The impact of advanced maternal age on endometrial differentiation and placental development

Woods, Laura May

January 2018

Maternal age is a significant risk factor for adverse pregnancy outcomes, and is strongly associated with an increased risk of aneuploidy of the conceptus, as well as a significantly higher frequency of serious pregnancy complications known as the "Great Obstetrical Syndromes", including miscarriage, pre-eclampsia and fetal growth restriction. In the last 40 years average maternal age has increased considerably in many wealthy countries, and in the UK the number of babies born to women aged 35 and over is set to surpass those born to women under 25. The high incidence of aneuploidy in older mothers can be attributed to abnormalities in the oocyte and embryo, however the "Great Obstetrical Syndromes" do not appear to be related to the oocyte and may instead be linked to abnormal development of the placenta. In this thesis, I show that advanced maternal age in the mouse is associated with a drastically increased variability of developmental progression in utero, including developmental delays and growth restriction, severe embryonic abnormalities and higher resorption rates. I find that these embryonic defects are always accompanied by gross morphological and transcriptomic abnormalities in the placenta. Notably, I show that the increased risk of these complications can be rescued by transfer of embryos from aged females to a young surrogate mother, thus implicating the aged maternal uterus as the basis for embryonic and placental defects. Transcriptomic analysis of the decidua compartment in placentas from aged pregnancies revealed abnormal expression of genes involved in the decidualization process, which occurs during early pregnancy and facilitates implantation and development of the conceptus. I show that these defects are already obvious in the peri-implantation window, with endometrial stromal cells from aged females being unable to mount an adequate decidualization response due to a decline in their ability to respond to pregnancy hormones. This blunted decidualization reaction in turn may lead to abnormal development of the placenta. These age-associated decidualization defects are cell-intrinsic and can be recapitulated in vitro. The detected insufficient activation levels and abnormal intracellular distribution of phospho-STAT3, combined with highly variable progesterone receptor expression, may be possible causes of these defects. In addition, I examined the possible effects of ageing on the epigenome as a potential contributor to the decline in endometrial function. My results indicate that ageing of the uterus displays some of the common epigenetic hallmarks of tissue ageing. However, more importantly, decidual cells of aged females exhibit abnormal distributions of the histone modification H3K4me3, and are refractory to the profound DNA methylation remodeling that I find takes place during pregnancy. These age-related changes in the epigenome may underpin, or contribute to, the observed decline in uterine function during pregnancy. Understanding the mechanism underlying these epigenomic and functional changes in the ageing reproductive tract may pave the way for new therapeutic strategies to improve maternal and fetal outcomes of pregnancy in older mothers.

Epigenetic Dysregulation in the Basocortical Cholinergic Projection System During the Progression of Alzheimer's Disease

January 2018

abstract: Alzheimer’s disease (AD) is characterized by the degeneration of cholinergic basal forebrain (CBF) neurons in the nucleus basalis of Meynert (nbM), which provides the majority of cholinergic input to the cortical mantle and together form the basocortical cholinergic system. Histone deacetylase (HDAC) dysregulation in the temporal lobe has been associated with neuronal degeneration during AD progression. However, whether HDAC alterations play a role in cortical and cortically-projecting cholinergic nbM neuronal degeneration during AD onset is unknown. In an effort to characterize alterations in the basocortical epigenome semi-quantitative western blotting and immunohistochemistry were utilized to evaluate HDAC and sirtuin (SIRT) levels in individuals that died with a premortem clinical diagnosis of no cognitive impairment (NCI), mild cognitive impairment (MCI), mild/moderate AD (mAD), or severe AD (sAD). In the frontal cortex, immunoblots revealed significant increases in HDAC1 and HDAC3 in MCI and mAD, followed by a decrease in sAD. Cortical HDAC2 levels remained stable across clinical groups. HDAC4 was significantly increased in prodromal and mild AD compared to aged cognitively normal controls. HDAC6 significantly increased during disease progression, while SIRT1 decreased in MCI, mAD, and sAD compared to controls. Basal forebrain levels of HDAC1, 3, 4, 6 and SIRT1 were stable across disease progression, while HDAC2 levels were significantly decreased in sAD. Quantitative immunohistochemistry was used to identify HDAC2 protein levels in individual cholinergic nbM nuclei immunoreactive for the early phosphorylated tau marker AT8, the late-stage apoptotic tau marker TauC3, and Thioflavin-S, a marker of mature neurofibrillary tangles (NFTs). HDAC2 nuclear immunoreactivity was reduced in individual cholinergic nbM neurons across disease stages, and was exacerbated in tangle-bearing cholinergic nbM neurons. HDAC2 nuclear reactivity correlated with multiple cognitive domains and with NFT formation. These findings identify global HDAC and SIRT alterations in the cortex while HDAC2 dysregulation contributes to cholinergic nbM neuronal dysfunction and NFT pathology during the progression of AD. / Dissertation/Thesis / Doctoral Dissertation Neuroscience 2018

