1 |
New model for long-range chromatin reorganisation upon enhancer-driven gene activationBenabdallah, Suzanne Nezha January 2017 (has links)
Enhancers are non-coding DNA sequences which are able to activate the expression of a gene in a specific tissue manner and at a precise stage during embryonic development. First identified almost 40 years ago, our growing understanding of enhancers has transformed the concept of gene regulation to recognise the key role of these sequences in the expression of many genes. Moreover, the identification of human diseases caused by genetic variation in non-coding enhancer elements highlights the importance of characterising enhancers in order to understand human disease. However, enhancers are often located far from the promoter they influence and the mechanisms through which enhancers govern gene expression remain unclear. The most widely accepted model for the action of distal enhancers involves the formation of a chromatin loop, in which the enhancer and promoter physically interact at the loop base. The kinetics or molecular basis for the formation of enhancer/promoter loops is unknown and it remains unclear whether this mechanism of enhancer communication is universal, or indeed whether it is the most pervasive. The aim of my PhD is to investigate further the mechanism of action of distal enhancers in the regulation of developmental genes. Using chromatin profiling during the differentiation of embryonic stem cells to neural progenitor cells in order to see which Shh enhancer is active in neural progenitor cells (NPCs), I report the identification of a novel long-range enhancer for Shh - Shh-Brain- Enhancer-6 (SBE6) – that is located 100kb upstream of Shh and that is required for the proper induction of Shh expression during a neural differentiation programme. SBE6 enhances Shh expression during the differentiation of neural progenitor cells (NPCs) and is active in the brain of developing zebrafish and mouse embryos. Next, using a super-resolution 3D-FISH based approach to study the enhancer-driven activation of the Sonic hedgehog gene (Shh) I have identified a novel mechanism of longrange enhancer regulation that is incompatible with the looping model. Instead, gene activation is associated with an increase in nuclear distance between Shh and Shh-Brain- Enhancers. Using a synthetic biology approach I have determined that the chromatin unfolding is regulated specifically by the Shh-Brain-Enhancer and is mediated by the recruitment of transcription factor SIX3 and Poly (ADP-Ribose) Polymerase 1. Chromatin decondensation upon gene activation has been observed previously in Drosophila polytene chromosomes. I suggest an analogous decompaction is driven by Shh-Brain-Enhancer to promote the activation of Shh in mouse neural progenitor cells. This ‘chromatin unfolding’ model represents a new mechanism of long-range enhancer-promoter communication in addition to the looping and tracking models.
|
2 |
The role of elements binding CTCF and cohesin in directing tissue-specific enhancer activityHanssen, Lars January 2016 (has links)
Distal enhancer elements regulate the tissue-specific expression of their target genes via the establishment of physical interactions with the gene promoter. In mice, a cluster of five enhancers, jointly classified as a super-enhancer, specifically upregulate α-globin gene expression during erythroid differentiation. Aside from the Nprl3 gene, whose promoter is located inside this enhancer region, expression-levels of other genes within a short distance (<,50kb) of the enhancer region are not affected by the activation of the enhancer in erythroid cells, despite being located within the same sub-TAD in erythroid cells. The CCCTC-binding factor (CTCF) is implicated in the organisation of chromosome topology through the formation of interactions between its binding sites in an orientation-dependent manner. In this thesis, I demonstrate that CTCF functions in vivo as a boundary to maintain α-globin enhancer-promoter specificity in erythroid cells. The study of the local chromatin architecture by next-generation Capture-C reveals that α-globin enhancer and promoter interactions are constrained to a compartment of roughly 70kb. The unidirectional interaction profiles of the α-globin enhancers are delimited by the interactions between two genomic domains flanking the α-globin cluster. Further investigation shows that each of these domains contains several CTCF binding sites orientated in tandem, such that CTCF binding orientation between domains is convergent. Although CTCF binding across the α-globin locus is identical between mouse embryonic stem (ES) cells and erythroid cells, interaction between these domains occurs only in erythroid cells suggesting it is dependent on the formation of tissue-specific α-globin enhancer-promoter interactions. By generating a series of mouse models, deleting CTCF binding sites at the α-globin enhancers