Veronica Valvo1, Asumi Iesato1, Taylor R Kavanagh2, Carmen Priolo2, Zsuzsanna Zsengeller3, Alfredo Pontecorvi4, Isaac E Stillman3, Suzanne D Burke5, Xiaowen Liu6, Carmelo Nucera1,7,8. 1. Laboratory of Human Thyroid Cancers Preclinical and Translational Research, Division of Experimental Pathology, Department of Pathology, Cancer Research Institute (CRI), Cancer Center, Beth Israel Deaconess Medical Center, Harvard Medical School, Boston, Massachusetts, USA. 2. Department of Medicine, Brigham and Women's Hospital, Harvard Medical School, Boston, Massachusetts, USA. 3. Department of Pathology; Harvard Medical School, Boston, Massachusetts, USA. 4. Department of Medicine, Agostino Gemelli Medical School, UCSC, Rome, Italy. 5. Department of Medicine; Harvard Medical School, Boston, Massachusetts, USA. 6. Department of Emergency Medicine; Harvard Medical School, Boston, Massachusetts, USA. 7. Center for Vascular Biology Research (CVBR); Beth Israel Deaconess Medical Center, Harvard Medical School, Boston, Massachusetts, USA. 8. Broad Institute of MIT and Harvard, Cambridge, Massachusetts, USA.
Abstract
Background: BRAFV600E acts as an ATP-dependent cytosolic kinase. BRAFV600E inhibitors are widely available, but resistance to them is widely reported in the clinic. Lipid metabolism (fatty acids) is fundamental for energy and to control cell stress. Whether and how BRAFV600E impacts lipid metabolism regulation in papillary thyroid carcinoma (PTC) is still unknown. Acetyl-CoA carboxylase (ACC) is a rate-limiting enzyme for de novo lipid synthesis and inhibition of fatty acid oxidation (FAO). ACC1 and ACC2 genes encode distinct isoforms of ACC. The aim of our study was to determine the relationship between BRAFV600E and ACC in PTC. Methods: We performed RNA-seq and DNA copy number analyses in PTC and normal thyroid (NT) in The Cancer Genome Atlas samples. Validations were performed by using assays on PTC-derived cell lines of differing BRAF status and a xenograft mouse model derived from a heterozygous BRAFWT/V600E PTC-derived cell line with knockdown (sh) of ACC1 or ACC2. Results: ACC2 mRNA expression was significantly downregulated in BRAFV600E-PTC vs. BRAFWT-PTC or NT clinical samples. ACC2 protein levels were downregulated in BRAFV600E-PTC cell lines vs. the BRAFWT/WT PTC cell line. Vemurafenib increased ACC2 (and to a lesser extent ACC1) mRNA levels in PTC-derived cell lines in a BRAFV600E allelic dose-dependent manner. BRAFV600E inhibition increased de novo lipid synthesis rates, and decreased FAO due to oxygen consumption rate (OCR), and extracellular acidification rate (ECAR), after addition of palmitate. Only shACC2 significantly increased OCR rates due to FAO, while it decreased ECAR in BRAFV600E PTC-derived cells vs. controls. BRAFV600E inhibition synergized with shACC2 to increase intracellular reactive oxygen species production, leading to increased cell proliferation and, ultimately, vemurafenib resistance. Mice implanted with a BRAFWT/V600E PTC-derived cell line with shACC2 showed significantly increased tumor growth after vemurafenib treatment, while vehicle-treated controls, or shGFP control cells treated with vemurafenib showed stable tumor growth. Conclusions: These findings suggest a potential link between BRAFV600E and lipid metabolism regulation in PTC. BRAFV600E downregulates ACC2 levels, which deregulates de novo lipid synthesis, FAO due to OCR, and ECAR rates. ShACC2 may contribute to vemurafenib resistance and increased tumor growth. ACC2 rescue may represent a novel molecular strategy for overcoming resistance to BRAFV600E inhibitors in refractory PTC.
