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1. L-2-Hydroxyglutarate remodeling of the epigenome and epitranscriptome creates a metabolic vulnerability in kidney cancer models

Author

Kundu, Anirban, Brinkley, Garrett J., Nam, Hyeyoung, Karki, Suman, Kirkman, Richard, Shim, Madhuparna PandiEunHee, Widden, Hayley, Liu, Juan, Heidarian, Yasaman, Mahmoudzadeh, Nader H., Absher, Alexander J. FitDevin, Ding, Han-Fei, Crossman, David K., Placzek, William J., Locasale, Jason W., Rakheja, Dinesh, McConathy, Jonathan E., Ramachandran, Rekha, Bae, Sejong, Tennessen, Jason M., and Sudarshan, Sunil

Subjects
Gene expression -- Analysis, Kidney cancer -- Diagnosis -- Care and treatment -- Genetic aspects, Methylation -- Health aspects, Metabolites -- Analysis, Health care industry, Diagnosis, Care and treatment, Analysis, Genetic aspects, Health aspects
Abstract

Tumor cells are known to undergo considerable metabolic reprogramming to meet their unique demands and drive tumor growth. At the same time, this reprogramming may come at a cost with resultant metabolic vulnerabilities. The small molecule l-2-hydroxyglutarate (L-2HG) is elevated in the most common histology of renal cancer. Similarly to other oncometabolites, L-2HG has the potential to profoundly impact gene expression. Here, we demonstrate that L-2HG remodels amino acid metabolism in renal cancer cells through combined effects on histone methylation and RNA [N.sup.6]- methyladenosine. The combined effects of L-2HG result in a metabolic liability that renders tumors cells reliant on exogenous serine to support proliferation, redox homeostasis, and tumor growth. In concert with these data, high-L-2HG kidney cancers demonstrate reduced expression of multiple serine biosynthetic enzymes. Collectively, our data indicate that high-L-2HG renal tumors could be specifically targeted by strategies that limit serine availability to tumors., Introduction Oncometabolites are small molecules that aberrantly accumulate within tumor cells. These small molecules can have either tumor-promoting or -suppressive effects, indicating that their impact on tumor biology is highly [...]

Published
2024
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2. PRMT1 promotes neuroblastoma cell survival through ATF5

Author

Hua, Zhong-Yan, Hansen, Jeanne N, He, Miao, Dai, Shang-Kun, Choi, Yoonjung, Fulton, Melody D, Lloyd, Sarah M, Szemes, Marianna, Sen, Ji, Ding, Han-Fei, Angelastro, James M, Fei, Xiang, Li, Hui-Ping, Wu, Chao-Ran, Yang, Sheng-Yong, Malik, Karim, Bao, Xiaomin, George Zheng, Y, Liu, Chang-Mei, Schor, Nina F, Li, Zhi-Jie, and Li, Xing-Guo

Subjects
Biochemistry and Cell Biology, Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Biological Sciences, Cancer, Neurosciences, Pediatric, Neuroblastoma, Biotechnology, Pediatric Cancer, Rare Diseases, Development of treatments and therapeutic interventions, Aetiology, 2.1 Biological and endogenous factors, 5.1 Pharmaceuticals, Genetics, Biochemistry and cell biology, Oncology and carcinogenesis
Abstract

Aberrant expression of protein arginine methyltransferases (PRMTs) has been implicated in a number of cancers, making PRMTs potential therapeutic targets. But it remains not well understood how PRMTs impact specific oncogenic pathways. We previously identified PRMTs as important regulators of cell growth in neuroblastoma, a deadly childhood tumor of the sympathetic nervous system. Here, we demonstrate a critical role for PRMT1 in neuroblastoma cell survival. PRMT1 depletion decreased the ability of murine neuroblastoma sphere cells to grow and form spheres, and suppressed proliferation and induced apoptosis of human neuroblastoma cells. Mechanistic studies reveal the prosurvival factor, activating transcription factor 5 (ATF5) as a downstream effector of PRMT1-mediated survival signaling. Furthermore, a diamidine class of PRMT1 inhibitors exhibited anti-neuroblastoma efficacy both in vitro and in vivo. Importantly, overexpression of ATF5 rescued cell apoptosis triggered by PRMT1 inhibition genetically or pharmacologically. Taken together, our findings shed new insights into PRMT1 signaling pathway, and provide evidence for PRMT1 as an actionable therapeutic target in neuroblastoma.

