Etudes structurales sur l'assemblage du nucléosome / Structural studies of Nucleosome Assembly

Aguilar Gurrieri, Carmen

05 July 2013

Au sein du noyau, l'ADN est organise en chromatine dont l'unité de base est le nucléosome. La structure de la chromatine est très dynamique, ce qui est nécessaire pour la plupart des opérations qui se produisent dans l'ADN telles que la réplication, la transcription, la réparation et la recombinaison. Le nucléosome est constitué de deux dimères H2A/H2B et deux dimères H3/H4 associés avec 147 paires de bases d'ADN. La protéine Nap1 est un chaperon d'histone H2A/H2B impliquée dans l'assemblage et démontage des nucléosomes. Nap1 protège les interactions non spécifiques entre l'ADN chargé négativement et les dimères H2A/H2B chargés positivement, afin de permettre la formation de la structure ordonnée des nucléosomes. Lors de l'assemblage des nucléosomes, les dimères d'histones H3/H4 sont déposés en premier lieu, suivi par le dépôt de dimères H2A/H2B. Lors du démontage du nucléosome, les dimères H2A/H2B sont retirés avant le retrait des dimères H3/H4. La determination de la structure du complexe Nap1-H2A/H2B pourra permettre une meilleure compréhension du processus d'assemblage du nucléosome. Dans cette étude, nous voulons comprendre comment le chaperon Nap1 cible spécifiquement les dimères d'histones H2A/H2B pour l'assemblage des nucléosomes. Notre objectif est de caractériser la structure et la fonction du complexe de Nap1-H2A/H2B. Ainsi nous nous sommes tout d'abord intéresse à la stoechiometrie de ce complexe. Nous avons trouvé qu'un dimère de Nap1 s'associe à un dimère H2A/H2B (Nap1_2-H2A/H2B). D'autre part, l'analyse par spectrométrie de masse non-dénaturante a montré que ce complexe de base peut s'oligomériser et contenir jusqu'à 6 copies de Nap1_2-H2A/H2B. L'analyse de ce complexe par spectrométrie de masse non-dénaturant a montré que ce complexe peu oligomériser dans un grand complexe contenant jusqu'à 6 copies de Nap1_2-H2A/H2B. Nous avons également obtenu la première structure cristalline à basse résolution de ce complexe. L'analyse du même complexe par microscopie électronique à coloration négative a révélé la présence en solution du même oligomère que dans l'unité asymétrique du cristal, qui contient aussi 6 copies de Nap1_2-H2A/H2B. Ainsi, nous avons pu mettre en évidence de nouvelles interfaces d'interaction entre les différents composants de ce complexe qui nous permettent de mieux comprendre le processus d'assemblage des nucléosomes. Le remodelage de la chromatine permet l'expression des gènes eucaryotes. Ce remodelage nécessite des enzymes telles que des histone acétyltransférases (HAT) et les chaperons d'histones. Les HATs acétylent les chaînes latérales des lysines. Il a été proposé que les HATs et les histones chaperons agissent en synergie pour moduler la structure de la chromatine pendant la transcription. La HAT p300 a été proposé d'interagir avec l'histone chaperon Nap1. Nous avons entrepris de caractériser cette interaction. Malheureusement, nos expériences n'ont pas pu détecter d'interaction directe entre ces protéines. / Assembly of chromatin is an essential process that concerns most DNA transactions in eukaryotic cells. The basic repeating unit of chromatin are nucleosomes, macromolecular complexes that consist of a histone octamer that organizes 147 bp of DNA in two superhelical turns. Although, the structures of nucleosomes are known in detail, their assembly is poorly understood. In vivo, nucleosome assembly is orchestrated by ATP-dependent remodelling enzymes, histone-modifying enzymes and a number of at least partially redundant histone chaperones. Histone chaperons are a structurally diverse class of proteins that direct the productive assembly and disassembly of nucleosomes by facilitating histone deposition and exchange. The currently accepted model is that nucleosome assembly is a sequential process that begins with the interaction of H3/H4 with DNA to form a (H3/H4)2 tetramer-DNA complex. The addition of two H2A/H2B dimers completes a canonical nucleosome. High-resolution structures of histone chaperons in complex with H3/H4 histones have resulted in detailed insights into the process of nucleosome assembly. However, our understanding of the mechanism of nucleosome assembly has been hampered by the as yet limited number of co-crystal structures of histone–chaperone complexes. In particular it remains unclear how histone chaperons mediate H2A/H2B deposition to complete nucleosome assembly. In this work, we have investigated the role of the H2A/H2B chaperon Nap1 (Nucleosome assembly protein 1) in nucleosome assembly. We have determined the crystal structure of the complex between Nap1 and H2A/H2B and analysed the assembly by various biophysical methods. The structure shows that a Nap1 dimer binds to one copy of H2A/H2B (Nap1_2-H2A/H2B). A large ~550 kDa macromolecular assembly containing 6 copies of the Nap12-H2A/H2B complex is seen in the asymmetric crystallographic unit. We confirmed by both non-denaturing mass spectroscopy and negative stain electron microscopy studies that this assembly is the predominant form of the Nap1_2-H2A/H2B complex in solution. We further investigated the potential interplay between p300-mediated histone acetylation and nucleosome assembly. Together, the structure and associated functional analysis provide a detailed mechanism for the Nap1 chaperon activity, its role in H2A/H2B deposition and in nucleosome assembly.

