The ICF syndrome and emergent players in DNA methylation and development : when studying a rare genetic disease sheds new light on an "old" field / Syndrome ICF et acteurs émergents dans la méthylation de l'ADN et le développement : l’étude d’une maladie génétique rare apporte un regard nouveau sur un « ancien » domaine

Grillo, Giacomo

06 July 2017

La méthylation de l'ADN est un processus vital pour le développement des mammifères. Sa distribution anormale,notamment au niveau des régions répétées du génome, est une signature pathologique. La découverte de maladies héréditaires touchant la stabilité du génome a permis des avancées considérables dans l'identification des acteurs et des mécanismes. Nous avons choisi d'étudier le syndrome ICF (Immunodéficience, instabilité Centromérique et anomalies Faciales), première maladie génétique identifiée avec des défauts de la méthylation de l’ADN, liés à une instabilité chromosomique. Lorsque j'ai commencé ma thèse, des mutations dans les gènes DNMT3B et ZBTB24 avaient été décrites comme causes génétiques du syndrome. Cependant, d'autres causes génétiques restaient inconnues. Nos travaux ont permis d'identifier deux nouveaux gènes, CDCA7 et HELLS, dont les mutations sont responsables du syndrome. J'ai montré que leur perte de fonction dans les cellules somatiques entraîne un défaut de méthylation des répétitions centromériques, suggérant leur rôle dans le maintien de la méthylation de l'ADN. Par conséquent, l'étude de l'étiologie d'une maladie génétique rare a permis d'identifier de nouveaux « gardiens » de la stabilité du génome, avec des fonctions jusqu'alors insoupçonnées dans les processus de méthylation de l'ADN et dans le développement. Au cours de mon doctorat, j'ai établi des cartes de méthylation des cellules de patients ICF afin d'identifier les cibles communes et distinctes de ces facteurs, ainsi que leurs caractéristiques génomiques et épigénomiques. Contrairement aux mutations de DNMT3B,celles de ZBTB24, CDCA7 et HELLS affectent la méthylation dans des régions pauvres en CpG, dans des régions intergéniques et dans des répétitions d'ADN intercalées. Plus généralement, ce sont les régions d'hétérochromatine qui sont les plus touchées et en particulier des clusters des gènes codants et non codants, dont certains sont exprimés de manière monoallélique. Pour mieux caractériser le rôle de ZBTB24 dans le développement et la méthylation de l'ADN,nous avons généré un modèle murin mutant qui nous a permis de monter que ZBTB24 était essentielle pour le développement embryonnaire précoce. De plus, ZBTB24 jouerait un rôle dans l'établissement de la méthylation des séquences répétées de l'ADN, à la fois en tandem ou intercalé. Fait intéressant, ZBTB24 semble être également impliqué dans l'établissement de la marque répressive H3K9me3, suggérant un rôle de la protéine dans le "dialogue" entre la méthylation de l'ADN et celle des histones. Dans l'ensemble, mon travail met l'accent sur la façon dont la méthylation de l'ADN et les marques d'hétérochromatine sont établies et maintenues à des gènes uniques et des répétitions de l'ADN, et fournit de nouveaux acteurs et mécanismes à considérer dans les études sur le maintien de la stabilité du génome. / DNA methylation is an essential process for the development of mammals. Its abnormal distribution, particularly at the level of the repeated regions of the genome, is a pathological signature. The discovery of hereditary diseases affecting DNA methylation and the stability of the genome allowed a considerable progress in the identification of their actors and mechanisms. We chose to study the ICF (Immunodeficiency, Centromeric Instability and Facial Abnormalities) syndrome, the first genetic disorder identified with defects in the distribution of DNA methylation, linked to chromosomal instability. When I started my PhD, mutations in two genes had been described to cause the ICF syndrome: DNMT3B and ZBTB24. However, the genetic origin of a subset of ICF patients remained unknown. We identified mutations in CDCA7 and HELLS as causative of the ICF syndrome. I showed that their loss of function in somatic cells results in the loss of DNA methylation at centromeric repeats, strongly suggestive of a role DNA methylation maintenance. Hence, the study of the aetiology of a genetic disease provided new candidate “guardians” of DNA repeats and genome stability, with virtually unknown functions but with exciting potential roles in the DNA methylation machinery and in development. During my PhD, I established methylation maps in ICF patients cells to identify common and distinct targets of these factors, as well as their genomic and epigenomic characteristics. In contrast to DNMT3B mutations, those in ZBTB24, CDCA7 and HELLS affect methylation at CpG-poor regions in intergenic genomic locations and at interspersed DNA repeats, and more generally, at genomic locations with heterochromatic features. Their integrity is required for the methylated status of coding and non-coding clusters of genes, some of which are expressed in a monoallelic manner. To better characterize the role of ZBTB24 in development and DNA methylation pathways, we generated a mouse model carrying mutations in ZBTB24. We showed that ZBTB24 is essential for early development, while it seemed to be dispensable for in vitro differentiation of murine ES cells. We implicated ZBTB24 in the establishment of DNA methylation at DNA repeats, both in tandem or interspersed, in differentiating ES cells. Interestingly, ZBTB24 seems to be also implicated in the establishment of the repressive mark H3K9me3 suggesting that ZBTB24 may indirectly control DNA methylation through an interplay with histone marks. As a whole, our work sheds light on how DNA methylation and heterochromatin marks are established and maintained at unique genes and DNA repeats, and provides new actors and mechanisms to consider in studies of the maintenance of genome stability.

