loss of function mutation of several chromatin modifiers has been identified. Thus, the main goal of my PhD is to study the involvement of potential candidate chromatin modifiers both during cerebellar development and in SHH MB.We focused our study on several chromatin modifiers that were found mutated in human SHH MB. We began to study three chromatin modifiers that were selected according to (i) their impact on survival, (ii) their expression during cerebellar development, (iii) their expression in human SHH MB and finally we selected one for further functional validation.In order to study this candidate, one important goal of my PhD has been to develop reliable tools. In that context, we developed conditional knock-out mice models and the CRISPR-Cas9 system in postnatal cerebellar development in order to study the impact of the loss of this chromatin modifier both in cerebellar development and SHH MB initiation. Then, we investigated the molecular mechanisms controlled by this chromatin modifier. In particular, we defined (i) the interactome, and (ii) specific target genes that helped us understanding how a protein implicated in chromatin modification can favor tumors. In conclusion, this work provides insights into how the loss of function of a specific chromatin modifier can differentially affect cell fate in the context of normal cerebellar development and in SHH MB, stressing the question of a more personalized patient care.
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Rôle du médiateur et des cohésines dans la réparation des dommages oxydatifs de l'ADN / Mediator's and Cohesin's role in the repair of oxidative DNA damageLebraud, Emilie 19 October 2018 (has links)
Les composants cellulaires sont constamment exposés à un stress oxydatif, lié à l’environnement et au métabolisme cellulaire. Les espèces réactives de l’oxygène produites par ce stress induisent de nombreuses lésions dans l’ADN, telles que l’oxydation des bases, la formation de sites abasiques ou la cassure de brins d’ADN. Ces dommages sont corrigés par un panel de systèmes de réparation, qui jouent un rôle critique dans la survie cellulaire et dans la prévention de pathologies telles que les maladies neurodégénératives ou le cancer. La modification de bases est le type de dommage le plus abondant, généré spontanément ou par des agents exogènes. Notre laboratoire s’intéresse ainsi au système de réparation par excision de base (BER), qui élimine les bases nucléotidiques altérées. Des études antérieures ont montré la formation « d’usines de réparation du BER » suite à des traitements induisant l’oxydation des bases dont la forme la plus courante est la 8-oxoguanine (8-oxoG). Dans le cas de cette lésion mutagène, l’assemblage du complexe BER dépend du recrutement d’OGG1 à la chromatine, l’enzyme qui reconnaît et excise la 8-oxoG. Cependant, ce recrutement ne nécessite pas la reconnaissance de la 8-oxoG, indiquant que d’autres signaux interviennent pour initier la réparation de la 8-oxoG par OGG1. Un crible à haut débit a été réalisé dans des cellules humaines pour rechercher des protéines impliquées dans le recrutement d’OGG1. Deux complexes ont été identifiés, les cohésines et le médiateur de la transcription.Dans ce projet de recherche, nous avons exploré le rôle de ces protéines dans la relocalisation d’OGG1 suite à un stress oxydatif. Nos études ont tout d’abord permis d’identifier des protéines essentielles au recrutement d’OGG1 : les protéines formant l’anneau de cohésines (SMC1, SMC3 et RAD21), plusieurs sous-unités du médiateur dont MED14, ainsi que le module CDK (MED12, MED13, Cycline C et CDK8). De plus, ces protéines sont nécessaires pour le recrutement d’OGG1 tout au long du cycle cellulaire. Nos résultats montrent que la relocalisation d’OGG1 sur la chromatine est liée à sa fonction de réparation de la 8-oxoG. Nous avons d’autre part montré que deux sous-unités du médiateur (MED12 et CDK8) sont relocalisées dans l’euchromatine, comme OGG1, de façon dépendante du corps du médiateur et des cohésines. Enfin, l’association d’OGG1 avec ses partenaires a été validée par microscopie FLIM-FRET et co-immunoprécipitation dans des conditions de stress oxydatif.En conclusion, ces résultats montrent pour la première fois un lien entre la réparation des bases oxydées et les complexes du médiateur et des cohésines, tous deux connus pour leur participation à d’autres voies de réparation de l’ADN. L’identification des mécanismes moléculaires et de nouveaux facteurs impliqués dans la réparation des bases oxydées pourrait fournir à terme des éléments essentiels pour la prise en charge de maladies telles que le cancer ou les maladies