The negative inotropic effect of acetylcholine on ferret ventricular myocardium.

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The negative inotropic effect of acetylcholine on ferret ventricular myocardium.

M R Boyett, M S Kirby, C H Orchard and A Roberts

Department of Physiology, University of Leeds.

1. The effects of acetylcholine (ACh) on developed tension andintracellular Ca2+ concentration (as measured with aequorin)were studied in ferret papillary muscles, and on twitch shortening,the action potential and membrane currents in ferret ventricularmyocytes. 2. Addition of ACh to ferret papillary muscles resultedin decreases in developed tension and the intracellular Ca2+transient, both of which then partially recovered in the continuedpresence of ACh ('fade' of the response). On wash-off of AChboth developed tension and the intracellular Ca2+ transientincreased above control ('rebound') before returning to controlvalues. 3. Addition of ACh to ferret ventricular myocytes resultedin a membrane hyperpolarization of 2 +/- 0.5 mV (mean +/- S.E.M.;n = 9), a decrease in action potential duration to 23 +/- 6%of control and a decrease in twitch shortening to 31 +/- 5%of control. In the continued presence of ACh these responsesto ACh faded. Thirty seconds after the maximal effect of ACh,action potential duration had partially recovered to 34 +/-6% of control and twitch shortening to 46 +/- 7% of control.4. The effects of ACh on twitch shortening could be mimickedunder voltage clamp by varying voltage clamp pulse durationto simulate the ACh-induced changes in action potential duration.5. When ACh was applied during a train of voltage clamp pulsesof constant duration, 81% of the cells showed less than a 20%decrease in Ca2+ current and twitch shortening. However in 19%of the cells twitch shortening and the apparent Ca2+ currentdecreased by more than 30%. 6. In the 81% of cells, the normaldecrease in twitch shortening was wholly the result of the shorteningof the action potential. This in turn was the result of an increasein an outward background current which increased the rate ofrepolarization during the action potential. The ACh-inducedbackground current reversed at -89 +/- 2 mV and showed inward-goingrectification; these properties suggest that it was carriedby K+. 7. In the 19% of cells, the normal decrease in twitchshortening was only partly the result of the shortening of theaction potential (due to both the increase in outward backgroundcurrent as well as the apparent decrease in Ca2+ current). Inthese cells the decrease in twitch shortening may also havebeen partly the direct result of the apparent decrease of Ca2+current.

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