TRIM24-REGULATED ESTROGEN RESPONSE IS DEPENDENT ON SPECIFIC HISTONE MODIFICATIONS IN BREAST CANCER CELLS

In this dissertation, I discovered that function of TRIM24 as a co-activator of ERα-mediated transcriptional activation is dependent on specific histone modifications in tumorigenic human breast cancer-derived MCF7 cells. In the first part, I proved that TRIM24-PHD finger domain, which recognizes unmethylated histone H3 lysine K4 (H3K4me0), is critical for ERα-regulated transcription. Therefore, when LSD1-mediated demethylation of H3K4 is inhibited, activation of TRIM24-regulated ERα target genes is greatly impaired. Importantly, I demonstrated that TRIM24 and LSD1 are cyclically recruited to estrogen responsive elements (EREs) in a time-dependent manner upon estrogen induction, and depletion of their expression exert corresponding time-dependent effect on target gene activation. I also identified that phosphorylation of histone H3 threonine T6 disrupts TRIM24 from binding to the chromatin and from activating ERα-regulated targets. In the second part, I revealed that TRIM24 depletion has additive effect to LSD1 inhibitor- and Tamoxifen-mediated reduction in survival and proliferation in breast cancer cells.

Hypoxia-induced transcriptional regulation through chromatin modifications and NC2 function

In response to tumor hypoxia, specific genes that promote angiogenesis, proliferation, and survival are induced. Globally, I find that hypoxia induces a mixed pattern of histone modifications that are typically associated with either transcriptional activation or repression. Furthermore, I find that selective activation of hypoxia-inducible genes occurs simultaneously with widespread repression of transcription. I analyzed histone modifications at the core promoters of hypoxia-repressed and -activated genes and find that distinct patterns of histone modifications correlate with transcriptional activity. Additionally, I discovered that trimethylated H3-K4, a modification generally associated with transcriptional activation, is induced at both hypoxia-activated and repressed genes, suggesting a novel pattern of histone modifications induced during hypoxia. ^ In order to determine the mechanism of hypoxia-induced widespread repression of transcription, I focused my studies on negative cofactor 2 (NC2). Previously, we found that hypoxia-induced repression of the alpha-fetoprotein (AFP) gene occurs during preinitiation complex (PIC) assembly, and I find that NC2, an inhibitor of PIC assembly, is induced during hypoxia. Moreover, I find that the beta subunit of NC2 is essential for hypoxia-mediated repression of AFP, as well as the widespread repression of transcription observed during hypoxia. Previous data in Drosophila and S. cerevisiae indicate that NC2 functions as either an activator or a repressor of transcription. The mechanism of NC2-mediated activation remains unclear; although, Drosophila NC2 function correlates with specific core promoter elements. I tested if NC2 activates transcription in mammalian cells using this core promoter-specific model as a guide. Utilizing site-specific mutagenesis, I find that NC2 function in mammalian cells is not dependent upon specific core promoter elements; however, I do find that mammalian NC2 does function in a gene-specific manner as either an activator or repressor of transcription during hypoxia. Furthermore, I find that binding of the alpha subunit of NC2 specifically correlates with NC2-mediated transcriptional activation. NC2α and NC2β are both required for NC2-mediated transcriptional activation; whereas, NC2β alone is required for hypoxia-induced transcriptional repression. Together, these data indicate that hypoxia mediates changes in gene expression through both chromatin modifications and NC2 function. ^