neurodégénératives. / Our laboratory focuses on the base excision repair (BER) mechanism that is responsible for the removal of damaged bases in DNA. Oxidative DNA damage is generated spontaneously by the endogenous metabolism of the cells or induced exogenously by chemical or physical agents. Our aim is to understand how BER complexes are assembled in the context of the cell nucleus in response to genotoxic stress. We previously found that after treatments generating oxidized bases into cellular DNA BER complexes are assembled on the chromatin. In the case of the 8-oxoguanine (8-oxoG) mutagenic lesion, assembly of the BER complex depends on the recruitment to the chromatin of OGG1, the DNA glycosylase that recognizes and excises the lesion. Surprisingly, characterization of OGG1 mutants that are not able to recognize 8-oxoG showed that the recruitment of this initiator protein does not require the recognition of the damaged base. This suggests that there are other mechanisms that allow recruitment of the enzyme to chromatin and thus initiation of the repair of the 8-oxoG by the BER. We performed a high-throughput siRNA screen in human cells to identify proteins required for the recruitment of OGG1 to chromatin. Among the candidates issued from the screen, two groups of proteins were selected for further study: members of the mediator and cohesin complexes.In this project, we explored the role of these proteins in OGG1 relocalization after an oxidative stress. Our studies confirmed the requirement of essential proteins for OGG1 recruitment: cohesins subunits (SMC1, SMC3 and RAD21), mediator subunits including the central protein MED14, and CDK subunits (MED12, MED13, Cyclin C and CDK8). Requirement of all these proteins is independent of the cell cycle. Furthermore we show that recrutement of OGG1 is essential for its 8-oxoG repair function. Microscopy studies revealed recruitment and colocalization of two mediator subunits (MED12 and CDK8) with OGG1 on euchromatin domains after an oxidative stress. Finally, the association between OGG1 and its partners, specifically after an oxidative stress, was validated by FLIM-FRET microscopy and co-immunoprecipitation.To conclude, these results show for the first time a link between repair of oxidized bases and mediator and cohesin complexes, both of them being already involved in other DNA repair pathways. The identification of molecular mechanisms and new factors involved in the repair of oxidized bases may ultimately provide new elements for the management of diseases such as cancer and neurodegenerative diseases.
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L'organisation post-méiotique de l'épigénome mâle / Post-meiotic male epigenome organizationBarral, Sophie 14 December 2018 (has links)
La spermatogénèse, processus de production des gamètes mâles, représente un modèle physiologique pertinent pour l’étude de la dynamique de la chromatine. En effet, une réorganisation drastique du génome est observée en fin de spermatogénèse, lors des étapes post-méiotiques du développement de la lignée germinale mâle. Ces réorganisations visent d’une part à compacter le génome afin de le protéger avant et lors de la fécondation et d’autre part à établir un épigénome mâle spécifique nécessaire pour le développement embryonnaire précoce. La chromatine organisée en nucléosomes est alors totalement remaniée de manière à ce que les protamines remplacent les histones dans les spermatozoïdes. Cette réorganisation est initiée par une vague d’acétylation des histones à l’échelle du génome, suivie par un remplacement massif des histones par de petites protéines basiques, les protéines de transition et les protamines. Les mécanismes moléculaires responsables de cette réorganisation de la chromatine sont très mal connus. Mon travail de thèse vise à explorer ces mécanismes en utilisant une approche d’invalidation de gènes chez la souris correspondant à des acteurs épigénétiques exprimés spécifiquement en post-méiose : le facteur nucléaire Nut (Nuclear protein in Testis) et le variant de l’histone H2A, H2A.L.2. Nous avons démontré que la protéine Nut recrute l’acétyltransferase p300 et induit l’hyperacétylation de l’histone H4 précisément au niveau des résidus lysines en position 5 et 8. Cette acétylation est nécessaire à l’interaction avec le premier bromodomaine de Brdt initiant le processus de remplacement des histones par les protamines. Ainsi, le facteur Nut est l’élément majeur de la vague d’acétylation des histones. Nous avons également mis en évidence le rôle crucial de H2A.L.2 dans “ l’ouverture ” de la structure du nucléosome permettant ainsi son invasion par les protéines de