Stefan J Schunk1, Juliane Hermann2, Tamim Sarakpi1, Sarah Triem3, Michaela Lellig2, Eunsil Hahm4, Stephen Zewinger1, David Schmit1, Ellen Becker3, Julia Möllmann5, Michael Lehrke5, Rafael Kramann6, Peter Boor7, Peter Lipp8, Ulrich Laufs9, Winfried März10,11,12, Jochen Reiser4, Joachim Jankowski2,13, Danilo Fliser1, Thimoteus Speer14,3, Vera Jankowski2. 1. Nephrology and Hypertension, Department of Internal Medicine IV, Saarland University, Homburg/Saar, Germany. 2. Institute of Molecular Cardiovascular Research, RWTH Aachen University Hospital, Aachen, Germany. 3. Translational Cardio-Renal Medicine, Saarland University, Homburg/Saar, Germany. 4. Department of Internal Medicine, Rush University Medical Center, Chicago, Illinois, USA. 5. Department of Cardiology, RWTH Aachen University Hospital, Aachen, Germany. 6. Department of Nephrology, RWTH Aachen University Hospital, Aachen, Germany. 7. Institute of Pathology, RWTH Aachen University Hospital, Aachen, Germany. 8. Präklinisches Zentrum für Molekulare Signalverarbeitung (PZMS), Institute of Cell Biology, Saarland University, Homburg/Saar, Germany. 9. Department of Cardiology, University Hospital Leipzig, Leipzig, Germany. 10. Vth Department of Medicine, University Heidelberg, Mannheim Medical Faculty, Mannheim, Germany. 11. Clinical Institute of Medical and Laboratory Diagnostics, Medical University Graz, Graz, Austria. 12. Synlab Academy, Synlab Holding, Mannheim, Germany. 13. School for Cardiovascular Diseases, Maastricht University, Maastrich, The Netherlands. 14. Nephrology and Hypertension, Department of Internal Medicine IV, Saarland University, Homburg/Saar, Germany timo.speer@uks.eu.
Abstract
BACKGROUND: Coexistent CKD and cardiovascular diseases are highly prevalent in Western populations and account for substantial mortality. We recently found that apolipoprotein C-3 (ApoC3), a major constituent of triglyceride-rich lipoproteins, induces sterile systemic inflammation by activating the NOD-like receptor protein-3 (NLRP3) inflammasome in human monocytes via an alternative pathway. METHODS: To identify posttranslational modifications of ApoC3 in patients with CKD, we used mass spectrometry to analyze ApoC3 from such patients and from healthy individuals. We determined the effects of posttranslationally modified ApoC3 on monocyte inflammatory response in vitro, as well as in humanized mice subjected to unilateral ureter ligation (a kidney fibrosis model) and in a humanized mouse model for vascular injury and regeneration. Finally, we conducted a prospective observational trial of 543 patients with CKD to explore the association of posttranslationally modified ApoC3 with renal and cardiovascular events in such patients. RESULTS: We identified significant posttranslational guanidinylation of ApoC3 (gApoC3) in patients with CKD. We also found that mechanistically, guanidine and urea induce guanidinylation of ApoC3. A 2D-proteomic analysis revealed that gApoC3 accumulated in kidneys and plasma in a CKD mouse model (mice fed an adenine-rich diet). In addition, gApoC3 augmented the proinflammatory effects of ApoC3 in monocytes in vitro. In humanized mice, gApoC3 promoted kidney tissue fibrosis and impeded vascular regeneration. In CKD patients, higher gApoC3 plasma levels (as determined by mass spectrometry) were associated with increased mortality as well as with renal and cardiovascular events. CONCLUSIONS: Guanidinylation of ApoC3 represents a novel pathogenic mechanism in CKD and CKD-associated vascular injury, pointing to gApoC3 as a potential therapeutic target.
BACKGROUND: Coexistent CKD and cardiovascular diseases are highly prevalent in Western populations and account for substantial mortality. We recently found that apolipoprotein C-3 (ApoC3), a major constituent of triglyceride-rich lipoproteins, induces sterile systemic inflammation by activating the NOD-like receptor protein-3 (NLRP3) inflammasome in human monocytes via an alternative pathway. METHODS: To identify posttranslational modifications of ApoC3 in patients with CKD, we used mass spectrometry to analyze ApoC3 from such patients and from healthy individuals. We determined the effects of posttranslationally modified ApoC3 on monocyte inflammatory response in vitro, as well as in humanized mice subjected to unilateral ureter ligation (a kidney fibrosis model) and in a humanized mouse model for vascular injury and regeneration. Finally, we conducted a prospective observational trial of 543 patients with CKD to explore the association of posttranslationally modified ApoC3 with renal and cardiovascular events in such patients. RESULTS: We identified significant posttranslational guanidinylation of ApoC3 (gApoC3) in patients with CKD. We also found that mechanistically, guanidine and urea induce guanidinylation of ApoC3. A 2D-proteomic analysis revealed that gApoC3 accumulated in kidneys and plasma in a CKD mouse model (mice fed an adenine-rich diet). In addition, gApoC3 augmented the proinflammatory effects of ApoC3 in monocytes in vitro. In humanized mice, gApoC3 promoted kidney tissue fibrosis and impeded vascular regeneration. In CKD patients, higher gApoC3 plasma levels (as determined by mass spectrometry) were associated with increased mortality as well as with renal and cardiovascular events. CONCLUSIONS: Guanidinylation of ApoC3 represents a novel pathogenic mechanism in CKD and CKD-associated vascular injury, pointing to gApoC3 as a potential therapeutic target.
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