Recombinational Repair of a Chromosomal DNA Double Strand Break: A Dissertation

Sinha, Manisha

16 March 2009

Repairing a chromosomal DNA double strand break is essential for survival and maintenance of genomic integrity of a eukaryotic organism. The eukaryotic cell has therefore evolved intricate mechanisms to counteract all sorts of genomic insults in the context of chromatin structure. Modulating chromatin structure has been crucial and integral in regulating a number of conserved repair processes along with other fundamental genomic processes like replication and transcription. The work in this dissertation has focused on understanding the role of chromatin remodeling enzymes in the repair of a chromosomal DNA double strand break by homologous recombination. This has been approached by recapitulating the biochemical formation of recombination intermediates on chromatin in vitro. In this study, we have demonstrated that the mere packaging of DNA into nucleosomal structure does not present a barrier for successful capture of homologous DNA sequences, a central step of the biochemical pathway of recombinational repair. It is only the assembly of heterochromatin-like more complex nucleo-protein structure that presents additional constraints to this key step. And, this additional constraint can be overcome by the activities of ATP-dependent chromatin remodeling enzymes. These findings have great implications for our perception of the mechanism of the recombinational repair process of a chromosomal DNA double strand break within the eukaryotic genome.

DNA Repair

Recombination

Genetic

Nucleosomes

Rad51 Recombinase

Saccharomyces cerevisiae Proteins

Chromatin Assembly and Disassembly

Heterochromatin

Amino Acids, Peptides, and Proteins

Cells

Enzymes and Coenzymes

Fungi

Genetic Phenomena

hox Gene Regulation and Function During Zebrafish Embryogenesis: A Dissertation

Weicksel, Steven E.

28 October 2013

Hox genes encode a conserved family of homeodomain containing transcription factors essential for metazoan development. The establishment of overlapping Hox expression domains specifies tissue identities along the anterior-posterior axis during early embryogenesis and is regulated by chromatin architecture and retinoic acid (RA). Here we present the role nucleosome positioning plays in hox activation during embryogenesis. Using four stages of early embryo development, we map nucleosome positions at 37 zebrafish hox promoters. We find nucleosome arrangement to be progressive, taking place over several stages independent of RA. This progressive change in nucleosome arrangement on invariant sequence suggests that trans-factors play an important role in organizing nucleosomes. To further test the role of trans-factors, we created hoxb1b and hoxb1a mutants to determine if the loss of either protein effected nucleosome positions at the promoter of a known target, hoxb1a. Characterization of these mutations identified hindbrain segmentation defects similar to targeted deletions of mouse orthologs Hoxa1 and Hoxb1 and zebrafish hoxb1b and hoxb1a morpholino (MO) loss-of-function experiments. However, we also identified differences in hindbrain segmentation as well as phenotypes in facial motor neuron migration and reticulospinal neuron formation not previously observed in the MO experiments. Finally, we find that nucleosomes at the hoxb1a promoter are positioned differently in hoxb1b-/- embryos compared to wild-type. Together, our data provides new insight into the roles of hoxb1b and hoxb1a in zebrafish hindbrain segmentation and reticulospinal neuron formation and indicates that nucleosome positioning at hox promoters is dynamic, depending on sequence specific factors such as Hox proteins.

Homeobox Genes

Homeodomain Proteins

Zebrafish

Zebrafish Proteins

Embryonic Development

Nucleosomes

Developmental Gene Expression Regulation

Dissertations, UMMS

Genes, Homeobox

Developmental Biology

Genetics

Genomics

Molecular Genetics

Dissecting cis and trans Determinants of Nucleosome Positioning: A Dissertation

Hughes, Amanda L.

