Time-irreversible subconductance gating associated with Ba2+ block of large conductance Ca2+-activated K+ channels

Ba2+ block of large conductance Ca2+-activated K+ channels was studied in patches of membrane excised from cultures of rat skeletal muscle using the patch clamp technique. Under conditions in which a blocking Ba2+ ion would dissociate to the external solution (150 mM N-methyl-D-glucamine(0)(+), 500 mM K-i(+), 10 mu M Ba-i(2+), + 30 mV, and 100 mu M Ca-i(2+) to fully activate the channel), Ba2+ blocks with a mean duration of similar to 2 s occurred, on average, once every similar to 100 ms of channel open time. Of these Ba2+ blocks, 78% terminated with a single step in the current to the fully open level and 22% terminated with a transition to a subconductance level at similar to 0.26 of the fully open level (preopening) before stepping to the fully open level. Only one apparent preclosing was observed in similar to 10,000 Ba2+ blocks. Thus, the preopenings represent Ba2+-induced time-irreversible subconductance gating. The fraction of Ba2+ blocks terminating with a preopening and the duration of preopenings (exponentially distributed, mean = 0.75 ms) appeared independent of changes in [Ba2+](i) or membrane potential. The fractional conductance of the preopenings increased from 0.24 at + 10 mV to 0.39 at + 90 mV. In contrast, the average subconductance level during normal gating in the absence of Ba2+ was independent of membrane potential, suggesting different mechanisms for preopenings and normal subconductance levels. Preopenings were also observed with 10 mM Ba-0(2+) and no added Ba-i(2+). Adding K+, Rb+, or Na+ to the external solution decreased the fraction of Ba2+ blocks with preopenings, with K+ and Rb+ being more effective than Na+. These results are consistent with models in which the blocking Ba?+ ion either induces a preopening gate, and then dissociates to the external solution, or moves to a site located on the external side of the Ba2+ blocking site and acts directly as the preopening gate.