Role of the NO-GC/cGMP signaling pathway in platelet biomechanics

Abstract

AbstractCyclic guanosine monophosphate (cGMP) is a second messenger produced by the NO-sensitive guanylyl cyclase (NO-GC) enzyme. In platelets, the NO-GC/cGMP pathway inhibits aggregation. One aspect of the inhibitory mechanism involves changes in the cytoskeleton; however, the molecular mechanisms underlying platelet inhibition and its correlation with cytoskeletal cellular stiffness are poorly understood.We measured the cellular stiffness of individual platelets after treatment with the NO-GC stimulator riociguat or the NO-GC activator cinaciguat, using scanning ion conductance microscopy (SICM). We quantified changes in platelet shape using deep learning-based platelet morphometry. Cytoskeletal actin polymerization and platelet activation were measured by co-immunostaining F-actin and P-selectin, respectively. To test for clinical applicability of NO-GC stimulators in the context of increased thrombogenicity risk, we investigated the effect of riociguat on platelets from human immunodeficiency virus (HIV)-positive patients taking abacavir sulphate (ABC)-containing regimens, compared with HIV-negative volunteers.Stimulation of human and murine platelets with the NO-GC stimulator riociguat or with the NO-GC activator cinaciguat downregulated P-selectin expression, decreased F-actin polymerization, and decreased cellular stiffness by ≈50%, compared to vehicle control. In addition, platelets became more circular, indicating decreased activation. Riociguat did not cause any change in platelet aggregation or circularity in HIV-positive patients taking ABC-containing regimens.These results corroborate a functional role of the NO-GC enzyme in platelet biomechanics (cellular stiffness) in correlation with the inhibition of platelet activation and morphological changes. The observed changes in stiffness and platelet shape therefore demonstrate the possibility of pharmacologically targeting the NO-GC/cGMP pathway.