Neurosciences

Alzheimer's disease

epigenetics

histone deacetylases

mild cognitive impairment

neurofibrillary tangle

nucleus basalis of Meynert

Avaliação do controle da expressão gênica de citocinas pró inflamatórias mediado pela IL-10. Participação da IL-10 na modulação da resposta inflamatória exercida pela glutamina e na restrição alimentar / Proinflammatory cytokines gene expression control mediated by IL-10. Participation of IL-10 on inflammatory response exerted by glutamine and dietary restriction

Oliveira, Dalila Cunha de

10 October 2017

O desenvolvimento de uma resposta imune adequada é um processo extremamente importante para a manutenção da homeostase do organismo. Uma série de processos são desencadeados a partir do primeiro contato com micro-organismos patógenos até a efetivação da resposta imune de memória. Todos esses processos envolvem a participação e a complexa atuação de mediadores como as citocinas inflamatórias e também citocinas regulatórias, que exercerão efeitos controlando o processo inflamatório. Diversos mecanismos moleculares, subjacentes à resposta inflamatória, ainda não estão totalmente compreendidos, como por exemplo o controle da expressão de genes inflamatórios exercido pela IL-10. Os processos envolvidos na resposta inflamatória são mantidos às custas do consumo de nutrientes, dentre eles podemos destacar o aminoácido glutamina, que atua em nível molecular, fornecendo nitrogênio para a formação do material genético e fonte energética para determinadas células do sistema imunológico como os macrófagos. Portanto, neste trabalho, investigamos os efeitos da IL-10 na modificação de nucleossomos, evidenciando o papel dessa citocina em regular a expressão de genes inflamatórios em macrófagos. Avaliamos também a função da glutamina, modulando a expressão de RNAm de citocinas inflamatórias e regulatórias dessas células. E por último, desenvolvemos um modelo de restrição alimentar em camundongos, nos quais avaliamos os efeitos desse modelo considerando-se alguns aspectos hematológicos e estudamos as alterações na resposta inflamatória em células esplênicas e do peritônio, bem como avaliamos a suplementação de glutamina in vitro na produção das citocinas (IL-12, TNF-alfa, IL-10) e a expressão do fator de transcrição NFkB. Os resultados compilados mostraram que a IL-10 leva a uma rápida redução da acetilação de nucleossomos, modulando a arquitetura da cromatina de genes inflamatórios como a IL-12. A glutamina modula a expressão de citocinas inflamatórias, regulando positivamente a expressão de IL-10 e Interferon beta. E a restrição alimentar induz a redução de citocinas proinflamatórias (IL-12 e TNF-α), influenciadas pelo aumento da produção de IL-10 e finalmente a suplementação com glutamina não interfere nesses parâmetros nas células peritoneiais e esplênicas do grupo submetido à restrição alimentar. Conclusão: a IL-10 modula a expressão gênica através da modificação de nucleossomos em macrófagos derivados da medula; a glutamina modula a expressão de IL-10 inibindo a resposta inflamatória, e a restrição alimentar modula alguns aspectos hematológicos e possui propriedades anti-inflamatórias. / The development of an appropriate immune response is an important process to the organism\'s homeostatic maintenance. A series of processes are triggered upon the very first contact with pathogens, up to the immunological memory establishment. These processes implicate in the participation of complex mediators, such as inflammatory and regulatory cytokines that will control the inflammatory process. Some mechanisms underlying the inflammatory response are not totally understood, the control of inflammatory genes exerted by IL-10 is an example. The processes involved in the inflammatory response are kept with nutrients expense, among these nutrients we can highlight the amino acid glutamine. It acts in a molecular level, supplying nitrogen to genetic material formation and as an energy supply for immune cells such as macrophages. Thus, we investigated the IL-10 effects on nucleosome modifications evidencing this cytokine role regulating inflammatory genes expression in macrophages. We also evaluated glutamine functions modulating inflammatory and regulatory cytokines mRNA expression on these cells. Ultimately, we developed a dietary restriction animal model where we evaluated it\'s effects on selected haematological aspects, analyzing the alteration in the inflammatory response of splenic and peritoneal cells. We also evaluated in vitro glutamine supplementation assessing cytokines production (IL-12, TNF-α, and IL-10) and the expression of NFkB transcription factor. The compiled results a expressive reduction in nucleosome acetylation modifying the chromatin architecture of inflammatory genes such as IL-12 and IL-6. Glutamine modulates inflammatory cytokines gene expression upregulating the expression of IL-10 and interferon beta. The dietary restriction reduces proinflammatory cytokines production (IL-12 and TNF-α), these results are influenced by the upregulated IL-10 production, glutamine supplementation have no effect on these parameters in the dietary restriction group. In conclusion, we can infer that IL-10 modulates gene expression trough nucleosome modification in bone marrow derived macrophages, glutamine has a potential effect on IL-10 expression, inhibiting the inflammatory response and dietary restriction modifies hematological parameters, presenting anti-inflammatory properties.