singly and in combination, I show that the deletion of two CTCF binding sites directly flanking the enhancer cluster results in a shift in interactions between flanking domains, away from the enhancer region. This leads to an expansion of enhancer interactions to include two genes directly upstream of the α-globin enhancers: Rhbdf1 and Mpg. Despite the Rhbdf1 gene being subject to polycomb group protein-mediated gene repression in erythroid cells, ablation of CTCF binding results in increased interactions between both the Rhbdf1 and Mpg gene promoters and the α-globin enhancers and concurrent strong transcriptional upregulation of both genes. The Rhbdf1 gene promoter acquires the active histone mark H3K4me3, but doesn't lose Polycomb Repressive Complex 2 (PRC2) mark H3K27me3 or binding of its catalytic component Ezh2. Despite the presence of this repressive mark, robust levels of Rhbdf1 expression are detected at levels higher than those in ES cells where this gene is actively expressed under the influence of its own enhancer. I conclude that regulation of the direction of enhancer interactions by CTCF is required for the promoter specificity of enhancers and the maintenance of transcriptional states of nearby genes.
|
3 |
The genomic health of human pluripotent stem cellsHenry, Marianne Patricia January 2018 (has links)
Human pluripotent stem cells are increasingly used for cell-based regenerative therapies worldwide, with the use of embryonic and induced pluripotent stem cells as potential treatments for a range of debilitating and chronic conditions. However, with the level of chromosomal aneuploidies the cells may generate in culture, their safety for therapeutic use could be in question. This study aimed to develop sensitive and high-throughput assays for the detection and quantification of human pluripotent stem cell aneuploidies, to assess any changes in their positioning in nuclei, as well as investigate the possible roles of lamins in the accumulation of aneuploidies. Using Droplet Digital PCR™, we optimised the detection of aneuploid cells in a predominantly diploid background. An assay was established for the sensitive detection of up to 1% of mosaicism and was used for the monitoring of low-level chromosome copy number changes across different cell lines, conditions and passages in the human pluripotent stem cells. In addition, fluorescence in-situ hybridisation was used to map genes ALB and AMELX on chromosomes 4 and X, respectively, in karyotype-stable chromosome X aneuploid lymphoblastoid cell lines. Our results demonstrated significant alternations in the gene loci positioning in the chromosome X aneuploid cell lines. Using the same established method, the positioning of ALB and AMELX was monitored, alongside the genomic instability with ddPCR™, in the different human pluripotent stem cell lines, conditions and passage. We demonstrated a highly plastic nuclear organisation in the pluripotent stem cells with many changes occurring within a single passage. Furthermore, these results were not exclusive to a single cell line or condition, regardless of the presence or absence of feeder cells and of passage number, and the flexibility of the chromatin organisation remained throughout the duration of the study. We demonstrated high levels of genomic instability with recurrent gains and losses in the AMELX copy number in the human embryonic stem cells during the course of our study, however no significant changes in their gene loci positioning from these abnormalities were observed. xvi | P a g e Additionally, we observed reduced levels of lamin B2 in the aneuploid lymphoblastoid cell lines and complete loss in some hPSC samples. Our results support recent findings that suggest a link between lamin B2 loss and the formation of chromosome aneuploidies in cell culture. In conclusion, our data demonstrates several key novel findings. Firstly, we have established a sensitive technique for the detection of up to 1% mosaicism, which to our knowledge is the most sensitive assay currently available. Secondly, we showed significant changes in the gene loci positioning between aneuploid and diploid cell lines. Thirdly, utilising our novel ddPCR™ assay, we demonstrated the karyotypical instability of hPCSs with consistent gains and/or loses of gene copy numbers in a short period of time in culture. When studying the effects of different growth conditions, we showed that the karyotypical instability was not exclusive to a single condition or a combination of conditions, and what is more, the karyotypical abnormalities detected were not observed to change the gene positioning of hPSCs significantly, with the genome organisation remaining plastic. Finally, our results support a potential association of lamin B2 loss and karyotypical instability. We conclude that more sensitive and robust techniques need to be readily used by clinicians for the screening of potential therapeutic hPSCs.