DEFINITION OF THE LANDSCAPE OF CHROMATIN STRUCTURE AT THE FRATAXIN GENE IN FRIEDREICH’S ATAXIA

Friedreich’s ataxia (FRDA) is caused by the transcriptional silencing of the frataxin (FXN) gene. FRDA patients have expansion of GAA repeats in intron 1 of the FXN gene in both alleles. A number of studies demonstrated that specific histone deacetylase inhibitors (HDACi) affect either histone modifications at the FXN gene or FXN expression in FRDA cells, indicating that the hyperexpanded GAA repeat may facilitate heterochromatin formation. However, the correlation between chromatin structure and transcription at the FXN gene is currently limited due to a lack of more detailed analysis. Therefore, I analyzed the effects of the hyperexpanded GAA repeats on transcription status and chromatin structure using lymphoid cell lines derived from FRDA patients. Using chromatin immunoprecipitation and quantitative PCR, I observed significant changes in the landscape of histone modifications in the vicinity of the GAA tract in FRDA cells relative to control cells. Similar epigenetic changes were observed in GFP reporter construct containing 560 GAA repeats. Further, I detected similar levels of FXN pre-mRNA at a region upstream of hyperexpanded GAA repeats in FRDA and control cells, indicating similar efficiency of transcription initiation in FRDA cells. I also showed that histone modifications associated with hyperexpanded GAA repeats are independent of transcription progression using the GFP reporter system. My data strongly support evidence that FXN deficiency in FRDA patients is consequence of defective transition from initiation to elongation of FXN transcription due to heterochromatin-like structures formed in the proximity of the hyperexpanded GAAs.

Regulation of chromatin structure, Smad binding and AFP expression by the Forkhead box transcription factor: Foxa1

Transcription factors must be able to access their DNA binding sites to either activate or repress transcription. However, DNA wrapping and compaction into chromatin occludes most binding sites from ready access by proteins. Pioneer transcription factors are capable of binding their DNA elements within a condensed chromatin context and then reducing the level of nucleosome occupancy so that the chromatin structure is more accessible. This altered accessibility increases the probability of other transcription factors binding to their own DNA binding elements. My hypothesis is that Foxa1, a ‘pioneer’ transcription factor, activates alpha-fetoprotein (AFP) expression by binding DNA in a chromatinized environment, reducing the nucleosome occupancy and facilitating binding of additional transcription factors.^ Using retinoic-acid differentiated mouse embryonic stem cells, we illustrate a mechanism for activation of the tumor marker AFP by the pioneer transcription factor Foxa1 and TGF-β downstream effector transcription factors Smad2 and Smad4. In differentiating embryonic stem cells, binding of the Foxa1 forkhead box transcription factor to chromatin reduces nucleosome occupancy and levels of linker histone H1 at the AFP distal promoter. The more accessible DNA is subsequently bound by the Smad2 and Smad4 transcription factors, concurrent with activation of transcription. Chromatin immunoprecipitation analyses combined with siRNA-mediated knockdown indicate that Smad protein binding and the reduction of nucleosome occupancy at the AFP distal promoter is dependent on Foxa1. In addition to facilitating transcription factor binding, Foxa1 is also associated with histone modifications related to active gene expression. Acetylation of lysine 9 on histone H3, a mark that is associated active transcription, is dependent on Foxa1, while methylation of H3K4, also associated with active transcription, is independent of Foxa1. I propose that Foxa1 potentiates a region of chromatin to respond to Smad proteins, leading to active expression of AFP.^ These studies demonstrate one mechanism whereby a transcription factor can alter the accessibility of additional transcription factors to chromatin, by altering nucleosome positions. Specifically, Foxa1 exposes DNA so that Smad4 can bind to its regulatory element and activate transcription of the tumor-marker gene AFP.^

Role of NonO-histone interaction in TNFalpha-suppressed prolyl-4-hydroxylase alpha1.

Inflammation is a key process in cardiovascular diseases. The extracellular matrix (ECM) of the vasculature is a major target of inflammatory cytokines, and TNFalpha regulates ECM metabolism by affecting collagen production. In this study, we have examined the pathways mediating TNFalpha-induced suppression of prolyl-4 hydroxylase alpha1 (P4Halpha1), the rate-limiting isoform of P4H responsible for procollagen hydroxylation, maturation, and organization. Using human aortic smooth muscle cells, we found that TNFalpha activated the MKK4-JNK1 pathway, which induced histone (H) 4 lysine 12 acetylation within the TNFalpha response element in the P4Halpha1 promoter. The acetylated-H4 then recruited a transcription factor, NonO, which, in turn, recruited HDACs and induced H3 lysine 9 deacetylation, thereby inhibiting transcription of the P4Halpha1 promoter. Furthermore, we found that TNFalpha oxidized DJ-1, which may be essential for the NonO-P4Halpha1 interaction because treatment with gene specific siRNA to knockout DJ-1 eliminated the TNFalpha-induced NonO-P4Halpha1 interaction and its suppression. Our findings may be relevant to aortic aneurysm and dissection and the stability of the fibrous cap of atherosclerotic plaque in which collagen metabolism is important in arterial remodeling. Defining this cytokine-mediated regulatory pathway may provide novel molecular targets for therapeutic intervention in preventing plaque rupture and acute coronary occlusion.