transition. Ces protéines vont à leur tour générer une plateforme pour le recrutement et la maturation des protamines et induire la formation de structures transitoires avant l’étape de compaction finale du génome des spermatozoïdes matures. Ces études nous ont ainsi permis d’établir pour la première fois un modèle moléculaire cohérent permettant de comprendre la programmation épigénétique post-méiotique du génome mâle et son impact sur la fertilité masculine. / Spermatogenesis, the process of producing male gametes, represents a relevant physiological model for the study of chromatin dynamics. Indeed, a drastic reorganization of the genome is observed at the end of spermatogenesis, during post-meiotic stages of the development of the male germ cells. These reorganizations are intended both to compact the genome to protect it before and during fertilization and to establish a specific male epigenome necessary for early embryonic development. In spermatozoa, during these post-meiotic stages, chromatin is completely reorganized so that the protamines replace the histones. This reorganization is initiated by a wave of genome-wide histone acetylation, followed by massive replacement of histones by small basic proteins, transition proteins and protamines. The molecular mechanisms responsible for this reorganization of the genome remain very poorly known today. My thesis aims to explore these mechanisms by using gene inactivation in mouse of epigenetic actors specifically expressed in post-meiotic germ cells : the nuclear factor Nut (Nuclear protein in Testis) and the histone H2A variant, H2A.L.2. We have demonstrated that the Nut protein interacts and stimulates the p300 acetyltransferase activity and induces the hyperacetylation of histone H4 precisely on the lysine residues at 5 and 8 positions. This acetylation is necessary for the interaction with the first bromodomain of Brdt initiating the process of histone replacement by protamines. Thus, the Nut factor is the main element of the histone acetylation wave. We have also deciphered the crucial role of H2A.L.2 in the “opening ” of nucleosomal structures in post-meiotic germ cells thus allowing its invasion by the transition proteins. These transition proteins will in turn generate a platform for the recruitment and maturation of protamines and induce the formation of transient structures before the final compaction of the mature sperm genome. These studies allowed us to establish for the first time a coherent molecular model for understanding the post-meiotic epigenetic programming of the male genome and its impact on male fertility.
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Measuring Stability of 3D Chromatin Conformations and Identifying Neuron Specific Chromatin Loops Associated with Schizophrenia RiskBorrman, Tyler M. 12 November 2020 (has links)
The 23 pairs of chromosomes comprising the human genome are intricately folded within the nucleus of each cell in a manner that promotes efficient gene regulation and cell function. Consequently, active gene rich regions are compartmentally segregated from inactive gene poor regions of the genome. To better understand the mechanisms driving compartmentalization we investigated what would occur if this system was disrupted. By digesting the genome to varying sizes and analyzing the fragmented 3D structure over time, our work revealed essential laws governing nuclear compartmentalization.
At a finer resolution within compartments, chromatin forms loop structures capable of regulating gene expression. Genome wide association studies have identified numerous single nucleotide polymorphisms (SNPs) associated with the neuropsychiatric disease schizophrenia. When these SNPs are not located within a gene it is difficult to gain insight into disease pathology; however, in some cases chromatin loops may link these noncoding schizophrenia risk variants to their pathological gene targets. By generating 3D genome maps, we identified and analyzed loops of glial cells, neural progenitor cells, and neurons thereby expanding the set of genes conferring schizophrenia risk.
The binding of T-cell receptors (TCRs) to foreign peptides on the surface of diseased cells triggers an immune response against the foreign invader. Utilizing available structural information of the TCR antigen interface, we developed computational methods for successful prediction of TCR-antigen binding. As this binding is a prerequisite for immune response, such improvements in binding prediction could lead to important advancements in the fields of autoimmunity and TCR design for cancer therapeutics.
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