Brian C Jensen1,2,3, Traci L Parry1,4, Wei Huang1, Ju Youn Beak1, Amro Ilaiwy5,6, James R Bain5,6, Christopher B Newgard5,6, Michael J Muehlbauer5, Cam Patterson7, Gary L Johnson3, Monte S Willis1,4,3. 1. McAllister Heart Institute, University of North Carolina, Chapel Hill, NC, USA. 2. Department of Internal Medicine, Division of Cardiology University of North Carolina, Chapel Hill, NC, USA. 3. Department of Pharmacology, University of North Carolina, Chapel Hill, NC, USA. 4. Department of Pathology & Laboratory Medicine, University of North Carolina, Chapel Hill, NC, USA. 5. Sarah W. Stedman Nutrition and Metabolism Center, Duke Molecular Physiology Institute, Duke University Medical Center, Durham, NC, USA. 6. Division of Endocrinology, Metabolism, and Nutrition, Department of Medicine, Duke University Medical Center, Durham, NC, USA. 7. Presbyterian Hospital/Weill-Cornell Medical Center, New York, NY, USA.
Abstract
BACKGROUND AND PURPOSE: The human kinome consists of roughly 500 kinases, including 150 that have been proposed as therapeutic targets. Protein kinases regulate an array of signalling pathways that control metabolism, cell cycle progression, cell death, differentiation and survival. It is not surprising, then, that new kinase inhibitors developed to treat cancer, including sorafenib, also exhibit cardiotoxicity. We hypothesized that sorafenib cardiotoxicity is related to its deleterious effects on specific cardiac metabolic pathways given the critical roles of protein kinases in cardiac metabolism. EXPERIMENTAL APPROACH: FVB/N mice (10 per group) were challenged with sorafenib or vehicle control daily for 2 weeks. Echocardiographic assessment of the heart identified systolic dysfunction consistent with cardiotoxicity in sorafenib-treated mice compared to vehicle-treated controls. Heart, skeletal muscle, liver and plasma were flash frozen and prepped for non-targeted GC-MS metabolomics analysis. KEY RESULTS: Compared to vehicle-treated controls, sorafenib-treated hearts exhibited significant alterations in 11 metabolites, including markedly altered taurine/hypotaurine metabolism (25-fold enrichment), identified by pathway enrichment analysis. CONCLUSIONS AND IMPLICATIONS: These studies identified alterations in taurine/hypotaurine metabolism in the hearts and skeletal muscles of mice treated with sorafenib. Interventions that rescue or prevent these sorafenib-induced changes, such as taurine supplementation, may be helpful in attenuating sorafenib-induced cardiac injury.
BACKGROUND AND PURPOSE: The human kinome consists of roughly 500 kinases, including 150 that have been proposed as therapeutic targets. Protein kinases regulate an array of signalling pathways that control metabolism, cell cycle progression, cell death, differentiation and survival. It is not surprising, then, that new kinase inhibitors developed to treat cancer, including sorafenib, also exhibit cardiotoxicity. We hypothesized that sorafenib cardiotoxicity is related to its deleterious effects on specific cardiac metabolic pathways given the critical roles of protein kinases in cardiac metabolism. EXPERIMENTAL APPROACH: FVB/N mice (10 per group) were challenged with sorafenib or vehicle control daily for 2 weeks. Echocardiographic assessment of the heart identified systolic dysfunction consistent with cardiotoxicity in sorafenib-treated mice compared to vehicle-treated controls. Heart, skeletal muscle, liver and plasma were flash frozen and prepped for non-targeted GC-MS metabolomics analysis. KEY RESULTS: Compared to vehicle-treated controls, sorafenib-treated hearts exhibited significant alterations in 11 metabolites, including markedly altered taurine/hypotaurine metabolism (25-fold enrichment), identified by pathway enrichment analysis. CONCLUSIONS AND IMPLICATIONS: These studies identified alterations in taurine/hypotaurine metabolism in the hearts and skeletal muscles of mice treated with sorafenib. Interventions that rescue or prevent these sorafenib-induced changes, such as taurine supplementation, may be helpful in attenuating sorafenib-induced cardiac injury.
Authors: Michael J Curtis; Richard A Bond; Domenico Spina; Amrita Ahluwalia; Stephen P A Alexander; Mark A Giembycz; Annette Gilchrist; Daniel Hoyer; Paul A Insel; Angelo A Izzo; Andrew J Lawrence; David J MacEwan; Lawrence D F Moon; Sue Wonnacott; Arthur H Weston; John C McGrath Journal: Br J Pharmacol Date: 2015-07 Impact factor: 8.739
Authors: Megan T Quintana; Traci L Parry; Jun He; Cecelia C Yates; Tatiana N Sidorova; Katherine T Murray; James R Bain; Christopher B Newgard; Michael J Muehlbauer; Samuel C Eaton; Akinori Hishiya; Shin Takayama; Monte S Willis Journal: Am J Pathol Date: 2016-06-17 Impact factor: 4.307
Authors: Manuela Schmidinger; Christoph C Zielinski; Ursula M Vogl; Andja Bojic; Marija Bojic; Christoph Schukro; Marquerite Ruhsam; Michael Hejna; Herwig Schmidinger Journal: J Clin Oncol Date: 2008-10-06 Impact factor: 44.544
Authors: Stephen Ph Alexander; Doriano Fabbro; Eamonn Kelly; Neil Marrion; John A Peters; Helen E Benson; Elena Faccenda; Adam J Pawson; Joanna L Sharman; Christopher Southan; Jamie A Davies Journal: Br J Pharmacol Date: 2015-12 Impact factor: 8.739
Authors: Robert W McGarrah; Scott B Crown; Guo-Fang Zhang; Svati H Shah; Christopher B Newgard Journal: Circ Res Date: 2018-04-27 Impact factor: 17.367
Authors: Amro Ilaiwy; Gabriella A M Ten Have; James R Bain; Michael J Muehlbauer; Sara K O'Neal; Jessica M Berthiaume; Traci L Parry; Nicolaas E Deutz; Monte S Willis Journal: Am J Pathol Date: 2019-09 Impact factor: 4.307
Authors: Jessica A Palmer; Alan M Smith; Vitalina Gryshkova; Elizabeth L R Donley; Jean-Pierre Valentin; Robert E Burrier Journal: Toxicol Sci Date: 2020-04-01 Impact factor: 4.849
Authors: Brian C Jensen; Traci L Parry; Wei Huang; Ju Youn Beak; Amro Ilaiwy; James R Bain; Christopher B Newgard; Michael J Muehlbauer; Cam Patterson; Gary L Johnson; Monte S Willis Journal: Br J Pharmacol Date: 2017-11-24 Impact factor: 8.739