Cloning, expression, and purification of the <i>Drosophila melanogaster</i> dosage compensation complex chromodomains and their <i>Homo sapiens</i> orthologues

Welham, Andrew James

25 February 2009

Sexual differentiation is a fundamental characteristic of all eukaryotes, dictating sex-specific morphology, physiology and behavior. Diploid organisms with heteromorphic sex chromosomes (XX or XY) require regulatory compensation of the X chromosome to maintain correct levels of genetic expression between the sexes, a process termed sex-specific dosage compensation (SSDC). The fruit fly, <i>Drosophila melanogaster</i> dosage compensates by upregulating transcription of most X-linked genes two-fold. Associated with this two-fold up regulation is the male-specific lethal (MSL) complex, a RNA-protein complex comprised of at least five known proteins; MSL1, MSL2, MSL3, males absent on the first (MOF), and maleless (MLE) and two non-translated RNA molecules; roX1 (RNA on the X chromosome) and roX2. The complex modulates the chromatin structure of the male X chromosome via acetylation of H4K16. MOF and MSL3 both exhibit an N-terminal chromodomain, whose function is unclear. The MSL3 chromodomain has been suggested to bind H3K36Me3. Chromodomains are a paradigm of how a single structural fold has evolved in diverse proteins to bind distinct targets. Chromodomains are common to nuclear regulators, and bind diverse targets including histones, DNA, and RNA. They function as recognition motifs of histone post-translational modifications and facilitate the translation of the histone code into a distinct local chromatin structure via recruiting the appropriate chromatin modulating machinery.<p> The goal of this research is to determine the structure of the <i>D. melanogaster</i> MOF and MSL3 chromodomains by X-ray crystallographic and/or nuclear magnetic resonance techniques, to advance our understanding of the structural characteristics of these diverse domains. Here we report the cloning and reproducible expression and purification of the <i>D. melanogaster</i> MOF and MSL3 chromodomains and their Homo sapiens orthologues. The <i>D. melanogaster</i> MOF chromodomain, whose NMR structure was published during this research, has been crystallized. Attempts to solve the crystal structure by molecular replacement, multiple-wavelength anomalous dispersion, and single-wavelength isomorphous replacement are reported.

Dosage compensation

Drosophila melanogaster

Epigenetic regulation

Cloning, expression, and purification of the <i>Drosophila melanogaster</i> dosage compensation complex chromodomains and their <i>Homo sapiens</i> orthologues

Welham, Andrew James

25 February 2009

Sexual differentiation is a fundamental characteristic of all eukaryotes, dictating sex-specific morphology, physiology and behavior. Diploid organisms with heteromorphic sex chromosomes (XX or XY) require regulatory compensation of the X chromosome to maintain correct levels of genetic expression between the sexes, a process termed sex-specific dosage compensation (SSDC). The fruit fly, <i>Drosophila melanogaster</i> dosage compensates by upregulating transcription of most X-linked genes two-fold. Associated with this two-fold up regulation is the male-specific lethal (MSL) complex, a RNA-protein complex comprised of at least five known proteins; MSL1, MSL2, MSL3, males absent on the first (MOF), and maleless (MLE) and two non-translated RNA molecules; roX1 (RNA on the X chromosome) and roX2. The complex modulates the chromatin structure of the male X chromosome via acetylation of H4K16. MOF and MSL3 both exhibit an N-terminal chromodomain, whose function is unclear. The MSL3 chromodomain has been suggested to bind H3K36Me3. Chromodomains are a paradigm of how a single structural fold has evolved in diverse proteins to bind distinct targets. Chromodomains are common to nuclear regulators, and bind diverse targets including histones, DNA, and RNA. They function as recognition motifs of histone post-translational modifications and facilitate the translation of the histone code into a distinct local chromatin structure via recruiting the appropriate chromatin modulating machinery.<p> The goal of this research is to determine the structure of the <i>D. melanogaster</i> MOF and MSL3 chromodomains by X-ray crystallographic and/or nuclear magnetic resonance techniques, to advance our understanding of the structural characteristics of these diverse domains. Here we report the cloning and reproducible expression and purification of the <i>D. melanogaster</i> MOF and MSL3 chromodomains and their Homo sapiens orthologues. The <i>D. melanogaster</i> MOF chromodomain, whose NMR structure was published during this research, has been crystallized. Attempts to solve the crystal structure by molecular replacement, multiple-wavelength anomalous dispersion, and single-wavelength isomorphous replacement are reported.

