pubmed:abstractText |
Fura red, a fluorescent Ca2+ indicator with absorbance bands at visible wavelengths, was injected into intact single muscle fibers that had been stretched to a long sarcomere length (approximately 3.8 microns) and bathed in a 'high-Ca2+' Ringer ([Ca2+] = 11.8 mM). From fura red's slow diffusion coefficient in myoplasm, 0.16 (+/- 0.01, SEM) x 10(-6) cm2 s-1 (N = 5; 16 degrees C), it is estimated that approximately 85% of the indicator molecules are bound to muscle constituents of large molecular weight. Binding appears to elevate, by 3- to 4-fold, the indicator's apparent dissociation constant for Ca2+ (KD), which is estimated to be 1.1-1.6 microM in myoplasm. Fura red's myoplasmic absorbance spectrum was used to estimate fr, the fraction of fura red molecules in the Ca2+-bound form at rest. In 3 fibers thought to be minimally damaged by the micro-injection, fr was estimated to be 0.15 (+/- 0.01). Thus, resting myoplasmic free [Ca2+] ([Ca2+]r) is estimated to be 0.19-0.28 microM. For fibers in normal Ringer solution ([Ca2+] = 1.8 mM), at shorter sarcomere length (approximately 2.7 microns), and containing a nonperturbing concentration of indicator (< or = 0.2 mM), [Ca2+]r is estimated to be 0.18-0.27 microM. This range is higher than estimated previously in frog fibers with other techniques. In 6 fibers, R, the indicator's fluorescence ratio signal (equal to the emission intensity measured with 420 nm excitation divided by that measured with 480 nm excitation), was measured at rest and following electrical stimulation and compared with absorbance measurements made from the same fiber region. The analysis implies that RMIN and RMAX (the values of R that would be measured if all indicator molecules were in the Ca(2+)-free and Ca(2+)-bound states, respectively) were substantially smaller in myoplasm than in calibration solutions lacking muscle proteins. Several methods for estimation of [Ca2+]r from R are analyzed and discussed.
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