The ability of acute application of the neurotoxicant methylmercury (MeHg) to disrupt the function of presynaptic Ca2+ and Na+ channels at intact neuromuscular junctions was examined using mouse triangularis sterni motor nerves. In Ba(2+)-containing solutions, potential changes arising from Na+ and Ca2+ channel function could be recorded from the perineurial sheath surrounding motor neurons when K+ channels were blocked by tetraethylammonium chloride and 3,4-diaminopyridine. MeHg (100 microM) reduced both Na(+)- and Ba(2+)-dependent components to block within 3-5 min at apparently equivalent rates. Time to block was approximately 7 min after exposure to 50 microM MeHg. In 2 of 5 preparations exposed to 50 microM MeHg, the Ca2+ channel-mediated component was blocked prior to the Na+ channel-mediated component. In the remaining three preparations, Na(+)- and Ba(2+)-dependent potentials were blocked at similar times. Following block by MeHg, neither perfusing the preparation in MeHg-free solutions nor increasing the intensity and/or duration of stimulus to the intercostal nerves resulted in recovery of Na+ or Ca2+ potentials. In the presence of K+ channel blockers, repetitive firing of nerves in response to a single stimulus was observed in 20-30% of the triangularis preparations; in the two preparations treated with MeHg in which repetitive firing was observed, it decreased prior to block of the stimulus-induced Na+/Ba2+ potentials. These results corroborate the results obtained in isolated synaptosomes and pheochromocytoma cells, and suggest that MeHg decreases motor nerve excitability by disrupting Na+ channel function and may block neurotransmitter release by disrupting Na+ and Ca2+ channel function.