Low pO2 selectively inhibits K channel activity in chemoreceptor cells of the mammalian carotid body.
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The hypothesis that changes in environmental O2 tension (pO2) could affect the ionic conductances of dissociated type I cells of the carotid body was tested and low pO2 appeared to slow down the activation time course of the K current but deactivation kinetics seemed to be unaltered.Abstract:
The hypothesis that changes in environmental O2 tension (pO2) could affect the ionic conductances of dissociated type I cells of the carotid body was tested. Cells were subjected to whole-cell patch clamp and ionic currents were recorded in a control solution with normal pO2 (pO2 = 150 mmHg) and 3-5 min after exposure to the same solution with a lower pO2. Na and Ca currents were unaffected by lowering pO2 to 10 mmHg, however, in all cells studied (n = 42) exposure to hypoxia produced a reversible reduction of the K current. In 14 cells exposed to a pO2 of 10 mmHg peak K current amplitude decreased to 35 +/- 8% of the control value. The effect of low pO2 was independent of the internal Ca2+ concentration and was observed in the absence of internal exogenous nucleotides. Inhibition of K channel activity by hypoxia is a graded phenomenon and in the range between 70 and 120 mmHg, which includes normal pO2 values in arterial blood, it is directly correlated with pO2 levels. Low pO2 appeared to slow down the activation time course of the K current but deactivation kinetics seemed to be unaltered. Type I cells subjected to current clamp generate large Na- and Ca-dependent action potentials repetitively. Exposure to low pO2 produces a 4-10 mV increase in the action potential amplitude and a faster depolarization rate of pacemaker potentials, which leads to an increase in the firing frequency. Repolarization rate of individual action potentials is, however, unaffected, or slightly increased. The selective inhibition of K channel activity by low pO2 is a phenomenon without precedents in the literature that explains the chemoreceptive properties of type I cells. The nature of the interaction of molecular O2 with the K channel protein is unknown, however, it is argued that a hemoglobin-like O2 sensor, perhaps coupled to a G protein, could be involved.read more
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Journal ArticleDOI
Cellular Mechanism of Oxygen Sensing
TL;DR: A deeper understanding of the cellular mechanisms of O2 sensing will facilitate the development of new pharmacological tools effective in the treatment of diseases such as stroke or myocardial ischemia caused by localized deficits of O 2.
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Oxygen sensing in airway chemoreceptors
TL;DR: The identification of an oxygen-sensing mechanism (namely the presence of an O1-sensitive potassium channel coupled to an O2 sensor protein5) in the cells of pulmonary neuroepithelial bodies indicates that they are transducers of the hypoxia stimulus and hence may function as airway chemoreceptors in the regulation of respiration.
OtherDOI
Peripheral Chemoreceptors: Function and Plasticity of the Carotid Body
Prem Kumar,Nanduri R. Prabhakar +1 more
TL;DR: The goal of this article is to provide a comprehensive review of current concepts on sensory transduction and transmission of the hypoxic stimulus at the carotid body with an emphasis on integrating cellular mechanisms with the whole organ responses and highlighting the gaps or discrepancies in knowledge.
Journal ArticleDOI
Effects of hypoxia on membrane potential and intracellular calcium in rat neonatal carotid body type I cells.
TL;DR: The effects of hypoxia on membrane potential and [Ca2+]i in enzymically isolated type I cells of the neonatal rat carotid body (the principal respiratory O2 chemosensor) are studied.
Journal ArticleDOI
Hypoxia reduces potassium currents in cultured rat pulmonary but not mesenteric arterial myocytes
TL;DR: The hypoxia-induced inhibition of Iout in PA cells was accompanied by an apparent increase in inward Ca2+ current, and some of the channels responsible for this current may be open at the resting membrane potential of PA cells used in this study.
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