Genome-wide Analysis of Chromatin Structure across Diverse Human Cell Types

Winter, Deborah R.

January 2013

<p>Chromatin structure plays an important role in gene regulation, especially in differentiating the diverse cell types in humans. In this dissertation, we analyze the nucleosome positioning and open chromatin profiles genome-wide and investigate the relationship with transcription initiation, the activity of regulatory elements, and expression levels. We mainly focus on the results of DNase-seq experiments, but also employ annotations from MNase-seq, FAIRE-seq, ChIP-seq, CAGE, and RNA microarrays. Our methods are based on computational approaches including managing large data sets, statistical analysis, and machine learning. We find that different transcription initiation patterns lead to distinct chromatin structures, suggesting diverse regulatory strategies. Moreover, we present a tool for comparing genome-wide annotation tracks and evaluate DNase-seq against a unique assay for detecting open chromatin. We also demonstrate how DNase-seq can be used to successfully predict rotationally stable nucleosomes that are conserved across cell types. We conclude that DNase-seq can be used to study genome-wide chromatin structure in an effort to better understand how it regulates gene expression.</p> / Dissertation

Bioinformatics

Molecular biology

computational biology

DNase-seq

nucleosome positioning

open chromatin

A Characterization of the Role of Post-translational Modification in Transcriptional Regulation by the Histone Variant H2A.Z

Draker, Ryan

11 December 2012

H2A.Z is an essential histone variant that has multiple chromosomal functions. One such role is transcriptional regulation. However, its role in this process is complex since it has been reported to function both as a repressor and activator. Earlier work in our lab showed that H2A.Z can be post-translationally modified with monoubiquitin (H2A.Zub1) and this form of H2A.Z is linked to transcriptional silencing. We further predicted that changes in the H2A.Z ubiquitylation status directly modulated its function in transcription. Furthermore, H2A.Z-containing nucleosomes possess a unique set of post-translational modifications (PTMs), compared to H2A nucleosomes, many of which are linked to transcriptional activation. The central aim of this thesis was to characterize the role of PTMs on H2A.Z nucleosomes in transcriptional regulation. To this end, I have provided the first evidence linking H2A.Z deubiquitylation to transcriptional activation. I demonstrated that ubiquitin specific protease 10 (USP10) is a deubiquitylase that targets H2A.Z in vitro and in vivo. Moreover, I found that both H2A.Z and USP10 are required for activation of androgen-receptor (AR)-regulated genes, and that USP10 regulates the levels of H2A.Zub1 at these genes. To understand how H2A.Z engages downstream effector proteins, in the nucleosome context, we used a mass spectrometry approach to identify H2A.Z-nucleosome-interacting proteins. Many of the identified proteins contained conserved structural motifs that bind post-translationally modified histones. For example, we found that Brd2 contains tandem bromodomains that engage H2A.Z nucleosomes through acetylated H4 residues. To investigate the biological relevance of this interaction, I present evidence that Brd2 is recruited to AR-regulated genes in a manner dependent on H2A.Z and the bromodomains of Brd2. Consistent with this observation, chemical inhibition of Brd2 recruitment greatly inhibited AR-regulated gene expression. Collectively, these studies have defined how H2A.Z mediates transcriptional regulation through multiple mechanisms and pathways.

chromatin

histone variants

H2A.Z

transcription

androgen receptor

post-translational modifications

0307

Roles for the Cohibin Complex and its Associated Factors in the Maintenance of Several Silent Chromatin Domains in S. cerevisiae

Poon, Betty Po Kei

26 November 2012

In Saccharomyces cerevisiae, the telomeres and rDNA repeats are repetitive silent chromatin domains that are tightly regulated to maintain silencing and genome stability. Disruption of the Cohibin complex, which maintains rDNA silencing and stability, also abrogates telomere localization and silencing. Cohibin-deficient cells have decreased Sir2 localization at telomeres, and restoring telomeric Sir2 concentrations rescues the telomeric defects observed in Cohibin-deficient cells. Genetic and molecular interactions suggest that Cohibin clusters telomeres to the nuclear envelope by binding inner nuclear membrane proteins. Futhermore, telomeric and rDNA sequences can form G-quadruplex structures. G-quadruplexes are non-canonical DNA structures that have been linked to processes affecting chromosome stability. Disruption of the G-quadruplex stabilizing protein Stm1, which also interacts with Cohibin, increases rDNA stability without affecting silent chromatin formation. In all, our findings have led to the discovery of new processes involved in the maintenance of repetitive silent chromatin domains that may be conserved across eukaryotes.