|
4 |
Transcription factor binding dynamics and spatial co-localization in human genomeMa, Xiaoyan January 2017 (has links)
Transcription factor (TF) binding has been studied extensively in relation to binding site affinity and chromosome modifications; however, the relationship between genome spatial organisation and transcription factor binding is not well studied. Using the recently available high resolution Hi-C contact map of human GM12878 lymphoblastoid cells, we investigated computationally the genome-wide spatial co-localization of transcription factor binding sites, for both within the same type and between different types. First, we observed a strong positive correlation between site occupancy and homotypic TF co-localization based on Hi-C contacts, consistent with our predictions from biophysical simulations of TF target search. This trend is more prominent in binding sites with weak binding sequences and within enhancers, suggesting genome spatial organisation plays an essential role in determining binding site occupancy, especially for weak regulatory elements. Furthermore, when investigating spatial co-localization between different TFs, we discovered two distinct co-localization networks of TFs in lymphoblastoid cells, one of which is enriched in lymphocyte specific pathways and distal enhancer binding. These two TF networks have strong biases for either the A1 or A2 chromosome subcompartment, but nonetheless are still preserved within each, indicating a potential causal link between cell-type-specific transcription factor binding and chromosome subcompartment segregation. We called 40 pairs of significantly co-localized TFs according to the genome wide Hi-C contact map, which are enriched in previously reported, physical interactions, thus linking TF spatial network to co-functioning. In addition to the above main project, I also worked on a side project to find compute-efficient ways in scaling binding site strength across different TFs based on Position-Weight-Matrices (PWM). While common bioinformatics tools produce scores that can reflect the binding strength between a specific TF and the DNA, these scores are not directly comparable between different TFs. We provided two approaches in estimating a scaling parameter $\lambda$ to the PWM score for different TFs. The first approach uses a PWM and background genomic sequence as input to estimate $\lambda$ for a specific TF, which we applied to show that $\lambda$ distributions for different TF families correspond with their DNA binding properties. Our second method can reliably convert $\lambda$ between different PWMs of the same TF, which allows us to directly compare PWMs that were generated by different approaches.
|
5 |
Characterisation of Nuclear Envelope-Associated Proteins (NEAPs) in Arabidopsis thaliana / Caractérisation des protéines associées à l'enveloppe nucléaire (NEAPs) chez Arabidopsis thalianaDétourné, Gwénaëlle 29 May 2019 (has links)
Au cours de l'évolution, les cellules eucaryotes ont acquis une enveloppe nucléaire (NE) renfermant et protégeant le génome organisé en chromatine, une structure où l'ADN s’enroule autour de protéines histones. La NE est composé de deux membranes : du côté nucléoplasmique, la membrane nucléaire interne (INM) et du côté cytoplasmique, la membrane nucléaire externe. La NE permet la communication entre les deux compartiments par le biais des complexes de pores nucléaires et relie le cytosquelette au nucléosquelette via le complexe LINC (LInker of Nucleoskeleton to