Published
2020

3. Metabolic Reprogramming by MYCN Confers Dependence on the Serine-Glycine-One-Carbon Biosynthetic Pathway

Author

Xia, Yingfeng, Ye, Bingwei, Ding, Jane, Yu, Yajie, Alptekin, Ahmet, Thangaraju, Muthusamy, Prasad, Puttur D, Ding, Zhi-Chun, Park, Eun Jeong, Choi, Jeong-Hyeon, Gao, Bei, Fiehn, Oliver, Yan, Chunhong, Dong, Zheng, Zha, Yunhong, and Ding, Han-Fei

Subjects
Neurosciences, Genetics, Neuroblastoma, Cancer, Rare Diseases, Clinical Research, Pediatric, 5.1 Pharmaceuticals, Development of treatments and therapeutic interventions, Biosynthetic Pathways, Carbon, Cell Line, Tumor, Child, Glycine, Humans, N-Myc Proto-Oncogene Protein, Serine, Oncology and Carcinogenesis, Oncology & Carcinogenesis
Abstract

MYCN amplification drives the development of neuronal cancers in children and adults. Given the challenge in therapeutically targeting MYCN directly, we searched for MYCN-activated metabolic pathways as potential drug targets. Here we report that neuroblastoma cells with MYCN amplification show increased transcriptional activation of the serine-glycine-one-carbon (SGOC) biosynthetic pathway and an increased dependence on this pathway for supplying glucose-derived carbon for serine and glycine synthesis. Small molecule inhibitors that block this metabolic pathway exhibit selective cytotoxicity to MYCN-amplified cell lines and xenografts by inducing metabolic stress and autophagy. Transcriptional activation of the SGOC pathway in MYCN-amplified cells requires both MYCN and ATF4, which form a positive feedback loop, with MYCN activation of ATF4 mRNA expression and ATF4 stabilization of MYCN protein by antagonizing FBXW7-mediated MYCN ubiquitination. Collectively, these findings suggest a coupled relationship between metabolic reprogramming and increased sensitivity to metabolic stress, which could be exploited as a strategy for selective cancer therapy. SIGNIFICANCE: This study identifies a MYCN-dependent metabolic vulnerability and suggests a coupled relationship between metabolic reprogramming and increased sensitivity to metabolic stress, which could be exploited for cancer therapy.See related commentary by Rodriguez Garcia and Arsenian-Henriksson, p. 3818.

Published
2019

5. p53/microRNA-214/ULK1 axis impairs renal tubular autophagy in diabetic kidney disease

Author

Ma, Zhengwei, Li, Lin, Livingston, Man J., Zhang, Dongshan, Mi, Qingsheng, Zhang, Ming, Ding, Han-Fei, Huo, Yuqing, Mei, Changlin, and Dong, Zheng

Subjects
Thermo Fisher Scientific Inc., Tumor proteins -- Development and progression, Type 2 diabetes -- Development and progression, Kidney diseases -- Development and progression, Scientific equipment industry, Health care industry
Abstract

Dysregulation of autophagy in diabetic kidney disease (DKD) has been reported, but the underlying mechanism and its pathogenic role remain elusive. We show that autophagy was inhibited in DKD models and in human diabetic kidneys. Ablation of autophagy-related gene 7 (Atg7) from kidney proximal tubules led to autophagy deficiency and worse renal hypertrophy, tubular damage, inflammation, fibrosis, and albuminuria in diabetic mice, indicating a protective role of autophagy in DKD. Autophagy impairment in DKD was associated with the downregulation of unc-51-like autophagy-activating kinase 1 (ULK1), which was mediated by the upregulation of microRNA-214 (miR-214) in diabetic kidney cells and tissues. Ablation of miR-214 from kidney proximal tubules prevented a decrease in ULK1 expression and autophagy impairment in diabetic kidneys, resulting in less renal hypertrophy and albuminuria. Furthermore, blockade of p53 attenuated miR-214 induction in DKD, leading to higher levels of ULK1 and autophagy, accompanied by an amelioration of DKD. Compared with nondiabetic samples, renal biopsies from patients with diabetes showed induction of p53 and miR-214, associated with downregulation of ULK1 and autophagy. We found a positive correlation between p53/miR-214 and renal fibrosis, but a negative correlation between ULK1/LC3 and renal fibrosis in patients with diabetes. Together, these results identify the p53/ miR-214/ULK1 axis in autophagy impairment in diabetic kidneys, pinpointing possible therapeutic targets for DKD., Introduction Diabetic kidney disease (DKD), a major complication of diabetes mellitus, is the leading cause of chronic kidney disease (CKD) and end-stage renal disease (ESRD). Approximately 30%-40% of patients with [...]