Epigénétique

Maladies humaines

Répétitions d’ADN

Modèles murins

Développement précoce

Epigenetics

DNA methylation

Human diseases

Methylome

Heterochromatin

DNA repeats

Mouse models

Early development

Epigenetic Instability Induced by DNA Base Lesion via DNA Base Excision Repair

Jiang, Zhongliang

26 September 2017

DNA damage can cause genome instability, which may lead to human cancer. The most common form of DNA damage is DNA base damage, which is efficiently repaired by DNA base excision repair (BER). Thus BER is the major DNA repair pathway that maintains the stability of the genome. On the other hand, BER mediates DNA demethylation that can occur on the promoter region of important tumor suppressor genes such as Breast Cancer 1 (BRCA1) gene that is also involved in prevention and development of cancer. In this study, employing cell-based and in vitro biochemical approaches along with bisulfite DNA sequencing, we initially discovered that an oxidized nucleotide, 5’,2-cyclo-2-deoxyadenosine in DNA duplex can either cause misinsertion by DNA polymerase β (pol β) during pol β-mediated BER or inhibit lesion bypass of pol β resulting in DNA strand breaks. We then explored how a T/G mismatch resulting from active DNA demethylation can affect genome integrity during BER and found that pol β can extend the mismatched T to cause mutation. We found that AP endonuclease 1 (APE1) can use its 3'-5' exonuclease to remove the mismatched T before pol β can extend the nucleotide preventing a C to T mutation. The results demonstrate that the 3'-5' exonuclease activity of APE1 can serve as a proofreader for pol β to prevent mutation. We further explored the effects of exposure of environmental toxicants, bromate and chromate on the DNA methylation pattern on the promoter region of BRCA1 gene with bisulfite DNA sequencing. We found that bromate and chromate induced demethylation of 5-methylcytosines (5mC) at the CpG sites as well as created additional methylation at several unmethylated CpG sites at BRCA1 gene in human embryonic kidney (HEK) 293 cells. We further demonstrated that the demethylation was mediated by pol β nucleotide misinsertion and an interaction between pol β and DNA methyltransferase 1 (DNMT1) suggesting a cross-talk between BER and DNA methyltransferases. We suggest that DNA base damage and BER govern the interactions among the environment, the genome and epigenome, modulating the stability of the genome and epigenome and disease development.

