TY - JOUR
T1 - Malic Enzyme 1 Absence in Synovial Sarcoma Shifts Antioxidant System Dependence and Increases Sensitivity to Ferroptosis Induction with ACXT-3102
AU - Brashears, Caitlyn B.
AU - Prudner, Bethany C.
AU - Rathore, Richa
AU - Caldwell, Katharine E.
AU - Dehner, Carina A.
AU - Buchanan, Jane L.
AU - Lange, Sara E.S.
AU - Poulin, Neal
AU - Sehn, Jennifer K.
AU - Roszik, Jason
AU - Spitzer, Dirk
AU - Jones, Kevin B.
AU - O’Keefe, Regis
AU - Nielsen, Torsten O.
AU - Taylor, Eric B.
AU - Held, Jason M.
AU - Hawkins, William
AU - Van Tine, Brian A.
N1 - Funding Information:
The authors would like to thank the following funding sources: NCI R01 CA227115 (B.A. Van Tine), CJ’s Journey (B.A. Van Tine and R. Rathore), Wipe Out Kids Cancer (B.A. Van Tine and S.E.S. Lange), The Sarcoma Foundation of America (B.A. Van Tine and B.C. Prudner), the Sarcoma Alliance for Research and Collaboration (B.A. Van Tine and C.B. Brashears), the Canadian Cancer Society Grant #701582 (T.O. Nielsen), the Sarcoma Cancer Foundation of Canada Beth England’s Sarcoma Research Fund (T.O. Nielsen), the Pedal for Home Impact Grant of the Canadian Cancer Society grant #705615 (T.O. Nielsen), Washington University in St. Louis School of Medicine MSTP training grant #5T32GM007200 (C.B. Brashears), NCI R01 CA163764 (W. Hawkins and D. Spitzer), Washington University Surgical Oncology Training Grant #T32CA009621 (K.E. Caldwell), NIH R01 DK104998 (E.B. Taylor), NIDDK F30 DK127845 (J.L. Buchanan), and University of Iowa Medical Scientist Training Program #T32TGM007337 (J.L. Buchanan) to Steven Lentz and Pamela Geyer. The results represented here are in whole or part based upon data generated by the TCGA Research Network: https://www.cancer.gov/ tcga. We would like to thank the lab of Dr. Rabinowitz for their generous gift of G6PDi-1.
Funding Information:
B.C. Prudner reports other support from Miltenyi Biomedicine outside the submitted work. R. Rathore reports personal fees from Natera outside the submitted work. D. Spitzer reports grants from NIH (R01 CA163764) and personal fees from
Publisher Copyright:
©2022 The Authors.
PY - 2022/8/15
Y1 - 2022/8/15
N2 - Purpose: To investigate the metabolism of synovial sarcoma (SS) and elucidate the effect of malic enzyme 1 absence on SS redox homeostasis. Experimental Design: ME1 expression was measured in SS clinical samples, SS cell lines, and tumors from an SS mouse model. The effect of ME1 absence on glucose metabolism was evaluated utilizing Seahorse assays, metabolomics, and C13 tracings. The impact of ME1 absence on SS redox homeostasis was evaluated by metabolomics, cell death assays with inhibitors of antioxidant systems, and measurements of intracellular reactive oxygen species (ROS). The susceptibility of ME1-null SS to ferroptosis induction was interrogated in vitro and in vivo. Results: ME1 absence in SS was confirmed in clinical samples, SS cell lines, and an SS tumor model. Investigation of SS glucose metabolism revealed that ME1-null cells exhibit higher rates of glycolysis and higher flux of glucose into the pentose phosphate pathway (PPP), which is necessary to produce NADPH. Evaluation of cellular redox homeostasis demonstrated that ME1 absence shifts dependence from the glutathione system to the thioredoxin system. Concomitantly, ME1 absence drives the accumulation of ROS and labile iron. ROS and iron accumulation enhances the susceptibility of ME1-null cells to ferroptosis induction with inhibitors of xCT (erastin and ACXT-3102). In vivo xenograft models of ME1-null SS demonstrate significantly increased tumor response to ACXT-3102 compared with ME1-expressing controls. Conclusions: These findings demonstrate the translational potential of targeting redox homeostasis in ME1-null cancers and establish the preclinical rationale for a phase I trial of ACXT-3102 in SS patients.
AB - Purpose: To investigate the metabolism of synovial sarcoma (SS) and elucidate the effect of malic enzyme 1 absence on SS redox homeostasis. Experimental Design: ME1 expression was measured in SS clinical samples, SS cell lines, and tumors from an SS mouse model. The effect of ME1 absence on glucose metabolism was evaluated utilizing Seahorse assays, metabolomics, and C13 tracings. The impact of ME1 absence on SS redox homeostasis was evaluated by metabolomics, cell death assays with inhibitors of antioxidant systems, and measurements of intracellular reactive oxygen species (ROS). The susceptibility of ME1-null SS to ferroptosis induction was interrogated in vitro and in vivo. Results: ME1 absence in SS was confirmed in clinical samples, SS cell lines, and an SS tumor model. Investigation of SS glucose metabolism revealed that ME1-null cells exhibit higher rates of glycolysis and higher flux of glucose into the pentose phosphate pathway (PPP), which is necessary to produce NADPH. Evaluation of cellular redox homeostasis demonstrated that ME1 absence shifts dependence from the glutathione system to the thioredoxin system. Concomitantly, ME1 absence drives the accumulation of ROS and labile iron. ROS and iron accumulation enhances the susceptibility of ME1-null cells to ferroptosis induction with inhibitors of xCT (erastin and ACXT-3102). In vivo xenograft models of ME1-null SS demonstrate significantly increased tumor response to ACXT-3102 compared with ME1-expressing controls. Conclusions: These findings demonstrate the translational potential of targeting redox homeostasis in ME1-null cancers and establish the preclinical rationale for a phase I trial of ACXT-3102 in SS patients.
UR - http://www.scopus.com/inward/record.url?scp=85136341579&partnerID=8YFLogxK
U2 - 10.1158/1078-0432.CCR-22-0470
DO - 10.1158/1078-0432.CCR-22-0470
M3 - Article
C2 - 35421237
AN - SCOPUS:85136341579
SN - 1078-0432
VL - 28
SP - 3573
EP - 3589
JO - Clinical Cancer Research
JF - Clinical Cancer Research
IS - 16
ER -