Revealing concealed cardioprotection by platelet Mfsd2b-released S1P in human and murine myocardial infarction

Abstract

Abstract Background/Introduction Platelet activation on ruptured or eroded atherosclerotic lesions leads to thrombus formation and ischemic events. Hence, platelet inhibition is the cornerstone of primary and secondary prevention in patients with cardiovascular disease. Recently, non-canonical effects of platelets in multiple disease processes were revealed. However, others have demonstrated the opposite: a protective and regenerative role of platelets during myocardial healing. Sphingosine-1-phosphate (S1P) is an important bioactive lipid released from platelets upon activation and has potent cardioprotective properties in AMI when acutely administered or kept constitutively high due to pharmacological or genetic inhibition of its degradation. In humans, S1P levels in plasma are dynamically regulated during AMI. Purpose We hypothesized that platelets may be an important source of the S1P burst during AMI and that platelet-derived S1P is relevant for the extent of myocardial damage due to AMI. Methods We have addressed these questions in experimental AMI in mice lacking components of the S1P synthesis, release and signaling pathways. In additon, we conducted a hypothesis generating, prospective, monocentric, time-series, translational analysis in 127 patients with ST-elevation myocardial infarction (STEMI) to analyze the association between S1P plasma concentration and infarct size. Results Injection of cell-free supernatant of activated platelets (SNT+) prior AMI in mice led to decreased infarct size after 24 h of reperfusion as compared to supernatant of non-activated platelets (SNT-). This reduction of infarct size by SNT+ was associated with reduced neutrophil accumulation and reduced apoptosis after AMI. S1P-concentrations in SNT+ was 25% higher as compared to SNT-. S1P concentrations in SNT- of mice lacking Sphingosinkinase-1 (SphK1) were 70% lower and did not increase in SNT+. Accordingly, SNT+ of SphK1- deficient platelets failed to reduce infarct size. Deficiency of platelet S1P exporter Mfsd2b shows increased infarct size during in vivo AMI compared to littermate controls. SNT+ of WT mice led to improved outcome after ischemia in a model of Langendorff-perfused hearts. This was blunted by inhibition of S1P receptor 1 and genetic cardiomyocyte deficiency of S1PR1. Platelet S1P release during activation was reduced by P2Y12 inhibition but preserved during GPIIb/IIIa (tirofiban) inhibition. This translated to blunted cardioprotection by SNT+ of cangrelor treated platelets but sustained cardioprotection during tirofiban treatment. Plasma S1P concentrations was associated with cardiovascular death and infarct size in patients with ST-elevation myocardial infarction. Conclusion We have identified the mechanisms underlying platelet-associated cardioprotection and finally, revealed the importance of platelet-released S1P on admission in patients with ST-elevation myocardial infarction (STEMI) regarding to infarct size and long-term prognosis.