Lithium ions and the release of transmitter at the frog neuromuscular junction.

1. Transmitter release has been examined at the frog neuromuscular junction when all or part of the Na of the Ringer is replaced by Li ions. 2. No immediate change occurs in either the mean quantal content of the end-plate potential or the miniature end-plate potential frequency on changing to Li Ringer but over the following hour both these quantities increase by more than two orders of magnitude. 3. During thefirst 30-40 min of an exposure to Li-Ringer the m.e.p.p. frequency rises exponentially with a time constant of 10 min, and the mean quantal content of the e.p.p. grows by addition of extra evoked quanta, the increment rising exponentially with a time constant the same as that of the m.e.p.p. frequency. 4. Following this initial period in Li-Ringer the m. e.p.p. frequency accelerates to a peak of several hundred quanta per second and then declines slowly over the next few hours. Just before the m.e.p.p.frequency peak the conduction velocity of the presynaptic action potential declines and shortly afterwards synaptic transmission fails as the action potential no longer conducts into the terminals. 5. The rise in the m.e.p.p. frequency during the first 30-40 min is independent of the [Ca-2+]o. At subsequent times before the peak external Cabecomes progressively more effective in accelerating the m.e.p.p. frequency and in the presence of 1mM-EGTA spontaneous release stabilizes at 60-80 quanta/sec. 6. The [Li-+]o strongly influences the rate of increases in both evoked and spontaneous release but not their extent; replacing only half the Na of the Ringer by Li increases the time constants of the increases to about 30 min. 7. Rises in the m.e.p.p. frequency can be irreversibly accelerated by tetanizing the nerve in a Li-Ringer in which the Ca has been chelated by EGTA. The extent of the increases in the m.e.p.p. frequency is dependent on the number of pulses in the tetanus and is little affected by the frequency of stimulation. Accumulation of Li ions inside the presynaptic terminals probably underlies the changes in spontaneous release. 8. When only 10 percent of the Na of the Ringer is replaced by Li-+ ions the magnitude of post-tetanic potentiation of the e.p.p. and of the post-tetanic rise in the m.e.p.p. frequency is increased. Under these conditions changes in facilitation of the e.p.p. are small. 9. Various mechanisms by which Li could alter transmitter release are discussed and it is suggested that intracellular Ca sequestering mechanisms of the presynaptic terminals are affected when an end-plate is exposed to Li-Ringer.