14 November 2014

Eukaryotic DNA is packaged in chromatin, whose repeating subunit, the nucleosome, consists of an octamer of histone proteins wrapped by about 147bp of DNA. This packaging affects the accessibility of DNA and hence any process that occurs on DNA, such as replication, repair, and transcription. An early observation from genome-wide nucleosome mapping in yeast was that genes had a surprisingly characteristic structure, which has motivated studies to understand what determines this architecture. Both sequence and trans acting factors are known to influence chromatin packaging, but the relative contributions of cis and trans determinants of nucleosome positioning is debated. Here we present data using genetic approaches to examine the contributions of cis and trans acting factors on nucleosome positioning in budding yeast. We developed the use of yeast artificial chromosomes to exploit quantitative differences in the chromatin structures of different yeast species. This allows us to place approximately 150kb of sequence from any species into the S.cerevisiae cellular environment and compare the nucleosome positions on this same sequence in different environments to discover what features are variant and hence regulated by trans acting factors. This method allowed us to conclusively show that the great preponderance of nucleosomes are positioned by trans acting factors. We observe the maintenance of nucleosome depletion over some promoter sequences, but partial fill-in of NDRs in some of the YAC v promoters indicates that even this feature is regulated to varying extents by trans acting factors. We are able to extend our use of evolutionary divergence in order to search for specific trans regulators whose effects vary between the species. We find that a subset of transcription factors can compete with histones to help generate some NDRs, with clear effects documented in a cbf1 deletion mutant. In addition, we find that Chd1p acts as a potential “molecular ruler” involved in defining the nucleosome repeat length differences between S.cerevisiae and K.lactis. The mechanism of this measurement is unclear as the alteration in activity is partially attributable to the N-terminal portion of the protein, for which there is no structural data. Our observations of a specialized chromatin structure at de novo transcriptional units along with results from nucleosome mapping in the absence of active transcription indicate that transcription plays a role in engineering genic nucleosome architecture. This work strongly supports the role of trans acting factors in setting up a dynamic, regulated chromatin structure that allows for robustness and fine-tuning of gene expression.

Chromatin

Chromatin Assembly and Disassembly

Artificial Yeast Chromosomes

DNA

Nucleosomes

Saccharomyces cerevisiae

Trans-Activators

Dissertations, UMMS

Chromosomes, Artificial, Yeast

Biochemistry

Genetics and Genomics

Investigation of the structure and dynamics of the centromeric epigenetic mark

Padeganeh, Abbas

04 1900

Le centromère est le site chromosomal où le kinetochore se forme, afin d’assurer une ségrégation fidèles des chromosomes et ainsi maintenir la ploïdie appropriée lors de la mitose. L’identité du centromere est héritée par un mécanisme épigénétique impliquant une variante de l’histone H3 nommée centromere protein-A (CENP-A), qui remplace l’histone H3 au niveau de la chromatine du centromère. Des erreurs de propagation de la chromatine du centromère peuvent mener à des problèmes de ségrégation des chromosomes, pouvant entraîner l’aneuploïdie, un phénomène fréquemment observé dans le cancer. De plus, une expression non-régulée de CENP-A a aussi été rapportée dans différentes tumeurs humaines. Ainsi, plusieurs études ont cherchées à élucider la structure et le rôle de la chromatine contenant CENP-A dans des cellules en prolifération. Toutefois, la nature moléculaire de CENP-A en tant que marqueur épigénétique ainsi que ces dynamiques à l'extérieur du cycle cellulaire demeurent des sujets débat. Dans cette thèse, une nouvelle méthode de comptage de molécules uniques à l'aide de la microscopie à réflexion totale interne de la fluorescence (TIRF) sera décrite, puis exploitée afin d'élucider la composition moléculaire des nucléosomes contenant CENP-A, extraits de cellules en prolifération. Nous démontrons que les nucléosomes contenant CENP-A marquent les centromères humains de façon épigénétique à travers le cycle cellulaire. De plus, nos données démontrent que la forme prénucléosomale de CENP-A, en association avec la protéine chaperon HJURP existe sous forme de monomère et de dimère, ce qui reflète une étape intermédiaire de l'assemblage de nucléosomes contenant CENP-A. Ensuite, des analyses quantitatives de centromères lors de différenciation myogénique, et dans différents tissus adultes révèlent des changements globaux qui maintiennent la marque épigénétique dans une forme inactive suite à la différentiation terminale. Ces changements incluent une réduction du nombre de points focaux de CENP-A, un réarrangement des points dans le noyau, ainsi qu'une réduction importante de la quantité de CENP-A. De plus, nous démontrons que lorsqu'une dédifférenciation cellulaire est induite puis le cycle cellulaire ré-entamé, le phénotype "différencié" décrit ci-haut est récupéré, et les centromères reprennent leur phénotype "prolifératif". En somme, cet oeuvre décrit la composition structurale sous-jacente à l'identité épigénétique des centromères de cellules humaines lors du cycle cellulaire, et met en lumière le rôle de CENP-A à l'extérieur du cycle cellulaire. / The centromere is a unique chromosomal locus where the kinetochore is formed to mediate faithful chromosome partitioning, thus maintaining ploidy during cell division. Centromere identity is inherited via an epigenetic mechanism involving a histone H3 variant, called centromere protein-A (CENP-A) which replaces histone H3 in centromeric chromatin. Defects in the centromeric chromatin can lead to missegregation of chromosomes resulting in aneuploidy, a ¬¬frequently observed phenomenon in cancer. Moreover, deregulated CENP-A expression has also been documented in a number of human malignancies. Therefore, much effort has been devoted to uncover the structure and role of CENP-A-containing chromatin in proliferating cells. However, the molecular nature of this epigenetic mark and its potential dynamics during and outside the cell cycle remains controversial. In this thesis, the development of a novel single-molecule imaging approach based on total internal reflection fluorescence and the use of this assay to gain quantitative information about the molecular composition of CENP-A-containing nucleosomes extracted from proliferating cells throughout the cell cycle as well as the dynamics and cellular fate of CENP-A chromatin in terminal differentiation are described. Here, we show that octameric CENP-A nucleosomes containing core Histones H2B and H4 epigenetically mark human centromeres throughout the cell cycle. Moreover, our data demonstrate that the prenucleosomal form of CENP-A bound by the chaperone HJURP transits between monomeric and dimeric forms likely reflecting intermediate steps in CENP-A nucleosomal assembly. Moreover, quantitative analyses of centromeres in myogenic differentiation and adult mouse tissue sections revealed that centromeres undergo global changes in order to retain a minimal CENP-A epigenetic code in an inactive state, upon induction of terminal differentiation. These include a robust decrease in the number of centromeric foci, subnuclear rearrangement as well as extensive loss of CENP-A protein. Interestingly, we show that forced dedifferentiation under cell cycle reentry permissive conditions, rescued the above-mentioned phenotype concomitantly with the restoration of cell division. Altogether, this work delineates the structural basis for the epigenetic specification of human centromeres during the cell cycle and sheds light on the cellular fate of the CENP-A epigenetic code outside the cell cycle.

