Jen-Tsan Ashley Chi
Molecular Genetics and Microbiology
Professor in Molecular Genetics and Microbiology
Research Interests
We are using functional genomic approaches to investigate the nutrient signaling and stress adaptations of cancer cells when exposed to various nutrient deprivations and microenvironmental stress conditions. Recently, we focus on two areas. First, we are elucidating the genetic determinants and disease relevance of ferroptosis, a newly recognized form of cell death. Second, we have identified the mammalian stringent response pathway which is highly similar to bacterial stringent response, but with some very interesting twists and novel mechanisms.
rnA. The genetic determinants and disease relevance of ferroptosis
rnFerroptosis is a newly recognized form of cell death that is characterized by iron dependency and lipid peroxidation. The importance of ferroptosis is being recognized in many human diseases, including cancers, ischemia injuries, and neurodegeneration. Previously, we have identified the profound cystine addiction of renal cell carcinoma (1), breast cancer cells (2, 3), and ovarian cancer cells (4). Based on the concept that cystine deprivation triggers the ferroptosis due to the unopposed oxidative stresses, we have performed functional genomic screens to identify many novel genetic determinants of ferroptosis. For example, we have found that DNA damage response and ATM kinase regulate ferroptosis via affecting iron metabolism (5). This finding supports the potential of ionizing radiation to trigger DNA damage response and synergize with ferroptosis to treat human cancers. In addition, we found that ferroptosis is highly regulated by cell density. When cells are grown at low density, they are highly susceptible to ferroptosis. In contrast, the same cells become resistant to ferroptosis when grown at high density and confluency. we have found the Hippo pathway effectors TAZ and YAP are responsible for the cell density-dependent ferroptosis (4, 6, 7). Right now, we are pursuing several other novel determinants of ferroptosis that will reveal surprising insights into this new form of cell death.
rnB. A new stress pathway – mammalian stress response
rnAll living organisms encounter a wide variety of nutrient deprivations and environmental stresses. Therefore, all organisms have developed various mechanisms to respond and promote survival under stress. In bacteria, the main strategy is “stringent response” triggered by the accumulation of the alarmone (p)ppGpp (shortened to ppGpp below) via regulation of its synthetase RelA and its hydrolase SpoT (8). The ppGpp binds to the transcription factor DksA and RNA polymerase to orchestrate extensive transcriptional changes that repress proliferation and promote stress survival (8, 9). While highly conserved among bacteria, the stringent response had not been reported in metazoans. However, a recent study identified Drosophila and human MESH1 (Metazoan SpoT Homolog 1) as the homologs of the ppGpp hydrolase domain of the bacterial SpoT (10). Both MESH1 proteins exhibit ppGpp hydrolase activity, and the deletion of Mesh1 in Drosophila led to a transcriptional response reminiscent of the bacterial stringent response (10). Recently, we have found that the genetic removal of MESH1 in tumor cells triggers extensive transcriptional changes and confers protection against oxidative stress-induced ferroptosis (11). Importantly, MESH1 removal also triggers proliferative arrest and other robust anti-tumor effects. Therefore, MESH1 knockdown leads to both stress survival and proliferation arrest, two cardinal features highly reminiscent of the bacterial stringent response. Therefore, we termed this pathway as “mammalian stringent response” (12). We have found that NADPH is the relevant MESH1 in the contexts of ferroptosis (13). Now, we are investigating how MESH1 removal leads to proliferation of arrests and anti-tumor phenotypes. Furthermore, we have found several other substrates of MESH1. We are investigating their function using culture cells, MESH1 KO mice, and other model organisms.
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C. Genomic and single cell RNA analysis of Red Blood Cells
rnRed blood cells (RBC) are responsible for oxygen delivery to muscles during vigorous exercise. Therefore, many doping efforts focus on increasing RBC number and function to boost athletic performance during competition. For many decades, RBC were thought to be merely identical “sacs of hemoglobin” with no discernable differences due to factors such as age or pre-transfusion storage time. Additionally, because RBC lose their nuclei during terminal differentiation, they were not believed to retain any genetic materials. These long-held beliefs have now been disproven and the results have significant implications for detecting autologous blood transfusion (ABT) doping in athletes. We were among the first to discover that RBCs contain abundant and diverse species of RNAs. Using this knowledge, we subsequently optimized protocols and performed genomic analysis of the RBC transcriptome in sickle cell disease; these results revealed that heterogeneous RBCs could be divided into several subpopulations, which had implications for the mechanisms of malaria resistance. As an extension of these studies, we used high resolution Illumina RNA-Seq approaches to identify hundreds of additional known and novel microRNAs, mRNAs, and other RNA species in RBCs. This dynamic RBC transcriptome represents a significant opportunity to assess the impact that environmental factors (such as pre-transfusion refrigerate storage) on the RBC transcriptome. We have now identified a >10-fold change in miR-720 as well as several other RNA transcripts whose levels are significantly altered by RBC storage (14) which gained significant press coverage. We are pursuing the genomic and single cell analysis of RNA transcriptome in the context of blood doping, sickle cell diseases and other red cell diseases.
