Control of nerve-mediated and urothelial ATP release by a protein kinase G-dependent pathway in the mouse bladder

Abstract

Aim:ATP signalling is involved in urinary bladder motor and sensory pathways, including stimulation-mediated release from parasympathetic varicosities to detrusor muscle and from urothelial cells when mechanically stressed. Both modalities are present in humans and other mammals but are especially prominent in overactive bladder syndromes. There is therefore an unmet need to understand how to regulate such release. This study tested the hypothesis that the nitric oxide (NO•)/ soluble guanylate cyclase (sGC)/ cyclic GMP/ protein kinase-G (PKG) pathway has a central role. Methods:In vitro nerve-mediated contractions and ATP/acetylcholine (ACh) release were measured from bladder wall strips, as was ATP release from urothelial cell suspensions subject to mechanical stresses. Enhanced spontaneous contractile activity was also measured in bladder wall preparations of spinal cord-injured mice. Interventions were designed to increase cellular cGMP levels (a cell-permeable cGMP analogue, a NO•donor, a phosphodiesterase inhibitor (PDEI), a sGC activator), or agents to reduce activity of pathway enzymes (sCG or PKG). Results:ATP-dependent contractions were reduced by the above interventions, as was ATP release; but ACh-dependent contractions and ACh release were unaffected. Spontaneous contractile activity was also reduced by the cGMP analogue and by a PDEI. ATP release from urothelial cell suspensions was also reduced by similar interventions. Conclusions:ATP release from efferent nerves and from urothelial cells were selectively reduced by upregulating the NO•/sGC/cGMP/PKG pathway. Translational aspects are discussed with respect to purinergic pathways and overactive bladder pathologies.