Background: BRAFV600E acts as an ATP-dependent cytosolic kinase. BRAFV600E inhibitors are widely available, but resistance to them is widely reported in the clinic. Lipid metabolism (fatty acids) is fundamental for energy and to control cell stress. Whether and how BRAFV600E impacts lipid metabolism regulation in papillary thyroid carcinoma (PTC) is still unknown. Acetyl-CoA carboxylase (ACC) is a rate-limiting enzyme for de novo lipid synthesis and inhibition of fatty acid oxidation (FAO). ACC1 and ACC2 genes encode distinct isoforms of ACC. The aim of our study was to determine the relationship between BRAFV600E and ACC in PTC. Methods: We performed RNA-seq and DNA copy number analyses in PTC and normal thyroid (NT) in The Cancer Genome Atlas samples. Validations were performed by using assays on PTC-derived cell lines of differing BRAF status and a xenograft mouse model derived from a heterozygous BRAFWT/V600E PTC-derived cell line with knockdown (sh) of ACC1 or ACC2. Results: ACC2 mRNA expression was significantly downregulated in BRAFV600E-PTC vs. BRAFWT-PTC or NT clinical samples. ACC2 protein levels were downregulated in BRAFV600E-PTC cell lines vs. the BRAFWT/WT PTC cell line. Vemurafenib increased ACC2 (and to a lesser extent ACC1) mRNA levels in PTC-derived cell lines in a BRAFV600E allelic dose-dependent manner. BRAFV600E inhibition increased de novo lipid synthesis rates, and decreased FAO due to oxygen consumption rate (OCR), and extracellular acidification rate (ECAR), after addition of palmitate. Only shACC2 significantly increased OCR rates due to FAO, while it decreased ECAR in BRAFV600E PTC-derived cells vs. controls. BRAFV600E inhibition synergized with shACC2 to increase intracellular reactive oxygen species production, leading to increased cell proliferation and, ultimately, vemurafenib resistance. Mice implanted with a BRAFWT/V600E PTC-derived cell line with shACC2 showed significantly increased tumor growth after vemurafenib treatment, while vehicle-treated controls, or shGFP control cells treated with vemurafenib showed stable tumor growth. Conclusions: These findings suggest a potential link between BRAFV600E and lipid metabolism regulation in PTC. BRAFV600E downregulates ACC2 levels, which deregulates de novo lipid synthesis, FAO due to OCR, and ECAR rates. ShACC2 may contribute to vemurafenib resistance and increased tumor growth. ACC2 rescue may represent a novel molecular strategy for overcoming resistance to BRAFV600E inhibitors in refractory PTC.
Entities:
Keywords:
ACC2; BRAFV600E, ACC1; ROS; beta-oxidation; de novo lipid synthesis; fatty acid synthesis; mitochondria; seahorse; vemurafenib
Authors: Rebecca E Schweppe; Joshua P Klopper; Christopher Korch; Umarani Pugazhenthi; Miriam Benezra; Jeffrey A Knauf; James A Fagin; Laura A Marlow; John A Copland; Robert C Smallridge; Bryan R Haugen Journal: J Clin Endocrinol Metab Date: 2008-08-19 Impact factor: 5.958
Authors: John C Castle; Yoshikazu Hara; Christopher K Raymond; Philip Garrett-Engele; Kenji Ohwaki; Zhengyan Kan; Jun Kusunoki; Jason M Johnson Journal: PLoS One Date: 2009-02-03 Impact factor: 3.240
Authors: Zeus A Antonello; Nancy Hsu; Manoj Bhasin; Giovanni Roti; Mukta Joshi; Paul Van Hummelen; Emily Ye; Agnes S Lo; S Ananth Karumanchi; Christine R Bryke; Carmelo Nucera Journal: Oncotarget Date: 2017-09-24
Authors: Marco Crocco; Antonio Verrico; Claudia Milanaccio; Gianluca Piccolo; Patrizia De Marco; Gabriele Gaggero; Valentina Iurilli; Sonia Di Profio; Federica Malerba; Marta Panciroli; Paolo Giordano; Maria Grazia Calevo; Emilio Casalini; Natascia Di Iorgi; Maria Luisa Garrè Journal: Cancers (Basel) Date: 2022-05-29 Impact factor: 6.575
Authors: Siarhei A Dabravolski; Nikita G Nikiforov; Alexander D Zhuravlev; Nikolay A Orekhov; Liudmila M Mikhaleva; Alexander N Orekhov Journal: Int J Mol Sci Date: 2021-12-31 Impact factor: 5.923