Nucleosome

Histone chaperone

Histones

Nucleosome assembly

Chromatin remodeling

Nap1

Nucleosome

Histone chaperone

Histones

Nucleosome assembly

Chromatin remodeling

Nap1

THE UNIQUE STRUCTURE AND MECHANISM OF INO80 - AN ATP DEPENDENT REMODELER OF THE HISTONE EXCHANGER FAMILY

Udugama, Maheshi Imalka

01 December 2010

INO80, a member of the multi-subunit SWI2/SNF2 superfamily, is involved in transcription regulation, DNA repair and replication. Not much is known about its substrate specificity and remodeling mechanism or how it differs in comparison to SWI/SNF or ISWI. Site-directed mapping of histone-DNA contacts showed that INO80 generally remodels mononucleosomes by moving them to the center of DNA. The length of extranucleosomal DNA was found to play an important role in nucleosome binding as well as remodeling by INO80 much like ISW2 and ISW1a. INO80 preferentially binds to nucleosomes containing >20bp of extranucleosomal DNA. Similarly, INO80 remodeling of mononucleosomes with different lengths of extranucleosomal DNA showed that at least 33bp of extranucleosomal DNA on one side of the nucleosome was required for initiation of remodeling. These data suggest that INO80 behaves much like ISW2 and ISW1a complexes based on their requirement for extranucleosomal DNA. INO80 does not unravel or displace nucleosomes like SWI/SNF. There are several key aspects of how INO80 interacts with and remodels nucleosomes that are quite distinct from SWI/SNF, ISW2, and ISW1a. Previously SWI/SNF and ISW2 were shown to initiate nucleosome movement by translocating along nucleosomal DNA two helical turns from the dyad axis. Nucleosome movement by INO80 instead requires translocation by the complex along nucleosomal DNA near the entry/exit site at the dimer-tetramer interface. Sliding interference of INO80 by the presence of nicks indicated that torsional strain at the site of translocation is required for nucleosome mobilization by INO80. Hydroxyl radical footprinting of the INO80-nucleosome complex shows found that INO80 interactioninteracts with extranucleosomal DNA at, the entry-exit site and to lesser extent at the dyad axis, but it lacks the protection found indoes not contact 2 helical turns from the dyad like ISW2 and SWI/SNF at two helical turns from the dyad axis as determined by photoaffinity cross-linking studies. The catalytic subunit (Ino80) rather than being found associated 2 helical turns from the dyad, was bound to extranucleosomal DNA and nucleosomal DNA near the entry-exit site. Other subunits (Arp8p, Arp5p and Nhp10) were also found to be contacting both nucleosomal and extranucleosomal DNA. Site-specific histone cross-linking studies revealed that Ino80, Arp5 and Arp4 interact extensively with the histone dimer of the nucleosome in comparison to H3-H4 tetramer. Although N-terminal histone tails are often important for chromatin remodeling, INO80 shows no requirement of histone tails for its nucleosome binding and mobilizing activities. The deviation of INO80 from the canonical model of how ATP-dependent remodelers interact and mobilize nucleosome is apparently due to its unique role as a member of the remodeling complexes that promote the exchange of H2A/H2B dimer from core nucleosome particle.

