K(+) currents in cultured neurones from a polyclad flatworm

Abstract

Cells from the brain of the polyclad flatworm Notoplana atomata were dispersed and maintained in primary culture for up to 3 weeks. Whole-cell patch-clamp of presumed neurones revealed outwardly directed K(+) currents that comprised, in varying proportions, a rapidly activating (time constant tau =0.94+/−0.79 ms; N=15) and inactivating (tau =26.1+/−1.9 ms; N=22) current and a second current that also activated rapidly (tau =1.1+/−0.2 ms; N=9) (means +/− s.e.m.) but did not inactivate within 100 ms. Both current types activated over similar voltage ranges. Activation and steady-state inactivation overlap and are markedly rightward-shifted compared with most Shaker-like currents (half-activation of 16.9+/−1. 9 mV, N=7, half-inactivation of −35.4+/−3.0 mV, N=5). Recovery from inactivation was rapid (50+/−2.5 ms at −90 mV). Both currents were unaffected by tetraethylammonium (25 mmol l(−1)), whereas 4-aminopyridine (10 mmol l(−1)) selectively blocked the inactivating current. The rapidly inactivating current, like cloned K(+) channels from cnidarians and certain cloned K(+) channels from molluscs and the Kv3 family of vertebrate channels, differed from most A-type K(+) currents reported to date. These findings suggest that K(+) currents in Notoplana atomata play novel roles in shaping excitability properties.