Cytoskeleton). Ainsi, le nucléosquelette associé à l'INM est nécessaire pour transmettre des signaux au noyau et induire des changements dans l'organisation de la chromatine et finalement dans l'expression des gènes.Une nouvelle famille de protéines associées à l'enveloppe nucléaire (NEAP),proposées comme nouveaux composants du nucléosquelette de la plante, a récemment été mise en évidence dans la plante modèle Arabidopsis thaliana. Ces protéines sont codées par une famille de trois gènes et sont ciblées vers le noyau via un NLS où elles sont ancrées à l'INM via leur domaine transmembranaire C-terminal. Les protéines AtNEAPs possèdent également plusieurs longs domaines en spirale (coiled-coil) rappelant la structure des lamines chez les animaux. Cette thèse visait à réaliser une analyse fonctionnelle des AtNEAPs à l'aide de lignées mutantes T-DNA et CRISPR/Cas9. L'interactome AtNEAP a été étudié par des approches moléculaires (Yeast Two Hybrid), indiquant des interactions entre AtNEAPs pouvant former des homo- ou hétéro-dimères; ainsi que la localisation et la co-localisation in vivo couplées à de l’imagerie (apFRET), qui ont confirmé les interactions avec le facteur de transcription (TF) AtbZIP18. Les anticorps spécifiques à AtNEAP générés au cours de cette étude ont été utilisés pour confirmer l'expression in vivo. En outre, les résultats ont indiqué que les AtNEAPs font partie du nucléosquelette et jouent un rôle dans l’ancrage des TF à l’INM afin de maintenir la morphologie nucléaire et l’organisation de la chromatine. / During evolution, eukaryotic cells have acquired a nuclear envelope (NE) enclosingand protecting the genome, which is organized in chromatin, a structure wrapping DNAaround histone proteins. The NE is composed of two membranes: on the nucleoplasmic side,the Inner Nuclear Membrane (INM) and on the cytoplasmic side, the Outer NuclearMembrane. The NE allows communication between both compartments through Nuclear PoreComplexes and bridges the cytoskeleton to the nucleoskeleton through the LInker ofNucleoskeleton to Cytoskeleton complex. Thus, the nucleoskeleton associated with the INMis needed to transmit signals to the nucleus and induce changes in chromatin organisation andultimately gene expression.A novel family of NUCLEAR ENVELOPE ASSOCIATED PROTEINS (NEAPs)proposed to be new components of the plant nucleoskeleton has been recently evidenced inthe model plant Arabidopsis thaliana. AtNEAP proteins are encoded by a small gene familycomposed of three genes and are targeted through a nuclear localisation signal to the nucleuswhere they are anchored at the INM through their C-terminal transmembrane domain.AtNEAPs also possess several long coiled-coil domains reminiscent of the lamin structure inanimals. This thesis aimed at performing a functional analysis of AtNEAPs using T-DNAinsertion and CRISPR/Cas9 mutant lines. The AtNEAP interactome was investigated bymolecular approaches (Yeast Two Hybrid), which indicated AtNEAP interactions with eachother to form homo or hetero-dimers; as well as in vivo localisation and co-localisationcoupled to image analyses (apFRET, acceptor photobleaching Fluorescence ResonanceEnergy Transfer), which confirmed interactions with the transcription factor (TF) AtbZIP18.AtNEAP specific antibodies generated during this study were used to confirm expression invivo. Altogether, results indicated that AtNEAPs are part of the nucleoskeleton, with a role inanchoring TFs at the INM to maintain nuclear morphology and chromatin organisation.
