Abstract
Isolated and cultured glomus cells, obtained from mouse carotid bodies, were superfused with Ham's F-12 equilibrated with air (mean PO 2, 119 Torr; altitude 1350 m). [Ca 2+] o was 3.0 mM. In one experimental series, dual cell penetrations with microelectrodes measured intracellular calcium ([Ca 2+] i) and the resting potential ( E m). In another series, [Ca 2+] i was measured with Indo-1/AM, dissolved in DMSO. Normoxic cells had a mean E m of −42.4 mV and [Ca 2+] i was about 80 nM (measured with both methods). The calculated calcium equilibrium potential ( E Ca) was 137±0.74 mV. Hypoxia, induced by Na 2S 2O 4 1 mM, reduced pO 2 to 10–14 Torr. This effect was accompanied by cell depolarization to −19.1 mV. Hypoxia increased [Ca 2+] i to 231 nM when detected with Ca-sensitive microelectrodes, but only to 130.2 nM when measured with Indo-1/AM. Calcium increases were preceded by decreases in [Ca 2+] i, which also were more pronounced with microelectrode measurements. CoCl 2 1 mM blocked the hypoxic [Ca 2+] i increase and exaggerated the decreases in [Ca 2+] i. Correlations between Δ E m and Δ[Ca 2+] i during hypoxia were significant ( p<0.05) in 19% of the cells. But, in 29% of them significance was at the p<0.1 level. In the rest (52%), there was no correlation between these parameters. Thus, voltage-gated calcium channels are rare in mouse glomus cells. Their activation by depolarization cannot explain the two to threefold increase in [Ca 2+] i seen during hypoxia. More likely, [Ca 2+] i increase may be due to hypoxic inactivation of a Ca–Mg ATPase transport system across the cell membrane. The blunting of hypoxic [Ca 2+] i increase, seen in Indo-1/AM experiments, is probably due to its solvent (DMSO), which also depresses hypoxic cell depolarization.
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