Effect of some ions on the sensory activity of the frog labyrinth

An inward Ca2+ -current and two outward K+-currents have recently been identified in frog vestibular hair cells. The Ca2+- current is more effectively carried by Ba2+ and it is suppressed by Ca2+ channel-blockers (Cd2+- Co2+). One of the two K+-currents, is Ca2+-dependent and is abolished by Ba2+, TEA and the divalent cations that block the Ca2+ -current; the other is a transient K+-current of the A-type which is specifically cancelled by 4-AP. In the frog labyrinth the resting receptor discharge depends on the external Ca2+ level and its frequency increases on increasing Ca2+ concentration in the bathing medium. Since the pre-synaptic currents most likely control the transmitter release at the cytoneural junction, their modifications will have a counterpart at the post-synaptic level. Therefore, it seems to be of interest to investigate the effect of Ba2+, TEA, 4-AP and CoCl2 on the EPSP and spike discharges recorded at rest from single fibres of the posterior nerve in the isolated frog labyrinth. In Ca-free Ringer solution Ba2+ preserved, at low concentration (0.3 mM), the resting activity and at higher levels (up to 6 mM) it resulted in a pronounced facilitation of the EPSP and spike discharges. The amplitude and shape of the sensory spikes were not modified by Ba2+ which therefore proved not to interfere with the K+-channel of the myelinated fibres. Facilitation increased on increasing Ba2+ concentration up to 4-5 mM and it was more prominent in those units exhibiting a low resting spike firing, The effect of Ba2+ (1 mM) was completely antagonized by 10 mM Ca2+. CoCl2 (3 mM) suppressed the resting rate at the normal external Ca2+ concentration (1.8 mM); the synaptic block operated by Co2+ was partially releaved by 1.8 mM Ba2+ . TEA (20 mM) evoked a clear-cut increase in the EPSP and spike discharges which, however, was less consistent than that produced by Ba2+. By comparing the effect of TEA on the spike frequency with that obtained at different Ba2+ levels, the Ba2+ capacity to carry the Ca2+-current was dissected. Such an effect is dose- dependent and it is more evident in low-frequency units. Conversely, 4-AP (4 mM) did not affect the resting discharge frequency. A more close evaluation of the synaptic effect of such ions was obtained when Ba2+ (1 mM) or TEA (20 mM) were added to a TTX-treated preparation, since their effect on the EPSP frequency was uncompiicated by the spike discharge. These experiments reveal that the Ba2+- and the Ca2+ -activated K+-current produced an increase in the EPSP frequency of 30 and 15%, respectively. These results indicate that either the Ca2+ - or the Ba2+-current sustain the transmitter release at the cytoneural junction. The effect of TEA suggests that the Ca2+ - dependent K+-current may play an important role in supporting the neurosecretory process by controlling the membrane potential of the hair cells.