Citocinas

Cytokines

Dietary restriction

Epigenética

Epigenetics

Glutamina

Glutamine

Immune response

Resposta imune

Restrição alimentar

Recherche de nouvelles protéines humaines se liant à l'ADN méthylé / Investigation for new human metyl-CpG-binding proteins

Joulie, Michaël

26 September 2011

L'épigénétique est un composant essentiel du fonctionnement des génomes eucaryotes. Les divers phénomènes épigénétiques modifient l’état chromatinien et participent à la plasticité du génome, mais aussi au maintien de son identité fonctionnelle à travers les générations cellulaires. Parmi ces processus, la méthylation de l’ADN joue un rôle fondamental dans la régulation de l’expression des gènes.Chez les mammifères, la méthylation de l'ADN est associée à la répression transcriptionnelle, et elle remplit au moins trois fonctions essentielles. Premièrement, elle permet de réprimer les séquences répétées afin de préserver l’intégrité du génome. Deuxièmement, la méthylation contrôle l’expression des gènes soumis à l’empreinte parentale, qui sont des régulateurs cruciaux du développement et de la vie adulte. Enfin, la méthylation permet de réprimer certains gènes tissu-spécifiques dans les organes où ils doivent être silencieux. En plus de ces rôles physiologiques, la méthylation est liée au cancer. En effet, des patrons de méthylation anormaux sont fréquemment observés dans les cellules tumorales, et ces anomalies participent à la transformation cellulaire par plusieurs mécanismes.La méthylation exerce ces effets par l'intermédiaire de protéines dédiées, qui reconnaissent spécifiquement l'ADN méthylé et contrôlent la transcription en modulant la chromatine. Trois familles de protéines liant l'ADN méthylé sont connues chez les mammifères, et elles totalisent entre elles neuf membres. De nombreux arguments suggèrent que cette liste est encore incomplète, et que des protéines humaines liant l'ADN méthylé restent à découvrir. Dans cette optique, nous avons opté pour deux types d’approches distinctes, une approche basée sur la littérature et une approche génétique. L’étude des protéines candidates ne nous a pas permis d’identifier de nouvelles protéines liant l’ADN méthylé et l’approche génétique par phage display a révélé deux protéines intéressantes, CHD3 et HMGB1 qui doivent désormais être validées par des approches in vivo et in vitro.Par ailleurs, nous avons entrepris l’étude de la régulation des éléments répétés par la protéine Zbtb4 chez la souris. Les expériences préliminaires indiquent une possible régulation des satellites mineurs par Zbtb4. Le rôle de cette régulation sera, par la suite, approfondi. / Epigenetic phenomena are key contributors to the function of eukaryotic genomes. These processes act on chromatin, and they are used to render the genome dynamic, but also stable throughout successive rounds of cell division. Among epigenetic processes, DNA methylation is especially well known for its role in the regulation of gene expression.In mammals, DNA methylation is strongly correlated with transcriptional repression, and fulfills at least three essential roles. First, it maintains repeated sequences transcriptionally silenced, thus ensuring the stability of the genome. Second, it is responsible for the proper regulation of parentally imprinted genes, which are crucial regulators of embryonic development and adult life. Finally, DNA methylation ensures that some tissue-specific genes are kept inactive in the organs in which they should be repressed. Besides these roles in the physiology of normal cells, DNA methylation has strong links to cancer. Indeed the pattern of DNA methylation on the genome is frequently altered in cancer cells, and these anomalies contribute to transformation by several mechanisms.DNA methylation does not control transcription directly, but instead acts via a set of dedicated proteins that specifically recognize methylated DNA and repress transcription by acting at the chromatin level. At present, three families of such proteins, totalling 9 members altogether, are known in humans. However, several lines of evidence suggest that the list is not exhaustive, and that other human proteins that bind methylated DNA remain to be found. This was the goal of the current project.To this end, we opted for two distinct types approaches, an approach based on literature and a genetic approach. The study of candidate proteins does not allow us to identify new methylated DNA binding proteins and the genetic approach by phage display revealed two proteins of interest, HMGB1 and CHD3 that must now be validated by in vivo and in vitro approaches.Furthermore, we studied the regulation of DNA repeats by Zbtb4 in mice. Preliminary results show a regulation of minor satellites by Zbtb4. The role of this regulation will be analyse further in the future.