Dosage compensation

Drosophila melanogaster

Epigenetic regulation

The Epigenetic Regulation of Wound Healing.

Lewis, Christopher J., Mardaryev, Andrei N., Sharov, A.A., Fessing, Michael Y., Botchkarev, Vladimir A.

January 2014

no / Significance: Epigenetic regulatory mechanisms are essential for epidermal homeostasis and contribute to the pathogenesis of many skin diseases, including skin cancer and psoriasis. However, while the epigenetic regulation of epidermal homeostasis is now becoming active area of research, the epigenetic mechanisms controlling the wound healing response remain relatively untouched. Recent Advances: Substantial progress achieved within the last two decades in understanding epigenetic mechanisms controlling gene expression allowed defining several levels, including covalent DNA and histone modifications, ATP-dependent and higher-order chromatin chromatin remodeling, as well as noncoding RNA- and microRNA-dependent regulation. Research pertained over the last few years suggests that epigenetic regulatory mechanisms play a pivotal role in the regulation of skin regeneration and control an execution of reparative gene expression programs in both skin epithelium and mesenchyme. Critical Issues: Epigenetic regulators appear to be inherently involved in the processes of skin repair, and are able to dynamically regulate keratinocyte proliferation, differentiation, and migration, together with influencing dermal regeneration and neoangiogenesis. This is achieved through a series of complex regulatory mechanisms that are able to both stimulate and repress gene activation to transiently alter cellular phenotype and behavior, and interact with growth factor activity. Future Directions: Understanding the molecular basis of epigenetic regulation is a priority as it represents potential therapeutic targets for the treatment of both acute and chronic skin conditions. Future research is, therefore, imperative to help distinguish epigenetic modulating drugs that can be used to improve wound healing.

P300 critically controls proliferation and survival of melanoma cells by transcriptionally regulating MITF

Kim, Edward

14 December 2017

The p300 transcriptional coactivator has been implicated in the development of a large number of malignancies; however, the precise mechanism of p300-associated tumorigenesis remains unclear. Here, we demonstrate the functional impact of p300 in human melanomas using both genetic and chemical approach. Depletion of p300 in human melanoma cells was associated with cellular growth arrest and senescence. Microarray analysis identified the Microphthalmia-associated transcription factor (MITF), a critical lineage-specific transcription factor in melanocytes and melanomas, as a major downstream target of p300 in human melanoma. Ectopic expression of MITF in p300-depleted melanoma cells allowed rescue of the p300-silencing phenotype, suggesting a critical regulatory axis involving p300 and MITF. Chromatin immunoprecipitation studies revealed direct regulation of MITF transcription through p300 acetylation of proximal regulatory domains. Critically, we identified that Forkhead Box M1 (FOXM1), a potent pro-proliferation transcription factor, is a target of the p300-MITF signaling axis. Further evaluation of p300 regulation of melanoma cell growth was performed using a highly selective p300/CBP HAT inhibitor, 228-1. Inhibition of p300/CBP histone acetyltransferase (HAT) activity was found to significantly inhibit proliferation of multiple melanoma lines in an MITF-dependent fashion. Together, these data support the role of p300 as a promising therapeutic target in human melanoma and suggest particular therapeutic efficacy of small molecule inhibitors of p300 HAT activity in tumors expressing high levels of MITF. / 2018-12-14T00:00:00Z

Medicine

Epigenetic regulation

FOXM1

Melanoma

MITF

p300

Small molecule inhibitor

Mechanism of valproic acid induced dysmorphogenesis via oxidative stress and epigenetic regulation at the Hoxa2 gene promoter

