Role of calcium stores and membrane voltage in the generation of slow wave action potentials in guinea‐pig gastric pylorus

Abstract

1 Intracellular recordings made in single bundle strips of a visceral smooth muscle revealed rhythmic spontaneous membrane depolarizations termed slow waves (SWs). These exhibited ‘pacemaker’ and ‘regenerative’ components composed of summations of more elementary events termed spontaneous transient depolarizations (STDs). 2 STDs and SWs persisted in the presence of tetrodotoxin, nifedipine and ryanodine, and upon brief exposure to Ca²⁺-free Cd²⁺-containing solutions; they were enhanced by ACh and blocked by BAPTA AM, cyclopiazonic acid and caffeine. SWs were also inhibited in heparin-loaded strips. 3 SWs were observed over a wide range of membrane potentials (e.g. -80 to -45 mV) with increased frequencies at more depolarized potentials. 4 Regular spontaneous SW activity in this preparation began after 1–3 h superfusion of the tissue with physiological saline following the dissection procedure. Membrane depolarization applied before the onset of this activity induced bursts of STD-like events (termed the ‘initial’ response) which, when larger than threshold levels initiated regenerative responses. The combined initial-regenerative waveform was termed the SW-like action potential. 5 Voltage-induced responses exhibited large variable latencies (typical range 0.3-4 s), refractory periods of ≈11 s and a pharmacology that was indistinguishable from those of STDs and spontaneous SWs. 6 The data indicate that SWs arise through more elementary inositol 1,4,5-trisphosphate (IP₃) receptor-induced Ca²⁺ release events which rhythmically synchronize to trigger regenerative Ca²⁺ release and induce inward current across the plasmalemma. The finding that action potentials, which were indistinguishable from SWs, could be evoked by depolarization suggests that membrane potential modulates IP₃ production. Voltage feedback on intracellular IP₃-sensitive Ca²⁺ release is likely to have a major influence on the generation and propagation of SWs.