Fluctuations in membrane current driven by intracellular calcium in cardiac Purkinje fibers.

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Fluctuations in membrane current driven by intracellular calcium in cardiac Purkinje fibers.

R S Kass and R W Tsien

ABSTRACT

Spontaneous oscillatory fluctuations in membrane potential areoften observed in heart cells, but their basis remains controversial.Such activity is enhanced in cardiac Purkinje fibers by exposureto digitalis or K-free solutions. Under these conditions, wefind that voltage noise is generated by current fluctuationsthat persist when membrane potential is voltage clamped. Powerspectra of current signals are not made up of single time-constantcomponents, as expected from gating of independent channels,but are dominated by resonant characteristics between 0.5 and2 HZ. Our evidence suggests that the periodicity arises fromoscillatory variations in intracellular free Ca that controlion movements across the surface membrane. The current fluctuationsare strongly cross-correlated with oscillatory fluctuationsin contractile force, and are inhibited by removing extracellularCa or exposure to D600. Chelating intracellular Ca with injectedEGTA also abolishes the current fluctuations. The oscillatorymechanism may involve cycles of Ca (or Sr) movement betweensarcoplasmic reticulum and myoplasm, as previously suggestedfor skinned cardiac preparations. Our experiments in intactcells indicate that changes in surface membrane potential canmodulate cytoplasmic Ca oscillations in frequency and perhapsamplitude as well. A two-way interaction between surface membranepotential and intracellular Ca stores may be a common featureof heart, neuron, and other cell types.

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