2013 May 1900

Valproic acid (2-propylpentanoic acid, VPA) is a clinically used anti-epileptic drug and an effective mood stabilizer. VPA is also a histone deacetylase inhibitor and can induce embryonic malformations in both humans and mice. The mechanism(s) of VPA-induced teratogenicity are not well characterized. The objectives of my study were three fold, to: (i) investigate the effect of VPA on mouse embryonic development, (ii) characterize the putative mechanism(s) of VPA-induced teratogenicity and, (iii) investigate VPA associated epigenetic regulation of Hoxa2 gene in cell lines and in developing embryos. Whole mouse embryo cultures were treated with VPA at doses of 0, 50 (0.35 mM), 100 (0.70 mM), 200 (1.4 mM), and 400 µg/mL (2.8 mM), encompassing the therapeutic range of 0.35 mM to 0.70 mM. Van Maele-Fabry’s morphologic scoring system was used to quantitatively assess embryonic organ differentiation and development. Hoxa2 gene expression was measured by quantitative real-time RT-PCR (Reverse Transcriptase-Polymerase Chain Reaction). To assess epigenetic changes on the Hoxa2 gene promoter, DNA methylation was determined by bisulfite (BSP) sequencing and pyrosequencing. Histone “bivalent domains” H3K4me3 (histone 3 lysine 4 trimethylation) and H3K27me3 (histone 3 lysine 27 trimethylation) associated with gene activation repression, respectively, analyzed qChIP-PCR (quantitative chromatin immunoprecipitation-PCR). Telomere length and telomerase activity were analyzed in mouse embryos and in NIH3T3 cell line treated with VPA. Results indicate significantly increased incidence of dysmorphogenesis in embryos (11.8%, 35.3%, 47.0% and 88.3%) exposed to increasing doses of VPA (0.35 mM, 0.70 mM, 1.4 mM and 2.8 mM respectively). Van Maele-Fabry’s quantitative differentiation assessment of developing embryos demonstrated a significantly lower score for the circulation system, central nervous system, craniofacial development and limb development in VPA treated embryos (0.35 mM to 2.8 mM) compared to the untreated control group. Glutathione homeostasis was altered as indicated by decreased total glutathione content and increased GSSG/GSH ratio in all VPA treatment groups. In addition, a dose-dependent inhibition of Hoxa2 gene expression was observed in embryos and in the NIH3T3 cell line exposed to VPA. Pre-treatment with ascorbic acid [1000 µg/mL (5 mM)] restored glutathione level and normalized Hoxa2 gene expression in embryos exposed to VPA. DNA methylation status was characterized on the Hoxa2 gene promoter at the three CpG islands; CpG island 1 (-277 to -620 bp), CpG island 2 (-919 to -1133 bp), and CpG island 3 (-1176 to -1301 bp) in the two cells lines (NIH3T3 and EG7) and in developing embryos. CpG sites remained unmethylated on the Hoxa2 gene promoter in the NIH3T3 cell line which expresses the Hoxa2 gene, whereas these same CpG sites were methylated in EG7 cells that did not express Hoxa2. CpG island 1 is closest to Hoxa2 transcription start site and its methylation status was most affected. In developing embryos, CpG island 1 was found to be highly methylated at E6.5 when Hoxa2 is not expressed, whereas the methylation status of CpG sites on the CpG island 1 declined between E8.5 and E10.5 when Hoxa2 expression is present. VPA induced methylation of several CpG sites on CpG island 1 in NIH3T3 cell line and in E10.5 embryos when Hoxa2 expression was down regulated following VPA exposure. In addition, embryos and the NIH3T3 cell line treated with VPA impacted the “bivalent domains” resulting in increased H3K27me3 enrichment and decreased H3K4me3 enrichment on Hoxa2 promoter. Pre-treatment with ascorbic acid normalized Hoxa2 expression and histone bivalent domain changes and prevented increased DNA methylation following VPA exposure. Moreover, the telomerase activity and telomere length were both impacted by changes in glutathione redox potential induced by VPA. Oxidative stress following VPA treatment reduced telomerase activity and accelerated telomere shortening. These results are the first to demonstrate: (i) a correlation between VPA dose and total morphologic score in the developing mouse embryos. VPA impacted embryonic tissue differentiation and neural system development in the dose range of 0.35 mM to 2.8 mM; (ii) VPA altered glutathione homeostasis in cultured mouse embryos and inhibited Hoxa2 gene expression; (iii) Histone bivalent domains of H3K27 and H3K4 trimethylation and DNA methylation status at the Hoxa2 gene promoter region were altered following treatment with VPA. This appears to be the epigenetic event in transcriptional silencing of Hoxa2 gene expression after VPA exposure; and (iv) Ascorbic acid normalizes glutathione homeostasis, H3K27 and H3K4 trimethylation and DNA methylation status, restoring Hoxa2 gene expression following VPA exposure. Taken together our results show VPA- induced altered glutathione homeostasis, telomere shortening and telomerase dysfunction, and an inhibition of Hoxa2 gene expression leads to developmental abnormalities. Exposure to ascorbic acid had a protective effect on developing embryos exposed to VPA.