DNA damage

Base Excision Repair

Epigenetics

DNA methylation

Amino Acids, Peptides, and Proteins

Biochemistry

Enzymes and Coenzymes

The Study of Tissue-Specific DNA Methylation as a Method for the Epigenetic Discrimination of Forensic Samples

Antunes, Joana AP

21 November 2017

In forensic sciences, the serological methods used to determine which body fluid was collected from the crime scene are merely presumptive or labor intensive since they rely on protein detection or on microscopic identification of cells. Given that certain forensic cases may need the precise identification of a body fluid to determine criminal contact, such is the example of a suspected sexual assault of a minor; certainty in the body fluid of origin may depict a precise picture of the events. The identification of loci that show differences in methylation according to the tissue of origin can aid forensic analysts in determining the origin of a DNA sample. The process of DNA methylation occurs naturally in the genome of living organisms and consists in the presence of a methyl group on the carbon 5 of a cytosine, which is typically followed by a guanine (CpG). Analyzing patterns of DNA methylation in body fluids collected from a crime scene is preferential to the analysis of proteins or mRNA since the same extracted DNA used for STR typing can be used for DNA methylation analysis. We have validated and identified loci able to discriminate blood, saliva, semen and vaginal epithelia. In the current study, we have also established the minimum amount of DNA able to provide reliable results using methodologies such as pyrosequencing and high-resolution melt (HRM) analysis for the different markers identified. Lastly, we performed an alternative bioinformatic analysis of data collected using an array that studied methylation in over 450,000 individual cytosines on the human genome. We were able to sort the locations that showed potentially higher methylation differences between body fluids and investigated over 100 of them using HRM analysis. The results of that study, allowed the identification of three new loci able to distinguish blood and two new loci able to distinguish saliva and vaginal epithelia, respectively. The use of DNA methylation patterns to aid forensic investigations started with a publication in 2010, therefore each small contribution such as this work may, similarly to what occured in the biochemistry field, result in the discovery of a method able to put the technology in the hands of forensic analysts.

epigenetics

forensic sciences

DNA

DNA methylation

pyrosequencing

high-resolution melt analysis

PCR

qPCR

body fluids

Life Sciences

Investigation du mécanisme fonctionnel des gènes AtRING1 et AtZRF1 dans la régulation de la croissance et du développement chez les plantes / Role of chromatin regulators AtRING1 and AtZRF1 in Arabidopsis growth and development

Wang, Qiannan

14 December 2018

Chez les plantes comme chez les animaux, les protéines du groupe Polycomb (PcG) jouent des rôles essentiels dans les processus développementaux par la répression de l'expression des gènes. Ces protéines fonctionnent en complexes multi-protéiques; dont les mieux caractérisés sont Polycomb Repressive Complex 1 (PRC1) et PRC2. Bien que PRC2 a été étudié extensivement chez Arabidopsis, ce n’est que récemment que des composants de PRC1 ont été identifiés chez les plantes et leur mécanisme de fonctionnement reste peu conclusif. Dans mes travaux de thèse, j’ai caractérisé AtRING1, un sous-unité essentiel du PRC1, et AtZRF1, une protéine proposée comme lecteur de l’histone H2A monoubiquitinée (H2Aub1) en aval du fonctionnement du PRC1. Mes résultats montrent qu’une perte-de-fonction totale de AtRING1A, par ‘CRISPR/Cas9 gene-editing’, causes une létalité partielle embryonnaire et la dédifférenciation cellulaire de la plantule d’Arabidopsis. Les mutations du domaine RAWUL au C-terminal de AtRING1A sont plus tolérées mais induisent certains défauts sur la croissance végétative, la floraison, l’organogénèse, et la production des graines. Mes analyses moléculaires révèlent que ces mutations du domaine RAWUL réduisent H2Aub1 et augmentent l’expression de plusieurs gènes essentiels dans la régulation du développement de la plante. Ainsi, mes données ont permis à établir une fonction primordiale de AtRING1 et à attribuer un rôle de son domaine RAWUL dans la déposition de H2Aub1 et répression des gènes in vivo. Nos analyses sur AtZRF1 ont permis à détailler son rôle sur la division and différenciation cellulaire. / In plants as in animals, the Polycomb Group (PcG) proteins play key roles in diverse developmental processes by repressing the expression of genes. These proteins work in multi-protein complexes, among them the best characterized ones are Polycomb Repressive Complex 1 (PRC1) and PRC2. Although PRC2 was extensively studied in Arabidopsis, it is only recently that components of PRC1 were identified in plants and their function mechanism remains largely elusive. My thesis work focused on the characterization of AtRING1A, one of the PRC1 core subunits, and of AtZRF1, a protein proposed as a reader of the histone H2A-monoubiquitin (H2Aub1) downstream to the PRC1 function. My results show that a total loss-of-function of AtRING1A, by CRISPR/Cas9 gene editing, leads to partial embryonic lethal and callus-formation of seedlings in Arabidopsis. Several mutations within the RAWUL domain at the C-terminus of AtRING1A are better tolerated and induce several defects in plant vegetative growth, flowering time, floral organ formation and seed production. My molecular data indicate a role of the RAWUL domain in H2Aub1 deposition in vivo and suppression of several key developmental genes. Our characterization of loss-of-function of AtZRF1 provides important detailed information about its function in the regulation of cell division and cell differentiation.