|
6 |
Dynamics of 3D chromatin landscapes during sex determinationMota Gómez-Argenté, Irene 23 May 2024 (has links)
Die Geschlechtsbestimmung bei Säugetieren erfolgt über gegensätzliche Netzwerke von ovariellen und testikulären Genen, die recht gut charakterisiert sind. Die epigenetischen Mechanismen, insbesondere diejenigen, die die 3D-Chromatinorganisation beeinflussen, sind jedoch größtenteils unbekannt. Ich habe die 3D-Chromatinlandschaft der Geschlechtsbestimmung in vivo untersucht, indem ich FACS-sortierte embryonale Mausgonadenpopulationen vor und nach der Geschlechtsbestimmung in beiden Geschlechtern analysierte. Dabei wurde eine begrenzte Variation in der dreidimensionalen Chromatindynamik beobachtet, insbesondere bei den Topologically Associating Domains (TADs). Konventionelle Hi-C-Analysemethoden sind hauptsächlich auf vordefinierte 3D-Strukturen ausgerichtet und könnten potenziell andere Veränderungen in der Chromatinorganisation übersehen, die für die Genregulation relevant sein könnten. Um diese Einschränkungen zu überwinden, wurde METALoci eingesetzt - ein innovatives Werkzeug, das Hi-C- und ChIP-seq-Daten integriert und räumliche Autokorrelationsanalyse nutzt, um dreidimensionale Enhancer-Hubs im gesamten Genom zu identifizieren. METALoci zeigte eine deutliche Umverdrahtung von Chromatininteraktionen während der Geschlechtsbestimmung, die die regulatorischen Landschaften von Hunderten von Genen beeinflusste. Darüber hinaus führte die Vorhersagekraft von METALoci in Kombination mit funktionalen Validierungen an transgenen Mäusen zur Identifizierung eines neuen Fgf9-regulatorischen Hubs. Die Deletion dieses Hubs führte zu teilweisem Geschlechtsumkehr von männlich zu weiblich, mit einer Hochregulierung ovarieller spezifischer Marker und der Einleitung der Meiose. So erweist sich die räumliche Autokorrelationsanalyse als eine effektive Strategie zur Identifizierung von regulatorischen Netzwerken, die mit biologischen Prozessen verbunden sind, und zur anschließenden Charakterisierung der funktionalen Rolle des dreidimensionalen Genoms. / Mammalian sex is determined by opposing networks of ovarian and testicular genes that
are relatively well characterized. Yet, the epigenetic mechanisms governing sex determi-
nation, in particular those involving 3D chromatin organization, remain largely unknown.
This gap of knowledge constrains our understanding of a fundamental process for species
reproduction and perpetuation. Here, I explored the 3D chromatin landscape of sex deter-
mination in vivo, by profiling FACS-sorted embryonic mouse gonadal populations, prior
and after sex determination, in both sexes. Using conventional Hi-C analysis tools, limited
variation in the 3D chromatin dynamics was observed, especially at the level of Topolog-
ically Associating Domains (TADs). This contrasts with the broad transcriptional differ-
ences occurring during sex determination. Yet, conventional Hi-C analysis methodologies
are largely focused on predefined 3D structures, potentially overlooking other types of
changes in chromatin organization that might be relevant for gene regulation. To ad-
dress these limitations, METALoci was applied- an innovative tool that integrates Hi-C
and ChIP-seq data and relies on spatial auto-correlation analysis to identify 3D enhancer
hubs distributed throughout the genome. METALoci uncovered a prominent rewiring
of chromatin interactions during sex determination, affecting the regulatory landscapes
of hundreds of genes. Furthermore, METALoci ’s predictive capacity, in combination with
functional validations in transgenic mice led to the identification of a novel Fgf9 regulatory
hub, which deletion resulted in partial male-to-female sex reversal with the upregulation of ovarian-specific markers and the initiation of meiosis. Thus, spatial auto-correlation anal-
ysis proves to be an effective strategy to identify regulatory networks linked to biological
processes and to subsequently characterize the functional role of the 3D genome.
|
7 |
Specificity and roles of chromatin organisation in mouse embryonic stem cells and dopaminergic neuronsHarabulă, Izabela-Cezara 09 February 2024 (has links)
Die dreidimensionale Organisation des Chromatins verändert sich während der Zelldifferenzierung als Reaktion auf die Umgebung und ist bei Krankheiten oftmals verändert. Das Zusammenspiel zwischen Chromatinzustand, Chromatinorganisation und Genexpression ist insbesondere bei Neuronen nach wie vor nur geringfügig erforscht.