Regulation of Set1-mediated methylation of Dam1

Eukaryotic genomes exist within a dynamic structure named chromatin in which DNA is wrapped around an octamer of histones forming the nucleosome. Histones are modified by a range of posttranslational modifications including methylation, phosphorylation, and ubiquitination, which are integral to a range of DNA-templated processes including transcriptional regulation. A hallmark for transcriptional activity is methylation of histone H3 on lysine (K) 4 within active gene promoters. In S. cerevisiae, H3K4 methylation is mediated by Set1 within the COMPASS complex. Methylation requires prior ubiquitination of histone H2BK123 by the E2-E3 ligases Rad6 and Bre1, as well as the Paf1 transcriptional elongation complex. This regulatory pathway exemplifies cross-talk in trans between posttranslational modifications on distinct histone molecules. Set1 has an additional substrate in the kinetochore protein Dam1, which is methylated on K233. This methylation antagonizes phosphorylation of adjacent serines by the Ipl1 Aurora kinase. The discovery of a second Set1 substrate raised the question of how Set1 function is regulated at the kinetochore. I hypothesized that transcriptional regulatory factors essential for H3K4 methylation at gene promoters might also regulate Set1-mediated methylation of Dam1K233. Here I show that the regulatory factors essential for COMPASS activity at gene promoters is also indispensable for the methylation of Dam1K233. Deletion of members of the COMPASS complex leads to loss of Dam1K233 methylation. In addition, deletion of Rad6, Bre1, or members of the Paf1 complex abolishes Dam1 methylation. The role of Rad6 and Bre1 in Dam1 methylation is dependent on H2BK123 ubiquitination, as mutation of K123 within H2B results in complete loss of Dam1 methylation. Importantly, methylation of Dam1K233 is independent of transcription and occurs at the kinetochore. My results demonstrate that Set1-mediated methylation is regulated by a general pathway regardless of substrate that is composed of transcriptional regulatory factors functioning independently of transcription at the kinetochore. My data provide the first example of cross-talk in trans between modifications on a histone and a non-histone protein. Additionally, my results indicate that several factors previously thought to be required for Set1 function at gene promoters are more generally required for the catalytic activity of the COMPASS complex regardless of substrate or cellular process.

FUNCTION OF ZNF668 IN CANCER DEVELOPMENT

Human cancer develops as a result of accumulation of mutations in oncogenes and tumor suppressor genes. Zinc finger protein 668 (ZNF668) has recently been identified and validated as one of the highly mutated genes in breast cancer, but its function is entirely unknown. Here, we report two major functions of ZNF668 in cancer development. (1) ZNF668 functions as a tumor suppressor by regulating p53 protein stability and function. We demonstrate that ZNF668 is a nucleolar protein that physically interacts with both MDM2 and p53. By binding to MDM2, ZNF668 regulates MDM2 autoubiquitination and prevents MDM2-mediated p53 ubiquitination and degradation; ZNF668 deficiency impairs DNA damage-induced p53 stabilization. Notably, ZNF668 effectively suppresses breast cancer cell proliferation and transformation in vitro and tumorigenicity in vivo. Consistently, ZNF668 knockdown readily transforms normal mammary epithelial cells. Together, our studies identify ZNF668 as a novel breast tumor suppressor gene that acts at least in part by regulating the stability and function of p53. (2) ZNF668 functions as a DNA repair protein by regulating histone acetylation. DNA repair proteins need to access the chromatin by chromatin modification or remodeling to use DNA template within chromatin. Dynamic posttranslational modifications of histones are critical for cells to relax chromatin in DNA repair. However, the precise underlying mechanism mediating enzymes responsible for these modifications and their recruitment to DNA lesions remains poorly understood. We observed ZNF668 depletion causes impaired chromatin relaxation as a result of impaired DNA-damage induced histone H2AX hyper-acetylation. This results in the decreased recruitment of repair proteins to DNA lesions, defective homologous recombination (HR) repair and impaired cell survival after DNA damage, albeit with the presence of a functional ATM/ATR dependent DNA-damage signaling cascade. Importantly, the impaired loading of repair proteins and the defect in DNA repair in ZNF668-deficient cells can be counteracted by chromatin relaxation, indicating that the DNA-repair defect that was observed in the absence of ZNF668 is due to impeded chromatin accessibility at sites of DNA breaks. Our findings therefore identify ZNF668 as a key molecule that links chromatin relaxation with response to DNA damage in the control of DNA repair.