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1. Tang X, Wu J, Ding CK, Lu M, Keenan MM, Lin CC, et al. Cystine Deprivation Triggers Programmed Necrosis in VHL-Deficient Renal Cell Carcinomas. Cancer Res. 2016;76(7):1892-903.
rn2. Tang X, Ding CK, Wu J, Sjol J, Wardell S, Spasojevic I, et al. Cystine addiction of triple-negative breast cancer associated with EMT augmented death signaling. Oncogene. 2017;36(30):4379.
rn3. Lin CC, Mabe NW, Lin YT, Yang WH, Tang X, Hong L, et al. RIPK3 upregulation confers robust proliferation and collateral cystine-dependence on breast cancer recurrence. Cell Death Differ. 2020.
rn4. Yang WH, Huang Z, Wu J, Ding C-KC, Murphy SK, Chi J-T. A TAZ-ANGPTL4-NOX2 axis regulates ferroptotic cell death and chemoresistance in epithelial ovarian cancer. Molecular Cancer Research. 2019: molcanres.0691.2019.
rn5. Chen PH, Wu J, Ding CC, Lin CC, Pan S, Bossa N, et al. Kinome screen of ferroptosis reveals a novel role of ATM in regulating iron metabolism. Cell Death Differ. 2019.
rn6. Yang W-H, Chi J-T. Hippo pathway effectors YAP/TAZ as novel determinants of ferroptosis. Molecular & Cellular Oncology. 2019:1699375.
rn7. Yang WH, Ding CKC, Sun T, Hsu DS, Chi JT. The Hippo Pathway Effector TAZ Regulates Ferroptosis in Renal Cell Carcinoma Cell Reports. 2019;28(10):2501-8.e4.
rn8. Potrykus K, Cashel M. (p)ppGpp: still magical? Annu Rev Microbiol. 2008;62:35-51.
rn9. Kriel A, Bittner AN, Kim SH, Liu K, Tehranchi AK, Zou WY, et al. Direct regulation of GTP homeostasis by (p)ppGpp: a critical component of viability and stress resistance. Mol Cell. 2012;48(2):231-41.
rn10. Sun D, Lee G, Lee JH, Kim HY, Rhee HW, Park SY, et al. A metazoan ortholog of SpoT hydrolyzes ppGpp and functions in starvation responses. Nat Struct Mol Biol. 2010;17(10):1188-94.
rn11. Dixon SJ, Lemberg KM, Lamprecht MR, Skouta R, Zaitsev EM, Gleason CE, et al. Ferroptosis: an iron-dependent form of nonapoptotic cell death. Cell. 2012;149(5):1060-72.
rn12. Ding C-KC, Rose J, Wu J, Sun T, Chen K-Y, Chen P-H, et al. Mammalian stringent-like response mediated by the cytosolic NADPH phosphatase MESH1. bioRxiv. 2018.
rn13. Ding C-KC, Rose J, Sun T, Wu J, Chen P-H, Lin C-C, et al. MESH1 is a cytosolic NADPH phosphatase that regulates ferroptosis. Nature Metabolism. 2020.
rn14. Yang WH, Doss JF, Walzer KA, McNulty SM, Wu J, Roback JD, et al. Angiogenin-mediated tRNA cleavage as a novel feature of stored red blood cells. Br J Haematol. 2018.
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Bio
We are using functional genomic approaches to investigate the nutrient signaling and stress adaptations of cancer cells when exposed to various nutrient deprivations and microenvironmental stress conditions. Recently, we focus on two areas. First, we are elucidating the genetic determinants and disease relevance of ferroptosis, a newly recognized form of cell death. Second, we have identified the mammalian stringent response pathway which is highly similar to bacterial stringent response, but with some very interesting twists and novel mechanisms.
A. The genetic determinants and disease relevance of ferroptosis
Ferroptosis is a newly recognized form of cell death that is characterized by iron dependency and lipid peroxidation. The importance of ferroptosis is being recognized in many human diseases, including cancers, ischemia injuries, and neurodegeneration. Previously, we have identified the profound cystine addiction of renal cell carcinoma (1), breast cancer cells (2, 3), and ovarian cancer cells (4). Based on the concept that cystine deprivation triggers the ferroptosis due to the unopposed oxidative stresses, we have performed functional genomic screens to identify many novel genetic determinants of ferroptosis. For example, we have found that DNA damage response and ATM kinase regulate ferroptosis via affecting iron metabolism (5). This finding supports the potential of ionizing radiation to trigger DNA damage response and synergize with ferroptosis to treat human cancers. In addition, we found that ferroptosis is highly regulated by cell density. When cells are grown at low density, they are highly susceptible to ferroptosis. In contrast, the same cells become resistant to ferroptosis when grown at high density and confluency. we have found the Hippo pathway effectors TAZ and YAP are responsible for the cell density-dependent ferroptosis (4, 6, 7). Right now, we are pursuing several other novel determinants of ferroptosis that will reveal surprising insights into this new form of cell death.