Published
2020
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12. Abstract 3705: L-2HG, oncometabolite-driven epigenetic and epitranscriptomic reprogramming creates metabolic vulnerability in renal cancer

Author

Kundu, Anirban, primary, Brinkley, Garrett J., additional, Nam, Hyeyoung, additional, Karki, Suman, additional, Kirkman, Richard, additional, Widden, Hayley, additional, Johnson, Michelle, additional, Liu, Juan, additional, Heidarian, Yasaman, additional, Mahmoudzadeh, Nader, additional, Absher, Devin, additional, Ding, Han-Fei, additional, Crosman, David, additional, Placzek, William J., additional, Locasale, Jason, additional, Rakheja, Dinesh, additional, Darley-Usmar, Victor, additional, Tennessen, Jason, additional, and Sudarshan, Sunil, additional

Published
2023
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19. DHODH is an independent prognostic marker and potent therapeutic target in neuroblastoma

Author

Olsen, Thale Kristin, primary, Dyberg, Cecilia, additional, Embaie, Bethel Tesfai, additional, Alchahin, Adele, additional, Milosevic, Jelena, additional, Ding, Jane, additional, Otte, Jörg, additional, Tümmler, Conny, additional, Hed Myrberg, Ida, additional, Westerhout, Ellen M., additional, Koster, Jan, additional, Versteeg, Rogier, additional, Ding, Han-Fei, additional, Kogner, Per, additional, Johnsen, John Inge, additional, Sykes, David B., additional, and Baryawno, Ninib, additional

Published
2022
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22. DHODH is an independent prognostic marker and potent therapeutic target in neuroblastoma

Author

Olsen, Thale Kristin, Dyberg, Cecilia, Embaie, Bethel Tesfai, Alchahin, Adele, Milosevic, Jelena, Ding, Jane, Otte, Jörg, Tümmler, Conny, Myrberg, Ida Hed, Westerhout, Ellen M., Koster, Jan, Versteeg, Rogier, Ding, Han-Fei, Kogner, Per, Johnsen, John Inge, Sykes, David B., Baryawno, Ninib, Olsen, Thale Kristin, Dyberg, Cecilia, Embaie, Bethel Tesfai, Alchahin, Adele, Milosevic, Jelena, Ding, Jane, Otte, Jörg, Tümmler, Conny, Myrberg, Ida Hed, Westerhout, Ellen M., Koster, Jan, Versteeg, Rogier, Ding, Han-Fei, Kogner, Per, Johnsen, John Inge, Sykes, David B., and Baryawno, Ninib

Abstract

Despite intensive therapy, children with high-risk neuroblastoma are at risk of treatment failure. We applied a multiomic system approach to evaluate metabolic vulnerabilities in human neuroblastoma. We combined metabolomics, CRISPR screening, and transcriptomic data across more than 700 solid tumor cell lines and identified dihydroorotate dehydrogenase (DHODH), a critical enzyme in pyrimidine synthesis, as a potential treatment target. Of note, DHODH inhibition is currently under clinical investigation in patients with hematologic malignancies. In neuroblastoma, DHODH expression was identified as an independent risk factor for aggressive disease, and high DHODH levels correlated to worse overall and event-free survival. A subset of tumors with the highest DHODH expression was associated with a dismal prognosis, with a 5-year survival of less than 10%. In xenograft and transgenic neuroblastoma mouse models treated with the DHODH inhibitor brequinar, tumor growth was dramatically reduced, and survival was extended. Furthermore, brequinar treatment was shown to reduce the expression of MYC targets in 3 neuroblastoma models in vivo. A combination of brequinar and temozolomide was curative in the majority of transgenic TH-MYCN neuroblastoma mice, indicating a highly active clinical combination therapy. Overall, DHODH inhibition combined with temozolomide has therapeutic potential in neuroblastoma, and we propose this combination for clinical testing., Thale Kristin Olsen, Cecilia Dyberg, David B Sykes, and Ninib Baryawno contributed equally to this work.

