Inhibition of sarcoplasmic reticulum function by polyunsaturated fatty acids in intact, isolated myocytes from rat ventricular muscle

We have studied the effects of two polyunsaturated fatty acids (PUFAs), eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA) on spontaneous and electrically stimulated contractions in single, isolated ventricular myocytes from rat hearts. The frequency of spontaneous waves of calcium release and contraction (induced by elevation of the bathing calcium concentration) is reduced in the presence of EPA. At the same time the resting level of intracellular calcium falls, the resting cell length increases and the amplitude of shortening decreases. All these effects are reversed on removal of EPA. Imaging of the waves of calcium release shows that the amplitude and the rate of propagation of the wave is increased in EPA. Consistent with the increased amplitude, integration of the caffeine-induced Na+-Ca2+ exchange current (a measure of the sarcoplasmic reticulum (SR) calcium content) is increased by both EPA and DHA. EPA has a maintained negative inotropic effect on voltage clamped myocytes. This seems to be entirely due to inhibition of the L-type calcium current. Smaller depolarising pulses in control conditions that elicit the same calcium current as in EPA also activate the same level of contraction. This is in spite of the increased SR calcium content in EPA. It is concluded that PUFAs have two effects on the SR; they reduce the availability of calcium for uptake and they inhibit the release mechanism. Both of these effects should lower the frequency of spontaneous waves of calcium release. As spontaneous release of calcium can initiate arrhythmias, some of the anti-arrhythmic action of PUFAs must be exerted at the level of the SR.