Correspondence to: S.M. Baylor, Department of Physiology, University of Pennsylvania School of Medicine, Philadelphia, PA 19104-6085. Fax:(215) 573-5851 E-mail:baylor{at}mail.med.upenn.edu.
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Abstract |
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Calcium sparks were studied in frog intact skeletal muscle fibers using a home-built confocal scanner whose point-spread function was estimated to be 0.21 µm in x and y and
0.51 µm in z. Observations were made at 1720°C on fibers from Rana pipiens and Rana temporaria. Fibers were studied in two external solutions: normal Ringer's ([K+] = 2.5 mM; estimated membrane potential, -80 to -90 mV) and elevated [K+] Ringer's (most frequently, [K+] = 13 mM; estimated membrane potential, -60 to -65 mV). The frequency of sparks was 0.040.05 sarcomere-1 s-1 in normal Ringer's; the frequency increased approximately tenfold in 13 mM [K+] Ringer's. Spark properties in each solution were similar for the two species; they were also similar when scanned in the x and the y directions. From fits of standard functional forms to the temporal and spatial profiles of the sparks, the following mean values were estimated for the morphological parameters: rise time,
4 ms; peak amplitude,
1
F/F (change in fluorescence divided by resting fluorescence); decay time constant,
5 ms; full duration at half maximum (FDHM),
6 ms; late offset,
0.01
F/F; full width at half maximum (FWHM),
1.0 µm; mass (calculated as amplitude x 1.206 x FWHM3), 1.31.9 µm3. Although the rise time is similar to that measured previously in frog cut fibers (56 ms; 1723°C), cut fiber sparks have a longer duration (FDHM, 915 ms), a wider extent (FWHM, 1.32.3 µm), and a strikingly larger mass (by 310-fold). Possible explanations for the increase in mass in cut fibers are a reduction in the Ca2+ buffering power of myoplasm in cut fibers and an increase in the flux of Ca2+ during release.
Key Words: ryanodine receptors, fluo-3, confocal microscopy, excitation-contraction coupling, frog muscle
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INTRODUCTION |
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Calcium sparks are transient localized increases in fluorescence in muscle cells that contain a Ca2+ indicator, such as fluo-3 (
Most studies of sparks in frog skeletal muscle have used the cut fiber preparation (0.1 µM and 0.51.0 mM, respectively). In spite of such precautions, abnormalities in the structure and function of cut fibers have been noted. For example, frog cut fibers appear to be more hydrated than intact fibers (inferred from fiber swelling;
32 ms at 610°C [
2 ms at 1415°C [
In this article, we describe the properties of several thousand voltage-activated calcium sparks. These were recorded in frog intact single fibers that were microinjected with fluo-3 and bathed in elevated [K+] Ringer's (typically, 13 mM [K+]; estimated membrane potential, -60 to -65 mV). A home-built confocal microscope, similar to that described by 4 ms in intact fibers, 1720°C; 56 ms in cut fibers, 1723°C), the full duration at half maximum (FDHM)* is briefer in intact fibers (
6 vs. 915 ms) and full width at half maximum (FWHM) is narrower (
1.0 vs. 1.32.3 µm). A more pronounced difference is found for spark "mass" (which, for an in-focus spark, is expected to be proportional to the volume integral of the change in fluo-3 fluorescence; see MATERIALS AND METHODS); mass is 310 fold larger in cut fibers than in intact fibers.