Chromatin

Chromatin Remodeling

INO80

Nucleosome

Base Excision Repair in Chromatin

Prasad, Amalthiya

08 October 2008

ABSTRACT DNA in the eukaryotic nucleus is complexed with histone and non-histone proteins into chromatin. Nucleosomes, the basic repeating unit of chromatin, not only package DNA but are also intimately involved the regulation of gene expression. All DNA transactions including replication, transcription, recombination and repair take place in such a chromatin environment. Access to packaged nucleosomal DNA in vivo is mediated at least in part by protein complexes that modify or remodel chromatin. Buried sequences in nucleosomes can also transiently become accessible to DNA binding proteins during cycles of partial, reversible unwrapping of nucleosomal DNA from the histone octamer. We have investigated the ability of the human, bifunctional DNA glycosylase, endonuclease III (hNTH1), to initiate base excision repair (BER) of discretely positioned oxidative lesions in model nucleosomes. hNTH1 was able to process a thymine glycol (Tg) lesion almost as efficiently as naked DNA, when the minor groove of the lesion faced away from the histone octamer. Lesion processing did not require or result in detectable nucleosome disruption, as assayed in gel mobility-shift experiments. Instead, hNTH1 formed a slower migrating enzyme-nucleosome ternary complex that was found to contain processed DNA. Processing of an inward-facing Tg residue located just 5 bp away from the outward-facing lesion was much reduced and processing of a sterically occluded Tg residue positioned closer to the dyad center of the nucleosome was even more reduced. Notably, processing of both inward-facing lesions was found to increase as a function of enzyme concentration. Restriction enzyme protection studies indicated that access to these inward-facing lesions did not entail nucleosomal translocation or sliding. Collectively, these observations are consistent with a model in which hNTH1 binds to lesions during cycles of reversible, partial unwrapping of nucleosomal DNA from the histone octamer core. To further investigate this partial unwrapping hypothesis, we studied the kinetics of hNTH1 processing of sterically occluded lesions in greater detail. Our results suggest that efficiency of processing of inward-facing lesions is a function of both DNA unwrapping and rewrapping rates, and enzyme affinity for the lesion. In addition, we determined that APE1 which catalyzes the second step in BER, exhibited an increasing capacity to process inward-facing furan residues as its concentration was increased. Thus as with hNTH1, we hypothesize that APE1 can capture occluded furan residues during cycles of partial DNA unwrapping. We propose that cellular regulatory factors benefit from this intrinsic, periodic exposure of nucleosomal DNA exposure in vivo, which may be amplified by the downstream recruitment of remodeling and / or modifying proteins to facilitate DNA transactions in the cell.

chromatin

base excision repair

oxidative damage

nucleosome

Post-translational Modifications of Newly Synthesized Histones H3 and the Role of H3 K56 Acetylation on Chromatin Assembly in Mammalian Cells

Tacheva, Silvia K.

January 2010

Thesis advisor: Anthony T. Annunziato / The project I am presenting aimed to: 1. Elucidate the pattern of post- translational modification on the different variants of newly synthesized histones H3 in mammalian cells; 2. Reveal whether the acetylation of residue K56 on newly synthesized H3 histones plays a role in the incorporation of the histone into chromatin in mammalian cells; and 3. Determine whether the acetylation of residue K56 on newly synthesized H3 histones plays a role in the incorporation of the histone specifically in replicating chromatin in mammalian cells. The experiments to answer these questions were performed using HEK293 cells with inducible expression of FLAG-histones, enabling us to control the synthesis of new histones of interest and to detect and analyze their presence and relative levels in the cells. The results suggest that the acetylation of lysine 56 on histone H3 may play a positive role in the incorporation of the histone into new chromatin, and lack of acetylation may be reducing the efficiency of incorporation compared to acetylated histones. / Thesis (MS) — Boston College, 2010. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Biology.

acetylation

chromatin

deposition

histones

modification

nucleosome

Effect of naturally occurring DNA modifications on DNA structure and packaging

Li, Zhe

January 2019

In eukaryotes, the genomic double-stranded DNA (dsDNA) coils around histones to form nucleosomes. Arrays of these nucleosomes bundle together to generate chromatin. Most DNA-related processes require interactions between chromatin-protected DNA and cellular machinery. Access of cell machinery to genomic DNA is partially regulated by the position and stability of nucleosomes, which may be influenced by changes in nucleosomal DNA. DNA is composed of adenine (A), guanine (G), cytosine (C), thymine (T) nucleotides and their derivatives. It has been shown that some C derivatives participate in directing multiple biological processes, and aberrant modification patterns are often linked to diseases. It has been proposed that T derivatives exhibit similar effects. This thesis focuses on elucidating the effect of naturally occurring DNA modifications on the properties of dsDNA and nucleosomes. dsDNA sequences systematically modified with various T derivatives were characterized using classical biophysical techniques to assess the effect of these DNA modifications. The results indicate that in the sequence context studied, 5-hydroxymethyluracil modifications destabilize dsDNA, while dense symmetrical 5-formyluracil (fU) modifications alter the dsDNA structure. These effects may provide clues to the differential protein recruitment observed in previous research. In vitro studies on nucleosome occupancy and stability revealed that 5-formylcytosine (fC) modifications have positive effects on nucleosome formation and stability compared to the unmodified counterpart by influencing the intrinsic biochemical and biophysical properties of the nucleosomes. These results provide casual links for the observation in vivo between fC and the increased nucleosome occupancy and positioning. In order to further understand the positional effect of fC on the nucleosomes, a method was developed for quick and reliable incorporation of C derivatives into dsDNA at desired positions. The positive effect of fC modifications on nucleosome occupancy and stability observed here has necessitated further studies to gain deeper insights into the biological functions of fC in the nucleosome context. Cryo-EM can be used to elucidate the structural foundation for the changes fC posts to nucleosome, and protein interacting assays will identify the cellular machineries specifically recruited/repulsed by fC-modified nucleosomes. The effect of DNA modifications elucidated by the above studies advances our understanding on the role that DNA modifications play in regulating cellular processes.

