By means of a patch pipette, an isolated ventricular myocyte was transferred into the taper of a silver holder covered by pioloform film. Once the cell was on the film, the cell was voltage clamped (pulses from -45 to +5 mV at 0.5 Hz). The amount of Ca entry was estimated from the Ca current. When contractility (cell shortening) was potentiated with either five pulses of 0.2 s or four pulses of 1 s, shock freezing was timed 116 or 816 ms after start of the clamp pulse. Electron micrographs from freeze-substituted cells revealed the good preservation of the intracellular compartments. The myocytes were cut at -150 degrees C, and the cryosections were freeze dried. In representative examples, the amount of Ca entry is compared with the subcellular Ca distribution as it is analyzed with energy dispersive X-ray microprobe analysis in cytoplasm, junctional sarcoplasmic reticulum (SR), mitochondria, and the subsarcolemmal space (sarcolemma, peripheral SR, fringe of cytosol).
In guinea pig ventricular strips and isolated cells, 0.1 mM LaCl3 blocks contractility and shortens the action potential (AP) in less than 2 min ("early La-effect"). After 30 min, it prolongs the APs which trigger slow contractions ("late La-effect"). These results confirm earlier reports. X-ray microprobe analysis shows that La initially displaces only a small fraction of that Ca which is superficially bound to the sarcolemma. But, since this Ca is completely removed by Ca-free solutions within 2 min, we suggest that La blocks contractility not by displacing superficial Ca but by blocking the Ca inward current iCa. Blocking of iCa is analyzed with voltage clamp experiments. It is not La-specific, and can also be observed with other calcium channel blockers as well. When iCa has been blocked, the membrane can still generate 100-200 ms long plateaus via the sodium inward current iNa. During the late La-effect, the cells internalize La. Intracellular La is detected by x-ray microprobe analysis in cryosections of frozen muscles and as La-precipitates in EM images from freeze substituted preparations. Simultaneously, the cytosol gains Na and Ca, but the plasmalemmal and sarcoplasmic reticulum (SR) membranes are no longer occupied by Ca but by La. The late La-effect on the prolongation of the AP is La-specific. In the absence of extracellular La, it can be induced by pressure injection of La into the cytosol. The long APs are based on an additional La, it can be induced by pressure injection of La into the cytosol. The long APs are based on an additional inward current which is insensitive to Ca-removal, is inactivated by holding potentials of -40 mV, and is TTX-sensitive. We suggest that the current flows through a fraction of original Na-channels that is modified by i.c. La with respect to inactivation and selectivity. We attribute the late re-occurrence of contractility to activator Ca entering from the bath. Ca-entry might be mediated via enhanced Na/Ca-exchange whose rate is increased by the i.c. Na-load. In addition, Ca may enter through the La-modified Na-channels due to their impaired selectivity. Since i.c. La is known to interfere with the Ca-sequestration by the SR, it is expected to impair relaxation.
Guinea-pig ventricular small papillary muscles and trabeculae were rapidly frozen presystolically after prolonged rest following positive inotropic interventions which strongly influenced peak of force and time to peak force. The possible sources of activator calcium for the different types of contraction were investigated. After rest in the presence of noradrenaline (10(-5)mol/l) the first post-rest contraction showed a retarded activation and a "late" peak of force. Muscle strips frozen after a rest period of 5 min in a bath solution containing noradrenaline were cryosectioned and analyzed with X-ray microanalysis for elemental distribution: although at this time an applied stimulus would induce a potentiated contraction, intracellular membrane systems such as sarcoplasmic reticulum and mitochondria failed to reveal any accumulation of calcium. After rest in a low sodium Tyrode the first post-rest contraction showed an "early" peak of force. Muscles frozen after rest in a low sodium solution revealed intracellular Ca accumulation on the sarcoplasmic reticulum, in the network at the level of the Z-lines. The results support the hypothesis that 1. the sarcoplasmic reticulum (SR) accumulates calcium presystolically when "early" contractions follow stimulation; 2. the network of sarcoplasmic reticulum at the level of the Z-lines is a crucial source of activator calcium; 3. the activator calcium for late contractions is probably of extracellular origin.
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