Browsing by Author "Nephew, Kenneth"
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Item Estrogen induces global reorganization of chromatin structure in human breast cancer cells(PLoS, 2014-12-03) Mourad, Raphael; Hsu, Pei-Yin; Juran, Liran; Shen, Changyu; Koneru, Prasad; Lin, Hai; Liu, Yunlong; Nephew, Kenneth; Huang, Tim H.; Li, Lang; Department of Medical and Molecular Genetics, IU School of MedicineIn the cell nucleus, each chromosome is confined to a chromosome territory. This spatial organization of chromosomes plays a crucial role in gene regulation and genome stability. An additional level of organization has been discovered at the chromosome scale: the spatial segregation into open and closed chromatins to form two genome-wide compartments. Although considerable progress has been made in our knowledge of chromatin organization, a fundamental issue remains the understanding of its dynamics, especially in cancer. To address this issue, we performed genome-wide mapping of chromatin interactions (Hi-C) over the time after estrogen stimulation of breast cancer cells. To biologically interpret these interactions, we integrated with estrogen receptor α (ERα) binding events, gene expression and epigenetic marks. We show that gene-rich chromosomes as well as areas of open and highly transcribed chromatins are rearranged to greater spatial proximity, thus enabling genes to share transcriptional machinery and regulatory elements. At a smaller scale, differentially interacting loci are enriched for cancer proliferation and estrogen-related genes. Moreover, these loci are correlated with higher ERα binding events and gene expression. Taken together these results reveal the role of a hormone--estrogen--on genome organization, and its effect on gene regulation in cancer.Item High-Throughput Acoustofluidic Fabrication of Tumor Spheroids(RSC, 2019) Chen, Bin; Wu, Yue; Ao, Zheng; Cai, Hongwei; Nunez, Asael; Liu, Yunhua; Foley, John; Nephew, Kenneth; Lu, Xiongbin; Guo, Feng; Medical and Molecular Genetics, School of MedicineThree-dimensional (3D) culture of multicellular spheroids, offering a desirable biomimetic microenvironment, is appropriate for recapitulating tissue cellular adhesive complexity and revealing a more realistic drug response. However, current 3D culture methods are suffering from low-throughput, poor controllability, intensive-labor, and variation in spheroid size, thus not ready for many high-throughput screening applications including drug discovery and toxicity testing. Herein, we developed a high-throughput multicellular spheroid fabrication method using acoustofluidics. By acoustically-assembling cancer cells with low-cost and disposable devices, our method can produce more than 12 000 multicellular aggregates within several minutes and allow us to transfer these aggregates into ultra-low attachment dishes for long-term culture. This method can generate more than 6000 tumor spheroids per operation, and reduce tumor spheroid formation time to one day. Our platform has advantages in forming spheroids with high throughput, short time, and long-term effectiveness, and is easy-to-operation. This acoustofluidic spheroid assembly method provides a simple and efficient way to produce large numbers of uniform-sized spheroids for biomedical applications in translational medicine, pharmaceutical industry and basic life science research.Item Hyperglycemia cooperates with Tet2 heterozygosity to induce leukemia driven by proinflammatory cytokine–induced lncRNA Morrbid(American Society for Clinical Investigation, 2021-01-04) Cai, Zhigang; Lu, Xiaoyu; Zhang, Chi; Nelanuthala, Sai; Aguilera, Fabiola; Hadley, Abigail; Ramdas, Baskar; Fang, Fang; Nephew, Kenneth; Kotzin, Jonathan J.; Williams, Adam; Henao-Mejia, Jorge; Haneline, Laura; Kapur, Reuben; Microbiology and Immunology, School of MedicineDiabetes mellitus (DM) is a risk factor for cancer. The role of DM-induced hyperglycemic (HG) stress in blood cancer is poorly understood. Epidemiologic studies show that individuals with DM are more likely to have a higher rate of mutations in genes found in pre-leukemic hematopoietic stem and progenitor cells (pre-LHSPCs) including TET2. TET2-mutant pre-LHSPCs require additional