Chromatine regulateur

Épigénétique

H2Aub1

H3K27me3

Régulation de la transcription

Développement de la plante

AtRING1

RAWUL

AtZRF1

Chromatin regulator

Epigenetics

H2Aub1

H3K27me3

Transcription regulation

Plant development

AtRING1

RAWUL

AtZRF1

572.8

571.2

581

“Transcriptional and Epigenetic regulation in the marine diatom Phaeodactylum tricornutum”

Maumus, Florian

06 July 2009

Les océans couvrent plus de 70% de la surface de la Terre (planète bleue) et la productivité primaire nette (PPN) marine est équivalente à celle terrestre. Alors qu‟il ne représente que 1% de la biomasse totale d‟organismes photosynthétiques de la planète, le phytoplancton est responsable d‟environ 45% de la PPN globale. Le terme phytoplancton décrit un assemblage polyphylétique comprenant des eucaryotes et procaryotes photosynthétiques dérivant avec les courants. Dans les océans contemporains, les diatomées constituent un groupe d‟eucaryotes unicellulaires autotrophes très abondant, responsable de 40% de la PPN marine. Les diatomées appartiennent à la lignée des straménopiles qui sont issus d‟un évènement d‟endosymbiose entre une algue rouge et un hôte hétérotrophe. Elles sont classifiées en deux groupes majeurs : les centriques qui son apparues il y a environ 200 millions d‟années (Ma), et les pennées qui ont évolué il y a environ 90 Ma. Deux génomes de diatomées ont récemment été séquencés : celui de la diatomée centrique Thalassiosira pseudonana (32 Mb), et celui de la diatomée pennée Phaeodactylum tricornutum (27 Mb). Mon sujet de doctorat s‟est focalisé sur l‟étude de différents aspects de la régulation de l‟expression génique ainsi que sur la dynamique et l‟évolution de ces génomes. L‟expression des gènes est régulée à différents niveaux: trancriptionel, post-transcriptionel, et épigénétique. Dans le cadre de mon doctorat, une étude de la régulation transcriptionelle chez les diatomées a été effectuée et comprend l‟identification et l‟analyse in silico des facteurs de transcription (FT). Cela a permis par exemple d‟établir qu‟une classe spécifique de FT, les Heat Shock Factors, sont particulièrement abondants chez les diatomées par rapport aux autres eucaryotes. L‟analyse de la représentation des FT identifiés dans différentes librairies d‟EST élaborées à partir de cultures ayant subi divers stress a permis de détecter certaines spécificités d‟expression. L‟évolution des génomes eucaryotes est largement impactée par les effets directs et secondaires des éléments transposables (ET) qui sont des éléments génétiques mobiles se trouvant dans le génome de la plupart des organismes. Dans le but d‟étudier la dynamique des génomes de diatomées, la recherche de différents types d‟ET a permis d‟établir qu‟une certaine classe, les rétrotransposons de type Copia, est la plus abondante dans ces génomes et constitue un part significativement plus importante du génome de P. tricornutum (5,8%) par rapport à T. pseudonana (1%). D‟autre part, des analyses phylogénitiques ont montré que les rétrotransposons de type copia forment deux classes distinctes et éloignées de la lignée Copia. L‟analyse de leurs niveaux d‟expression a montré que la transcription de deux éléments s‟active en réponse à des stress spécifiques comme la limitation en nitrate dans le milieu de culture. Cette activation est accompagnée par un hypométhylation de l‟ADN et l‟analyse de profils d‟insertions chez différents écotypes de P. tricornutum ainsi que l‟étude d‟autres phénomènes suggèrent que les rétrotransposons de type Copia ont joué un rôle important dans l‟évolution des diatomées. Mon grand intérêt pour les ET m‟a ensuite amené à chercher à les caractériser dans d‟autres génomes récemment séquencés tels