Published
2022
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29. NF-κB2 mutation targets survival, proliferation and differentiation pathways in the pathogenesis of plasma cell tumors

Author

McCarthy Brian A, Yang Liqun, Ding Jane, Ren Mingqiang, King William, ElSalanty Mohammed, Zakhary Ibrahim, Sharawy Mohamed, Cui Hongjuan, and Ding Han-Fei

Subjects
Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282
Abstract

Abstract Background Abnormal NF-κB2 activation has been implicated in the pathogenesis of multiple myeloma, a cancer of plasma cells. However, a causal role for aberrant NF-κB2 signaling in the development of plasma cell tumors has not been established. Also unclear is the molecular mechanism that drives the tumorigenic process. We investigated these questions by using a transgenic mouse model with lymphocyte-targeted expression of p80HT, a lymphoma-associated NF-κB2 mutant, and human multiple myeloma cell lines. Methods We conducted a detailed histopathological characterization of lymphomas developed in p80HT transgenic mice and microarray gene expression profiling of p80HT B cells with the goal of identifying genes that drive plasma cell tumor development. We further verified the significance of our findings in human multiple myeloma cell lines. Results Approximately 40% of p80HT mice showed elevated levels of monoclonal immunoglobulin (M-protein) in the serum and developed plasma cell tumors. Some of these mice displayed key features of human multiple myeloma with accumulation of plasma cells in the bone marrow, osteolytic bone lesions and/or diffuse osteoporosis. Gene expression profiling of B cells from M-protein-positive p80HT mice revealed aberrant expression of genes known to be important in the pathogenesis of multiple myeloma, including cyclin D1, cyclin D2, Blimp1, survivin, IL-10 and IL-15. In vitro assays demonstrated a critical role of Stat3, a key downstream component of IL-10 signaling, in the survival of human multiple myeloma cells. Conclusions These findings provide a mouse model for human multiple myeloma with aberrant NF-κB2 activation and suggest a molecular mechanism for NF-κB2 signaling in the pathogenesis of plasma cell tumors by coordinated regulation of plasma cell generation, proliferation and survival.

Published
2012
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32. Bif-1 Interacts with Prohibitin-2 to Regulate Mitochondrial Inner Membrane during Cell Stress and Apoptosis

Author

Cho, Sung-Gyu, primary, Xiao, Xiao, additional, Wang, Shixuan, additional, Gao, Hua, additional, Rafikov, Ruslan, additional, Black, Stephen, additional, Huang, Shang, additional, Ding, Han-Fei, additional, Yoon, Yisang, additional, Kirken, Robert A., additional, Yin, Xiao-Ming, additional, Wang, Hong-Gang, additional, and Dong, Zheng, additional

Published
2019
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36. IRES-based Bicistronic in-situ Reporter Assays for Discovery of Transcription-targeted Lead Compounds

Author

Lang, Liwei, Ding, Han-Fei, Chen, Xiaoguang, Sun, Shi-Yong, Liu, Gang, and Yan, Chunhong

Subjects
Genes, Transcription, Genetic, Genes, Reporter, Gene Targeting, Humans, CRISPR-Cas Systems, Internal Ribosome Entry Sites, Genetic Engineering, Article
Abstract

Although transgene-based reporter gene assays have been used to discover small molecules targeting expression of cancer-driving genes, the success is limited due to the fact that reporter gene expression regulated by incomplete cis-acting elements and foreign epigenetic environments does not faithfully reproduce chemical responses of endogenous genes. Here, we present an internal ribosome entry site-based strategy for bicistronically co-expressing reporter genes with an endogenous gene in the native gene locus, yielding an in situ reporter assay closely mimicking endogenous gene expression without disintegrating its function. This strategy combines the CRISPR-Cas9-mediated genome-editing tool with the recombinase-mediated cassette-exchange technology, and allows for rapid development of orthogonal assays for excluding false hits generated from primary screens. We validated this strategy by developing a screening platform for identifying compounds targeting oncogenic eIF4E, and demonstrated that the novel reporter assays are powerful in searching for transcription-targeted lead compounds with high confidence.

Published
2015

38. Transcriptional Profiling Reveals a Common Metabolic Program in High-Risk Human Neuroblastoma and Mouse Neuroblastoma Sphere-Forming Cells

Author

Liu, Mengling, primary, Xia, Yingfeng, additional, Ding, Jane, additional, Ye, Bingwei, additional, Zhao, Erhu, additional, Choi, Jeong-Hyeon, additional, Alptekin, Ahmet, additional, Yan, Chunhong, additional, Dong, Zheng, additional, Huang, Shuang, additional, Yang, Liqun, additional, Cui, Hongjuan, additional, Zha, Yunhong, additional, and Ding, Han-Fei, additional

Published
2016
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41. KDM4C and ATF4 Cooperate in Transcriptional Control of Amino Acid Metabolism