Épigénétique

Méthylation de l’ADN

MBP

Phage display

Epigenetics

DNA methylation

Methyl binding proteins

Phage display

Engineering Open Chromatin with Synthetic Pioneer Factors: Enhancing Mammalian Transgene Expression and Improving Cas9-Mediated Genome Editing in Closed Chromatin

January 2019

abstract: Chromatin is the dynamic structure of proteins and nucleic acids into which eukaryotic genomes are organized. For those looking to engineer mammalian genomes, chromatin is both an opportunity and an obstacle. While chromatin provides another tool with which to control gene expression, regional density can lead to variability in genome editing efficiency by CRISPR/Cas9 systems. Many groups have attempted to de-silence chromatin to regulate genes and enhance DNA's accessibility to nucleases, but inconsistent results leave outstanding questions. Here, I test different types of activators, to analyze changes in chromatin features that result for chromatin opening, and to identify the critical biochemical features that support artificially generated open, transcriptionally active chromatin. I designed, built, and tested a panel of synthetic pioneer factors (SPiFs) to open condensed, repressive chromatin with the aims of 1) activating repressed transgenes in mammalian cells and 2) reversing the inhibitory effects of closed chromatin on Cas9-endonuclease activity. Pioneer factors are unique in their ability to bind DNA in closed chromatin. In order to repurpose this natural function, I designed SPiFs from a Gal4 DNA binding domain, which has inherent pioneer functionality, fused with chromatin-modifying peptides with distinct functions. SPiFs with transcriptional activation as their primary mechanism were able to reverse this repression and induced a stably active state. My work also revealed the active site from proto-oncogene MYB as a novel transgene activator. To determine if MYB could be used generally to restore transgene expression, I fused it to a deactivated Cas9 and targeted a silenced transgene in native heterochromatin. The resulting activator was able to reverse silencing and can be chemically controlled with a small molecule drug. Other SPiFs in my panel did not increase gene expression. However, pretreatment with several of these expression-neutral SPiFs increased Cas9-mediated editing in closed chromatin, suggesting a crucial difference between chromatin that is accessible and that which contains genes being actively transcribed. Understanding this distinction will be vital to the engineering of stable transgenic cell lines for product production and disease modeling, as well as therapeutic applications such as restoring epigenetic order to misregulated disease cells. / Dissertation/Thesis / Doctoral Dissertation Biological Design 2019