Cohibin

G-quadruplex

telomere

ribosomal DNA

silent chromatin

genome stability

0369

0307

In Vitro Function of Frozen-Thawed Bottlenose Dolphin (Tursiops truncatus) Spermatozoa Undergoing Sorting and Recyopreservation

Montano Pedroso, Gisele 1981-

14 March 2013

Artificial insemination (AI) with sex-sorted bottlenose dolphin spermatozoa provides female calves for obtaining more cohesive social groups and optimum genetic management of captive populations. However, distance of animals to the sorting facility represents a limit to the procedure. Although one bottlenose dolphin calf has been born using spermatozoa from frozen-thawed, sorted and recryopreserved spermatozoa, critical evaluation of the steps involved in this process is required to maximize its efficiency for future AIs and expansion of the technology to other species. Two experiments were designed to determine the efficiency of the sorting process and the quality of frozen-thawed bottlenose dolphin spermatozoa during sorting and recryopreservation. In experiment 1, the effect of two washing media (with and without 4 percent egg yolk, v/v) following density gradient centrifugation (DGC) on sperm recovery rate and in vitro characteristics of cryopreserved spermatozoa was examined. In experiment 2, cryopreserved semen was used to compare the effects of two recryopreservation methods (conventional straw freezing and directional freezing) on in vitro sperm characteristics of control (non-sorted) and sorted spermatozoa. Egg yolk supplementation of the washing medium in experiment 1 did not influence (P > 0.05) the sperm recovery rate, however, sperm motility parameters and viability were improved (P < 0.05). For Experiment 2, motility parameters and viability were influenced by stage of sex-sorting process, sperm type (non-sorted and sorted) and freezing method (P < 0.05). After recryopreservation, sorted spermatozoa frozen with the directional freezing method maintained higher (P < 0.05) motility parameters over the 24 h incubation period compared to spermatozoa frozen using straws. Quality of sperm DNA of nonsorted spermatozoa, as assessed by the SCSA, remained unchanged throughout the process. However, a possible interaction between Hoechst 33342 and acridine orange was observed in sorted samples. After recryopreservation, viability of sorted spermatozoa was higher (P < 0.05) than that of non-sorted spermatozoa across all time points. The percentages of viable spermatozoa determined by light (eosin-nigrosin) and fluorescence microscopy (propidium iodide) techniques were correlated (R^2=0.79, P < 0.001). Collective results indicate that bottlenose dolphin spermatozoa undergoing cryopreservation, sorting and recryopreservation are of adequate quality for use in AI.

sperm sorting

sperm cryopreservation

sperm chromatin structure assay

cetacean

artificial insemination

Sequence Determinants of In Vivo and Intrinsic Nucleosome Occupancy

Tillo, Desiree C.

31 August 2011

The genomes of all eukaryotic organisms are packaged into chromatin, the fundamental unit of which is the nucleosome. Since the proposal of the nucleosome as the primary repeating unit of chromatin structure in 1974, it has become clear that the biological roles of nucleosomes extend far beyond simple DNA packaging and include virtually all processes involving the genome. Despite the integral roles of nucleosomes in many fundamental biological processes, the relative contributions of the cellular cues and sequence features that directly govern their arrangement on genomic DNA remain unclear. In this Thesis, I characterise the sequence preferences of nucleosomes using data sets derived from genome-wide studies. I describe the analysis of data derived from the first genome-wide map of in vivo nucleosome occupancy across a eukaryotic genome (in this case, the budding yeast, Saccharomyces cerevisiae). Using these data, I construct a sequence-based linear model of nucleosome occupancy that takes into account structural features of DNA (which correlate with simple base composition) as well as transcription factor (TF) binding site information, which has significant ability to predict nucleosome occupancy in vivo. I go on to test particular aspects of this model and show that genetic perturbation of TFs that the in vivo model deems important (Abf1, Reb1, and Rsc3) have the expected effects, an increase in nucleosome occupancy over their cognate binding sites as well as a reduction in transcription from the corresponding genes, suggesting that these factors are required for promoter function and definition. I also confirm that in vitro nucleosome occupancy correlates highly with sequence features important for nucleosome occupancy in vivo and go on to develop a simple model for nucleosome occupancy based solely on histone-DNA interactions. This model suggests that base composition (G+C content) is a dominant feature in determining intrinsic nucleosome occupancy. Finally, I apply a model of intrinsic nucleosome occupancy to the human genome and show that there is a fundamental difference in intrinsic nucleosome occupancy at regulatory regions across species. This finding illustrates a potential functional consequence of variation in base composition in eukaryotic genomes.

nucleosomes

chromatin

gene regulation

transcription

transcription factors

genomics

computational biology

0307

0715

Sequence Determinants of In Vivo and Intrinsic Nucleosome Occupancy

Tillo, Desiree C.

