Identification of ionic currents at presynaptic nerve endings of the lizard.

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Identification of ionic currents at presynaptic nerve endings of the lizard.

C A Lindgren and J W Moore

Department of Neurobiology, Duke University Medical Center, Durham, NC 27710.

1. Ionic currents associated with the invasion of an actionpotential into the motor nerve ending of the lizard, Anoliscarolinensis, were measured with a focal extracellular electrodeat several locations along the nerve ending. 2. These experimentallyobserved currents could be matched with computer simulationsof action potential propagation into the nerve ending. Theyrevealed that while Na+ channels are the major ionic currentpathway in the heminode, K+ channels provide the major pathwayin the terminal branches and boutons. 3. Calcium current inthe presynaptic ending was unmasked by the application of tetraethylammonium(TEA). This current was blocked by: (a) cadmium, (b) omega-conotoxinGVIA and (c) nifedipine, but was unaffected by nickel at concentrationsless than or equal to 100 microM. Nifedipine's action becamemore definitive when the duration of the action potential wasgreatly extended by pre-treatment with TEA. The effect of BayK 8644 was inconsistent. 4. Transmitter release, as measuredby postsynaptic current, had a pharmacological response profilesimilar to that of the Ca2+ current, with the exception thattransmitter release was increased reliably and reversibly byBay K 8644. 5. This pharmacological response profile is identicalto that of the L type Ca2+ channel identified by Fox, Nowycky& Tsien (1987 alpha) in chick dorsal root ganglion neurones.We saw no evidence for more than a single type of Ca2+ channelin lizard motor nerve endings. 6. A calcium-activated K+ currentIK(Ca) was revealed by application of 3,4-diaminopyridine (DAP),a delayed-rectifier K+ channel blocker. This K(Ca) current wasblocked by TEA, charybdotoxin and by substitution of cobaltfor extracellular calcium.

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