Quantal puffs of intracellular Ca2+ evoked by inositol trisphosphate in Xenopus oocytes.

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Quantal puffs of intracellular Ca2+ evoked by inositol trisphosphate in Xenopus oocytes.

Y Yao, J Choi and I Parker

Department of Psychobiology, University of California Irvine 92717, USA.

1. Ca2+ liberation induced in Xenopus oocytes by a poorly metabolizedderivative of inositol 1,4,5-trisphosphate (3-deoxy-3-fluoro-D-myo-inositol1,4,5-trisphosphate; 3-F-InsP3) was visualized using a video-rateconfocal microscope to image fluorescence signals reported bythe indicator dye calcium green-1. 2. Low (10-30 nM) intracellularconcentrations of 3-F-InsP3 evoked Ca2+ release as localizedtransient 'puffs'. Progressively higher concentrations (30-60nM) gave rise to abortive Ca2+ waves triggered by puffs, andthen (> 60 nM) to a sustained elevation of Ca2+ followedby the appearance of propagating Ca2+ waves. At concentrationsup to that giving waves, the frequency of puffs increased asabout the third power of [InsP3], whereas their amplitudes increasedonly slightly. 3. The rise of cytosolic Ca2+ during a puff beganabruptly, and peaked within about 50 ms. The peak free Ca2+level was about 180 nM, and the total amount of Ca2+ liberatedwas several attomoles (10(-18) mol), too much to be accountedfor by opening of a single InsP3-gated channel. The subsequentdecline of Ca2+ occurred over a few hundred milliseconds, determinedlargely by diffusion of Ca2+ away from the release site, ratherthan by resequestration. Lateral spread of Ca2+ was restrictedto a few micrometres, consistent with an effective diffusioncoefficient for Ca2+ ions of about 27 microns2 s-1. 4. The peakamplitudes of puffs recorded at a given site were distributedin a roughly Gaussian manner, and a small proportion of sitesconsistently gave puffs much larger than the main population.Intervals between successive puffs at a single site were exponentiallydistributed, except for a progressive fall-off in puffs seenat intervals shorter than about 10 s. Thus, triggering of puffsappeared to be stochastically determined after recovery froma refractory period. 5. There was little correlation betweenthe occurrence of puffs at sites more than a few micrometresapart, indicating that puff sites can function autonomously,but closely (ca 2 microns) adjacent sites showed highly correlatedbehaviour. 6. Puffs arose from sites-present at a density ofabout 1 per 30 microns2 in the animal hemisphere, located withina narrow band about 5-7 microns below the plasma membrane. 7.We conclude that Ca2+ puffs represent a 'quantal' unit of InsP3-evokedCa2+ liberation, which may arise because local regenerativefeedback by cytosolic Ca2+ ions causes the concerted openingof several closely clustered InsP3 receptor channels.

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