B. A new stress pathway – mammalian stress response
All living organisms encounter a wide variety of nutrient deprivations and environmental stresses. Therefore, all organisms have developed various mechanisms to respond and promote survival under stress. In bacteria, the main strategy is “stringent response” triggered by the accumulation of the alarmone (p)ppGpp (shortened to ppGpp below) via regulation of its synthetase RelA and its hydrolase SpoT (8). The ppGpp binds to the transcription factor DksA and RNA polymerase to orchestrate extensive transcriptional changes that repress proliferation and promote stress survival (8, 9). While highly conserved among bacteria, the stringent response had not been reported in metazoans. However, a recent study identified Drosophila and human MESH1 (Metazoan SpoT Homolog 1) as the homologs of the ppGpp hydrolase domain of the bacterial SpoT (10). Both MESH1 proteins exhibit ppGpp hydrolase activity, and the deletion of Mesh1 in Drosophila led to a transcriptional response reminiscent of the bacterial stringent response (10). Recently, we have found that the genetic removal of MESH1 in tumor cells triggers extensive transcriptional changes and confers protection against oxidative stress-induced ferroptosis (11). Importantly, MESH1 removal also triggers proliferative arrest and other robust anti-tumor effects. Therefore, MESH1 knockdown leads to both stress survival and proliferation arrest, two cardinal features highly reminiscent of the bacterial stringent response. Therefore, we termed this pathway as “mammalian stringent response” (12). We have found that NADPH is the relevant MESH1 in the contexts of ferroptosis (13). Now, we are investigating how MESH1 removal leads to proliferation of arrests and anti-tumor phenotypes. Furthermore, we have found several other substrates of MESH1. We are investigating their function using culture cells, MESH1 KO mice, and other model organisms.
C. Genomic and single cell RNA analysis of Red Blood Cells
Red blood cells (RBC) are responsible for oxygen delivery to muscles during vigorous exercise. Therefore, many doping efforts focus on increasing RBC number and function to boost athletic performance during competition. For many decades, RBC were thought to be merely identical “sacs of hemoglobin” with no discernable differences due to factors such as age or pre-transfusion storage time. Additionally, because RBC lose their nuclei during terminal differentiation, they were not believed to retain any genetic materials. These long-held beliefs have now been disproven and the results have significant implications for detecting autologous blood transfusion (ABT) doping in athletes. We were among the first to discover that RBCs contain abundant and diverse species of RNAs. Using this knowledge, we subsequently optimized protocols and performed genomic analysis of the RBC transcriptome in sickle cell disease; these results revealed that heterogeneous RBCs could be divided into several subpopulations, which had implications for the mechanisms of malaria resistance. As an extension of these studies, we used high resolution Illumina RNA-Seq approaches to identify hundreds of additional known and novel microRNAs, mRNAs, and other RNA species in RBCs. This dynamic RBC transcriptome represents a significant opportunity to assess the impact that environmental factors (such as pre-transfusion refrigerate storage) on the RBC transcriptome. We have now identified a >10-fold change in miR-720 as well as several other RNA transcripts whose levels are significantly altered by RBC storage (14) which gained significant press coverage. We are pursuing the genomic and single cell analysis of RNA transcriptome in the context of blood doping, sickle cell diseases and other red cell diseases.
1. Tang X, Wu J, Ding CK, Lu M, Keenan MM, Lin CC, et al. Cystine Deprivation Triggers Programmed Necrosis in VHL-Deficient Renal Cell Carcinomas. Cancer Res. 2016;76(7):1892-903.
2. Tang X, Ding CK, Wu J, Sjol J, Wardell S, Spasojevic I, et al. Cystine addiction of triple-negative breast cancer associated with EMT augmented death signaling. Oncogene. 2017;36(30):4379.
3. Lin CC, Mabe NW, Lin YT, Yang WH, Tang X, Hong L, et al. RIPK3 upregulation confers robust proliferation and collateral cystine-dependence on breast cancer recurrence. Cell Death Differ. 2020.
4. Yang WH, Huang Z, Wu J, Ding C-KC, Murphy SK, Chi J-T. A TAZ-ANGPTL4-NOX2 axis regulates ferroptotic cell death and chemoresistance in epithelial ovarian cancer. Molecular Cancer Research. 2019: molcanres.0691.2019.
5. Chen PH, Wu J, Ding CC, Lin CC, Pan S, Bossa N, et al. Kinome screen of ferroptosis reveals a novel role of ATM in regulating iron metabolism. Cell Death Differ. 2019.
6. Yang W-H, Chi J-T. Hippo pathway effectors YAP/TAZ as novel determinants of ferroptosis. Molecular & Cellular Oncology. 2019:1699375.
7. Yang WH, Ding CKC, Sun T, Hsu DS, Chi JT. The Hippo Pathway Effector TAZ Regulates Ferroptosis in Renal Cell Carcinoma Cell Reports. 2019;28(10):2501-8.e4.
8. Potrykus K, Cashel M. (p)ppGpp: still magical? Annu Rev Microbiol. 2008;62:35-51.
9. Kriel A, Bittner AN, Kim SH, Liu K, Tehranchi AK, Zou WY, et al. Direct regulation of GTP homeostasis by (p)ppGpp: a critical component of viability and stress resistance. Mol Cell. 2012;48(2):231-41.
