Integrated Chromatin Analyses Offer Insights Into Trans-factor Function In Cancer Cell Lines

Tewari, Alok

January 2012

<p>Understanding the mechanisms whereby the sequence of the human genome is interpreted into diverse cellular phenotypes is a critical endeavor in modern biology. A major determinant of cellular phenotype is the spatial and temporal pattern gene expression, which is regulated in part by epigenomic properties such as histone post-translational modifications, DNA methylation, chromatin accessibility and the 3-dimensional architecture of the genome within the nucleus. These properties regulate the dynamic assembly of transcription factors and their co-regulatory proteins upon chromatin. To properly understand the interplay between the epigenomic framework of a cell and transcription factors, integrated analysis of transcription factor-DNA binding, chromatin status, and transcription is required. This work integrates information about chromatin accessibility, as measured by DNaseI hypersensitivity, transcription factor binding, as measured by chromatin immunoprecipitation, and transcription, as measured by microarray or transcriptome sequencing, to further understand the functional role of two important transcription factors, the androgen receptor (AR) and CTCF, in cancer cell line models. Data gathered from a prostate cancer cell line model demonstrate that the AR does not exclusively bind accessible chromatin upon ligand-activation, and induces significant changes in chromatin accessibility upon binding. Regions of quantitative change in chromatin accessibility contain motifs corresponding to potential collaborators for AR function, and are also significantly associated with AR-regulated transcriptional changes. Furthermore, base pair resolution of the DNaseI cleavage profile revealed three distinct patterns of AR-DNA interaction, suggesting multiple modes of AR interacting with the genome. A novel role for the nuclear receptor REV-ERB&#945; in AR-mediated transcription was explored within the same model system. Though preliminary, results thus far indicate that REV-ERB&#945; is required for AR-induced increases in target gene transcription in a manner that is likely dependent on HDAC3. Genetic knockdown of REV-ERB&#945; resulted in notable changes in chromatin accessibility around AR-target genes both before and after AR activation. The function of CTCF was interrogated using stable knockdown in a breast cancer cell line model. CTCF knockdown led to widespread changes in chromatin accessibility that were dependent on DNA sequence. Further analysis suggested that AP-1 and FOXA1 are involved in CTCF function. Together, the work presented in this dissertation offers novel insight into the behavior of two critical transcription factors in cancer cell lines, and describe a framework of analysis that can be extended and applied to any transcription factor within any desired cellular context.</p> / Dissertation

Molecular biology

androgen receptor

chromatin accessibility

CTCF

DNaseI hypersensitivity

The Nickel-responsive Binding and Regulation of Two Novel Helicobacter pylori NikR–targeted Genes

Ademi, Irsa

11 July 2013

Nickel is an essential transition metal for the virulence and survival of Helicobacter pylori in the acidic human stomach. The nickel– and proton– dependent transcriptional regulator HpNikR is important for maintaining nickel homeostasis inside the cytosol by regulating multiple H. pylori genes. A previous ChIP-sequencing experiment with H. pylori G27 and HpNikR identified two novel genes currently annotated as putative iron-transporters, HpG27_866 and HpG27_1499. In vitro DNA-binding assays with the promoter sequences of the two genes revealed nickel-dependent HpNikR binding with an affinity of ~10-7 M. The recognition site of HpNikR was identified on HpG27_1499 by footprinting assays, which loosely correlates with the HpNikR pseudo-consensus sequence. Furthermore, HpG27_1499 transcription showed nickel-dependent repression in WT H. pylori, and no changes in an isogenic ΔnikR strain. These data suggest that HpG27_1499 could be a nickel importer that is regulated by HpNikR in a nickel-responsive manner.

Helicobacter pylori

nickel

HpNikR

DNaseI footprinting

DNA mobility shift assay

qRT-PCR

transcription factor

metalloprotein

0487

The Nickel-responsive Binding and Regulation of Two Novel Helicobacter pylori NikR–targeted Genes

Ademi, Irsa

11 July 2013

Nickel is an essential transition metal for the virulence and survival of Helicobacter pylori in the acidic human stomach. The nickel– and proton– dependent transcriptional regulator HpNikR is important for maintaining nickel homeostasis inside the cytosol by regulating multiple H. pylori genes. A previous ChIP-sequencing experiment with H. pylori G27 and HpNikR identified two novel genes currently annotated as putative iron-transporters, HpG27_866 and HpG27_1499. In vitro DNA-binding assays with the promoter sequences of the two genes revealed nickel-dependent HpNikR binding with an affinity of ~10-7 M. The recognition site of HpNikR was identified on HpG27_1499 by footprinting assays, which loosely correlates with the HpNikR pseudo-consensus sequence. Furthermore, HpG27_1499 transcription showed nickel-dependent repression in WT H. pylori, and no changes in an isogenic ΔnikR strain. These data suggest that HpG27_1499 could be a nickel importer that is regulated by HpNikR in a nickel-responsive manner.