celui de l‟algue brune Ectocarpus siliculosus. La recherche in silico de différents gènes codant des protéines capables d‟introduire ou de stabiliser des états épigénétiques telle que la modification des histones et la méthylation de l‟ADN a montré leur présence chez P. tricornutum ainsi que leurs particularités. La présence de certaines modifications d‟histones spécifiques d‟une conformation compacte ou ouverte de la chromatine dans le proteome de P. tricornutum a été montrée. De plus, la mise au point de la technique d‟immunoprécipitation de la chromatine chez P. tricornutum a permis d‟établir que les nucléosomes enrobés d‟éléments transposables étaient marqués par des modifications spécifiques. D‟autres expériences ont permis d‟établir que l‟ADN de différents types d‟éléments transposables est marqué par la méthylation de cytosines chez P. tricornutum. Une expérience permettant l‟analyse du profil de méthylation à l‟échelle de génome en utilisant une puce à ADN a été lancée et permettra de découvrir si certains gènes portent aussi des traces de méthylation. Enfin, les ARN interférents constituent un troisième mode de régulation de l‟expression se situant à l‟interface de la régulation transcriptionelle, post-transcriptionelle et épigénétique. Les mécanismes d‟interférences chez les diatomées ont été étudié par la recherche in silico d‟enzymes clés impliquées dans ce processus ainsi qu‟en établissant expérimentalement un lien direct avec la méthylation de l‟ADN.

Marine microbiology

comparative genomics

diatoms

chromalveolates

epigenetics

genome dynamics

DNA methylation

Copia elements

Transcriptional regulation

Epigenetic Regulation of Replication Timing and Signal Transduction

Bergström, Rosita

January 2008

Upon fertilization the paternal and maternal genomes unite, giving rise to the embryo, with its unique genetic code. All cells in the human body are derived from the fertilized ovum: hence they all contain (with a few exceptions) the same genetic composition. However, by selective processes, genes are turned on and off in an adaptable, and cell type-specific, manner. The aim of this thesis is to investigate how signals coming from outside the cell and epigenetic factors residing in the cell nucleus, cooperate to control gene expression. The transforming growth factor-β (TGF-β) superfamily consists of around 30 cytokines, which are essential for accurate gene regulation during embryonic development and adult life. Among these are the ligands TGF-β1 and bone morphogenetic (BMP) -7, which interact with diverse plasma membrane receptors, but signal via partly the same Smad proteins. Smad4 is essential to achieve TGF-β-dependent responses. We observed that by regulating transcription factors such as Id2 and Id3 in a specific manner, TGF-β1 and BMP-7 achieve distinct physiological responses. Moreover, we demonstrate that CTCF, an insulator protein regulating higher order chromatin conformation, is able to direct transcription by recruiting RNA polymerase II to its target sites. This is the first mechanistic explanation of how an insulator protein can direct transcription, and reveals a link between epigenetic modifications and classical regulators of transcription. We also detected that DNA loci occupied by CTCF replicate late. The timing of replication is a crucial determinant of gene activity. Genes replicating early tend to be active, whereas genes replicating late often are silenced. Thus, CTCF can regulate transcription at several levels. Finally, we detected a substantial cross-talk between CTCF and TGF-β signaling. This is the first time that a direct interplay between a signal transduction pathway and the chromatin insulator CTCF is demonstrated.

