The voltage-gated calcium and sodium currents of starburst
amacrine cells were examined in slices of the adult rabbit retina.
ON-center starburst amacrine cells were targeted for whole-cell
recording by prelabeling the retina with the nuclear dye
4′-6-diamidino-2-phenylindole hydrochloride (DAPI). Calcium
currents were isolated using an external Ringer that contained
tetrodotoxin to block sodium currents and barium to block potassium
channels. When starburst amacrine cells were stepped to holding
potentials positive to −50 mV, a series of voltage-dependent
calcium currents were activated. The calcium current peaked
at −10 mV. The calcium currents kinetics were mainly
sustained in nature, showing only a small amount of slow
inactivation. Nickel (100 μM), a T-type channel blocker,
had no effect on the calcium current. Application of the L-type
channel agonist BAY K8644 (1–2.5 μM) had small variable
effects on the calcium current while the L-type channel antagonist
nifedipine (10 μM) had no effect. However, addition of a
reported N-type calcium channel antagonist, omega-conotoxin
G6A (1 μM), blocked a large portion of the calcium current,
as did a more nonselective antagonist, omega-conotoxin M7C (200
nM). Agatoxin 4A (500 nM) reduced a smaller sustained calcium
current component, implying a P/Q-type calcium channel was present
on these neurons. In addition to the calcium currents, a fast
voltage-gated sodium current was observed in many starburst
cells. This current could be blocked by tetrodotoxin (200–500
nM). The differing kinetics and durations of the sodium and
calcium currents could play important roles in the regulation
of synaptic release and in the coordination of spiking by starburst
amacrine cell dendrites during retinal development and in the
encoding of motion across the retinal surface.