10. Sun D, Lee G, Lee JH, Kim HY, Rhee HW, Park SY, et al. A metazoan ortholog of SpoT hydrolyzes ppGpp and functions in starvation responses. Nat Struct Mol Biol. 2010;17(10):1188-94.
11. Dixon SJ, Lemberg KM, Lamprecht MR, Skouta R, Zaitsev EM, Gleason CE, et al. Ferroptosis: an iron-dependent form of nonapoptotic cell death. Cell. 2012;149(5):1060-72.
12. Ding C-KC, Rose J, Wu J, Sun T, Chen K-Y, Chen P-H, et al. Mammalian stringent-like response mediated by the cytosolic NADPH phosphatase MESH1. bioRxiv. 2018.
13. Ding C-KC, Rose J, Sun T, Wu J, Chen P-H, Lin C-C, et al. MESH1 is a cytosolic NADPH phosphatase that regulates ferroptosis. Nature Metabolism. 2020.
14. Yang WH, Doss JF, Walzer KA, McNulty SM, Wu J, Roback JD, et al. Angiogenin-mediated tRNA cleavage as a novel feature of stored red blood cells. Br J Haematol. 2018.
Education
- M.D. National Taiwan University (Taiwan), 1991
- Ph.D. Stanford University, 2000
Trainings & Certifications
- Postdoctoral Research, Biochemistry (2000 - 2004) Stanford University
Positions
- Professor in Molecular Genetics and Microbiology
- Associate Professor of Cell Biology
- Professor of Biomedical Engineering
- Professor in Integrative Immunobiology
- Professor of Cell Biology
- Professor of Pharmacology and Cancer Biology
- Professor in Radiation Oncology
- Professor in Medicine
- Member of the Duke Cancer Institute
Awards, Honors, and Distinctions
- Michael B. Kastan Award for Research Excellence. AACR. 2021
- Member of American Society of Clinical Investigation. American Society of Clinical Investigation. 2011
- Investigators in Pathogenesis of Infectious Diseases. Burroughs Wellcome Fund. 2009
Courses Taught
- UPGEN 778F: University Program in Genetics and Genomics Biological Solutions Module VI
- MGM 593: Research Independent Study
- MGM 293: Research Independent Study I
Publications
- Chen S-Y, Wu J, Chen Y, Wang Y-E, Setayeshpour Y, Federico C, et al. NINJ1 regulates ferroptosis via xCT antiporter interaction and CoA modulation. Cell Death Dis. 2024 Oct 18;15(10):755.
- Dai E, Chen X, Linkermann A, Jiang X, Kang R, Kagan VE, et al. A guideline on the molecular ecosystem regulating ferroptosis. Nat Cell Biol. 2024 Sep;26(9):1447–57.
- Chi J-T, Lin CC, Lin Y-T, Chen S-Y, Setayeshpour Y, Chen Y, et al. Coenzyme A protects against ferroptosis via CoAlation of thioredoxin reductase 2. 2024.
- Chen X, Tsvetkov AS, Shen H-M, Isidoro C, Ktistakis NT, Linkermann A, et al. International consensus guidelines for the definition, detection, and interpretation of autophagy-dependent ferroptosis. Autophagy. 2024 Jun;20(6):1213–46.
- Chen Y, Lin P-H, Freedland SJ, Chi J-T. Metabolic Response to Androgen Deprivation Therapy of Prostate Cancer. Cancers (Basel). 2024 May 24;16(11).
- Wang C, Chang C-C, Chi J-T, Yuan F. Sucrose Treatment Enhances the Electrotransfer of DNA by Activating Phospholipase A2. Pharmaceutics. 2024 Mar 29;16(4).
- Lin C-C, Chi J-T. Abstract 359: The Hippo pathway on breast tumor recurrence <and> collateral vulnerability to ferroptosis. In: Cancer Research. American Association for Cancer Research (AACR); 2024. p. 359–359.
- Chen S-Y, Lin C-C, Wu J, Chen Y, Wang Y-E, Setayeshpour Y, et al. NINJ1 regulates ferroptosis via xCT antiporter interaction and CoA modulation. 2024.
- Chen Y, Lu X, Whitney RL, Li Y, Robson MJ, Blakely RD, et al. Novel anti-inflammatory effects of the IL-1 receptor in kidney myeloid cells following ischemic AKI. Front Mol Biosci. 2024;11:1366259.
- Amaral LJ, Gresham G, Butowski NA, Peters KB, Sharma A, Fonkem E, et al. DIET2TREAT: A randomized, multi-center, phase 2 trial of a ketogenic diet vs standard dietary guidance in combination with standard-of-care treatment for patients with newly diagnosed glioblastoma. In: JOURNAL OF CLINICAL ONCOLOGY. 2024.
- Huynh DT, Tsolova KN, Watson AJ, Khal SK, Green JR, Li D, et al. O-GlcNAcylation regulates neurofilament-light assembly and function and is perturbed by Charcot-Marie-Tooth disease mutations. Nat Commun. 2023 Oct 17;14(1):6558.