ROLE OF THE GCN5 HISTONE ACETYLTRANSFERASE IN SPINOCEREBELLAR ATAXIA TYPE 7 AND IN IMMATURE NEURONS

Spinocerebellar Ataxia type 7 (SCA7) is a neurodegenerative disease caused by expansion of a CAG repeat encoding a polyglutamine tract in ATXN7, a component of the SAGA histone acetyltransferase (HAT) complex. Previous studies provided conflicting evidence regarding the effects of polyQ-ATXN7 on the activity of Gcn5, the HAT catalytic subunit of SAGA. Here I showed that reducing Gcn5 expression accelerates both cerebellar and retinal degeneration in a mouse model of SCA7. Deletion of Gcn5 in Purkinje cells in mice expressing wild type Atxn7, however, causes only mild ataxia and does not lead to the early lethality observed in SCA7 mice. Reduced Gcn5 expression strongly enhances retinopathy in SCA7 mice, but does not affect the transcriptional targets of Atxn7, as expression of these genes is not further altered by Gcn5 depletion. These findings demonstrate that loss of Gcn5 functions can contribute to the time of onset and severity of SCA7 phenotypes, but suggest that non-transcriptional functions of SAGA may play a role in neurodegeneration in this disease.

THE HISTONE DEACETYLASE INHIBITOR, MS-275, SENSITIZES METASTATIC OSTEOSARCOMA TO FASL-INDUCED CELL DEATH: A ROLE FOR C-FLIP

The purpose of this study was to determine the effects of the histone deacetylase inhibitor, MS-275, on the Fas signaling pathway and susceptibility of osteosarcoma (OS) to Fas ligand (FasL)-induced cell death. OS metastasizes almost exclusively to the lungs. We have shown that Fas expression in OS cells is inversely correlated with their metastatic potential. Fas+ cells are rapidly eliminated when they enter the lungs via interaction with FasL, which is constitutively expressed in the lungs. Fas- OS cells escape this FasL-induced apoptosis and survive in the lung microenvironment. Moreover, upregulation of Fas in established OS lung metastases results in tumor regression. Therefore, agents that upregulate Fas expression or activate the Fas signaling pathway may have therapeutic potential. Treatment of Fas- metastatic OS cell lines with 2 μM MS-275 sensitized cells to FasL-induced cell death in vitro. We found that MS-275 did not alter the expression of Fas on the cell surface; rather it resulted in increased levels of Fas within the membrane lipid rafts, as demonstrated by an increase in Fas expression in detergent insoluble lipid raft fractions. We further demonstrated that following MS-275 treatment, Fas colocalized with GM1+ lipid rafts and that there was a decrease in c-FLIP (cellular FLICE-inhibitory protein) mRNA and protein. Downregulation of c-FLIP correlated with caspase activation and apoptosis induction. Transfection of cells with shRNA to c-FLIP also resulted in the localization of Fas to lipid rafts. These studies indicate that MS-275 sensitizes OS cells to FasL by upregulating the expression of Fas in membrane lipid rafts, which correlated with the downregulation of c-FLIP. Treatment of nu/nu-mice with established OS lung metastases with oral MS-275 resulted in increased apoptosis, a significant inhibition of c-FLIP expression in tumors and tumor regression. Histopathological examination of mice showed no significant organ toxicity. Overall, these results suggest that the mechanism by which MS-275 sensitizes OS cells and lung metastases to FasL-induced cell death may be by a reduction in the expression of c-FLIP.