31 August 2011

The genomes of all eukaryotic organisms are packaged into chromatin, the fundamental unit of which is the nucleosome. Since the proposal of the nucleosome as the primary repeating unit of chromatin structure in 1974, it has become clear that the biological roles of nucleosomes extend far beyond simple DNA packaging and include virtually all processes involving the genome. Despite the integral roles of nucleosomes in many fundamental biological processes, the relative contributions of the cellular cues and sequence features that directly govern their arrangement on genomic DNA remain unclear. In this Thesis, I characterise the sequence preferences of nucleosomes using data sets derived from genome-wide studies. I describe the analysis of data derived from the first genome-wide map of in vivo nucleosome occupancy across a eukaryotic genome (in this case, the budding yeast, Saccharomyces cerevisiae). Using these data, I construct a sequence-based linear model of nucleosome occupancy that takes into account structural features of DNA (which correlate with simple base composition) as well as transcription factor (TF) binding site information, which has significant ability to predict nucleosome occupancy in vivo. I go on to test particular aspects of this model and show that genetic perturbation of TFs that the in vivo model deems important (Abf1, Reb1, and Rsc3) have the expected effects, an increase in nucleosome occupancy over their cognate binding sites as well as a reduction in transcription from the corresponding genes, suggesting that these factors are required for promoter function and definition. I also confirm that in vitro nucleosome occupancy correlates highly with sequence features important for nucleosome occupancy in vivo and go on to develop a simple model for nucleosome occupancy based solely on histone-DNA interactions. This model suggests that base composition (G+C content) is a dominant feature in determining intrinsic nucleosome occupancy. Finally, I apply a model of intrinsic nucleosome occupancy to the human genome and show that there is a fundamental difference in intrinsic nucleosome occupancy at regulatory regions across species. This finding illustrates a potential functional consequence of variation in base composition in eukaryotic genomes.

nucleosomes

chromatin

gene regulation

transcription

transcription factors

genomics

computational biology

0307

0715

The Ribosomal DNA Genes Influence Genome-Wide Gene Expression in Drosophila melanogaster

Paredes Martinez, Lida Silvana

2011 May 1900

Chromatin structure is a fundamental determinant of eukaryotic gene expression and it is composed of two chromatin environments, euchromatin and heterochromatin. Euchromatin provides an accessible platform for transcription factors; hence it is permissive for gene expression. Heterochromatin on the other hand is highly compacted and inaccessible, which in most cases leads to transcriptional repression. A locus that is composed of both of these environments is the ribosomal DNA (rDNA). In eukaryotes the rDNA is composed of hundreds to thousands of tandemly repeated genes where maintaining both silent and active copies is fundamental for the stability of the genome. The aim of this research was to investigate the role of the rDNA in gene expression in Drosophila melanogaster. In D. melanogaster the rDNA loci are present on the X and Y chromosomes. This research used the Y-linked rDNA array to investigate the role of this locus on gene expression. A genetic and molecular strategy was designed to create and quantify specific, graded and isogenic Y- linked rDNA deletions. Then the deletions were used to address the effect of rDNA deletions on gene expression using reporter genes sensitive to Position Effect Variegation (PEV). In addition, the effect of the deletions in nucleolus size and structure as well as the effect of spontaneous rDNA deletions on gene expression were tested in this study. This research found that changes in rDNA size change the chromatin balance, which resulted in increased expression of the reporter genes, decreased nucleolus volume, and altered nucleolus structure. These findings prompted a further research question on whether this effect on gene expression occured globally in the genome. This was addressed by performing microarray analysis where the results showed that rDNA deletions affect about half of the genes on the genome. Presented in this dissertation is evidence that suggest a novel role for the rDNA is a global modulator of gene expression and also is a contributor to the gene expression variance observed in natural populations.

Chromatin

Position Effect Variegation (PEV)

Ribosomal DNA

epigenetics

Nucleolus

transcriptional profiling

genetics

The Role of Chromatin Structure and Histone Modifications in Gene Silencing at the Ribosomal DNA Locus in Saccharomyces cerevisiae

Williamson, Kelly M.

