Targeting Sphingosine-1-Phosphate Signaling to Prevent the Progression of Aortic Valve Disease.

IF 5.2 3区工程技术 Q2 ENERGY & FUELS

Energy & Fuels Pub Date : 2024-10-21 DOI:10.1161/circulationaha.123.067270

Marcel Benkhoff,Maike Barcik,Philipp Mourikis,Jana Dahlmanns,Paulina Kahmann,Philipp Wollnitzke,Moritz Hering,Tim Huckenbeck,Julia Hoppe,Nina Semleit,Jennifer Deister-Jonas,Saif Zako,Jasmin Seel,Cristina Coman,Mareike Barth,Mareike Cramer,Carolin Helten,Laura Wildeis,Hao Hu,Gabrielle Al-Kassis,Daniel Metzen,Julia Hesse,Jessica Weber,Lisa Dannenberg,Payam Akhyari,Artur Lichtenberg,Christine Quast,Norbert Gerdes,Tobias Zeus,Oliver Borst,Malte Kelm,Tobias Petzold,Robert Ahrends,Bodo Levkau,Amin Polzin

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引用次数: 0

Abstract

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.

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以鞘磷脂-1-磷酸信号为靶点，防止主动脉瓣疾病恶化

背景主动脉瓣疾病（AVD）与高死亡率和发病率有关。迄今为止，尚无药物疗法可预防主动脉瓣病变的发展。方法在线束损伤诱导的小鼠主动脉瓣病变模型中研究了主动脉瓣病变的进展及其对心脏功能的影响，并对 S1P 的产生、降解和受体信号转导进行了药物和基因调控。S1P 通过 LC-MS 测量。结合 S1P 信号转导分析了瓣膜间质细胞的钙化及其对生物力学应力的反应。结果通过药物抑制 S1P 的唯一降解酶 S1P 裂解酶，提高了损伤诱导的 AVD 小鼠体内 S1P 的浓度，这极大地促进了 AVD 的进展，并损害了与人类疾病相似的心脏功能。与此相反，SphK1（鞘氨醇激酶 1）缺乏导致的低 S1P 水平能有效减轻 AVD 的进展。我们发现 S1P/S1PR2（S1P 受体 2）信号传导是 S1P 负面效应的原因，因为 S1PR2 缺失的小鼠在高 S1P 的作用下可防止 AVD 进展及其恶化。值得注意的是，在钢丝损伤后施用药理 S1PR2 抑制剂成功地防止了 AVD 的发展。从机理上讲，生物力学拉伸刺激人瓣膜间质细胞中的SphK1产生S1P（通过C17-S1P生成来测量），而S1P/S1PR2信号通过成骨RUNX2/OPG信号和GSK3β-Wnt-β-catenin通路诱导其成骨分化和钙化。结论全身或局部 S1P 水平升高会导致瓣膜钙化增加。S1PR2拮抗剂和SphK1抑制剂可为人类AVD提供可行的药物治疗方法，以预防、改变疾病或防止复发。

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来源期刊

Energy & Fuels 工程技术-工程：化工

CiteScore

9.20

自引率

13.20%

发文量

1101

审稿时长

2.1 months

期刊介绍： Energy & Fuels publishes reports of research in the technical area defined by the intersection of the disciplines of chemistry and chemical engineering and the application domain of non-nuclear energy and fuels. This includes research directed at the formation of, exploration for, and production of fossil fuels and biomass; the properties and structure or molecular composition of both raw fuels and refined products; the chemistry involved in the processing and utilization of fuels; fuel cells and their applications; and the analytical and instrumental techniques used in investigations of the foregoing areas.