H2B histone gene expression during {\it Xenopus laevis\/} development

Histone gene expression is replication-independent during oogenesis and early embryogenesis in amphibians; however, it becomes replication-dependent during later embryogenesis and remains replication-dependent through adulthood. In order to understand the mechanism for this switch in transcriptional regulation of histone gene expression during amphibian development, linker-scanning mutations were made in a Xenopus laevis H2B histone gene promoter by oligonucleotide site-directed mutagenesis and assayed by microinjection into oocytes and embryos. The Xenopus H2B gene has a relatively simple promoter containing several transcriptional regulatory elements, including TFIID, CCAAT, and ATF motifs, required for maximal transcription in both oocytes and embryos. Factors binding to the CCAAT and ATF motifs are present in oocytes and embryos and increase slightly in abundance during early development. A sequence (CTTTACAT) in the frog H2B promoter resembling the conserved octamer motif (ATTTGCAT), the target for cell-cycle regulation of a human H2B gene, is additionally required for maximal H2B transcription in frog embryos. Oocytes and embryos contain multiple octamer-binding proteins that are expressed in a sequential manner during early development. Sequences encoding three novel octamer-binding proteins were isolated from Xenopus cDNA libraries by virtue of their similarity with the DNA binding (POU) domain of the ubiquitously expressed transcription factor Oct-1. The protein encoded by one of these genes, termed Oct-60, was localized mainly in the cytoplasm of oocytes and was also present in early embryos until the gastrula stage of development. Proteins encoded by the other two genes, Oct-25 and Oct-91, were present in embryos after the mid-blastula stage of development and decreased by early neurula stage. The activity of the Xenopus H2B octamer motif in embryos is not specifically associated with increased binding by Oct-1 or the appearance of novel octamer-binding proteins but requires the presence of an intact CCAAT motif. We found that synergistic interactions among promoter elements are important for full H2B promoter activity. The results suggest that transcription of the Xenopus H2B gene is replication-dependent when it is activated at the mid-blastula stage of development and that replication-dependent H2B transcription is mediated by Oct-1. ^

CHARACTERIZATION OF HIGH MOBILITY GROUP AND HISTONE H1 PROTEIN LEVELS AND SYNTHESIS DURING SPERMATOGENESIS IN THE RAT

In order to propose a role for internucleosomal high mobility group proteins (HMGs), and HI histone variants study of their levels and synthesis in a system of development and differentiation--rat spermatogenesis--was undertaken. HMG1, 2, 14, and 17 were isolated from rat testes and found to be very similar to calf thymus HMGs. Testis levels of HMGs, relative to DNA, were equivalent to other rat tissues for HMG1 (13 ug/mg DNA), HMG14 (2 ug/mg DNA), and HMG17 (5 ug/mg DNA). HMG2 levels were different among rat tissues, with three groups observed: (1) nonproliferating tissues (1-5 ug/mg DNA); (2) proliferating tissues (8-13 ug/mg DNA); and (3) the testis (32 ug/mg DNA). Other species (toad, opposum, mouse, dog, and monkey) showed the same testis-specific increase of HMG2. Populations of purified testis cell types were separated by centrifugal elutriation and density gradient centrifugation from adult and immature rat testes. Pachytene spermatocytes and early spermatids (56 and 47 ug/mg DNA, respectively) caused the testis-specific increase of HMG2 levels. Cell types preceding pachytenes (types A and B spermatogonia, mixtures of spermatogonia and early primary spermatocytes, and early pachytenes contained HMG2 levels similar to proliferating tissues (12 ug/mg DNA). Late spermatids did not contain HMGs. Somatic Sertoli and Leydig cells (2 ug/mg DNA) exhibited HMG2 levels similar to nonproliferating tissues. HMGs synthesized in spermatogonia and spermatocytes had similar specific activities, but early spermatids did not synthesize HMGs. Germ cells also contained an HMG2 species (on acid-urea gels) not found in somatic tissues. Other investigators have shown that HMGs may be associated with transcriptional or replicative processes. Thus, it is proposed that HMG2 plays a role in modulatable gene expression, while HMG1 is associated with housekeeping functions.^ HI histone variants were also studied throughout spermatogenesis. The minor somatic variant, HIa, is the predominant variant in spermatogonia and early primary spermatocytes. In early pachytenes, the testis-specific variant, HIt, is first synthesized and appears, largely replacing somatic variants HIbcd and e by late pachytene stage. Early spermatids contain the same HI composition as pachytenes, but do not synthesize HI histones. HI('0) is present in low amounts in all germ cells. These results suggest that expression of HI variants is developmentally controlled.^