In dieser Arbeit untersuchte ich die Organisation und den Zustand des Chromatins im Zusammenhang mit der Transkription in embryonalen Stammzellen (ESCs) und dopaminergen Neuronen (DNs) der Maus. Dazu habe ich die Organisation des Chromatins mittels Genome Architecture Mapping (GAM) bestimmt und zelltypspezifische Genexpressionsprofile zur Klassifizierungen von Promotoren, Enhancern und Super-Enhancern (SEs) erzeugt. Anschließend habe ich diese linearen Chromatinprofile mit den verschiedenen Stufen der Chromatinorganisation kombiniert und konnte so Unterschiede zwischen den 3D-Genomstrukturen von ESCs und DNs aufzeigen. Zudem konnte ich verstärkt Dreifach-Wechselwirkungen zwischen zelltypspezifischen SEs und/oder exprimierten Genen nachweisen, die bei DNs besonders oft neuronale Signalgene darstellen und oftmals bei neurologischen Störungen betroffen sind. Ich fand auch heraus, dass die Grenzen topologisch assoziierter Domänen (TADs) oft mit Genen zur zellulären Differenzierung zusammen fallen und zudem zelltyp-spezifische Eigenschaften aufweisen, was von Bedeutung für zukünftige funktionelle Untersuchungen solcher Grenzen sein dürfte. Schließlich konnte ich zeigen, dass Chromatinkompartimente zwischen ESCs und DNs in Abhängigkeit vom Chromatinzustands und der Chromatinexpression variieren und dass eine Gruppe transkriptionell aktiver DN Gene, die für die neuronale Aktivität wichtig sind, in B-Kompartimenten liegt.
Mit diesen neuen Erkenntnissen erweitert meine Arbeit das Verständnis der Chromatinorganisation bei der Regulierung der Genexpression in Maus ESCs und DNs. / The three-dimensional organization of chromatin changes during cell differentiation, in response to the environment, and is often altered in disease. The interplay between chromatin state, chromatin organization and gene expression remains poorly understood, particularly in neurons.
In this work, I examined the organization and state of chromatin associated with transcription in mouse embryonic stem cells (ESCs) and dopaminergic neurons (DNs). To do this, I determined the organization of chromatin using genome architecture mapping (GAM) and generated cell type-specific gene expression profiles to classify promoters, enhancers and super-enhancers (SEs). I then combined these linear chromatin profiles with the different levels of chromatin organization and was able to show differences between the 3D genome structures of ESCs and DNs. In addition, I was able to demonstrate increased triple interactions between cell type-specific SEs and/or expressed genes, which are often neuronal signalling genes in DNs and affected in neurological disorders. I also found that the boundaries of topologically associated domains (TADs) often coincide with cellular differentiation genes and also exhibit cell type-specific properties, which may be important for future functional studies of such boundaries. Finally, I was able to show that chromatin compartments between ESCs and DNs vary depending on chromatin state and chromatin expression, and that a group of transcriptionally active DN genes important for neuronal activity are located in B compartments.
With these new findings, my work expands the understanding of chromatin organization in regulating gene expression in mouse ESCs and DNs.