2011 May 1900

One of the fundamental questions in science is how chromatin transitions from actively transcribed euchromatin to silent heterochromatin, and what factors affect this transition. One area of my research has focused on understanding the differences in the chromatin structure of active and silent regions in the ribosomal DNA locus (rDNA), a heterochromatin region in S. cerevisiae. Secondly, I have focused on understanding a histone methyltransferase Set1, which is involved in both euchromatin and heterochromatin regions. To distinguish actively transcribed open regions of chromatin from silent and closed regions of chromatin, we have expressed a DNA methyltransferase M.CviPI in vivo to utilize its accessibility to GpC sites. We have used this technique to study changes in nucleosome positioning within the NTS2 region of the rDNA in two cases: as a result of a silencing defect caused by the loss of Sir2, a histone deacetylase involved in silencing at the rDNA, and as an indicator of active transcription by RNA Pol I. Using this technique, we observed differences between open and closed chromatin structure by changes in nucleosome positioning within NTS2. Additionally, we have observed the presence of bound factors within the 35S rRNA gene promoter that are unique to actively transcribed genes. The second area of my research focused on the protein methyltransferase Set1 that mono-, di-, and trimethylates lysine 4 of histone H3 (H3K4) utilizing the methyl group from S-adenosyl methionine (SAM). Set1 is part of a multi protein complex called COMPASS (Complex associated with Set1), and is associated with both actively transcribed and silent regions. Thirty mutants of Set1 were made within the SET domain to learn more about the catalytic mechanism of Set1. The crystal structures of human SET domain proteins, as well as sequence alignments and a random mutagenesis of yeast Set1, were used to identify conserved amino acids in the SET domain of Set1. Mutants were analyzed for their effect on histone methylation in vivo, silencing of RNA Pol II transcription within the rDNA, suppression of ipl1-2, and COMPASS complex formation. Our results show that trimethylated H3K4 is required for silencing of RNA Pol II transcription at the rDNA. Overall, we have shown the importance of tyrosine residues in SET domain proteins. To summarize, my research has strived to understand chromatin structure and the factors that affect the transition between euchromatin and heterochromatin.

histone methylation

gene silencing

ribosomal DNA locus

chromatin structure

Saccharomyces cerevisiae

Generation and characterization of a knock-in allele of EKLF probing the in vivo role of the chromatin remodeling domain in definitive hematopoietic cells /

Jansen, Valerie Malyvanh,

January 2009

Thesis (Ph.D.)--University of Tennessee Health Science Center, 2009. / Title from title page screen (viewed on February 4, 2010). Research advisor: John M. Cunningham, M.D. Document formatted into pages (xiv, 115 p. : ill.). Vita. Abstract. Includes bibliographical references (p. 89-103).

Novel Roles for the Transcriptional Repressor PRDM1 in Human Natural Killer Cells and Identification of an Inhibitor of its Interacting Methyltransferase G9a

Smith, Matthew Adams

01 January 2011

The studies presented within this dissertation provide the first description of PRDM1 (also known as Blimp-1 or PRDI-BF1) function in natural killer cells. NK cells are major effectors of the innate immune response via antigen-independent cytotoxicity and link to the adaptive immune response through cytokine release. Molecular mechanisms mediating NK activation are relatively well-studied; however, much less is known about the mechanisms that restrain activation. In the first study, the transcriptional repressor PRDM1 is shown to be a critical negative regulator of NK function. Microarray analysis was used to characterize transcriptional changes associated with cytokine-mediated activation. PRDM1 is expressed at low levels in resting NK cells and three distinct PRDM1 isoforms are selectively induced in the CD56dim NK population in response to activation. PRDM1 coordinately suppresses the production of IFNγ, TNFα and TNFβ through direct binding to multiple conserved regulatory regions. Ablation of PRDM1 expression leads to enhanced production of IFNγ and TNFα but does not alter cytotoxicity, whereas over-expression blocks cytokine production. PRDM1 response elements are defined at the IFNG and TNF loci. To further delineate the targets of PRDM1-mediated regulation in NK cells, global approaches were utilized. Experiments utilizing chromatin immunoprecipitation coupled to promoter tiling arrays identified 292 novel direct targets of PRDM1 binding. These studies revealed widespread binding of PRDM1 to the genome, which was not limited to proximal promoter regions. Furthermore, microarray analysis of stimulated NK cells combined with PRDM1 knockdown has enabled the identification of genes responsive to PRDM1 knockdown using primary cells. Collectively, these experiments identify both direct and indirect targets of PRDM1 regulation and help define a PRDM1-centered gene regulatory network in NK cells. Data presented in the final chapter pertains to an independent project aimed at identifying small molecule inhibitors of the methyltransferase G9a, which is recruited by PRDM1 and is required for silencing of target genes. A mass spectrometry-based assay was developed and used to screen a small molecule library. Several hits were identified and combinatorial chemistry yielded several compounds with < 20µM IC50 values. In cell-based assays, however, treatment with the small molecules had limited efficacy, indicating additional chemical modifications are necessary to yield bioactive compounds. The data presented here demonstrate a key role for PRDM1 in the negative regulation of NK activation and position PRDM1 as a common regulator of the adaptive and innate immune response.

Blimp-1

Chromatin

Cytokines

Innate Immunity

American Studies

Arts and Humanities

Immunology and Infectious Disease

Molecular Biology