Another difference between voltage-activated sparks in intact and cut fibers is evident during the late phase of a spark. F/F (change in fluorescence divided by resting fluorescence), which is about fivefold smaller than that reported by
Some of the results have been reported in abstract form (
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MATERIALS AND METHODS |
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Microscope Configuration and Procedures for Image Acquisition
The experiments were performed in the Department of Physiology at the University of Pennsylvania. A home-built confocal line scanner, similar to that described by 200 µm). These optical elements, plus a set of lenses and mirrors, permitted the 488-nm light from a 25-mW argon ion laser to be focused as a diffraction-limited spot on the fiber. The laser was run in "light control" mode, which maintained a nearly ripple-free output at close to maximum power. The spot was moved along the fiber axis (x displacement) by rotation of a galvanometer scan mirror (S), which was driven by an approximately saw-tooth input to the mirror controller (
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Data acquisition was controlled by a master timer/AD/DA unit (model IDA 12500; Indec Systems). DA output from the IDA unit supplied a synchronized voltage waveform to drive the mirror controller. A sample line scan usually consisted of 256 data points collected at 125 kHz (line scan period, 2.048 ms). The usable portion of the scan consisted of 215 points, which were collected during the linear displacement of the spot along a 43.0-µm length of fiber (0.20 µm per pixel). The remaining 41 points were collected during the fly-back of the scan mirror and were ignored. A unit x-t image consisted of 256 such line scans acquired in 524 ms.
The program controlling data acquisition was custom written in C7.0 (Microsoft Corp.). It used library links to elementary AD/DA functions supplied by Indec Systems, which were written in both assembly language and C. Our acquisition program, when run on a 266-MHz Pentium II computer, could acquire and store to disk an essentially unlimited stream of line scans without loss of data. However, most fiber runs consisted of only three continuous unit images, which comprised a 43.0-µm by 1.571-s x-t image (for technical reasons, the first scan line was always discarded). In a few experiments (see RESULTS), x-t images were also recorded with a briefer line scan period, 1.024 ms instead of 2.048 ms. To achieve the faster scan speed, the mirror excursion was reduced by slightly more than twofold. In this situation, there were 192 usable data points at a pixel separation of 0.09 µm, yielding a useful scan length of 17.3 µm.
As in the system described by 2 photon counts per µs), have a quantum efficiency of 5060% at the wavelengths of fluo-3's fluorescence (500600 nm). For the detection of low light levels, they supplied the largest signal-to-noise ratio of four types of detectors tested (
In early experiments, a time-dependent decline was observed in the mean intensity of successive line scans in an image. Most of this decline was traced to light-induced warm up of optical filters F1 and ND located after shutter S1 (Fig 1). This decline was reduced substantially by the use of a second shutter S2, which was opened after S1. The small residual decline in intensity was corrected as described below. Upon completion of scanning, a rotation of the scan mirror moved the laser spot off the fiber to avoid fiber damage.
Slow x-y scans (see Fig 2 A, described below) were performed with a motorized drive that moved the vertical position of relay lens RL. At the fiber, this movement produced a linear displacement of the line scan in the y direction, i.e., the direction perpendicular to the normal scan direction. To match the pixel displacement in y to that in x (0.20 µm per point), the rate of data acquisition (and the laser intensity) were reduced by about an order of magnitude.
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Microscope Point-spread Function
The point-spread function (PSF) of the microscope was estimated from a series of x-y images of fluorescent beads (diameter 0.1 µm; Polysciences Inc.). The pixel separation in x and y was 0.10 µm and the z distance between images was 0.25 µm (z being the direction along the light path). The beads were immobilized by suspension in an agarose gel (30% sucrose + 0.5% agarose) that had solidified on the upper surface of a coverslip. The nominal refractive index of the gel, 1.38 (
Fiber Preparation and Measurement Procedures
Most of the early experiments of this study were performed on intact single fibers isolated from leg muscles (iliofibularis and semitendinosus) of Rana temporaria. Later experiments, with more complete results, were usually performed on single fibers from Rana pipiens. An isolated fiber was mounted on an optical bench apparatus, stretched to a sarcomere length of 3.6 µm, and pressure-injected with fluo-3 (
F/F signal was all or none and had a peak value greater than nine (range, 9.524; N = 27).