Protein Arginine Methyltransferase 5 in Castration-Resistant and Neuroendocrine Prostate Cancer

Elena Wild (9732323)

15 December 2020

Prostate cancer is one of the most frequently diagnosed cancers and the second leading cause of cancer-related deaths in male population. While localized prostate cancer can be successfully treated with surgery or radiation therapy, the metastatic disease has no curable options. Metastasis can be developed as a result of failed therapy of localized cancer or present at initial diagnosis. As metastasis is the most common cause of prostate cancer-related death, developing novel approaches and improving the efficiency of existing therapies for the metastatic prostate cancer treatment will significantly improve patients’ survival. <div><br><div>The first-line treatment option for metastatic prostate cancer and localized prostate cancer with high risk of recurrence is androgen deprivation therapy (ADT) that decreases androgen receptor (AR) signaling. However, targeting AR signaling inevitably leads to AR reactivation and cancer progression to the castration-resistant prostate cancer (CRPC) that has no curable treatment options. Moreover, about 30% of CRPC cases progress to neuroendocrine prostate cancer (NEPC), highly aggressive and lethal type of prostate cancer. </div><div><br></div><div>Recently my group has shown that protein arginine methyltransferase 5 (PRMT5) functions as an activator of AR expression in hormone-naïve prostate cancer (HNPC). In this dissertation, I demonstrate that PRMT5 also functions as an epigenetic activator of AR transcription in CRPC via symmetric dimethylation of H4R3 at the AR promoter. This epigenetic activation is dependent on pICln, a PRMT5 interaction partner involved in spliceosome assembly, and independent of MEP50, the canonical cofactor of PRMT5. PRMT5 and pICln, but not MEP50, were required for the expression of AR signaling pathway genes. In clinical samples of both HNPC and CRPC, nuclear PRMT5 and pICln protein expressions were highly positively correlated with nuclear AR protein expression. In xenograft tumors, targeting PRMT5 or pICln significantly decreased tumor growth and AR expression. </div><div><br></div><div>Overall, this work identifies PRMT5/pICln as a therapeutic target for HNPC and CRPC treatment that needs to be further evaluated in clinical setting. </div></div>

Cancer

PRMT5

prostate cancer

androgen receptor

epigenetic regulation

Cloning and nextPBM analysis of the mediator and BRG1 associated factor complexes

Buckshaw II, Robert S.

11 June 2020

Coordination of gene expression within the cell requires the integrated actions of various multi-protein, gene regulatory complexes. The Mediator and BRG1 Associate Factor (BAF) complexes are large, dynamic regulatory cofactors (COF) that are made up of multiple different submodules, and play key roles in regulating gene expression. Gene-specific regulation requires that transcription factors (TFs) recruit these COF complexes to gene promoters. How separate subdomains in each complex interact with distinct sets of TFs in each cell remains an important question. In this study, to address this question, we sought to apply the nuclear extract protein-binding microarray (nextPBM) technology being developed in our lab to study interactions between TFs and subunits of the Mediator and BAF complexes. To facilitate this, we cloned, expressed and purified subdomains of proteins from the Mediator and BAF complexes. We then used the nextPBM technology to study the interactions of our subdomains with TFs in human macrophages. We identified several new interactions with TFs, and demonstrate the utility of this approach to student TF-COF interaction.

Systematic biology

BAF

Epigenetic regulation

Immunology

Mediator

PBM

SWI/SNF

SS18-SSX, the Oncogenic Fusion Protein in Synovial Sarcoma, Is a Cellular Context-Dependent Epigenetic Modifier / 滑膜肉腫特異的融合タンパクSS18-SSXは細胞背景依存性のエピゲノム修飾因子である

Tamaki, Sakura

23 March 2016

京都大学 / 0048 / 新制・課程博士 / 博士(医科学) / 甲第19632号 / 医科博第70号 / 新制||医科||5(附属図書館) / 32668 / 京都大学大学院医学研究科医科学専攻 / (主査)教授 斎藤 通紀, 教授 小川 誠司, 教授 野田 亮 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Synovial Sarcoma

SS18-SSX

FZD10

Epigenetic regulation

Cellular context

491

Analysis of Nucleosome Mobility, Fragility, and Recovery: From Embryonic Stem Cells to Invitrosomes