Helicobacter pylori

nickel

HpNikR

DNaseI footprinting

DNA mobility shift assay

qRT-PCR

transcription factor

metalloprotein

0487

Genome-wide DNaseI hypersensitive sites profiles in laboratory mouse strains by DNase-seq

Hosseini, Mona

January 2013

Variation at regulatory elements, identified through hypersensitivity to digestion by Deoxyribonuclease I (DNase I), is believed to contribute to variation in complex traits, but the extent and consequences of this variation are poorly characterized. To investigate the relationship between sequence variation, and the functional consequences of variation in chromatin accessibility, genome-wide DNase I hypersensitive sites (DHS) of terminally differentiated erythroblasts were studied in eight inbred strains of mice studied (A/J, AKR/J, BALBc/J, C3H/HeJ, C57BL/6J, CBA/J, DBA/2J, and LP/J). These strains were selected because of the availability of their genome sequence and quantitative trait loci (QTL) data. After confirming that next generation sequencing could identify DNase I hypersensitive sites with high sensitivity and specificity, and that differential peaks could be found, an automated peak calling pipeline was developed and optimized. 36,693 DHS peaks were identified covering 9.1 Mb (0.29%) of mouse genome. There was no indication of within strain variation. Between strains reproducible variation was observed at approximately 5% of DNase hypersensitive sites (1,397 DHSs). Variable DHSs were more likely to be enhancers than promoters and less likely to occur at conserved regions of the genome. Only 36% of such variable DHSs contain a sequence variant predictive of site variation and 12% contain at least one variant that disrupts transcription factor binding sites. The majority (86%) of variable DHSs differ in size/shape and the remaining 14% demonstrate discrete variation in single peak or cluster of peaks. Sequence variants within variable DHS are more likely to be associated with complex traits than those in non-variant DHS, and variants associated with complex traits preferentially occur in enhancer-like elements. Changes at a small proportion (7%) of discretely variable DHS are associated with changes in nearby transcriptional activity. Our results show that whilst DNA sequence variation is not the major determinant of variation in open chromatin, where such variants exist they are likely to be causal for complex traits.

616.027

Chromatin alterations imposed by the oncogenic transcription factor PML-RAR

Morey Ramonell, Lluís

01 February 2008

En mamíferos, así como en plantas, mutaciones en AND helicasas/ATPasas del la família SNF2, no solo afectan a la estructura de la cromatina, sino que también afectan al patrón global de la metilación del ADN. Sugiriendo una relación funcional entre la estructura de la cromatina y la epigenética. El complejo NuRD, el cual posee una ATPasa de la familía SNF2, está relacionado con la represión de la transcripción y en el remodelamiento de la cromatina. Nuestro laboratorio demostró que la proteína leucémica PML-RAR&#945; reprime la transcripción de sus genes diana por el reclutamiento de DNMTs y el complejo PRC2. En esta tesis, demostramos una relación directa del complejo NuRD en la represión génica y en los cambios epigenéticos en la leucemia promielocítica aguda (APL). Mostramos que PML-RAR&#945; se une y recluta NuRD a sus genes diana, incluyendo el gen supresor de tumores RAR&#61538;2, facilitando que el complejo de Polycomb se reclute y metile la lisina 27 de la histona H3. Tratamiento con Acido Retinóico (RA), el qual se utiliza en pacientes, reduce la ocupación de NuRD en células leucémicas. Eliminando NuRD no solo provoca que las histonas no se deacetilen y que la cromatina no se compacte, sino que también provoca que tanto la metilación del ADN y de las histonas no se produzca, así como la represión génica del gen RAR&#61538;2, favoreciendo la diferenciación celular. Nuestros resultados caracterizan un nuevo papel del complejo NuRD en el establecimiento de los patrones epigenéticos en APL, demostrando una relación esencial entre la estructura de la cromatina y epigenética durante el desarrollo de la leucemia, pudiéndose aplicar a la terapia de esta enfermedad. / In mammals, as in plants, mutations in SNF2-like DNA helicases/ATPases were shown to affect not only chromatin structure but also global methylation patterns, suggesting a potential functional link between chromatin structure and epigentic marks. The SNF2-like containing NuRD complex is involved in gene transcriptional repression and chromatin remodeling. We have previously shown that the leukemogenic protein PMLRAR&#945; represses target genes through recruitment of DNMTs and Polycomb complex. In this thesis, we demonstrate a direct role of the NuRD complex in aberrant gene repression and transmission of epigenetic repressive marks in acute promyelocytic leucemia (APL). We show that PML-RAR&#945; &#61472;binds and recruits NuRD to target genes, including to the tumor-suppressor gene RAR&#61538;2. In turn, the NuRD complex facilitates Polycomb binding and histone methylation at lysine 27. Retinoic acid treatment reduced the promoter occupancy of the NuRD complex. Knock-down of the NuRD complex in leukemic cells not only prevented histone deacetylation and chromatin compaction, but also impaired DNA and histone methylation as well as stable silencing, thus favoring cellular differentiation. These results unveil an important role for NuRD in the establishment of altered epigenetic marks in APL, demonstrating an essential link between chromatin structure and epigenetics in leukemogenesis that could be exploited for therapeutic intervention.

DNaseI

transcription repression

chromatin immunoprecipitation

bisulfite genomic sequence

histone modifications

DNA methylation

RAR&#61538;2

Suz12

PRC2

Mi-2&#61537;&#61487;&#61538;

MTA2

MBD3

HDAC1/2

Retinoic Acid

NuRD

PML-RAR&#945;

APL

575

616.4