A central role for oxygen-sensitive K⁺ channels and mitochondria in the specialized oxygen-sensing system

Mammals possess a specialized O₂-sensing system (SOS), which compensates for encounters with hypoxia that occur during development, disease, and at altitude. Consisting of the resistance pulmonary arteries (PA), ductus arteriosus, carotid body, neuroepithelial body, systemic arteries, fetal adrenomedullary cell and fetoplacental arteries, the SOS optimizes O ₂-uptake and delivery. Hypoxic pulmonary vasoconstriction (HPV), a vasomotor response of resistance PAs to alveolar hypoxia, optimizes ventilation/perfusion matching and systemic pO2. Though modulated by the endothelium, HPV's core mechanism resides in the smooth muscle cell (SMC). The Redox Theory proposes that HPV results from the coordinated action of a redox sensor (proximal mitochondrial electron transport chain) which generates a diffusible mediator (a reactive O₂ species, ROS) that regulates effector proteins (voltage-gated Kv channels). Hypoxic withdrawal of ROS inhibits K_v1.5 and K_v2.1, depolarizes PASMCs, activates voltage-gated Ca²⁺ channels, increasing Ca²⁺ influx and causing vasoconstriction. Hypoxia's effect on ROS (decrease vs. increase) and the molecular origins of ROS (mitochondria vs. NADPH oxidase) remains controversial. Distal to this pathway, Rho kinase regulates the contractile apparatus' sensitivity to Ca²⁺. Also, a role for cADP ribose as a redox-regulated mediator of intracellular Ca²⁺ release has been proposed. Despite tissue heterogeneity in the SOS's output (vasomotion versus neurosecretion), O₂-sensitive K⁺ channels constitute a conserved effector mechanism. Disorders of the O₂-sensing may contribute to diseases, such as pulmonary hypertension.