Wright, Ashley Nicolle

01 June 2014

Several factors direct the placement of specific nucleosomes, which in turn have the ability to regulate DNA accessibility. These factors include, but are not limited to, nucleotide sequence preference, nucleotide modifications, the type of histones present within the nucleosome, and the presence of additional transcription factor or chromatin remodelers. A combination of these and other factors are responsible for tightly controlled efficient transcription within the eukaryotic cell. In order to contribute to the understanding of these complicated processes, three separate hypothesis-driven investigations were carried out. First, we looked into nucleosome positioning and phasing within closely related cells lines. Second, we examined domain level nucleosome occupancy on various portions of the chromosome. Finally, we generated a novel method that significantly reduces data loss in in vitro nucleosome reconstitution experiments caused by nucleosome fragment-end bias. All three of our investigations yielded separate results. First, by examining positions and phasing patterns within similar cell types we find common patterns and minor differences within similar cell types. The presence of minor differences in nucleosome positions may cause unique expression patterns. Secondly, we found that decreased domain level nucleosome occupancy at the chromosome arms is not caused by the presence of a class of nucleosomes, termed fragile nucleosomes. Finally, we found that when our nucleosome recovery method is applied conservatively to our dataset, it is possible to recover 80% of the lost nucleosome reconstitution data.

epigenetic regulation

nucleosome positioning

in vitro nucleosome reconsitution

Microbiology

Mechanisms of epigenetic regulation in epidermal keratinocytes during skin development : role of p63 transcription factor in the establishment of lineage-specific gene expression programs in keratinocytes via regulation of nuclear envelope-associated genes and polycomb chromatin remodelling factors

Rapisarda, Valentina

January 2014

During tissues development multipotent progenitor cells establish tissue-specific gene expression programmes, leading to differentiation into specialized cell types. It has been previously shown that the transcription factor p63, a master regulator of skin development, controls the expression of adhesion molecules and essential cytoskeleton components. It has also been shown that p63 plays an important role in establishing distinct three-dimensional conformations in the Epidermal Differentiation Complex (EDC) locus (Fessing et al., 2011). Here we show that in p63-null mice about 32% of keratinocytes showed altered nuclear morphology. Alterations in the nuclear shape were accompanied by decreased expression of nuclear lamins (Lamin A/C and Lamin B1), proteins of the LINC complex (Sun-1, nesprin-2/3) and Plectin. Plectin links components of the nuclear envelope (nesprin-3) with cytoskeleton and ChIP-qPCR assay with adult epidermal keratinocytes showed p63 binding to the consensus binding sequences on Plectin 1c, Sun-1 and Nesprin-3 promoters. As a possible consequence of the altered expression of nuclear lamins and nuclear envelope-associated proteins, changes in heterochromatin distribution as well as decrease of the expression of several polycomb proteins (Ezh2, Ring1B, Cbx4) has been observed in p63-null keratinocytes. Moreover, recent data in our lab have showed that p63 directly regulates Cbx4, a component of the polycomb PRC1 complex. Here we show that mice lacking Cbx4 displayed a skin phenotype, which partially resembles the one observed in p63-null mice with reduced epidermal thickness and keratinocyte proliferation. All together these data demonstrate that p63-regulated gene expression program in epidermal keratinocytes includes not only genes encoding adhesion molecules, cytoskeleton proteins (cytokeratins) and chromatin remodelling factors (Satb1, Brg1), but also polycomb proteins and components of the nuclear envelope, suggesting the existence of a functional link between cytoskeleton, nuclear architecture and three dimensional nuclear organization. Other proteins important for proper epidermal development and stratification, are cytokeratins. Here, we show that keratin genes play an essential role in spatial organization of other lineage-specific genes in keratinocytes during epidermal development. In fact, ablation of keratin type II locus from chromosome 15 in epidermal keratinocytes led to changes in the genomic organization with increased distance between the Loricrin gene located on chromosome 3 as well as between Satb1 gene located on chromosome 17 and keratin type II locus, resulting in a more peripheral localization of these genes in the nucleus. As a possible consequence of their peripheral localization, reduced expression of Loricrin and Satb1 has also been observed in keratins type II-deficient mice. These findings together with recent circularized chromosome conformation capture (4C) data, strongly suggest that keratin 5, Loricrin and Satb1 are part of the same interactome, which is required for the proper expression of these genes and proper epidermal development and epidermal barrier formation. Taken together these data suggest that higher order chromatin remodelling and spatial organization of genes in the nucleus are important for the establishment of lineage-specific differentiation programs in epidermal progenitor cells. These data provide an important background for further analyses of nuclear architecture in the alterations of epidermal differentiation, seen in pathological conditions, such as psoriasis and epithelial skin cancers.

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