hits to evolve into full-blown leukemia and/or an aggressive myeloproliferative neoplasm (MPN). Intrinsic mutations have been shown to cooperate with Tet2 to promote leukemic transformation. However, the extrinsic factors are poorly understood. Using a mouse model carrying Tet2 haploinsufficiency to mimic the human pre-LHSPC condition and HG stress, in the form of an Ins2Akita/+ mutation, which induces hyperglycemia and type 1 DM, we show that the compound mutant mice developed a lethal form of MPN and/or acute myeloid leukemia (AML). RNA-Seq revealed that this was due in part to upregulation of proinflammatory pathways, thereby generating a feed-forward loop, including expression of the antiapoptotic, long noncoding RNA (lncRNA) Morrbid. Loss of Morrbid in the compound mutants rescued the lethality and mitigated MPN/AML. We describe a mouse model for age-dependent MPN/AML and suggest that hyperglycemia acts as an environmental driver for myeloid neoplasms, which could be prevented by reducing expression levels of the inflammation-related lncRNA Morrbid.Item Indiana Center for Breast Cancer Research(Office of the Vice Chancellor for Research, 2014-04-11) Nakshatri, Harikrishna; Gilley, David P.; Wells, Clark D.; Nephew, Kenneth; Radovich, Milan; Guise, Theresa; Bales, Casey; Perkins, Susan; Badve, Sunil; Vladislav, Ioan Tudor; Miller, KathyThe mission of IUPUI breast cancer signature center is to address prevention, early detection, and treatment of breast cancer through translational projects, supportive cores, and synergistic programs. This poster details our efforts improve resources for breast cancer research and efforts to develop multi-PI investigator proposals. The Signature Center has developed two web resources: the Breast Cancer Prognostics Database (PROGgene) to study prognostic implications of genes of interest in publically available breast cancer databases and PROGmiR, a microRNA database. The PROGgene can be used to study overall, recurrence free and metastasis free survival in large patient series. PROGmiR allows investigators to study the prognostic importance of microRNAs. Both PROGgene and PROGmiR have recently been published and accessed by investigators from >10 countries. The signature center has also devoted considerable efforts in developing tumor tissue resource. Tissue Bank includes a total sample of N = 600 cases with 30% non-Caucasian cases. Currently 460 cases have been assembled into a Tissue Microarray with clinical and follow up data. Expression pattern of AP2γ, a potential marker of breast cancer progression, has been analyzed in a TMA with ~170 cases. The breast cancer signature center has funded four pilot projects and projects for the fourth round of funding are currently under review. Drs. Clark Wells received funding for the project “Histologic Analysis of the Protein Levels of Amot130, AmotL1 and YAP in Normal, Hyperplastic and Invasive Breast Cancer Tissues”, which resulted in a publication in PNAS. Dr. David Gilley and his group received funding for the project: “Luminal mammary progenitors are a unique site of telomere dysfunction”, which was published in Stem Cell Reports. In the third project, Dr. Theresa Guise is investigating the mechanisms of cancer-associated muscular dysfunction with a future plan for a clinical trial. Drs. Ken Nephew and Milan Radovich received funding to obtain preliminary results for a multi-PI R01 or P01, which will explore genomics and epigenomics of breast cancer using clinical trial materials. Progress made by the signature center was integral in our request to Vera Bradley Foundation for Breast Cancer. This foundation has recently committed $15 million for the breast cancer program, which will be used to develop three themes of research with a focus on personalized therapies to improve outcome in breast cancer patients.Item MiR-10a as a Modulator of Proliferation and Cell Cycle Progression in Ovarian Clear Cell Carcinoma(2024-08) Collins, Kaitlyn Elizabeth; Hawkins, Shannon; Kim, Jaeyeon; Mayo, Lindsey; Nephew, Kenneth; Zhang, Chi; Zimmers, TeresaEndometriosis, a benign inflammatory disease whereby endometrial-like tissue grows outside the uterus, is a significant risk factor for endometriosis-associated