Browsing by Author "O'Hagan, Heather M."
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Item Consensus molecular subtyping of colorectal cancers is influenced by goblet cell content(Elsevier, 2021) Miller, Samuel A.; Ghobashi, Ahmed H.; O'Hagan, Heather M.; Medical and Molecular Genetics, School of MedicineA critical obstacle in the field of colorectal cancer (CRC) is the establishment of precise tumor subtypes to facilitate the development of targeted therapeutic regimens. While dysregulated mucin production is a histopathological feature of multiple CRC subtypes, it is not clear how well these pathologies are associated with the proportion of goblet cells in the tumor, or whether or not this proportion is variable across all CRC. This study demonstrates that consensus molecular subtype 3 (CMS3) CRC tumors and cell lines are enriched for the expression of goblet cell marker genes. Further, the proportion of goblet cells in the tumor is associated with the probability of CMS3 subtype assignment and these CMS3 subtype tumors are mutually exclusive from mucinous adenocarcinoma pathologies. This study provides proof of principle for the use of machine learning classification systems to subtype tumors based on cellular content, and provides further context regarding the features weighing CMS3 subtype assignment.Item Dietary antioxidants remodel DNA methylation patterns in chronic disease(Wiley, 2020-03) Beetch, Megan; Harandi-Zadeh, Sadaf; Shen, Kate; Lubecka, Katarzyna; Kitts, David D.; O'Hagan, Heather M.; Stefanska, Barbara; Medicine, School of MedicineChronic diseases account for over 60% of all deaths worldwide according to the World Health Organization reports. Majority of cases are triggered by environmental exposures that lead to aberrant changes in the epigenome, specifically, the DNA methylation patterns. These changes result in altered expression of gene networks and activity of signalling pathways. Dietary antioxidants, including catechins, flavonoids, anthocyanins, stilbenes and carotenoids, demonstrate benefits in the prevention and/or support of therapy in chronic diseases. This review provides a comprehensive discussion of potential epigenetic mechanisms of antioxidant compounds in reversing altered patterns of DNA methylation in chronic disease. Antioxidants remodel the DNA methylation patterns through multiple mechanisms, including regulation of epigenetic enzymes and chromatin remodelling complexes. These effects can further contribute to antioxidant properties of the compounds. On the other hand, decrease in oxidative stress itself can impact DNA methylation delivering additional link between antioxidant mechanisms and epigenetic effects of the compounds. LINKED ARTICLES: This article is part of a themed section on The Pharmacology of Nutraceuticals. To view the other articles in this section visit http://onlinelibrary.wiley.com/doi/10.1111/bph.v177.6/issuetoc.Item DVL regulation of tissue-specific aromatase transcripts in breast cancer(Impact Journals, 2018-12-25) O'Hagan, Heather M.; Medical Sciences, IU School of MedicineItem The Emerging Role of Epigenetic Modifiers in Repair of DNA Damage Associated with Chronic Inflammatory Diseases(Elsevier, 2017) Ding, Ning; Maiuri, Ashley R.; O'Hagan, Heather M.; Medicine, School of MedicineAt sites of chronic inflammation epithelial cells are exposed to high levels of reactive oxygen species (ROS), which can contribute to the initiation and development of many different human cancers. Aberrant epigenetic alterations that cause transcriptional silencing of tumor suppressor genes are also implicated in many diseases associated with inflammation, including cancer. However, it is not clear how altered epigenetic gene silencing is initiated during chronic inflammation. The high level of ROS at sites of inflammation is known to induce oxidative DNA damage in surrounding epithelial cells. Furthermore, DNA damage is known to trigger several responses, including recruitment of DNA repair proteins, transcriptional repression, chromatin modifications and other cell signaling events. Recruitment of epigenetic modifiers to chromatin in response to DNA damage results in transient covalent modifications to chromatin such as histone ubiquitination, acetylation and methylation and DNA methylation. DNA damage also alters non-coding RNA expression. All of these alterations have the potential to alter gene expression at sites of damage. Typically, these modifications and gene transcription are restored back to normal once the repair of the DNA damage is completed. However, chronic inflammation may induce sustained DNA damage and DNA damage responses that result in these transient covalent chromatin modifications becoming mitotically stable epigenetic alterations. Understanding how epigenetic alterations are initiated during chronic inflammation will allow us to develop pharmaceutical strategies to prevent or treat chronic inflammation-induced cancer. This review will focus on types of DNA damage and epigenetic alterations associated with chronic inflammatory diseases, the types of DNA damage and transient covalent chromatin modifications induced by inflammation and oxidative DNA damage and how these modifications may result in epigenetic alterations.Item How Epigenetic Therapy Beats Adverse Genetics in Monosomy Karyotype AML(AACR, 