- Setayeshpour Y, Lee Y, Chi J-T. Environmental Determinants of Ferroptosis in Cancer. Cancers (Basel). 2023 Jul 29;15(15).
- Du K, Maeso-Díaz R, Oh SH, Wang E, Chen T, Pan C, et al. Targeting YAP-mediated HSC death susceptibility and senescence for treatment of liver fibrosis. In: Hepatology. 2023. p. 1998–2015.
- Byun J-K, Lee SH, Moon EJ, Park M-H, Jang H, Weitzel DH, et al. Manassantin A inhibits tumour growth under hypoxia through the activation of chaperone-mediated autophagy by modulating Hsp90 activity. Br J Cancer. 2023 Apr;128(8):1491–502.
- Sun T, Ding C-KC, Chi J-T. Data on the transcriptional response to MESH1 knockdown and mammalian stringent response. Data Brief. 2023 Apr;47:108938.
- Huynh DT, Hu J, Schneider JR, Tsolova KN, Soderblom EJ, Watson AJ, et al. O-GlcNAcylation regulates neurofilament-light assembly and function and is perturbed by Charcot-Marie-Tooth disease mutations. 2023.
- Chi J-T, Zhou P. From magic spot ppGpp to MESH1: Stringent response from bacteria to metazoa. PLoS Pathog. 2023 Feb;19(2):e1011105.
- Du K, Jun JH, Diaz RM, Dutta RK, Oh S-H, Chi J-TA, et al. BREAKING THE LINK BETWEEN AGING AND NAFLD: UNRAVELING THE ROLE OF FERROPTOSIS. In: HEPATOLOGY. 2023. p. S1074–S1074.
- Hsieh CH, Huang WY, Hsieh MC, Tai YT, Chi JTA, Dong SJ, et al. A Labchip with Co-Cultured Spheroids Applied for HIPEC Cancer Drug Screening. In: 2023 22nd International Conference on Solid-State Sensors, Actuators and Microsystems, Transducers 2023. 2023. p. 1288–91.
- Chien YS, Wang CP, Hsieh MC, Tai YT, Chi JTA, Don SJ, et al. Peritoneal Tumor Microenvironment Labchip For The Selection Of Hipec Drugs. In: 2023 22nd International Conference on Solid-State Sensors, Actuators and Microsystems, Transducers 2023. 2023. p. 1024–7.
- Huynh DT, Hu J, Tsolova K, Zorawski M, Lin CC, Soderblom E, et al. Regulation of Human Neurofilament-light Assembly State by O-GlcNAc and Potential Hypoglycosylation of Charcot-Marie-Tooth Disease Mutants. In: MOLECULAR BIOLOGY OF THE CELL. 2023. p. 429–429.
- Lin C-C, Yan J, Kapur MD, Norris KL, Hsieh C-W, Huang D, et al. Parkin coordinates mitochondrial lipid remodeling to execute mitophagy. EMBO Rep. 2022 Dec 6;23(12):e55191.
- Kovach AR, Oristian KM, Kirsch DG, Bentley RC, Cheng C, Chen X, et al. Identification and targeting of a HES1-YAP1-CDKN1C functional interaction in fusion-negative rhabdomyosarcoma. Mol Oncol. 2022 Oct;16(20):3587–605.
- Chi J-T, Lin P-H, Tolstikov V, Howard L, Chen EY, Bussberg V, et al. Serum metabolomic analysis of men on a low-carbohydrate diet for biochemically recurrent prostate cancer reveals the potential role of ketogenesis to slow tumor growth: a secondary analysis of the CAPS2 diet trial. Prostate Cancer Prostatic Dis. 2022 Apr;25(4):770–7.
- Sun T, Ding C-KC, Zhang Y, Lin C-C, Wu J, Setayeshpour Y, et al. MESH1 knockdown triggers proliferation arrest through TAZ repression. Cell Death Dis. 2022 Mar 10;13(3):221.
- Schirmer AU, Driver LM, Zhao MT, Wells CI, Pickett JE, O’Bryne SN, et al. Non-canonical role of Hippo tumor suppressor serine/threonine kinase 3 STK3 in prostate cancer. Mol Ther. 2022 Jan 5;30(1):485–500.
- Boyce M, Hu J, Huynh DT, Chen P-H, Chi J-T. O-GlcNAcylation in KLHL proteostasis pathways links upstream signals to downstream cytoskeletal dynamics and ion homeostasis. In: GLYCOBIOLOGY. 2022. p. 1013–4.
- Mestre AA, Zhou P, Chi J-T. Metazoan stringent-like response mediated by MESH1 phenotypic conservation via distinct mechanisms. Comput Struct Biotechnol J. 2022;20:2680–4.
- Jain V, Yang W-H, Wu J, Roback JD, Gregory SG, Chi J-T. Single Cell RNA-Seq Analysis of Human Red Cells. Front Physiol. 2022;13:828700.