ovarian cancers. In particular, ovarian endometriomas, cystic lesions of deeply invasive endometriosis, are a potential precursor lesion for ovarian clear cell carcinoma (OCCC). To explore the transcriptomic landscape, OCCC from women with pathology-proven concurrent endometriosis (n=4) were compared to benign endometriomas (n=4) by bulk RNA and small-RNA sequencing. Analysis of protein-coding genes identified 2449 upregulated and 3131 downregulated protein-coding genes (DESeq2, P<0.05, log2 fold-change>|1|) in OCCC with concurrent endometriosis compared to endometriomas. Gene set enrichment analysis showed upregulation of cell cycle regulation and DNA replication pathways and downregulation in cytokine receptor signaling and matrisome pathways. Analysis of miRNAs revealed 64 upregulated and 61 downregulated mature miRNA molecules (DESeq2, P<0.05, log2 fold-change>|1|). Hsa-miR-10a-5p represented over 21% of the miRNA molecules in OCCC with endometriosis and was significantly upregulated (NGS: log2 fold change=4.37, P=2.43E-18; QPCR: 8.1-fold change, P<0.05). Correlation between miR-10a expression level in OCCC cell lines and IC50 (50% inhibitory concentration) of carboplatin in vitro revealed a positive correlation (R2=0.92). The cellular function of miR-10a was investigated by overexpressing miR-10a in vitro. MiR-10a overexpression revealed a significant decrease in proliferation (n=6; P< 0.05), compared to a non-targeting control. Cell-cycle analysis revealed a significant shift in cells from S and G2 to G1 in (n=6; P<0.0001). MiR-10a overexpression in vitro was correlated with decreased expression of predicted miR-10a target genes critical for proliferation, cell-cycle regulation, and cell survival [SERPINE1 (3.2 downregulated; P<0.05), CDK6 (2.4 downregulated; P<0.05) and, RAP2A (2-3 downregulated; P<0.05)].Item TONSL is an immortalizing oncogene and a therapeutic target in breast cancer(American Association for Cancer Research, 2023) Khatpe, Aditi S.; Dirks, Rebecca; Bhat-Nakshatri, Poornima; Mang, Henry; Batic, Katie; Swiezy, Sarah; Olson, Jacob; Rao, Xi; Wang, Yue; Tanaka, Hiromi; Liu, Sheng; Wan, Jun; Chen, Duojiao; Liu, Yunlong; Fang, Fang; Althouse, Sandra; Hulsey, Emily; Granatir, Maggie M.; Addison, Rebekah; Temm, Constance J.; Sandusky, George; Lee-Gosselin, Audrey; Nephew, Kenneth; Miller, Kathy D.; Nakshatri, Harikrishna; Surgery, School of MedicineStudy of genomic aberrations leading to immortalization of epithelial cells has been technically challenging due to the lack of isogenic models. To address this, we utilized healthy primary breast luminal epithelial cells of different genetic ancestry and their hTERT-immortalized counterparts to identify transcriptomic changes associated with immortalization. Elevated expression of TONSL (Tonsoku Like, DNA Repair Protein) was identified as one of the earliest events during immortalization. TONSL, which is located on chromosome 8q24.3, was found to be amplified in ~20% of breast cancers. TONSL alone immortalized primary breast epithelial cells and increased telomerase activity, but overexpression was insufficient for neoplastic transformation. However, TONSL-immortalized primary cells overexpressing defined oncogenes generated estrogen receptor-positive adenocarcinomas in mice. Analysis of a breast tumor microarray with ~600 tumors revealed poor overall and progression free survival of patients with TONSL overexpressing tumors. TONSL increased chromatin accessibility to pro-oncogenic transcription factors including NF-κB and limited access to the tumor suppressor p53. TONSL overexpression resulted in significant changes in the expression of genes associated with DNA repair hubs, including upregulation of several genes in the homologous recombination (HR) and Fanconi Anemia pathways. Consistent with these results, TONSL overexpressing primary cells exhibited upregulated DNA repair via HR. Moreover, TONSL was essential for growth of TONSL-amplified breast cancer cell lines in vivo, and these cells were sensitive to TONSL-FACT complex inhibitor CBL0137. Together, these findings identify TONSL as a regulator of epithelial cell immortalization to facilitate cancer initiation and as a target for breast cancer therapy.