Cell and molecular biology

Chromatin

CTCF

Epigenetics

Genomic Imprinting

H19

Id

Igf2

Insulator

Replication

Signal Transduction

Smad

TGF-β

Transcription

Cell- och molekylärbiologi

Functional organisation of the cell nucleus in the fission yeast, Schizosaccharomyces pombe

Alfredsson Timmins, Jenny

January 2009

In eukaryotes the genome adopts a non-random spatial organisation, which is important for gene regulation. However, very little is known about the driving forces behind nuclear organisation. In the simple model eukaryote fission yeast, Schizosaccharomyces pombe, it has been known for a long time that transcriptionally repressed heterochromatin localise to the nuclear membrane (NM); the centromeres attaches to spindle pole body (SPB), while the telomeres are positioned at the NM on the opposite side of the nucleus compared to the SPB. Studies presented in this thesis aimed at advancing our knowledge of nuclear organisation in Schizosaccharomyces pombe. We show that the heterochromatic mating-type region localises to the NM in the vicinity of the SPB. This positioning was completely dependent on Clr4, a histone methyl transferase crucial for the formation of heterochromatin. Additional factors important for localisation were also identified: the chromo domain protein Swi6, and the two boundary elements IR-L and IR-R surrounding this locus. We further identify two other chromo domain proteins; Chp1 and Chp2, as crucial factors for correct subnuclear localisation of this region. From these results we suggest that the boundary elements together with chromodomain proteins in balanced dosage and composition cooperate in organising the mating-type chromatin. Gene regulation can affect the subnuclear localisation of genes. Using nitrogen starvation in S. pombe as a model for gene induction we determined the subnuclear localisation of two gene clusters repressed by nitrogen: Chr1 and Tel1. When repressed these loci localise to the NM, and this positioning is dependent on the histone deacetylase Clr3. During induction the gene clusters moved towards the nuclear interior in a transcription dependent manner. The knowledge gained from work presented in this thesis, regarding nuclear organisation in the S. pombe model system, can hopefully aid to a better understanding of human nuclear organisation.

fission yeast

heterochromatin

subnuclear organisation

chromo domain proteins

boundary elements

transcriptional regulation

epigenetics

Molecular biology

Molekylärbiologi

Cell and molecular biology

Cell- och molekylärbiologi

Genetics

Genetik

Examination of NMDA receptor subunit prevalence and distribution in crude synaptic membranes purified from a mouse model of Rett syndrome.

Maliszewska-Cyna, Ewelina

17 February 2010

In this study we tested whether the prevalence or synaptic distribution of NMDA receptor subunits would be altered in the brain of the MeCP2-null mouse model of Rett syndrome. Detergent resistant membranes (DRMs) and post-synaptic densities (PSDs) were isolated from the synaptic membranes treated with TritonX-100, and resolved by sucrose density gradient centrifugation. Immunoblot analysis of the resulting density gradient fractions revealed that the relative distribution of the different NMDA receptor subunits between the DRM fractions, soluble fractions, and insoluble postsynaptic density fractions was preserved in the MeCP2-null brain. However, analysis of the overall NMDA receptor subunit prevalence within these fractions revealed a significant decrease in the expression of the NR1 and NR2A subunits, but not the NR2B subunit, in the MeCP2-null brain. The preservation of distribution of NMDAR subunits to the synaptic membranes, together with the decrease in NR1 and NR2A prevalence, suggest an imbalance in equilibrium between the mature and the immature synapses in a mouse model of Rett syndrome.

Rett syndrome

MeCP2

epigenetics

neurodevelopment

synaptic maturation

glutamate

NMDA receptor complex

NR2A

lipid rafts

postsynaptic density

discontinuous sucrose gradient

0719

0317

Examination of NMDA receptor subunit prevalence and distribution in crude synaptic membranes purified from a mouse model of Rett syndrome.