Somewhat surprisingly, the values of the spatially averaged F/F elicited by an action potential were larger in the present study than in our previous studies. For fibers from R. temporaria, the increase in mean
F/F was about twofold: 14.2 ± 0.8 (N = 12) in this study versus 6.8 ± 0.5 (N = 15) in
F/F, 18.6 ± 0.9 (N = 15). Because smaller values of resting myoplasmic [Ca2+] ([Ca2+]R) will produce smaller values of resting F and correspondingly larger values of
F/F, the larger
F/F values detected in the present study indicate that [Ca2+]R was smaller than in our earlier studies (on the assumption that
F changes little with [Ca2+]R; see RESULTS).
A possible explanation for a larger [Ca2+]R in the experiments of 15 min, were required for the injections. In the present study, there was less difficulty with clogging, and impalements were much briefer, usually <3 min. A possible explanation for the higher values of
F/F observed in the fibers of R. pipiens versus R. temporaria (18.6 vs. 14.2, respectively) is that the R. pipiens were in better overall condition than the R. temporaria. R. pipiens, which are readily available within the United States, were ordered more frequently and in smaller numbers than R. temporaria, which were obtained from Ireland. As a result, R. pipiens were kept in hibernation for a shorter period of time before use.
After injection, the fiber was transferred to a different chamber and sarcomere length was set to 3.0 µm (range, 2.703.66 µm). Two L-shaped glass rods attached to microdrives on the chamber walls pressed the fiber downward so that the bottom surface of the fiber region that contained the injection site was 0.10.2 mm above the chamber floor, within the working distance of the microscope objective. The center of the chamber floor consisted of an 18-mm square coverslip, which was held by Vaseline on a Perspex rim and changed daily. The thickness of the coverslip (155 µm) was selected to match the adjustable coverslip setting on the collar of the microscope objective. The chamber was mounted on the stage of the microscope and the solution bathing the fiber (see below) was cooled to 1720°C.
To avoid overexposure of the fiber to laser light, x-t images were recorded at different locations in x, y, and z. Typically, a continuous set of three x-t images was acquired at one z location. Then, the microscope focus was changed manually by 5 µm and another triplet of images was recorded. Several such runs were performed at different z locations (030 µm above the bottom surface of the fiber), after which the y recording location was changed by a slight translation (530 µm) of the stage perpendicular to the fiber axis. After similar runs at two to four different y locations, the microscope stage was translated in the x direction (along the fiber axis) by 50250 µm, and a new series of recordings was made. With these procedures, up to several hundred images could be acquired from different regions of a fiber in a period of 3060 min.
Resting sparks were measured in normal Ringer's solution (in mM: 120 NaCl, 2.5 KCl, 1.8 CaCl2, 5 PIPES, pH 7.1) and voltage-activated sparks were measured in solutions containing elevated [K+], most frequently 13 mM [K+] (referred to as 13 mM [K+] Ringer's), achieved by the addition of K2SO4 to Ringer's. Membrane potential was not measured but is expected to be approximately -80 to -90 mV in normal Ringer's and approximately -60 to -65 mV in 13 mM [K+] Ringer's (
In experiments with solution changes, image runs were usually taken immediately before and after the solution change at the same x location. This permitted an estimation of the effect of the solution change on the resting fluorescence of fluo-3.
Estimation of Indicator Concentration
In four experiments, the method of 10 min after injection. This concentration and the value of fluo-3's resting fluorescence were used to estimate a calibration factor that related the concentration of fluo-3 to the resting fluorescence intensity per fiber cross-sectional area. The mean of the calibration factors from the four fibers was used to estimate the indicator concentration in the remaining fibers. For the 27 fibers of this study, the fluo-3 concentration estimated shortly after injection was 225 ± 17 µM (mean ± SEM). Indicator concentration was not measured during confocal recording, which was performed 2080 min after injection and usually 50300 µm along the fiber axis from the injection site. From calculations based on one-dimensional diffusion of fluo-3, the average indicator concentration during confocal recording was estimated to be
100 µM.