Biomedical engineering

Molecular biology

Biogeochemistry

chromatin

CRISPR

epigenetics

mammalian synthetic biology

MYB

transgene

DNA Methylation and Gene Expression Profiling for Parkinson’s Biomarker Discovery

January 2019

abstract: Parkinson’s disease (PD) is a progressive neurodegenerative disorder, diagnosed late in the disease by a series of motor deficits that manifest over years or decades. It is characterized by degeneration of mid-brain dopaminergic neurons with a high prevalence of dementia associated with the spread of pathology to cortical regions. Patients exhibiting symptoms have already undergone significant neuronal loss without chance for recovery. Analysis of disease specific changes in gene expression directly from human patients can uncover invaluable clues about a still unknown etiology, the potential of which grows exponentially as additional gene regulatory measures are questioned. Epigenetic mechanisms are emerging as important components of neurodegeneration, including PD; the extent to which methylation changes correlate with disease progression has not yet been reported. This collection of work aims to define multiple layers of PD that will work toward developing biomarkers that not only could improve diagnostic accuracy, but also push the boundaries of the disease detection timeline. I examined changes in gene expression, alternative splicing of those gene products, and the regulatory mechanism of DNA methylation in the Parkinson’s disease system, as well as the pathologically related Alzheimer’s disease (AD). I first used RNA sequencing (RNAseq) to evaluate differential gene expression and alternative splicing in the posterior cingulate cortex of patients with PD and PD with dementia (PDD). Next, I performed a longitudinal genome-wide methylation study surveying ~850K CpG methylation sites in whole blood from 189 PD patients and 191 control individuals obtained at both a baseline and at a follow-up visit after 2 years. I also considered how symptom management medications could affect the regulatory mechanism of DNA methylation. In the last chapter of this work, I intersected RNAseq and DNA methylation array datasets from whole blood patient samples for integrated differential analyses of both PD and AD. Changes in gene expression and DNA methylation reveal clear patterns of pathway dysregulation that can be seen across brain and blood, from one study to the next. I present a thorough survey of molecular changes occurring within the idiopathic Parkinson’s disease patient and propose candidate targets for potential molecular biomarkers. / Dissertation/Thesis / Doctoral Dissertation Molecular and Cellular Biology 2019

Molecular biology

Cellular biology

Genetics

Alzheimer's

DNA methylation

Epigenetics

Gene expression

Longitudinal

Parkinson's

Caractérisation structurale et fonctionnelle de l’ARN long non codant MEG3 / Structure-functional studies on lncRNA MEG3