2021-02) O'Hagan, Heather M.; Rassool, Feyruz V.; Nephew, Kenneth P.; Radiation Oncology, School of MedicineThe study by Greve and colleagues, in this issue of Cancer Research, provides new molecular insights into the intriguing clinical activity of DNA hypomethylating agents (HMA) in patients with acute myeloid leukemia (AML) with monosomal karyotypes. Patients with AML with adverse monosomal karyotypes are known to benefit from HMAs, but not cytarabine, a cytidine analog without HMA activity, but the specific molecular mechanisms remain poorly understood. The authors investigated the mechanistic effects of HMAs on gene reactivation in AML in the context of the most common monosomal karyotypes, genetic deletion of chromosome 7q and 5q. They identified genes with tumor-suppressive properties, an endogenous retrovirus cooperatively repressed by DNA hypermethylation, and increased genetic losses on hemizygous chromosomal regions versus normal biallelic regions in AML cell models. Treatment with HMAs preferentially induced expression of these hemizygous genes to levels similar to those of genes in a biallelic state. In addition to CpG hypomethylation, decitabine treatment resulted in histone acetylation and an open chromatin configuration specifically at hemizygous loci. By using primary blood blasts isolated from patients with AML receiving decitabine and AML patient-derived xenograft models established from patients with either monosomal karyotypes or normal cytogenetics, Greve and colleagues both validated their findings in primary patient samples and demonstrated superior antileukemic activity of decitabine compared with chemotherapy with cytarabine. These mechanistic insights into how epigenetic therapy beats adverse genetics in monosomy karyotype AML will open new therapeutic opportunities for a difficult-to-treat patient group.Item JAK2 regulates mismatch repair protein‐mediated epigenetic alterations in response to oxidative damage(Wiley, 2019) Ding, Ning; Miller, Sam A.; Savant, Sudha S.; O'Hagan, Heather M.; Medicine, School of MedicineAt sites of chronic inflammation epithelial cells undergo aberrant DNA methylation that contributes to tumorigenesis. Inflammation is associated with an increase in reactive oxygen species (ROS) that cause oxidative DNA damage, which has also been linked to epigenetic alterations. We previously demonstrated that in response to ROS, mismatch repair proteins MSH2 and MSH6 recruit epigenetic silencing proteins DNA methyltransferase 1 (DNMT1) and polycomb repressive complex 2 (PRC2) members to sites of DNA damage, resulting in transcriptional repression of tumor suppressor genes (TSGs). However, it was unclear what signal is unique to ROS that results in the chromatin binding of MSH2 and MSH6. Herein, we demonstrate that in response to hydrogen peroxide (H2O2), JAK2 localizes to the nucleus and interacts with MSH2 and MSH6. Inhibition or knockdown of JAK2 reduces the H2O2‐induced chromatin interaction of MSH2, MSH6, DNMT1, and PRC2 members, reduces H2O2‐induced global increase in trimethylation of lysine 27 of histone H3 (H3K27me3), and abrogates oxidative damage‐induced transcriptional repression of candidate TSGs. Moreover, JAK2 mRNA expression is associated with CpG island methylator phenotype (CIMP) status in human colorectal cancer. Our findings provide novel insight into the connection between kinase activation and epigenetic alterations during oxidative damage and inflammation. Environ. Mol. Mutagen. 2018. © 2018 Wiley Periodicals, Inc.Item Lysine-Specific Demethylase 1 Mediates AKT Activity and Promotes Epithelial-to-Mesenchymal Transition in PIK3CA-Mutant Colorectal Cancer(American Association for Cancer Research, 2020-02-01) Miller, Samuel A.; Policastro, Robert A.; Savant, Sudha S.; Sriramkumar, Shruthi; Ding, Ning; Lu, Xiaoyu; Mohammad, Helai P.; Cao, Sha; Kalin, Jay H.; Cole, Philip A.; Zentner, Gabriel E.; O'Hagan, Heather M.; Medical and Molecular Genetics, School of MedicineActivation of the epithelial-mesenchymal transition (EMT) program is a critical mechanism for initiating cancer progression and migration. Colorectal cancers (CRCs) contain many genetic and epigenetic alterations that can contribute to EMT. Mutations activating the PI3K/AKT signaling pathway are observed in >40% of patients with CRC contributing to increased invasion and metastasis. Little is known about how oncogenic signaling pathways such as PI3K/AKT synergize with chromatin modifiers to activate the EMT program. Lysine Specific Demethylase 1 (LSD1) is a chromatin-modifying enzyme that is overexpressed in colorectal cancer (CRC) and enhances cell migration. In this study we determine that LSD1 expression is significantly elevated in CRC patients with mutation of the catalytic subunit of PI3K, PIK3CA, compared to CRC patients with WT PIK3CA. LSD1 enhances activation of the AKT kinase in CRC cells through a non-catalytic mechanism, acting as a scaffolding protein for the transcription-repressing CoREST complex. Additionally, growth of PIK3CA mutant CRC cells is uniquely dependent on LSD1. Knockdown or CRISPR knockout of LSD1 blocks AKT-mediated stabilization of the EMT-promoting transcription factor Snail and effectively blocks AKT-mediated EMT and migration. Overall we uniquely demonstrate that LSD1 mediates AKT activation in response to growth factors and oxidative