Nucleosome positioning dynamics in evolution and disease

Hu, Zhenhua

January 2016

Nucleosome positioning is involved in a variety of cellular processes, and it provides a likely substrate for species evolution and may play roles in human disease. However, many fundamental aspects of nucleosome positioning remain controversial, such as the relative importance of underlying sequence features, genomic neighbourhood and trans-acting factors. In this thesis, I have focused on analyses of the divergence and conservation of nucleosome positioning, associated substitution spectra, and the interplay between them. I have investigated the extent to which nucleosome positioning patterns change following the duplication of a DNA sequence and its insertion into a new genomic region within the same species, by assessing the relative nucleosome positioning between paralogous regions in both the human (using in vitro and in vivo datasets) and yeast (in vivo) genomes. I observed that the positioning of paralogous nucleosomes is generally well conserved and detected a strong rotational preference where nucleosome positioning has diverged. I have also found, in all datasets, that DNA sequence features appear to be more important than local chromosomal environments in nucleosome positioning evolution, while controlling for trans-acting factors that can potentially confound inter-species comparisons. I have also examined the relationships between chromatin structure and DNA sequence variation, with a particular focus on the spectra of (germline and somatic) substitutions seen in human diseases. Both somatic and germline substitutions are found to be enriched at sequences coinciding with nucleosome cores. In addition, transitions appear to be enriched in germline relative to somatic substitutions at nucleosome core regions. This difference in transition to transversion ratio is also seen at transcription start sites (TSSs) genome wide. However, the contrasts seen between somatic and germline mutational spectra do not appear to be attributable to alterations in nucleosome positioning between cell types. Examination of multiple human nucleosome positioning datasets shows conserved positioning across TSSs and strongly conserved global phasing between 4 cancer cell lines and 7 non-cancer cell lines. This suggests that the particular mutational profiles seen for somatic and germline cells occur upon a common landscape of conserved chromatin structure. I extended my studies of mutational spectra by analysing genome sequencing data from various tissues in a cohort of individuals to identify human somatic mutations. This allowed an assessment of the relationship between age and mutation accumulation and a search for inherited genetic variants linked to high somatic mutation rates. A list of candidate germline variants that potentially predispose to increased somatic mutation rates was the outcome. Together these analyses contribute to an integrated view of genome evolution, encompassing the divergence of DNA sequence and chromatin structure, and explorations of how they may interact in human disease.

572.8

The Effects of Nucleosome Positioning and Chromatin Architecture on Transgene Expression

Kempton, Colton E.

01 June 2017

Eukaryotes use proteins to carefully package and compact their genomes to fit into the nuclei of their individual cells. Nucleosomes are the primary level of compaction. Nucleosomes are formed when DNA wraps around an octamer of histone proteins and a nucleosome's position can limit access to genetic regulatory elements. Therefore, nucleosomes represent a basic level of gene regulation. DNA and its associated proteins, called chromatin, is usually classified as euchromatin or heterochromatin. Euchromatin is transcriptionally active with loosely packed nucleosomes while heterochromatin is condensed with tightly packed nucleosomes and is transcriptionally silent. In order to become active, heterochromatin must first be remodeled. We have studied the effects of nucleosome positioning on transgene expression in vivo using Caenorhabditis elegans as a model. We show that both location and polarity of the DNA sequence can influence transgene expression. We also discuss some considerations for working with CRISPR/Cas9. A major reason for doing in vitro nucleosome reconstitutions is to determine the effects of DNA sequence on nucleosome formation and position. It has previously been implied that nucleosome reconstitutions are stochastic and not very reproducible. We show that nucleosome reconstitutions are highly reproducible under our reaction conditions. Our results also indicate that a minimum depth of 35X sequencing coverage be maintained for maximal gains in Pearson's correlation coefficients. Communicating science with others is an important skill for any researcher. The rising generation of scientists need mentors who can teach them how to be independent thinkers who can carry out scientific experiments and communicate their finding to others. With this goal in mind, we have devised a scaffolding pedagogical method to help transform undergraduates into confident independent thinkers and researchers.

