Light absorbance changes in the mouse carotid body during hypoxia and cyanide poisoning

Oxygen and acid chemoreception in the carotid body chemoreceptors

The carotid bodies are arterial chemoreceptors that are sensitive to blood PO2, PCO2 and pH. They are the origin of reflexes that are crucial for maintaining PCO2 and pH in the internal milieu and for adjusting the O2 supply according to the metabolic needs of the organism in situations of increased demand, such as exercise and while breathing at decreased O2 partial pressures during ascent or when living at high altitude. Chemoreceptor cells of the carotid body transduce the blood-borne stimuli into a neurosecretory response that is dependent on external Ca2+. These cells have an O2-sensitive K+ current that is reversibly inhibited by low PO2. It is proposed that the depolarization produced by inhibition of this K+ current activates Ca2+ channels; Ca2+ influx and neurosecretion follow. The cells have also a potent Na(+)-Ca2+ antiporter that could be responsible for the intracellular Ca2+ rise required to trigger the release of neurotransmitters during high PCO2 or low pH stimulation.

Indications to an NADPH oxidase as a possible pO2 sensor in the rat carotid body

The rat carotid body superfused with low pO2 exhibited an optical absorbance spectrum which resembles the reduced spectrum of the NADPH oxidase in neutrophils. Diphenylene iodonium (DPI) as a specific inhibitor of the oxidase attenuated the reduced absorbance spectrum in the carotid body. Also absorbance bleaching by low doses of cyanide (50 and 100 microM) was inhibited by DPI, whereas higher doses of cyanide (300 microM) caused an absorbance spectrum typical for reduced cytochromes. It is concluded that an NADPH oxidase acts as a pO2 sensor in the carotid body with low affinity for oxygen and high affinity for cyanide.

Ionic currents on type-I cells of the rabbit carotid body measured by voltage-clamp experiments and the effect of hypoxia

Type-I cells (from rabbit embryos) in primary culture were studied in voltage-clamp experiments using the whole cell arrangement of the patch-clamp technique. With a pipette solution containing 130 mM K+ and 3 mM Mg-ATP, large outward currents were obtained positive to a threshold of about -30 mV by clamping cells from -50 mV to different test pulses (-80 to 50 mV). Negative to -30 mV, the slope conductance was low (outward rectification). The outward currents were blocked by external Cs+ (5 mM) and partially blocked by TEA (5 mM) and Co2+ (1 mM). The initial part of the outward currents during depolarizing voltage pulses exhibited a transient Ca2+ inward component partially superimposed to a Ca2+-dependent outward current. Inward currents were further characterized by replacing K+ with Cs+ in the intra- and extracellular solution in order to minimize the outward component and by using 1.8 mM Ca2+, 10.8 mM Ca2+ or 10.8 mM Ba2+ as charge carrier. Slow-inactivating inward currents were recorded at test potentials ranging from -50 to 40 mV (holding potential -80 mV). The maximal amplitude, measured at 10 mV in the U-shaped I-V curve, amounted to 247 +/- 103 pA (n = 3). This inward current was insensitive to 3 microM TTX, but blocked by 1 mM Co2+ and partially reduced by 10 microM D600 and 3 microM PN 200-100. In contrast to outward currents, the inward currents exhibited a 'run-down' within about 10 min. Lowering the pO2 from the control of 150 Torr (air-gassed medium) to 28 Torr had no apparent effect on inward currents, but depressed reversibly outward currents by 28%. In conclusion, it is suggested that type-I cells possess voltage-activated K+ and Ca2+ channels which might be essential for chemoreception in the carotid body.