- Chi J-T, Lin P-H, Tolstikov V, Howard L, Chen E, Bussberg V, et al. Serum metabolomic analysis of men on a low-carbohydrate diet for biochemically recurrent prostate cancer reveal the potential role of ketogenesis to slow tumor growth: A secondary analysis of the CAPS2 diet trial. 2022;
- Wang L, Wu T-H, Hu X, Liu J, Wu D, Miguez PA, et al. Biomimetic polydopamine-laced hydroxyapatite collagen material orients osteoclast behavior to an anti-resorptive pattern without compromising osteoclasts' coupling to osteoblasts. Biomater Sci. 2021 Nov 9;9(22):7565–74.
- Park H-S, Price H, Ceballos S, Chi J-T, Wax A. Single Cell Analysis of Stored Red Blood Cells Using Ultra-High Throughput Holographic Cytometry. Cells. 2021 Sep 17;10(9).
- Du K, Oh SH, Dutta RK, Sun T, Yang W-H, Chi J-T, et al. Inhibiting xCT/SLC7A11 induces ferroptosis of myofibroblastic hepatic stellate cells but exacerbates chronic liver injury. Liver Int. 2021 Sep;41(9):2214–27.
- Lin C-C, Ding C-KC, Sun T, Wu J, Chen K-Y, Zhou P, et al. The regulation of ferroptosis by MESH1 through the activation of the integrative stress response. Cell Death Dis. 2021 Jul 22;12(8):727.
- Moon EJ, Mello SS, Li CG, Chi J-T, Thakkar K, Kirkland JG, et al. The HIF target MAFF promotes tumor invasion and metastasis through IL11 and STAT3 signaling. Nat Commun. 2021 Jul 14;12(1):4308.
- Chi J-T, Lin P-H, Tolstikov V, Oyekunle T, Alvarado GCG, Ramirez-Torres A, et al. The influence of low-carbohydrate diets on the metabolic response to androgen-deprivation therapy in prostate cancer. Prostate. 2021 Jul;81(10):618–28.
- Chen P-H, Chi J-T. Unexpected zinc dependency of ferroptosis: what is in a name? Oncotarget. 2021 Jun 8;12(12):1126–7.
- Yang W-H, Lin C-C, Wu J, Chao P-Y, Chen K, Chen P-H, et al. The Hippo Pathway Effector YAP Promotes Ferroptosis via the E3 Ligase SKP2. Mol Cancer Res. 2021 Jun;19(6):1005–14.
- Sun T, Chi J-T. Regulation of ferroptosis in cancer cells by YAP/TAZ and Hippo pathways: The therapeutic implications. Genes Dis. 2021 May;8(3):241–9.
- Lin C-C, Yang W-H, Lin Y-T, Tang X, Chen P-H, Ding C-KC, et al. DDR2 upregulation confers ferroptosis susceptibility of recurrent breast tumors through the Hippo pathway. Oncogene. 2021 Mar;40(11):2018–34.
- Chen P-H, Wu J, Xu Y, Ding C-KC, Mestre AA, Lin C-C, et al. Zinc transporter ZIP7 is a novel determinant of ferroptosis. Cell Death Dis. 2021 Feb 19;12(2):198.
- Slemmons KK, Deel MD, Lin Y-T, Oristian KM, Kuprasertkul N, Genadry KC, et al. A method to culture human alveolar rhabdomyosarcoma cell lines as rhabdospheres demonstrates an enrichment in stemness and Notch signaling. Biol Open. 2021 Feb 9;10(2).
- Setayeshpour Y, Chi J-T. Editorial: Novel Insights Into Ferroptosis. Front Cell Dev Biol. 2021;9:754160.
- Park HS, Price H, Ceballos S, Chi J-T, Wax A. Characterizing stored red blood cells using ultra-high throughput holographic cytometry. 2021;
- Wang L, Lee DJ, Han H, Zhao L, Tsukamoto H, Kim Y-I, et al. Application of bioluminescence resonance energy transfer-based cell tracking approach in bone tissue engineering. J Tissue Eng. 2021;12:2041731421995465.
- Du K, Oh S-H, Diaz RM, Chi J-TA, Diehl AM. HIPPO-YAP PATHWAY IS A MASTER REGULATOR OF HEPATIC STELLATE CELL SENESCENCE AND FERROPTOSIS SUSCEPTIBILITY. In: HEPATOLOGY. 2021. p. 115A-115A.
- Mabe NW, Garcia NMG, Wolery SE, Newcomb R, Meingasner RC, Vilona BA, et al. G9a Promotes Breast Cancer Recurrence through Repression of a Pro-inflammatory Program. Cell Rep. 2020 Nov 3;33(5):108341.
- Lin C-C, Chi J-T. Ferroptosis of epithelial ovarian cancer: genetic determinants and therapeutic potential. Oncotarget. 2020 Sep 29;11(39):3562–70.
- Chi J-T, Lin P-H, Tolstikov V, Oyekunle T, Galván Alvarado GC, Ramirez-Torres A, et al. The effects of low-carbohydrate diets on the metabolic response to androgen-deprivation therapy in prostate cancer. 2020 Sep 25;
- Chen P-H, Tseng WH-S, Chi J-T. The Intersection of DNA Damage Response and Ferroptosis-A Rationale for Combination Therapeutics. Biology (Basel). 2020 Jul 23;9(8).