|
8 |
Study of the role of plant nuclear envelope and lamina-like components in nuclear and chromatin organisation using 3D imaging / Analyse du rôle de l'enveloppe nucléaire et des composants de la lamina-like dans l'organisation chromatinienne et nucléaire chez les plantes en utilisant de l'imagerie 3DPoulet, Axel 06 June 2016 (has links)
Le complexe linker of nucleoskeleton and cytoskeleton (LINC) est un complexe protéique conservé au cours de l’évolution, reliant les compartiments cytoplasmiques et nucléaires au travers la membrane nucléaire. Bien que les données récentes montrent une de ce complexe dans la régulation de la morphologie nucléaire et de la méiose, son implication dans l’organisation de la chromatine a été moins étudié chez les plantes. Le premier objectif de ce travail était de développer un plugin NucleusJ ImageJ dédié à la caractérisation de la morphologie nucléaire et de l’organisation de la chromatine en 3D. NucleusJ calcul 15 paramètres, y compris la forme et la taille des noyaux ainsi que des objets intra-nuclaires et leur position dans le noyau. Une documentation pour ce programme est disponible pour son utilisation, ainsi que des qu’un jeu données de noyaux pour tester ce programme. Plusieurs améliorations sont en cours pour développer une nouvelle version de ce plugin. Dans une deuxième partie de ce travail, des méthodes d’imagerie 3D ont été utilisées pour étudier la morphologie nucléaire et l’organisation de la chromatine dans les noyaux interphasiques chez Arabidopsis thaliana dans lequel les domaines d’htrochromatique sont groupés en régions detectable appelés chromocentres. Ces chromocentres forment un environnement répressif contribuant la rpression transcriptionnelle de séquences répétées permettant la stabilité du génome. Des mesures quantitatives de la position 3D de chromocentres dans le noyau montrent que la plupart chromocentres sont situés proximité de la périphérie du noyau, mais que cette distance peut être modifiée par le volume nucléaire ou dans certains mutants affectant le complexe LINC. Ce complexe LINC est proposé pour contribuer l’organisation de la chromatine et à son positionnement, de plus la mutation de ce complexe est associée une dérégulation l’inactivation de la transcription, ainsi qu’a une décompaction des séquences hétérochromatiques. La dernière partie de ce travail tire profit de séquences gnomiques disponibles et les données de RNA-seq pour explorer l’évolution des protines de la NE chez les plantes. Au Final, le travail réalisé durant cette thèse associe la génétique, la biologie moléculaire, la bioinformatique et de l’imagerie afin de mieux comprendre la contribution de l’enveloppe nucléaire dans l’organisation de la morphologie du noyaux et de la chromatine et suggère l’implication fonctionnelle du complexe LINC dans ces processus. / The linker of nucleoskeleton and cytoskeleton (LINC) complex is an evolutionarily well-conserved protein bridge connecting the cytoplasmic and nuclear compartments across the nuclear membrane. While recent data supports its function in nuclear morphology and meiosis, its implication for chromatin organisation has been less studied in plants. The first aim of this work was to develop NucleusJ a simple and user-friendly ImageJ plugin dedicated to the characterisation of nuclear morphology and chromatin organisation in 3D. NucleusJ quantifies 15 parameters including shape and size of nuclei as well as intra-nuclear objects and their position within the nucleus. A step-by-step documentation is available for self-training, together with data sets of nuclei with different nuclear organisation. Several improvements are ongoing to release a new version of this plugin. In a second part of this work, 3D imaging methods have been used to investigate nuclear morphology and chromatin organisation in interphase nuclei of the plant model Arabidopsis thaliana in which heterochromatin domains cluster in conspicuous chromatin regions called chromocentres. Chromocentres form a repressive chromatin environment contributing to the transcriptional silencing of repeated sequences a general mechanism needed for genome stability. Quantitative measurements of 3D position of chromocentres in the nucleus indicate that most chromocentres are situated in close proximity to the periphery of the nucleus but that this distance can be altered according to nuclear volume or in specific mutants affecting the LINC complex. Finally, the LINC complex is proposed to contribute at the proper chromatin organisation and positioning since its alteration is associated with the release of transcriptional silencing as well as decompaction of heterochromatic sequences. The last part of this work takes advantage of available genomic sequences and RNA-seq data to explore the evolution of NE proteins in plants and propose a minimal requirement to built the simplest functional nuclear envelope. Altogether, work achieved in this thesis associate genetics, molecular biology, bioinformatics and imaging to better understand the contribution of the nuclear envelope in nuclear morphology and chromatin organisation and suggests the functional implication of the LINC complex in these processes.
|
Page generated in 0.1036 seconds