Electrocalcium coupling in brain capillaries: Rapidly traveling electrical signals ignite local calcium signals.

The routing of blood flow throughout the brain vasculature is precisely controlled by mechanisms that serve to maintain a fine balance between local neuronal demands and vascular supply of nutrients. We recently identified two capillary endothelial cell (cEC)-based mechanisms that control cerebral blood flow in vivo: 1) electrical signaling, mediated by extracellular K-dependent activation of strong inward rectifying K (Kir2.1) channels, which are steeply activated by hyperpolarization and thus are capable of cell-to-cell propagation, and 2) calcium (Ca) signaling, which reflects release of Ca via the inositol 1,4,5-trisphosphate receptor (IPR)-a target of G-protein-coupled receptor signaling.

Urothelium-derived prostanoids enhance contractility of urinary bladder smooth muscle and stimulate bladder afferent nerve activity in the mouse.

The transitional epithelial cells (urothelium) that line the lumen of the urinary bladder form a barrier between potentially harmful pathogens, toxins, and other bladder contents and the inner layers of the bladder wall. The urothelium, however, is not simply a passive barrier, as it can produce signaling factors, such as ATP, nitric oxide, prostaglandins, and other prostanoids, that can modulate bladder function. We investigated whether substances produced by the urothelium could directly modulate the contractility of the underlying urinary bladder smooth muscle.

Intraluminal pressure elevates intracellular calcium and contracts CNS pericytes: Role of voltage-dependent calcium channels.

Arteriolar smooth muscle cells (SMCs) and capillary pericytes dynamically regulate blood flow in the central nervous system in the face of fluctuating perfusion pressures. Pressure-induced depolarization and Ca elevation provide a mechanism for regulation of SMC contraction, but whether pericytes participate in pressure-induced changes in blood flow remains unknown. Here, utilizing a pressurized whole-retina preparation, we found that increases in intraluminal pressure in the physiological range induce contraction of both dynamically contractile pericytes in the arteriole-proximate transition zone and distal pericytes of the capillary bed.

Afferent nerve activity in a mouse model increases with faster bladder filling rates in vitro, but voiding behavior remains unaltered in vivo.

Storage and voiding functions in urinary bladder are well-known, yet fundamental physiological events coordinating these behaviors remain elusive. We sought to understand how voiding function is influenced by the rate at which the bladder fills. We hypothesized that faster filling rates would increase afferent sensory activity and increase micturition rate.

Adenosine signaling activates ATP-sensitive K channels in endothelial cells and pericytes in CNS capillaries.

The dense network of capillaries composed of capillary endothelial cells (cECs) and pericytes lies in close proximity to all neurons, ideally positioning it to sense neuron- and glial-derived compounds that enhance regional and global cerebral perfusion. The membrane potential () of vascular cells serves as the physiological bridge that translates brain activity into vascular function. In other beds, the ATP-sensitive K (K) channel regulates in vascular smooth muscle, which is absent in the capillary network.