Functional requirements of histone deacetylases in Tup1-Ssn6 repression

The corepressor complex Tup1-Ssn6 regulates many classes of genes in yeast including cell type specific, glucose repressible, and DNA damage inducible. Tup1 and Ssn6 are recruited to target promoters through their interactions with specific DNA binding proteins such as α2, Mig1, and Crt1. Most promoters that are repressed by this corepressor complex exhibit a high degree of nucleosomal organization. This chromatin domain occludes transcription factor access to the promoter element resulting in gene repression. Previous work indicated that Tup1 interacts with underacetylated isoforms of H3 and H4, and that mutation of these histones synergistically compromises repression. These studies predict that Tup1-hypoacetyalted histone interaction is important to the repression mechanism, and in vivo hyperacetylation might compromise the corepressors ability to repress target genes. ^ One way to alter histone acetylation levels in vivo is to alter the balance between histone acetyltransferases and histone deacetylases. To date five histone deacetylases (HDACs) have been identified in yeast Rpd3, Hos1, Hos2, Hos3 and Hda1. Deletion of single or double HDAC genes had little to no effect on Tup1-Ssn6 repression, but simultaneous deletion of three specific activities Rpd3, Hos1, and Hos2 abolished repression in vivo. Promoter regions of Tup1-Ssn6 target genes in these triple deacetylase mutant cells are dramatically hyperacetylated in both H3 and H4. Examination of bulk histone acetylation levels showed that this specific HDAC triple mutant combination (rpd3 hos1 hos2) caused a dramatic and concomitant hyperacetylation of both H3 and H4. The loss of repression in the rpd3 hos1 hos2 cells, but not in other mutants, is consistent with previous observations, which indicate that histones provide redundant functions in the repression mechanism and that high levels of acetylation are required to prevent Tup1 binding. Investigation into a potential direct interaction between the Tup1-Ssn6 corepressor complex and one or more HDAC activities showed that both Rpd3 and Hos2 interact with the corepressor complex in vivo. These findings indicate that Tup1-Ssn6 repression involves the recruitment of histone deacetylase activities to target promoters, where they locally deacetylate histone residues promoting Tup1-histone tail interaction to initiate and/or maintain the repressed state. ^

Involvement of histone H3 methylation in Tup1-Ssn6 repression

The Tup1-Ssn6 complex regulates the expression of diverse classes of genes in Saccharomyces cerevisiae including those regulated by mating type, DNA damage, glucose, and anaerobic stress. The complex is recruited to target genes by sequence-specific repressor proteins. Once recruited to particular promoters, it is not completely clear how it functions to block transcription. Repression probably occurs through interactions with both the basal transcriptional machinery and components of chromatin. Tup1 interactions with chromatin are strongly influenced by acetylation of histories H3 and H4. Tup1 binds to underacetylated histone tails and requires multiple histone deacetylases (HDACs) for its repressive functions. Like acetylation, histone methylation is involved in regulation of gene expression. The possible role of histone methylation in Tup1 repression is not known. Here we examined possible roles of histone methyltransferases in Tup1-Ssn6 functions. We found that like other genes, Tup1-Ssn6 target genes exhibit increases in the levels of histone H3 lysine 4 methylation upon activation. However, deletion of individual or multiple histone methyltransferases (HMTs) and other SET-domain containing genes has no apparent effect on Tup1-Ssn6 mediated repression of a number of well-defined targets. Interestingly, we discovered that Ssn6 interacts with Set2. Since deletion of SET2 does not affect Tup1-Ssn6 repression, Ssn6 may utilize Set2 in other contexts to regulate gene repression. In order examine if the two components of the Tup1-Ssn6 complex have independent functions in the cell, we identified genes differentially expressed in tup1Δ and ssn6Δ mutants using DNA microarrays. Our data indicate that ∼4% of genes in the cell are regulated by Ssn6 independently of Tup1. In addition, expression of genes regulated by Tup1-Ssn6 seems to be differently affected by deletion of Ssn6 and deletion of Tup1, which indicates that these components might have separate functions. Our data shed new light on the classical view of Tup1-Ssn6 functions, and indicate that Ssn6 might have repressive functions as well. ^