Spark Detection
Programs for spark detection and analysis were written in the IDL programming language (Research Systems Inc.). Each x-t fluorescence intensity image, F(x,t), was first corrected for a small, time-dependent decay in fluorescence that likely arose from residual warm up of components in the light path (see above). For this correction, a decaying exponential plus sloping baseline was fitted to F(t), the fluorescence averaged from all x locations at different t. At each t, F(x,t) was then multiplied by the ratio of the fitted value of F(0) and the fitted value of F(t). The resulting F(x,t) image was then converted to a F/F image: (
F/F)(x,t) = (F(x,t) - F(x))/F(x). F(x), the spatial profile of resting fluorescence, was initially estimated as the time average of all F(x,t).
Each image was processed by an automatic spark detection algorithm, which is similar to that described by F/F image was scanned for possible sparks. A spark was identified if at least three consecutive pixels on a given scan line, and one contiguous pixel on the subsequent scan line had values of
F/F above a threshold value. F(x) was then recalculated from F(x,t) after exclusion of the regions identified as sparks, and a new
F/F image was calculated and the detection algorithm was repeated. This process was continued until the number of detected sparks and the points associated with these sparks remained unchanged. Threshold was set at
F/F = 0.3. Depending on resting fluorescence, this value was three to seven times the standard deviation of F(x,t) in the spark-excluded, 3 x 3 smoothed image. To find out whether spurious sparks might arise from noise, detection was also performed for negative
F/F with a threshold of -0.3. In 604 images in which 2,617 positive sparks were identified with the positive threshold, only one negative spark, in the noisiest image, was detected with the negative threshold. Because tests with smaller threshold values showed more spurious "negative" sparks, 0.3 appeared to be the minimum threshold at which all images could be reliably analyzed.
Spark Morphology
Spark profiles in time (t) and space (x) were calculated from the unsmoothed F/F images, and spark morphological parameters were obtained from least-squares fits of functional forms to these profiles. The time profile was obtained from an average of three time lines located at the center of the spark in x. These data were least-squares fitted by Equation 1, which is similar to the functional form used by
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(1) |
Although there is no a priori reason to expect Equation 1 to exactly fit the time course of a spark, it can be used to characterize its main features. The data were usually fitted for 25 pixels preceding and 50 pixels after the spark peak (51.2 and 102.4 ms, respectively). Equation 1 assumes that F/F has an initial value of A0; at t1, it increases abruptly with a time constant
on to a peak value at t2. After peak, the spark is assumed to decay exponentially, with a time constant
off, to a final value of (A0 + A2). The 0100% rise time (= t2 - t1), peak amplitude (= A1(1 - exp(-(t2 - t1)/
on))), decay time constant (=
off), FDHM, and late offset (A2) were obtained from the fitted curve. Because the rise time of most sparks occurred during one to three time points (26 ms), the value of
on could not be estimated accurately. Consequently, its value was fixed at 4 ms for all fits (see Shtifman et al., 2000 [p. 826]). This choice is not critical because the estimates of the fitted spark parameters were little changed with
on set to 2, 4, or 8 ms. As described in RESULTS, the mean values of rise time from measurements made with 2-ms line scans may be overestimated by 1020%.
The spatial profile of a spark was obtained from an average of the two line scans recorded just before and just after t2. A Gaussian function, Equation 2, was fitted to the spatial profile by adjustment of parameters A3, A4, x0, and var:
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(2) |
As was the case with Equation 1, Equation 2 is not expected to exactly fit the data; it is used to approximately characterize the spatial spread of a spark. These data were usually fitted for 25 pixels (5.0 µm) on either side of the central location of the spark, x0. The FWHM of the spark at time of peak was estimated with Equation 3 from the variance parameter, var:
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(3) |
About 15% of detected sparks could not be analyzed either because they were located near the edge of an image or because there was significant overlap with another spark in time or space. In addition, broad limits were applied to exclude atypical fluorescence events: 0.4 < rise time < 25 ms; 0 < off < 20 ms; 2.5 ms
FDHM
40 ms; offsets (A1, A2, A3) between -0.15 and 0.15
F/F; 0.3 < FWHM < 4 µm. About 6% of analyzed sparks failed to satisfy these limits.