Maliszewska-Cyna, Ewelina

17 February 2010

In this study we tested whether the prevalence or synaptic distribution of NMDA receptor subunits would be altered in the brain of the MeCP2-null mouse model of Rett syndrome. Detergent resistant membranes (DRMs) and post-synaptic densities (PSDs) were isolated from the synaptic membranes treated with TritonX-100, and resolved by sucrose density gradient centrifugation. Immunoblot analysis of the resulting density gradient fractions revealed that the relative distribution of the different NMDA receptor subunits between the DRM fractions, soluble fractions, and insoluble postsynaptic density fractions was preserved in the MeCP2-null brain. However, analysis of the overall NMDA receptor subunit prevalence within these fractions revealed a significant decrease in the expression of the NR1 and NR2A subunits, but not the NR2B subunit, in the MeCP2-null brain. The preservation of distribution of NMDAR subunits to the synaptic membranes, together with the decrease in NR1 and NR2A prevalence, suggest an imbalance in equilibrium between the mature and the immature synapses in a mouse model of Rett syndrome.

Rett syndrome

MeCP2

epigenetics

neurodevelopment

synaptic maturation

glutamate

NMDA receptor complex

NR2A

lipid rafts

postsynaptic density

discontinuous sucrose gradient

0719

0317

The Epigenetic Regulation of Cytokine Inducible Mammalian Transcription by the 26S Proteasome

Koues, Olivia I

08 July 2009

It is evident that components of the 26S proteasome function beyond protein degradation in the regulation of transcription. Studies in yeast implicate the 26S proteasome, specifically the 19S cap, in the epigenetic regulation of transcription. Saccharomyces cerevisiae 19S ATPases remodel chromatin by facilitating histone acetylation and methylation. However, it is unclear if the 19S ATPases play similar roles in mammalian cells. We previously found that the 19S ATPase Sug1 positively regulates transcription of the critical inflammatory gene MHC-II and that the MHC-II promoter fails to efficiently bind transcription factors upon Sug1 knockdown. MHC-II transcription is regulated by the critical coactivator CIITA. We now find that Sug1 is crucial for regulating histone H3 acetylation at the cytokine inducible MHC-II and CIITA promoters. Histone H3 acetylation is dramatically decreased upon Sug1 knockdown with a preferential loss occurring at lysine 18. Research in yeast indicates that the ortholog of Sug1, Rpt6, acts as a mediator between the activating modifications of histone H2B ubiquitination and H3 methylation. Therefore, we characterized the role the 19S proteasome plays in regulating additional activating modifications. As with acetylation, Sug1 is necessary for proper histone H3K4 and H3R17 methylation at cytokine inducible promoters. In the absence of Sug1, histone H3K4me3 and H3R17me2 are substantially inhibited. Our observation that the loss of Sug1 has no significant effect on H3K36me3 implies that Sug1’s regulation of histone modifications is localized to promoter regions as H3K4me3 but not H3K36me3 is clustered around gene promoters. Here we show that multiple H3K4 histone methyltransferase subunits bind constitutively to the inducible MHC-II and CIITA promoters and that over-expressing one subunit significantly enhances promoter activity. Furthermore, we identified a critical subunit of the H3K4 methyltransferase complex that binds multiple histone modifying enzymes, but fails to bind the CIITA promoter in the absence of Sug1, implicating Sug1 in recruiting multi-enzyme complexes responsible for initiating transcription. Finally, Sug1 knockdown maintains gene silencing as elevated levels of H3K27 trimethylation are observed upon Sug1 knockdown. Together these studies strongly implicate the 19S proteasome in mediating the initial reorganization events to relax the repressive chromatin structure surrounding inducible genes.

19S proteasome

Sug1

26S proteasome

Class II transactivator

Histone remodeling enzymes

Histone modifications

Epigenetics

Transcriptional regulation

Biology, general