Thati Madhusudhan1,2, Sanchita Ghosh3,4, Hongjie Wang3,5, Wei Dong3, Dheerendra Gupta3,4, Ahmed Elwakiel3,4, Stoyan Stoyanov6, Moh'd Mohanad Al-Dabet3,4,7, Shruthi Krishnan3,4, Ronald Biemann3,4, Sumra Nazir3, Silke Zimmermann3,4, Akash Mathew3,4, Ihsan Gadi3,4, Rajiv Rana3,4, Jinyang Zeng-Brouwers8, Marcus J Moeller9, Liliana Schaefer8, Charles T Esmon10, Shrey Kohli3,4, Jochen Reiser11, Alireza R Rezaie12, Wolfram Ruf2,13, Berend Isermann1,4. 1. Institute of Clinical Chemistry and Pathobiochemistry, Otto von Guericke University Magdeburg, Magdeburg, Germany m.thati@uni-mainz.de berend.isermann@medizin.uni-leipzig.de. 2. Center for Thrombosis and Hemostasis, University Medical Center Mainz, Mainz, Germany. 3. Institute of Clinical Chemistry and Pathobiochemistry, Otto von Guericke University Magdeburg, Magdeburg, Germany. 4. Institute of Laboratory Medicine, Clinical Chemistry and Molecular Diagnostics, University Hospital Leipzig, Leipzig, Germany. 5. Department of Cardiology, Tongji Hospital, Tongji Medical College, Huazhong University of Science and Technology, Wuhan, China. 6. German Center for Neurodegenerative Diseases, Otto von Guericke University Magdeburg, Magdeburg, Germany. 7. Department of Medical Laboratories, Faculty of Health Sciences, American University of Madaba, Amman, Jordan. 8. Institute of Pharmacology, University Hospital and Goethe University, Frankfurt, Germany. 9. Division of Nephrology and Immunology, University Hospital of the Rheinisch-Westfälische Technische Hochschule, Aachen University of Technology, Aachen, Germany. 10. Coagulation Biology Laboratory, Oklahoma Medical Research Foundation, University of Oklahoma Health Sciences Center, Oklahoma City, Oklahoma. 11. Department of Medicine, Rush University Medical Center, Chicago, Illinois. 12. Cardiovascular Biology Research Program, Oklahoma Medical Research Foundation, University of Oklahoma Health Sciences Center, Oklahoma City, Oklahoma. 13. Department of Immunology and Microbiology, The Scripps Research Institute, La Jolla, California.
Abstract
BACKGROUND: Diabetic nephropathy (dNP), now the leading cause of ESKD, lacks efficient therapies. Coagulation protease-dependent signaling modulates dNP, in part via the G protein-coupled, protease-activated receptors (PARs). Specifically, the cytoprotective protease-activated protein C (aPC) protects from dNP, but the mechanisms are not clear. METHODS: A combination of in vitro approaches and mouse models evaluated the role of aPC-integrin interaction and related signaling in dNP. RESULTS: The zymogen protein C and aPC bind to podocyte integrin-β 3, a subunit of integrin-α v β 3. Deficiency of this integrin impairs thrombin-mediated generation of aPC on podocytes. The interaction of aPC with integrin-α v β 3 induces transient binding of integrin-β 3 with G α13 and controls PAR-dependent RhoA signaling in podocytes. Binding of aPC to integrin-β 3 via its RGD sequence is required for the temporal restriction of RhoA signaling in podocytes. In podocytes lacking integrin-β 3, aPC induces sustained RhoA activation, mimicking the effect of thrombin. In vivo, overexpression of wild-type aPC suppresses pathologic renal RhoA activation and protects against dNP. Disrupting the aPC-integrin-β 3 interaction by specifically deleting podocyte integrin-β 3 or by abolishing aPC's integrin-binding RGD sequence enhances RhoA signaling in mice with high aPC levels and abolishes aPC's nephroprotective effect. Pharmacologic inhibition of PAR1, the pivotal thrombin receptor, restricts RhoA activation and nephroprotects RGE-aPChigh and wild-type mice.Conclusions aPC-integrin-α v β 3 acts as a rheostat, controlling PAR1-dependent RhoA activation in podocytes in diabetic nephropathy. These results identify integrin-α v β 3 as an essential coreceptor for aPC that is required for nephroprotective aPC-PAR signaling in dNP.
BACKGROUND:Diabetic nephropathy (dNP), now the leading cause of ESKD, lacks efficient therapies. Coagulation protease-dependent signaling modulates dNP, in part via the G protein-coupled, protease-activated receptors (PARs). Specifically, the cytoprotective protease-activated protein C (aPC) protects from dNP, but the mechanisms are not clear. METHODS: A combination of in vitro approaches and mouse models evaluated the role of aPC-integrin interaction and related signaling in dNP. RESULTS: The zymogen protein C and aPC bind to podocyte integrin-β 3, a subunit of integrin-α v β 3. Deficiency of this integrin impairs thrombin-mediated generation of aPC on podocytes. The interaction of aPC with integrin-α v β 3 induces transient binding of integrin-β 3 with G α13 and controls PAR-dependent RhoA signaling in podocytes. Binding of aPC to integrin-β 3 via its RGD sequence is required for the temporal restriction of RhoA signaling in podocytes. In podocytes lacking integrin-β 3, aPC induces sustained RhoA activation, mimicking the effect of thrombin. In vivo, overexpression of wild-type aPC suppresses pathologic renal RhoA activation and protects against dNP. Disrupting the aPC-integrin-β 3 interaction by specifically deleting podocyte integrin-β 3 or by abolishing aPC's integrin-binding RGD sequence enhances RhoA signaling in mice with high aPC levels and abolishes aPC's nephroprotective effect. Pharmacologic inhibition of PAR1, the pivotal thrombin receptor, restricts RhoA activation and nephroprotects RGE-aPChigh and wild-type mice.Conclusions aPC-integrin-α v β 3 acts as a rheostat, controlling PAR1-dependent RhoA activation in podocytes in diabetic nephropathy. These results identify integrin-α v β 3 as an essential coreceptor for aPC that is required for nephroprotective aPC-PAR signaling in dNP.
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