- Lin C-C, Mabe NW, Lin Y-T, Yang W-H, Tang X, Hong L, et al. RIPK3 upregulation confers robust proliferation and collateral cystine-dependence on breast cancer recurrence. Cell Death Differ. 2020 Jul;27(7):2234–47.
- Chi J-T, Lin P-H, Tolstikov V, Oyekunle T, Chen EY, Bussberg V, et al. Metabolomic effects of androgen deprivation therapy treatment for prostate cancer. Cancer Med. 2020 Jun;9(11):3691–702.
- Dambal S, Alfaqih M, Sanders S, Maravilla E, Ramirez-Torres A, Galvan GC, et al. 27-Hydroxycholesterol Impairs Plasma Membrane Lipid Raft Signaling as Evidenced by Inhibition of IL6-JAK-STAT3 Signaling in Prostate Cancer Cells. Mol Cancer Res. 2020 May;18(5):671–84.
- Huynh DT, Chen P-H, Hu J, Smith TJ, Chi J-T, Boyce MS. Kelch‐like Proteins Have A Sweet Spot: Site‐specific Glycosylation Influences Metabolic Regulation and Protein Homeostasis. In: The FASEB Journal. Wiley; 2020. p. 1–1.
- Ding C-KC, Rose J, Sun T, Wu J, Chen P-H, Lin C-C, et al. MESH1 is a cytosolic NADPH phosphatase that regulates ferroptosis. Nature metabolism. 2020 Mar;2(3):270–7.
- Chen P-H, Wu J, Ding C-KC, Lin C-C, Pan S, Bossa N, et al. Kinome screen of ferroptosis reveals a novel role of ATM in regulating iron metabolism. Cell Death Differ. 2020 Mar;27(3):1008–22.
- Chen P-H, Hu J, Wu J, Huynh DT, Smith TJ, Pan S, et al. Gigaxonin glycosylation regulates intermediate filament turnover and may impact giant axonal neuropathy etiology or treatment. JCI Insight. 2020 Jan 16;5(1).
- Yang W-H, Chi J-T. Hippo pathway effectors YAP/TAZ as novel determinants of ferroptosis. Mol Cell Oncol. 2020;7(1):1699375.
- Du K, Oh S-H, Sun T, Yang W-H, Chi J-TA, Diehl AM. YAP SIGNALING DICTATES CELL-STATE-DEPENDENT FERROPTOSIS SUSCEPTIBILITY IN HEPATIC STELLATE CELLS. In: HEPATOLOGY. 2020. p. 215A-215A.
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- Syu J-P, Chi J-T, Kung H-N. Nrf2 is the key to chemotherapy resistance in MCF7 breast cancer cells under hypoxia. Oncotarget. 2016 Mar 22;7(12):14659–72.
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- Tang X, Keenan MM, Wu J, Lin C-A, Dubois L, Thompson JW, et al. Comprehensive profiling of amino acid response uncovers unique methionine-deprived response dependent on intact creatine biosynthesis. PLoS Genet. 2015 Apr;11(4):e1005158.
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- Mo L, Bachelder RE, Kennedy M, Chen P-H, Chi J-T, Berchuck A, et al. Syngeneic Murine Ovarian Cancer Model Reveals That Ascites Enriches for Ovarian Cancer Stem-Like Cells Expressing Membrane GRP78. Mol Cancer Ther. 2015 Mar;14(3):747–56.
- Mercer JL, Argus JP, Crabtree DM, Keenan MM, Wilks MQ, Chi J-TA, et al. Modulation of PICALM Levels Perturbs Cellular Cholesterol Homeostasis. PLoS One. 2015;10(6):e0129776.
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- Jiang X, Nevins JR, Shats I, Chi J-T. E2F1-Mediated Induction of NFYB Attenuates Apoptosis via Joint Regulation of a Pro-Survival Transcriptional Program. PLoS One. 2015;10(6):e0127951.
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- Keenan MM, Chi J-T. Alternative fuels for cancer cells. Cancer J. 2015;21(2):49–55.
- Kung HN, Chi JT. The role of glutamine synthetase in the glutamine independence in mammary tissue. 2015 Jan 1;87–97.
- Rempel RE, Jiang X, Fullerton P, Tan TZ, Ye J, Lau JA, et al. Utilization of the Eμ-Myc mouse to model heterogeneity of therapeutic response. Mol Cancer Ther. 2014 Dec;13(12):3219–29.
- Keenan MM, Ding C-KC, Chi J-T. An unexpected alliance between stress responses to drive oncogenesis. Breast Cancer Res. 2014 Nov 6;16(6):471.
- Wang B, Liu T-Y, Lai C-H, Rao Y-H, Choi M-C, Chi J-T, et al. Glycolysis-dependent histone deacetylase 4 degradation regulates inflammatory cytokine production. Mol Biol Cell. 2014 Nov 1;25(21):3300–7.
- Kephart J, Jones R, Crose L, Chi J-TA, Linardic C. Abstract A57: The secreted Wnt inhibitor SFRP3 is required for PAX3-FOXO1-positive alveolar rhabdomyosarcoma tumorigenesis. In: Cancer Research. American Association for Cancer Research (AACR); 2014. p. A57–A57.
