TY - JOUR
T1 - Targeting Sphingosine-1-Phosphate Signaling to Prevent the Progression of Aortic Valve Disease
AU - Benkhoff, Marcel
AU - Barcik, Maike
AU - Mourikis, Philipp
AU - Dahlmanns, Jana
AU - Kahmann, Paulina
AU - Wollnitzke, Philipp
AU - Hering, Moritz
AU - Huckenbeck, Tim
AU - Hoppe, Julia
AU - Semleit, Nina
AU - Deister-Jonas, Jennifer
AU - Zako, Saif
AU - Seel, Jasmin
AU - Coman, Cristina
AU - Barth, Mareike
AU - Cramer, Mareike
AU - Helten, Carolin
AU - Wildeis, Laura
AU - Hu, Hao
AU - Al-Kassis, Gabrielle
AU - Metzen, Daniel
AU - Hesse, Julia
AU - Weber, Jessica
AU - Dannenberg, Lisa
AU - Akhyari, Payam
AU - Lichtenberg, Artur
AU - Quast, Christine
AU - Gerdes, Norbert
AU - Zeus, Tobias
AU - Borst, Oliver
AU - Kelm, Malte
AU - Petzold, Tobias
AU - Ahrends, Robert
AU - Levkau, Bodo
AU - Polzin, Amin
N1 - Publisher Copyright:
© 2024 Lippincott Williams and Wilkins. All rights reserved.
PY - 2024
Y1 - 2024
N2 - BACKGROUND: Aortic valve disease (AVD) is associated with high mortality and morbidity. To date, there is no pharmacological therapy available to prevent AVD progression. Because valve calcification is the hallmark of AVD and S1P (sphingosine-1-phosphate) plays an important role in osteogenic signaling, we examined the role of S1P signaling in aortic stenosis disease. METHODS: AVD progression and its consequences for cardiac function were examined in a murine wire injury-induced AVD model with and without pharmacological and genetic modulation of S1P production, degradation, and receptor signaling. S1P was measured by LC-MS. Calcification of valvular interstitial cells and their response to biomechanical stress were analyzed in the context of S1P signaling. Human explanted aortic valves from patients undergoing aortic valve replacement and cardiovascular magnetic resonance imaging were analyzed for S1P by LC-MS. RESULTS: Raising S1P concentrations in mice with injury-induced AVD by pharmacological inhibition of its sole degrading enzyme S1P lyase vastly enhanced AVD progression and impaired cardiac function resembling human disease. In contrast, low S1P levels caused by SphK1 (sphingosine kinase 1) deficiency potently attenuated AVD progression. We found S1P/S1PR2 (S1P receptor 2) signaling to be responsible for the adverse S1P effect because S1PR2-deficient mice were protected against AVD progression and its deterioration by high S1P. It is important to note that pharmacological S1PR2 inhibition administered after wire injury successfully prevented AVD development. Mechanistically, biomechanical stretch stimulated S1P production by SphK1 in human valvular interstitial cells as measured by C17-S1P generation, whereas S1P/S1PR2 signaling induced their osteoblastic differentiation and calcification through osteogenic RUNX2/OPG signaling and the GSK3β-Wnt-β-catenin pathway. In patients with AVD, stenotic valves exposed to high wall shear stress had higher S1P content and increased SphK1 expression. CONCLUSIONS: Increased systemic or local S1P levels lead to increased valvular calcification. S1PR2 antagonists and SphK1 inhibitors may offer feasible pharmacological approaches to human AVD in prophylactic, disease-modifying or relapse-preventing manners.
AB - BACKGROUND: Aortic valve disease (AVD) is associated with high mortality and morbidity. To date, there is no pharmacological therapy available to prevent AVD progression. Because valve calcification is the hallmark of AVD and S1P (sphingosine-1-phosphate) plays an important role in osteogenic signaling, we examined the role of S1P signaling in aortic stenosis disease. METHODS: AVD progression and its consequences for cardiac function were examined in a murine wire injury-induced AVD model with and without pharmacological and genetic modulation of S1P production, degradation, and receptor signaling. S1P was measured by LC-MS. Calcification of valvular interstitial cells and their response to biomechanical stress were analyzed in the context of S1P signaling. Human explanted aortic valves from patients undergoing aortic valve replacement and cardiovascular magnetic resonance imaging were analyzed for S1P by LC-MS. RESULTS: Raising S1P concentrations in mice with injury-induced AVD by pharmacological inhibition of its sole degrading enzyme S1P lyase vastly enhanced AVD progression and impaired cardiac function resembling human disease. In contrast, low S1P levels caused by SphK1 (sphingosine kinase 1) deficiency potently attenuated AVD progression. We found S1P/S1PR2 (S1P receptor 2) signaling to be responsible for the adverse S1P effect because S1PR2-deficient mice were protected against AVD progression and its deterioration by high S1P. It is important to note that pharmacological S1PR2 inhibition administered after wire injury successfully prevented AVD development. Mechanistically, biomechanical stretch stimulated S1P production by SphK1 in human valvular interstitial cells as measured by C17-S1P generation, whereas S1P/S1PR2 signaling induced their osteoblastic differentiation and calcification through osteogenic RUNX2/OPG signaling and the GSK3β-Wnt-β-catenin pathway. In patients with AVD, stenotic valves exposed to high wall shear stress had higher S1P content and increased SphK1 expression. CONCLUSIONS: Increased systemic or local S1P levels lead to increased valvular calcification. S1PR2 antagonists and SphK1 inhibitors may offer feasible pharmacological approaches to human AVD in prophylactic, disease-modifying or relapse-preventing manners.
KW - aortic valve disease
KW - calcification
KW - sphingosine-1-phosphate
UR - http://www.scopus.com/inward/record.url?scp=85207441237&partnerID=8YFLogxK
U2 - 10.1161/CIRCULATIONAHA.123.067270
DO - 10.1161/CIRCULATIONAHA.123.067270
M3 - Article
C2 - 39429140
AN - SCOPUS:85207441237
SN - 0009-7322
JO - Circulation
JF - Circulation
ER -