Uroda, Tina

09 May 2019

Les ARNs long non codants (ARNlnc) jouent un rôle clé dans les processus cellulaires vitaux, notamment le remodelage de la chromatine, la réparation de l'ADN et la traduction. Cependant, la taille et la complexité des ARNlnc présentent des défis sans précédent pour les études moléculaires mécanistiques, de sorte qu'il s'est avéré difficile jusqu'à présent de relier l'information structurelle à la fonction biologique pour les ARNlnc.Le gène 3 humain exprimé maternellement (de l’anglais "maternally expressed gene 3", MEG3), est un ARNlnc abondant, soumis à empreinte parentale et épissé alternativement. Pendant l'embryogenèse, MEG3 contrôle les protéines Polycomb, régulant la différenciation cellulaire, et dans les cellules adultes, MEG3 contrôle p53, régulant la réponse cellulaire aux stress environnementaux. Dans les cellules cancéreuses, MEG3 est régulé négativement, mais la surexpression ectopique de MEG3 réduit la prolifération incontrôlée, ce qui prouve que MEG3 agit comme un suppresseur de tumeur. Les données suggèrent que les fonctions de MEG3 pourraient être régulées par la structure de MEG3. Par exemple, on pense que MEG3 se lie directement aux protéines p53 et Polycomb. De plus, les différents variants d'épissage de MEG3, qui comprennent différents exons et possèdent ainsi des structures potentiellement différentes, présentent des fonctions différentes. Enfin, la mutagenèse par délétion, basée sur une structure de MEG3 prédit in silico, a permis d’identifier un motif MEG3 supposé structuré impliqué dans l'activation de p53. Cependant, au début de mes travaux, la structure expérimentale de MEG3 était inconnue.Pour comprendre la structure et la fonction de MEG3, j'ai utilisé des sondes chimiques in vitro et in vivo pour déterminer la structure secondaire de deux variants humains de MEG3 qui diffèrent par leurs niveaux d'activation de p53. À l'aide d'essais fonctionnels dans les cellules et de mutagenèse, j'ai systématiquement analysé la structure de MEG3 et identifié le noyau activant p53 dans deux domaines (D2 et D3) qui sont conservés structuralement dans les variants humains et conservés dans l’évolution chez les mammifères. Dans D2-D3, les régions structurales les plus importantes sont les hélices H11 et H27, car dans ces régions, j’ai pu supprimer l'activation de p53 grâce à des mutations ponctuelles, un degré de précision jamais atteint pour les autres ARNlnc jusqu’ici. J'ai découvert de manière surprenante que H11 et H27 sont reliés par des boucles connectées l’une à l’autre (de l’anglais "kissing loops") et j'ai confirmé l'importance fonctionnelle de ces interactions de structure tertiaire à longue distance par mutagenèse compensatoire. Allant au-delà de l’état de l’art, j'ai donc essayé de visualiser la structure 3D d’une isoforme de MEG3 longue de 1595 nucléotides, par diffusion de rayons X à petit angle (SAXS), microscopie électronique (EM) et microscopie à force atomique (AFM). Alors que le SAXS et l’EM sont limités par des défis techniques actuellement insurmontables, l’imagerie par AFM m’a permis d’obtenir la première structure 3D à basse résolution de MEG3 et de révéler son échafaudage tertiaire compact et globulaire. Plus remarquable encore, les mêmes mutations qui perturbent la connexion entre les «boucles» H11-H27 et qui inhibent la fonction de MEG3, perturbent aussi la structure 3D de cet ARNlnc, fournissant ainsi le premier lien direct entre la structure 3D et la fonction biologique pour un ARNlnc.Sur la base de mes découvertes, je peux donc proposer un mécanisme de l’activation de p53 basé sur la structure de MEG3, avec des implications importantes pour la compréhension de la cancérogenèse. Plus généralement, mes travaux prouvent que les relations structure-fonction des ARNlnc peuvent être disséquées avec une grande précision et ouvrent la voie à des études analogues visant à obtenir des informations mécanistes pour de nombreux autres ARNlnc d’importance médicale. / Long non-coding RNAs (lncRNAs) are key players in vital cellular processes, including chromatin remodelling, DNA repair and translation. However, the size and complexity of lncRNAs present unprecedented challenges for mechanistic molecular studies, so that connecting structural information with biological function for lncRNAs has proven difficult so far.Human maternally expressed gene 3 (MEG3) is an abundant, imprinted, alternatively-spliced lncRNA. During embryogenesis MEG3 controls Polycomb proteins, regulating cell differentiation, and in adult cells MEG3 controls p53, regulating the cellular response to environmental stresses. In cancerous cells, MEG3 is downregulated, but ectopic overexpression of MEG3 reduces uncontrolled proliferation, proving that MEG3 acts as a tumour suppressor. Evidence suggests that MEG3 functions may be regulated by the MEG3 structure. For instance, MEG3 is thought to bind p53 and Polycomb proteins directly. Moreover, different MEG3 splice variants, which comprise different exons and thus possess potentially different structures, display different functions. Finally, deletion mutagenesis based on a MEG3 structure predicted in silico identified a putatively-structured MEG3 motif involved in p53 activation. However, at the beginning of my work, the experimental structure of MEG3 was unknown.To understand the MEG3 structure and function, I used chemical probing in vitro and in vivo to determine the secondary structure maps of two human MEG3 variants that differ in their p53 activation levels. Using functional assays in cells and mutagenesis, I systematically scanned the MEG3 structure and identified the p53-activating core in two domains (D2 and D3) that are structurally conserved across human variants and evolutionarily conserved across mammals. In D2-D3, the most important structural regions are helices H11 and H27, because in these regions I could tune p53 activation even by point mutations, a degree of precision never achieved for any other lncRNA to date. I surprisingly discovered that H11 and H27 are connected by “kissing loops”, and I confirmed the functional importance of these long-range tertiary structure interactions by compensatory mutagenesis. Going beyond state-of-the-art, I thus attempted to visualize the 3D structure of a 1595-nucleotide long MEG3 isoform by small angle X-ray scattering (SAXS), electron microscopy (EM), and atomic force microscopy (AFM). While SAXS and EM are limited by currently-insurmountable technical challenges, single particle imaging by AFM allowed me to obtain the first low resolution 3D structure of MEG3 and reveal its compact, globular tertiary scaffold. Most remarkably, functionally-disrupting mutations that break the H11-H27 “kissing loops” disrupt such MEG3 scaffold, providing the first direct connection between 3D structure and biological function for an lncRNA.Based on my discoveries, I can therefore propose a structure-based mechanism for p53 activation by human MEG3, with important implications in understanding carcinogenesis. More broadly, my work serves as proof-of-concept that lncRNA structure-function relationships can be dissected with high precision and opens the field to analogous studies aimed to gain mechanistic insights into many other medically-relevant lncRNAs.

