Under optimised conditions for intoxication, botulinum neurotoxin type A was shown to inhibit approximately 90% of Ca2+-dependent K+-evoked release of [3H]acetylcholine, [3H]noradrenaline, and [3H]dopamine from rat cerebrocortical synaptosomes; cholinergic terminals were most susceptible. In each case, the dose-response curve for the neurotoxin was extended, with about 50% of evoked release being inhibited at approximately 10 nM whereas 200 nM was required for the maximal blockade. This may suggest some heterogeneity in the release process. The action of the toxin was time and temperature dependent and appeared to involve binding and sequestration steps prior to blockade of release. The neurotoxin failed to exert any effect on synaptosomal integrity or on Ca2+-independent release of the transmitters tested; it produced only minimal changes in neurotransmitter uptake although small secondary effects were detected with cholinergic terminals. Blockade by the neurotoxin of Ca2+-dependent resting release of transmitter was apparent; Sr2+, Ba2+, or high concentrations of Ca2+ restored the resting release of 3H-catecholamine but not [3H]acetylcholine. Interestingly, none of the latter conditions or 4-aminopyridine could reverse the toxin-induced blockade of evoked release. This lack of specificity in its action on synaptosomes, and other published findings, lead to the conclusion that toxin-sensitive component(s) exist in all nerve terminals that are concerned with transmitter release.