nucleosome

CRISPR/Cas9

Caenorhabditis elegans

Microbiology

Regulation of the polycomb repressive complexes by histone reader domains

Weaver, Tyler M.

01 May 2019

Histone post-translational modifications (PTMs) are key determinants of the local chromatin landscape and critical for regulation of eukaryotic gene expression. These histone marks are deposited by a vast number of chromatin modifying enzymes and preferentially recognized by specific associated histone reader domains. Recognition of histone PTMs by histone reader domains is important for either targeting these complexes to chromatin or regulating their enzymatic activity once there. The Polycomb repressive complex 1 and 2 (PRC1 and PRC2) are two such chromatin modifying complexes that are critical for developmental gene repression. The enzymatic activity of PRC2 is tightly regulated by many histone reader domains whereas the PRC1 complex is targeted to chromatin through these domains. In this thesis, I explore how PRC1 and PRC2 functions are regulated by histone reader domains. I identify a previously unrecognized histone reader domain within the PRC2 complex, the EZH2 SANT1 domain, which has important implications for regulating PRC2 enzymatic activity. In addition, I explore the mechanism through which the CBX8 chromodomain targets the PRC1 complex to chromatin. Together, these studies provide significant insight into the regulation of chromatin modifying complexes by histone reader domains and how this occurs via multiple mechanisms.

Chromatin

Histone Reader Domain

NMR

Nucleosome

Biochemistry

Chromatin dynamics at the Saccharomyces cerevisiae PHO5 promoter

Jessen, Walter Joseph

12 April 2006

In eukaryotes, the organization of DNA into chromatin is a primary determinant of gene expression. Positioned nucleosomes in promoter regions are frequently found to regulate gene expression by obstructing the accessibility of cis-regulatory elements in DNA to trans-factors. This dissertation focuses on the chromatin structure and remodeling program at the S. cerevisiae PHO5 promoter, extending the use of DNA methyltransferases as in vivo probes of chromatin structure. Our studies address the diversity of histone-DNA interactions in vivo by examining nucleosome conformational stabilities at the PHO5 promoter. We present high-resolution chromatin structural mapping of the promoter, required to relate in vivo site accessibility to nucleosome stability and show that the PHO5 promoter nucleosomes have different accessibilities. We show a correlation between DNA curvature and nucleosome positioning, which is consistent with the observed differences in accessibility/stability. Kinetic analyses of the chromatin remodeling program at PHO5 show that nucleosomes proximal to the enhancer are disrupted preferentially and prior to those more distal, demonstrating bidirectional and finite propagation of chromatin remodeling from bound activators and providing a novel mechanism by which transactivation at a distance occurs.

PHO5

promoter

chromatin

remodeling

nucleosome

accessibility

Chromatin dynamics at the Saccharomyces cerevisiae PHO5 promoter

Jessen, Walter Joseph

12 April 2006

In eukaryotes, the organization of DNA into chromatin is a primary determinant of gene expression. Positioned nucleosomes in promoter regions are frequently found to regulate gene expression by obstructing the accessibility of cis-regulatory elements in DNA to trans-factors. This dissertation focuses on the chromatin structure and remodeling program at the S. cerevisiae PHO5 promoter, extending the use of DNA methyltransferases as in vivo probes of chromatin structure. Our studies address the diversity of histone-DNA interactions in vivo by examining nucleosome conformational stabilities at the PHO5 promoter. We present high-resolution chromatin structural mapping of the promoter, required to relate in vivo site accessibility to nucleosome stability and show that the PHO5 promoter nucleosomes have different accessibilities. We show a correlation between DNA curvature and nucleosome positioning, which is consistent with the observed differences in accessibility/stability. Kinetic analyses of the chromatin remodeling program at PHO5 show that nucleosomes proximal to the enhancer are disrupted preferentially and prior to those more distal, demonstrating bidirectional and finite propagation of chromatin remodeling from bound activators and providing a novel mechanism by which transactivation at a distance occurs.

PHO5

promoter

chromatin

remodeling

nucleosome

accessibility