Nucleosomes

Chromosome

Centromere

Kinetochore

Stem cell differentiation

Single-molecule imaging

Epigenetics

Cancer

Aneuploidy

Cell cycle

Nucléosomes

Centromère

Cycle cellulaire

Différenciation des cellules souches

L'imagerie molécules uniques

Épigénétique

Cancer

Aneuploïdie

Chromosome

Kinetochore

RNA Exosome & Chromatin: The Yin & Yang of Transcription: A Dissertation

Rege, Mayuri

12 November 2015

Eukaryotic genomes can produce two types of transcripts: protein-coding and non-coding RNAs (ncRNAs). Cryptic ncRNA transcripts are bona fide RNA Pol II products that originate from bidirectional promoters, yet they are degraded by the RNA exosome. Such pervasive transcription is prevalent across eukaryotes, yet its regulation and function is poorly understood. We hypothesized that chromatin architecture at cryptic promoters may regulate ncRNA transcription. Nucleosomes that flank promoters are highly enriched in two histone marks: H3-K56Ac and the variant H2A.Z, which make nucleosomes highly dynamic. These histone modifications are present at a majority of promoters and their stereotypic pattern is conserved from yeast to mammals, suggesting their evolutionary importance. Although required for inducing a handful of genes, their contribution to steady-state transcription has remained elusive. In this work, we set out to understand if dynamic nucleosomes regulate cryptic transcription and how this is coordinated with the RNA exosome. Remarkably, we find that H3-K56Ac promotes RNA polymerase II occupancy at a large number of protein coding and noncoding loci, yet neither histone mark has a significant impact on steady state mRNA levels in budding yeast. Instead, broad effects of H3-K56Ac or H2A.Z on levels of both coding and ncRNAs are only revealed in the absence of the nuclear RNA exosome. We show that H2A.Z functions with H3-K56Ac in chromosome folding, facilitating formation of Chromosomal Interaction Domains (CIDs). Our study suggests that H2A.Z and H3-K56Ac work in concert with the RNA exosome to control mRNA and ncRNA levels, perhaps in part by regulating higher order chromatin structures. Together, these chromatin factors achieve a balance of RNA exosome activity (yin; negative) and Pol II (yang; positive) to maintain transcriptional homeostasis.

chromatin

H3-K56Ac

H2A.Z

ncRNAs

RNA exosome

chromosome interaction domains

Dissertations, UMMS

Chromatin

Exosomes

Homeostasis

Nucleosomes

RNA, Messenger

Saccharomyces cerevisiae

RNA, Long Noncoding

Transcription Factors

Biochemistry

Molecular Biology

Molecular Genetics

Structural Biology