To complement our electrophysiological analyses of VDCC function, we monitored VDCC-dependent changes in the intracellular calcium concentration of cells located on the abluminal wall of feeder vessels and capillaries. An advantage of this experimental approach was that while our perforated-patch recordings detected VDCC currents generated from a population of microvascular cells, calcium imaging permitted the monitoring of VDCC-dependent changes in the calcium concentration of individual abluminal cells. In one series of calcium-imaging experiments designed to help determine the effect of VDCCs on the basal level of abluminal cell calcium, we caused the membrane potential of retinal microvessels to increase; this was useful because hyperpolarization causes inactivation of microvascular VDCCs.
15 We induced hyperpolarization by increasing the K
+ concentration of the perfusate from 3 mM (solution B) to 10 mM (solution C). As detailed in a previous study of the retinal microvasculature,
8 this 7-mM increase in extracellular K
+ resulted in a 14-mV hyperpolarization that was chiefly caused by enhanced K
+ efflux through inwardly rectifying K
+ channels. A similar physiologically relevant rise in K
+ is well known to cause hyperpolarization at numerous sites throughout the circulatory system.
23 –25 In this study, we observed that switching from solution B (3 mM K
+) to solution C (10 mM K
+) resulted in a significant (
P < 0.0001) decrease in the intracellular calcium concentration of mural cells located on feeder vessels (
Fig. 5A). Consistent with this hyperpolarization-induced decrease in calcium being attributed to a decrease in the basal activity of VDCCs, this effect was profoundly blocked by nifedipine, which, as shown in
Figure 3D, potently inhibits VDCC function in feeder vessels. Of note, although nifedipine can block voltage-insensitive, store-operated calcium channels in choroidal arteriolar smooth muscle,
26 inhibition of the store-operated channels is unlikely to account for the inhibition by this dihydropyridine of the voltage-induced changes in abluminal cell calcium. In contrast to the effect of the 10 mM K
+-induced hyperpolarization on mural cell calcium in the feeder vessels, the calcium concentration of capillary pericytes was not significantly affected (
Fig. 5B). Thus, the experiments summarized in
Figure 5 provide further support for the concept that VDCC function is greater in the mural cells of the feeder vessels than in the pericytes of the capillaries.