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- Tang X, Lin C-C, Spasojevic I, Iversen ES, Chi J-T, Marks JR. A joint analysis of metabolomics and genetics of breast cancer. Breast Cancer Res. 2014 Aug 5;16(4):415.
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- Dewhirst MW, Chi J-T. Understanding the tumor microenvironment and radioresistance by combining functional imaging with global gene expression. Semin Radiat Oncol. 2013 Oct;23(4):296–305.
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- Sangokoya C, Doss JF, Chi J-T. Iron-responsive miR-485-3p regulates cellular iron homeostasis by targeting ferroportin. PLoS Genet. 2013 Apr;9(4):e1003408.
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- Lacsina JR, LaMonte G, Nicchitta CV, Chi J-T. Polysome profiling of the malaria parasite Plasmodium falciparum. Mol Biochem Parasitol. 2011 Sep;179(1):42–6.
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- Lucas JE, Kung H-N, Chi J-TA. Latent factor analysis to discover pathway-associated putative segmental aneuploidies in human cancers. PLoS Comput Biol. 2010 Sep 2;6(9):e1000920.
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- Lindsay RG, Chi JT. Contact lens management of infantile aphakia. Clin Exp Optom. 2010 Jan;93(1):3–14.
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- Lucas JE, Carvalho CM, Chen JL-Y, Chi J-T, West M. Cross-study projections of genomic biomarkers: an evaluation in cancer genomics. PLoS One. 2009;4(2):e4523.
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- Nuyten DSA, Hastie T, Chi J-TA, Chang HY, van de Vijver MJ. Combining biological gene expression signatures in predicting outcome in breast cancer: An alternative to supervised classification. Eur J Cancer. 2008 Oct;44(15):2319–29.
- Chen S-Y, Wang Y, Telen MJ, Chi J-T. The genomic analysis of erythrocyte microRNA expression in sickle cell diseases. PLoS One. 2008 Jun 4;3(6):e2360.
- Chi JTA, Nevins JR, Febbo PG. Transcriptome analysis. 2008 Mar 26;283–91.
- Edelman EJ, Guinney J, Chi J-T, Febbo PG, Mukherjee S. Modeling cancer progression via pathway dependencies. PLoS Comput Biol. 2008 Feb;4(2):e28.
- Gottwein E, Mukherjee N, Sachse C, Frenzel C, Majoros WH, Chi J-TA, et al. A viral microRNA functions as an orthologue of cellular miR-155. Nature. 2007 Dec 13;450(7172):1096–9.
- Chi JTA, Wang Z, Potti A. Regional specialization of endothelial cells as revealed by genomic analysis. 2007 Dec 1;123–34.
- Chen S-Y, Wang Y, Telen MI, Chi J-TA. The Identification and Genomic Analysis of microRNAs in Human Erythrocytes in Sickle Cell Diseases. In: Blood. American Society of Hematology; 2007. p. 3400–3400.
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- Moon EJ, Brizel DM, Chi J-TA, Dewhirst MW. The potential role of intrinsic hypoxia markers as prognostic variables in cancer. Antioxid Redox Signal. 2007 Aug;9(8):1237–94.
- Myers JW, Chi J-T, Gong D, Schaner ME, Brown PO, Ferrell JE. Minimizing off-target effects by using diced siRNAs for RNA interference. J RNAi Gene Silencing. 2006 Jul 17;2(2):181–94.
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- Chang HY, Wang NN, Chi JT. High-throughput RNA interference. 2005 Jan 1;470–9.
- Chang HY, Sneddon JB, Alizadeh AA, Sood R, West RB, Montgomery K, et al. Gene expression signature of fibroblast serum response predicts human cancer progression: similarities between tumors and wounds. PLoS Biol. 2004 Feb;2(2):E7.
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- Chi J-T, Chang HY, Wang NN, Chang DS, Dunphy N, Brown PO. Genomewide view of gene silencing by small interfering RNAs. Proc Natl Acad Sci U S A. 2003 May 27;100(11):6343–6.
- Yang GP, Ashley Chi JT, Longaker MT. Genetic susceptibility to keloid disease and hypertrophic scarring: Transforming growth factor β1 common polymorphisms and plasma levels: Discussion. Plastic and Reconstructive Surgery. 2003 Feb 1;111(2):544–6.
- Chang HY, Chi J-T, Dudoit S, Bondre C, van de Rijn M, Botstein D, et al. Diversity, topographic differentiation, and positional memory in human fibroblasts. Proc Natl Acad Sci U S A. 2002 Oct 1;99(20):12877–82.
- Ji J, Chen X, Leung SY, Chi J-TA, Chu KM, Yuen ST, et al. Comprehensive analysis of the gene expression profiles in human gastric cancer cell lines. Oncogene. 2002 Sep 19;21(42):6549–56.
- Messika EJ, Lu PS, Sung YJ, Yao T, Chi JT, Chien YH, et al. Differential effect of B lymphocyte-induced maturation protein (Blimp-1) expression on cell fate during B cell development. J Exp Med. 1998 Aug 3;188(3):515–25.
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