Etude structurale du complexe de remodelage de la chromatine NuRD et sa sous-unité MBD3 liée à l'ADN / Structural study of the chromatin remodeling complex NuRD and its DNA-binding subunit MBD3

Tabaroni, Rachel

12 December 2018

La régulation de la transcription est un processus dynamique faisant intervenir le recrutement de complexes protéiques impliqués dans le remodelage de la chromatine. Parmi eux, mon travail s’est focalisé sur le complexe NuRD (Nucleosome Remodeling and histone Deacetylation) et sa sous-unité de liaison à l’ADN CpG MBD3. Pour cela une approche de biologie structurale intégrative combinant la préparation biochimique, la caractérisation biophysique et l’étude structurale par cryo-EM et cristallographie aux rayons-X a été mise en place. Les caractérisations biophysiques de MBD3 ont permis de mettre en évidence son interaction avec un ADN non-modifié CpG et des cristaux diffractant jusqu’à 3.9 Å ont été obtenu. De plus la région désordonnée en aval du domaine de liaison a été identifiée et son impact dans la formation de complexe caractérisé. Des cristaux pour les différentes constructions en complexe avec l’ADN ont été obtenus et sont actuellement optimisés. Enfin l’optimisation de la purification et la préparation du complexe, ont permis la visualisation du complexe NuRD et mettent en avant pour la première fois une organisation en domaines du complexe. / Transcription regulation of chromatin is a very dynamic process regulated through the recruitment of chromatin-remodeling complexes. My work focuses on NuRD for Nucleosome remodeling and histones deacetylation complex a 1 MDa multi-subunit protein complex and its subunit MBD3 a CpG-binding protein and more precisely on an integrated biology approach of this molecular assembly and its interaction with DNA. It combines biochemical preparation, biophysical characterization, single particle cryo-eletron microscopy and x-ray crystallography. Biophysical analysis show that MBD domain of MBD3 interacts with unmodified CpG DNA, a crystal diffracting up to 3.9 Å were obtained. Moreover a C-terminal intrinsically disordered region of MBD3 were identified and despite is inherent disorder seems to increase the binding affinity of MBD3 for DNA. Crystals were obtained for both constructs in complex with DNA and are currently optimized.Cryo-EM study of NuRD complex allows us to develop and optimized purification and grids preparation for the visualization of the complex. The present results reveal a domain organization of the complex never identify before.

NuRD

MBD3

Cristallographie aux rayons-X

Cryo-EM

NuRD

MBD3

X-ray crystallography

Cryo-EM

Remodelling

572.8

571.4

Regulation of Pluripotency and Differentiation by Chromatin Remodeling Factors

Ee, Ly-Sha

08 August 2017

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.

Embryonic stem cells

chromatin

gene regulation

MBD3/NuRD

H3K56ac

Cell and Developmental Biology

Life Sciences

EVOLUTION AND DIVERGENCE OF THE STRUCTURAL AND PHYSICAL PROPERTIES OF DNA BINDING BY METHYL-CYTOSINE BINDING DOMAIN FAMILY MEMBERS 2 AND 3

Cramer, Jason

01 January 2014

The studies presented in this dissertation, Evolution And Divergence Of The Structural And Physical Properties Of DNA Binding By Methyl-Cytosine Binding Domain Family Members 2 And 3, pertain primarily to two key epigenetic regulators involved with the biological interpretation of methylated DNA marks. We provide insights into the emergence and evolution of the MBD2 and MBD3 and how those molecular entities influence heritable changes in gene activity. We further provide details regarding the mystery surrounding MBD3 function and the MBD2-mediated capacity of primitive animals to carry out methylation-specific epigenetic mechanisms. In chapter two, we describe the DNA binding properties of MBD2 and MBD3. This study provides information regarding previously unidentified MBD3 binding properties and potential biological function. In chapter three, we show that sponges demonstrate a MBD2-mediated capacity for binding methylated DNA sites, recruit NuRD components in vitro, and knockdown of MBD2 in the freshwater desmosponge, Ephydatia muelleri, promotes an abnormal growth phenotype.

MBD3

MBD2

Nuclear magnetic resonance

DNA methylation

DNA binding protein

biophysics

protein dynamics

hydroxymethylated DNA

residual dipolar couplings

NuRD

Ephydatia muelleri

Biochemistry

Chromatin alterations imposed by the oncogenic transcription factor PML-RAR

Morey Ramonell, Lluís

01 February 2008

En mamíferos, así como en plantas, mutaciones en AND helicasas/ATPasas del la família SNF2, no solo afectan a la estructura de la cromatina, sino que también afectan al patrón global de la metilación del ADN. Sugiriendo una relación funcional entre la estructura de la cromatina y la epigenética. El complejo NuRD, el cual posee una ATPasa de la familía SNF2, está relacionado con la represión de la transcripción y en el remodelamiento de la cromatina. Nuestro laboratorio demostró que la proteína leucémica PML-RARα reprime la transcripción de sus genes diana por el reclutamiento de DNMTs y el complejo PRC2. En esta tesis, demostramos una relación directa del complejo NuRD en la represión génica y en los cambios epigenéticos en la leucemia promielocítica aguda (APL). Mostramos que PML-RARα se une y recluta NuRD a sus genes diana, incluyendo el gen supresor de tumores RAR2, facilitando que el complejo de Polycomb se reclute y metile la lisina 27 de la histona H3. Tratamiento con Acido Retinóico (RA), el qual se utiliza en pacientes, reduce la ocupación de NuRD en células leucémicas. Eliminando NuRD no solo provoca que las histonas no se deacetilen y que la cromatina no se compacte, sino que también provoca que tanto la metilación del ADN y de las histonas no se produzca, así como la represión génica del gen RAR2, favoreciendo la diferenciación celular. Nuestros resultados caracterizan un nuevo papel del complejo NuRD en el establecimiento de los patrones epigenéticos en APL, demostrando una relación esencial entre la estructura de la cromatina y epigenética durante el desarrollo de la leucemia, pudiéndose aplicar a la terapia de esta enfermedad. / In mammals, as in plants, mutations in SNF2-like DNA helicases/ATPases were shown to affect not only chromatin structure but also global methylation patterns, suggesting a potential functional link between chromatin structure and epigentic marks. The SNF2-like containing NuRD complex is involved in gene transcriptional repression and chromatin remodeling. We have previously shown that the leukemogenic protein PMLRARα represses target genes through recruitment of DNMTs and Polycomb complex. In this thesis, we demonstrate a direct role of the NuRD complex in aberrant gene repression and transmission of epigenetic repressive marks in acute promyelocytic leucemia (APL). We show that PML-RARα binds and recruits NuRD to target genes, including to the tumor-suppressor gene RAR2. In turn, the NuRD complex facilitates Polycomb binding and histone methylation at lysine 27. Retinoic acid treatment reduced the promoter occupancy of the NuRD complex. Knock-down of the NuRD complex in leukemic cells not only prevented histone deacetylation and chromatin compaction, but also impaired DNA and histone methylation as well as stable silencing, thus favoring cellular differentiation. These results unveil an important role for NuRD in the establishment of altered epigenetic marks in APL, demonstrating an essential link between chromatin structure and epigenetics in leukemogenesis that could be exploited for therapeutic intervention.

DNaseI

transcription repression

chromatin immunoprecipitation

bisulfite genomic sequence

histone modifications

DNA methylation

RAR2

Suz12

PRC2

Mi-2

MTA2

MBD3

HDAC1/2

Retinoic Acid

NuRD

PML-RARα

APL

575

616.4