stress, and LSD1-regulated AKT activity promotes EMT-like characteristics in a subset of PIK3CA mutant cells. Implications Our data supports the hypothesis that inhibitors targeting the CoREST complex may be clinically effective in CRC patients harboring PIK3CA mutations.Item Mismatch repair proteins recruit DNA methyltransferase 1 to sites of oxidative DNA damage(Oxford University Press, 2016-06) Ding, Ning; Bonham, Emily M.; Hannon, Brooke E.; Amick, Thomas R.; Baylin, Stephen B.; O'Hagan, Heather M.; Medical and Molecular Genetics, School of MedicineAt sites of chronic inflammation, epithelial cells are exposed to high levels of reactive oxygen species and undergo cancer-associated DNA methylation changes, suggesting that inflammation may initiate epigenetic alterations. Previously, we demonstrated that oxidative damage causes epigenetic silencing proteins to become part of a large complex that is localized to GC-rich regions of the genome, including promoter CpG islands that are epigenetically silenced in cancer. However, whether these proteins were recruited directly to damaged DNA or during the DNA repair process was unknown. Here we demonstrate that the mismatch repair protein heterodimer MSH2-MSH6 participates in the oxidative damage-induced recruitment of DNA methyltransferase 1 (DNMT1) to chromatin. Hydrogen peroxide treatment induces the interaction of MSH2-MSH6 with DNMT1, suggesting that the recruitment is through a protein–protein interaction. Importantly, the reduction in transcription for genes with CpG island-containing promoters caused by oxidative damage is abrogated by knockdown of MSH6 and/or DNMT1. Our findings provide evidence that the role of DNMT1 at sites of oxidative damage is to reduce transcription, potentially preventing transcription from interfering with the repair process. This study uniquely brings together several factors that are known to contribute to colon cancer, namely inflammation, mismatch repair proteins, and epigenetic changes.Item Poly-ADP-Ribosylation of Estrogen Receptor-Alpha by PARP1 Mediates Antiestrogen Resistance in Human Breast Cancer Cells(MDPI, 2019-01-04) Pulliam, Nicholas; Tang, Jessica; Wang, Weini; Fang, Fang; Sood, Riddhi; O'Hagan, Heather M.; Miller, Kathy D.; Clarke, Robert; Nephew, Kenneth P.; Biology, School of ScienceTherapeutic targeting of estrogen receptor-α (ERα) by the anti-estrogen tamoxifen is standard of care for premenopausal breast cancer patients and remains a key component of treatment strategies for postmenopausal patients. While tamoxifen significantly increases overall survival, tamoxifen resistance remains a major limitation despite continued expression of ERα in resistant tumors. Previous reports have described increased oxidative stress in tamoxifen resistant versus sensitive breast cancer and a role for PARP1 in mediating oxidative damage repair. We hypothesized that PARP1 activity mediated tamoxifen resistance in ERα-positive breast cancer and that combining the antiestrogen tamoxifen with a PARP1 inhibitor (PARPi) would sensitize tamoxifen resistant cells to tamoxifen therapy. In tamoxifen-resistant vs. -sensitive breast cancer cells, oxidative stress and PARP1 overexpression were increased. Furthermore, differential PARylation of ERα was observed in tamoxifen-resistant versus -sensitive cells, and ERα PARylation was increased by tamoxifen treatment. Loss of ERα PARylation following treatment with a PARP inhibitor (talazoparib) augmented tamoxifen sensitivity and decreased localization of both ERα and PARP1 to ERα-target genes. Co-administration of talazoparib plus tamoxifen increased DNA damage accumulation and decreased cell survival in a dose-dependent manner. The ability of PARPi to overcome tamoxifen resistance was dependent on ERα, as lack of ERα-mediated estrogen signaling expression and showed no response to tamoxifen-PARPi treatment. These results correlate ERα PARylation with tamoxifen resistance and indicate a novel mechanism-based approach to overcome tamoxifen resistance in ER+ breast cancer.Item The Role of Inflammation and Inflammatory Mediators in the Development, Progression, Metastasis, and Chemoresistance of Epithelial Ovarian Cancer(MDPI, 2018-07-30) Savant, Sudha S.; Sriramkumar, Shruthi; O'Hagan, Heather M.; Medical Sciences, IU School of MedicineInflammation plays a role in the initiation and development of many types of cancers, including epithelial ovarian cancer (EOC) and high grade serous ovarian cancer (HGSC), a type of EOC. There are connections between EOC and both peritoneal and ovulation-induced inflammation. Additionally, EOCs have an inflammatory component that contributes to their progression. At sites of inflammation, epithelial cells are exposed to increased levels of inflammatory mediators such as reactive oxygen species, cytokines, prostaglandins, and growth factors that contribute to increased cell division, and genetic and epigenetic changes. These exposure-induced changes promote excessive cell proliferation, increased survival, malignant transformation, and cancer development. Furthermore, the pro-inflammatory tumor microenvironment environment (TME) contributes to EOC metastasis and chemoresistance. In this review we will discuss the roles inflammation and inflammatory mediators play in the development, progression, metastasis, and chemoresistance of EOC.