Abstract

Peak values reported for mitochondrial matrix [Ca(2+)] following stimulation have ranged from micromolar to near-millimolar in various cells. Measurements using fluorescent indicators have traditionally used high-affinity dyes such as rhod-2, whose fluorescence would be expected to saturate if matrix [Ca(2+)] approaches millimolar levels. To avoid this potential problem, we loaded lizard motor terminal mitochondria with the low-affinity indicator rhod-5N (K(d) approximately 320 microM). During trains of action potentials at 50Hz, matrix fluorescence transients (measured as F/F(rest)) increased to a plateau level that was maintained throughout the stimulus train. This plateau of matrix [Ca(2+)] occurred in spite of evidence that Ca(2+) continued to enter the terminal and continued to be sequestered by mitochondria. When the stimulation frequency was increased, or when Ca(2+) entry per action potential was increased with the K(+) channel blocker 3,4-diaminopyridine (3,4-DAP), or reduced by lowering bath [Ca(2+)], the rate of rise of matrix [Ca(2+)] changed, but the plateau amplitude remained constant. Calculations demonstrated that the F/F(rest) measured at this plateau corresponded to a matrix [Ca(2+)] of approximately 1 microM. The high K(d) of rhod-5N ensures that this value is not a result of dye saturation, but rather reflects a powerful Ca(2+) buffering mechanism within the matrix of these mitochondria.