Author

Zhao, Erhu, primary, Ding, Jane, additional, Xia, Yingfeng, additional, Liu, Mengling, additional, Ye, Bingwei, additional, Choi, Jeong-Hyeon, additional, Yan, Chunhong, additional, Dong, Zheng, additional, Huang, Shuang, additional, Zha, Yunhong, additional, Yang, Liqun, additional, Cui, Hongjuan, additional, and Ding, Han-Fei, additional

Published
2016
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46. HOXC9-Induced Differentiation in Neuroblastoma Development

Author

GEORGIA REGENTS UNIV AUGUSTA GEORGIA HEALTH SCIENCES UNIV RESEARCH INST, Ding, Han-Fei, GEORGIA REGENTS UNIV AUGUSTA GEORGIA HEALTH SCIENCES UNIV RESEARCH INST, and Ding, Han-Fei

Abstract

The overall objective of this project is to test the hypothesis that HOXC9 expression levels have a causal role in determining the differentiation states of neuroblastoma tumors, with higher levels of HOXC9 promoting differentiation. At the cellular level, HOXC9 promotes the differentiation of neuroblastoma stem cells. At the molecular level, HOXC9 activates the H3K4 demethylase KDM5B and the H3K27 demethylase KDM6B for global control of its differentiation program. During the second budget year of this grant, significant progress has been made in the proposed studies, which is described in detail in the Overall Project Summary section below. Briefly, we have 2 publications reporting our new findings on the molecular mechanism by which HOXC9 induces neuronal differentiation of neuroblastoma cells. We show that HOXC9 directly regulate a large number of genes involved in neuronal differentiation, upregulating neuronal genes and downregulating cell cycle and DNA repair genes. For Aim 1, we have completed the experiments proposed in MYCN mouse tumor development studies. For Aim 2, we have developed a culture system for enriching and long-term propagating neuroblastoma stem cell and shown that high Hoxc9 expression is essential for their differentiation induced by RA. For Aim 3, we have identified 3 modes of epigenetic regulation of transcription by HOXC9 that involve modulation of H3K4me3 and H3K27me3 levels, thereby providing a molecular basis for the role of KDM5B and KDM6B in the control of neuroblastoma differentiation. These findings significantly advance our molecular understanding of neuroblastoma differentiation and suggest new targets for neuroblastoma therapy., The original document contains color images.

Published
2014

48. HOXC9-Induced Differentiation in Neuroblastoma Development

Author

MEDICAL COLL OF GEORGIA AUGUSTA RESEARCH INST, Ding, Han-fei, MEDICAL COLL OF GEORGIA AUGUSTA RESEARCH INST, and Ding, Han-fei

Abstract

The overall objective of this project is to test the hypothesis that HOXC9 expression levels have a causal role in determining the differentiation states of neuroblastoma tumors, with higher levels of HOXC9 promoting differentiation. At the cellular level, HOXC9 promotes the differentiation and represses the self-renewal of neuroblastoma stem cells. At the molecular level, HOXC9 activates the H3K4 demethylase KDM5B and the H3K27 demethylase KDM6B for global control of its differentiation program. During the first budget year of this grant, significant progress has been made in the proposed studies, which is described in detail in the BODY section below. Briefly, we have submitted a manuscript reporting our new findings on the molecular mechanism by which HOXC9 induces neuronal differentiation of neuroblastoma cells. We show that HOXC9 directly regulate a large number of genes involved in neuronal differentiation, upregulating neuronal genes and downregulating cell cycle and DNA repair genes. We further present evidence for an essential role of E2F6 in HOXC9 repression of cell cycle genes and induction of G1 arrest. For Aim 1, we have generated MYCN mice (a mouse neuroblastoma model) with Hoxc9 deficiency or heterozygosity and initiated the study on their effects on neuroblastoma initiation and progression. For Aim 3, we have obtained evidence for critical roles of KDM5B and KDM6B in HOXC9 control of cell cycle and neuronal genes, respectively. These findings significantly advance our molecular understanding of neuroblastoma differentiation and suggest new targets for neuroblastoma therapy., The original document contains color images.

Published
2013

49. HOXC9 directly regulates distinct sets of genes to coordinate diverse cellular processes during neuronal differentiation

Author

Wang, Xiangwei, primary, Choi, Jeong-Hyeon, additional, Ding, Jane, additional, Yang, Liqun, additional, Ngoka, Lambert C, additional, Lee, Eun J, additional, Zha, Yunhong, additional, Mao, Ling, additional, Jin, Bilian, additional, Ren, Mingqiang, additional, Cowell, John, additional, Huang, Shuang, additional, Shi, Huidong, additional, Cui, Hongjuan, additional, and Ding, Han-Fei, additional

Published
2013
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