A G protein-biased S1P1 agonist, SAR247799, protects endothelial cells without affecting lymphocyte numbers.

Endothelial dysfunction is a hallmark of tissue injury and is believed to initiate the development of vascular diseases. Sphingosine-1 phosphate receptor-1 (S1P1) plays fundamental physiological roles in endothelial function and lymphocyte homing. Currently available clinical molecules that target this receptor are desensitizing and are essentially S1P1 functional antagonists that cause lymphopenia. They are clinically beneficial in autoimmune diseases such as multiple sclerosis. In patients, several side effects of S1P1 desensitization have been attributed to endothelial damage, suggesting that drugs with the opposite effect, namely, the ability to activate S1P1, could help to restore endothelial homeostasis. We found and characterized a biased agonist of S1P1, SAR247799, which preferentially activated downstream G protein signaling to a greater extent than ß-arrestin and internalization signaling pathways. SAR247799 activated S1P1 on endothelium without causing receptor desensitization and potently activated protection pathways in human endothelial cells. In a pig model of coronary endothelial damage, SAR247799 improved the microvascular hyperemic response without reducing lymphocyte numbers. Similarly, in a rat model of renal ischemia/reperfusion injury, SAR247799 preserved renal structure and function at doses that did not induce S1P1-desensitizing effects, such as lymphopenia and lung vascular leakage. In contrast, a clinically used S1P1 functional antagonist, siponimod, conferred minimal renal protection and desensitized S1P1 These findings demonstrate that sustained S1P1 activation can occur pharmacologically without compromising the immune response, providing a new approach to treat diseases associated with endothelial dysfunction and vascular hyperpermeability.

Adjustment and characterization of an original model of chronic ischemic heart failure in pig.

We present and characterize an original experimental model to create a chronic ischemic heart failure in pig. Two ameroid constrictors were placed around the LAD and the circumflex artery. Two months after surgery, pigs presented a poor LV function associated with a severe mitral valve insufficiency. Echocardiography analysis showed substantial anomalies in radial and circumferential deformations, both on the anterior and lateral surface of the heart. These anomalies in function were coupled with anomalies of perfusion observed in echocardiography after injection of contrast medium. No demonstration of myocardial infarction was observed with histological analysis. Our findings suggest that we were able to create and to stabilize a chronic ischemic heart failure model in the pig. This model represents a useful tool for the development of new medical or surgical treatment in this field.

Echocardiographic analysis with a two-dimensional strain of chronic myocardial ischemia induced with ameroid constrictor in the pig.

Despite much progress in the medical management of myocardial ischemia, several problems remain and experimental models help to improve our understanding of the pathophysiology involved in this domain. The ameroid constrictor model is the most widely used to create ischemia but evaluation of patent ischemia is still under debate. In the present study, we describe the potential of a two-dimensional (2D) strain for experimentally evaluating myocardial ischemia in the pig. An ameroid constrictor was placed around the circumflex artery in 30 pigs. Angiography showed 90% stenosis at one and two months. Left ventricular function was moderately altered and associated with mitral valve insufficiency in 30% of cases. Longitudinal and circumference strains were dramatically modified in the ischemic inferior-lateral zone compared to the healthy anterior zone (P<0.01) at one and two months. We correlated these results to myocardial ischemia by using contrast echocardiography, which showed a significant reduction in myocardial perfusion in the ischemic zone compared to the uninjured area, and by using histological analysis. We showed that evaluation of the 2D strain could be an interesting approach for assessing myocardial ischemia after ameroid constrictor implantation. The 2D strain represents a useful tool for the evaluation of experimental models of myocardial ischemia.