Structure d’ARN

Épigénétique

Biologie structurale intégrée

Long non coding RNAs

RNA structure

Epigenetics

Integrated structural biology

570

Dynamics of epigenome and 3D genome in hematopoietic stem cell development

Chen, Changya

15 December 2017

Hematopoietic stem cell (HSC) development is accompanied by dynamic changes in the transcriptional program. How the corresponding transcriptional programs are related to the epigenetic mechanism is poorly understood. To fill this gap, we first profiled the transcriptomes and epigenomes using RNA-Seq and ChIP-Seq for five key developmental stages of HSC emergence in the mouse embryo. Using epigenetic markers, we identified novel 12,000~17,000 enhancers for each developmental stage. We applied a computational tool to link those enhancers to their target genes. Systematical analysis of enhancer-promoter (EP) pairs using network-based strategy reveals multiple novel key transcription factors for early specification of HSC in the mouse embryo. Second, we compared the 3D genome organization, epigenomes, and transcriptome of fetal and adult HSCs in the mouse. We found that higher-order genome structures are largely conserved between fetal and adult HSCs, including chromosomal compartments and topologically associating domains (TADs). However, chromatin interactions within TADs exhibit substantial differences. We found that promoters within 23% (242/1039) of TADs undergo interaction changes. Transcription factor motif analysis of HSC-specific enhancer-promoter loops suggests a role of KLF1 in mediating condition-specific enhancer looping and regulation of genes involved in cell cycle. Our result provides a comprehensive view of the differences in 3D genome organization, epigenome, and transcriptome between fetal and adult HSCs.

ChIP-Seq

enhancer-promoter interaction

epigenetics

genome organization

hematopoietic stem cells

transcriptional program

Genetics

Identification of a tissue-specific cofactor of polycomb repressive complex 2 / Identification d'un nouveau cofacteur du complexe polycomb repressive complex 2 spécifique aux gonades

