Shear Stress Augments Expression of C-Type Natriuretic Peptide and Adrenomedullin

Abstract

Abstract Shear stress is known to dilate blood vessels and exert antiproliferative effects on vascular walls; these effects have been ascribed to shear stress–induced upregulation of endothelium-derived vasoactive substances, mainly nitric oxide and prostacyclin. We have demonstrated the significance of C-type natriuretic peptide (CNP) as a novel endothelium-derived relaxing peptide (EDRP) that shares a cGMP pathway with nitric oxide. Adrenomedullin is a recently isolated EDRP that elevates intracellular cAMP as prostacyclin does. To elucidate the possible role of these EDRPs under shear stress, we examined the effect of physiological shear stress on CNP mRNA expression in endothelial cells derived from the human umbilical vein (HUVECs), bovine aorta (BAECs), and murine lymph nodes (MLECs) as well as adrenomedullin mRNA expression in HUVECs. CNP mRNA was stimulated prominently in HUVECs under shear stress of 15 dyne/cm ² in a time-dependent manner (4 hours, sixfold increase compared with that in the static condition; 24 hours, 30-fold increase). Similar results were obtained in BAECs (4 hours, twofold increase; 24 hours, threefold increase) and MLECs (4 hours, threefold increase; 24 hours, 10-fold increase). Augmentation of CNP mRNA expression that was dependent on shear stress intensity was also observed (5 dyne/cm ² , 2.5-fold increase of static; 15 dyne/cm ² , 4.5-fold increase). Increased CNP secretion was also confirmed by the specific radioimmunoassay for CNP. Adrenomedullin mRNA expression in HUVECs increased under shear stress of 15 dyne/cm ² in a time-dependent manner (4 hours, 1.2-fold increase of static; 24 hours, threefold increase) and shear stress intensity–dependent manner (15 dyne/cm ² , threefold increase compared with that at 5 dyne/cm ² ). These results suggest that the coordinated augmentation of mRNA expression of these novel EDRPs may constitute shear stress–dependent vasodilator and antiproliferative effects.