Ragazzini, Roberta

25 September 2017

Répression des genes par le dépôt de la marque H3K27me3. Divers cofacteurs contrôlent sa fonction dans des cellules de différentes origines, comme les gametes. Au cours de ma thèse, j'ai utilisé des modèles murins ou un tag a été introduit dans les gènes Ezh2 et Ezh1, j'ai isolé des extraits nucléaires de testicules adultes entiers et identifié un nouveau polypeptide interagissant avec PRC2. Ce dernier est spécifiquement exprimé dans les gonades et sa fonction est inconnue. J'ai confirmé son interaction avec PRC2 et montré qu'il pourrait recruter PRC2 à la chromatine. Grâce à un modèle de souris knock-out, j'ai démontré que la protéine est nécessaire pour la fertilité féminine, alors que son ablation apporte une augmentation globale de la marque associée à PRC2, dans les cellules germinales masculines avec peu de conséquences sur la fertilité. J'ai également contribué à la caractérisation de l'interaction entre le long ARN non-codant HOTAIR et PRC2. Nombreux ARNnc ont été proposés pour moduler l'action des complexes modifiant la chromatine. Avec l'aide d'un nouveau système de recrutement artificiel d'ARN, l'expression induite par HOTAIR provoque une répression transgénique indépendamment de PRC2. La surexpression forcée de HOTAIR a également peu d'impact sur le transcriptome dans des cellules cancéreuses. En conclusion, la liaison PRC2 à l'ARN n'est pas requise pour le ciblage de la chromatine. / The Polycomb Repressive Complex 2 (PRC2) plays an essential role in development by maintaining gene repression through the deposition of H3K27me3. A variety of cofactors have been shown to control its function in cells of various origins however little is known about PRC2 regulation during gametogenesis. During my PhD, I took advantage of murine models where Ezh2 and Ezh1 were knocked-in, I isolated nuclear extracts from whole adult testis and, identified a new polypeptide interacting with PRC2. This protein is specifically expressed in gonads, is of unknown function and does not contain any conserved domain. I have confirmed its interaction with PRC2, identified the domain of interaction with PRC2 and shown that it could tether PRC2 to chromatin. Thanks to a knockout mouse model, I demonstrated that the protein is required for female fertility, whereas its ablation brings to a global increase of H3K27me3 PRC2-associated mark in male germ cells with little consequences on male fertility. I also contributed to the characterization of the interplay between the long non-coding RNA (lncRNA) HOTAIR and PRC2 complex. Many lncRNAs have been proposed to modulate chromatin-modifying complexes action on chromatin. With the help of novel RNA-tethering system, HOTAIR inducible expression causes transgene repression independently from PRC2. Forced overexpression of HOTAIR also has little impact on transcriptome in breast cancer cells. Generally, PRC2 binding to RNA is not required for chromatin targeting. Taken together these results shed light to the mechanism of a new-identified cofactor regulating PRC2 in the gonads and contribute to dissect PRC2-RNA relationship at molecular level.

Epigénètique

Polycomb

Cellules germinales

Gametogénèse

Long ARN non-Codants

Fertilité

Mammifères

Cancer

Epigenetics

Polycomb

Germ cells

572.8

Regulatory crosstalk and interference between the PCB 126 stimulated AHR and hypoxia stimulated HIF-1α signaling pathways

Vorrink, Sabine Ulrike

01 May 2014

Polychlorinated biphenyls (PCBs) are synthetic organic chemicals that persist in the environment and are known to be carcinogenic to humans. Virtually all of the deleterious effects of PCB 126, the most potent dioxin-like PCB, are mediated by the aryl hydrocarbon receptor (AhR). By means of the common cofactor ARNT, the AhR signaling pathway can crosstalk with the hypoxia signaling pathway. Regulated by hypoxia-inducible factors (HIFs), the hypoxia pathway mediates responses to environments of reduced oxygen availability (hypoxia). This dissertation specifically examines the crosstalk and interference between these two pathways in the context of PCB 126 exposure. The results of this dissertation show that the antagonistic relationship between the AhR and hypoxia signaling pathways affects the function and responses of both AhR and HIF-1Α. We provide substantial evidence that ARNT is indeed a crucial factor in both the AhR and HIF-1Α signaling pathways. Furthermore, this dissertation examines regulatory mechanisms involved in AhR-mediated gene expression and identifies epigenetic regulation as a critical factor in AhR target gene expression. In summary, this dissertation helped to improve the understanding of mechanisms of PCB 126 toxicity. Understanding the detrimental biological effects of these ubiquitous environmental pollutants might ultimately have significant implications for human health.

aryl hydrocarbon receptor

epigenetics

hepatocytes

hypoxia-inducible factor

oxygen sensing

polychlorinated biphenyls

Toxicology