8 counts per µs per detector; thus, most spark measurements were made near the linear range of the detectors. Second, an analysis of the population of "in-focus" sparks (defined as the largest 5% of sparks collected from each experiment, total number = 158 sparks) revealed no dependence of spark amplitude on resting fluorescence intensity per detector. The values of resting intensity ranged between 0.5 and 7 counts/µs, and the best-fitted regression line of amplitude vs. resting intensity had a slope of 0.0320
F/F per (counts per microsecond), which was not significantly different from zero (at P < 0.05).
Spark Mass
Following the concept of signal mass introduced by F/F:
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(4) |
In confocal experiments with fluo-3, (F/F)(x,y,z) is given by the convolution of the microscope PSF with
[Ffluo]/[Ffluo]R; the subscript R denotes the resting state. The concentration variable [Ffluo] (Equation 5) is introduced because Ca2+-free fluo-3 is weakly fluorescent. It is equal to the value of [Ca-fluo-3] that would give the same fluorescence as a mixture of [Ca-fluo-3] and [fluo-3]:
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(5) |
[Ca-fluo-3] and [fluo-3] are the concentrations of Ca2+-bound and Ca2+-free fluo-3, respectively, and Fmin and Fmax represent the fluorescence intensity of Ca2+-free and Ca2+-bound fluo-3, respectively. In myoplasm, Fmin/Fmax 0.01 (
[Ffluo]/[Ffluo]R (unpublished theoretical analysis). the product of mass and [Ffluo]R gives the total increase in Ffluo (in moles). This increase closely approximates the total increase in Ca-fluo-3 (in moles).
Because measurements of F/F are usually limited to scans in x at one location in the y-z plane, some approximations are required to calculate spark mass from these measurements. First, we assume that the scan line runs through the location of Ca2+ release ("in-focus spark"), which will be taken as the origin of the coordinate system, (0,0,0). Second, we assume that (
F/F)(x,y,z) can be approximated as the product of three Gaussians (compare Equation 6 with Equation 2):
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(6) |
in which A is the signal amplitude at the origin. Equation 4 gives:
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(7) |
Third, we assume that the gaussians are isotropic in space (varx = vary = varz). The last two assumptions may introduce some error because the spatial spread of Ffluo may not be Gaussian and isotropic, and the microscope PSF is not isotropic (varz > vary = varx). Substitution of Equation 3 in Equation 7 (with var = varx = vary = varz) gives:
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(8) |
Equation 8 is used in RESULTS to estimate spark mass from the fitted values of amplitude and FWHM (see previous section). Spark mass is considered in this article primarily to emphasize the 3-D nature of a spark and to permit additional comparisons with sparks measured in other preparations. Spark mass will be explored more fully in a forthcoming article. Preliminary calculations for this article indicate that Equation 8 underestimates, by about one third, the mass of an in-focus simulated spark that is calculated with Equation 4.
A somewhat different method was used by
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(9) |
which yields a value of mass that is 0.434 times that calculated with Equation 8.
An Upper Limit for Microscope FWHMX in Muscle Fibers
Most images recorded in this study were x-t scans. Toward the end of some experiments, however, occasional x-y scans were also recorded. An unusual feature of some of these scans was the presence of punctate regions of high fluorescence ("hot spots"; Fig 2 A). Hot spots do not appear to be caused by transient elevations in myoplasmic [Ca2+] because their appearance was unchanged in a second x-y scan of the same fiber location (hence hot spots reflect persistent rather than transient events), and their center location was always 0.5 µm from the z-line (whereas sparks are centered at the z-line; see RESULTS). The physical basis of hot spots is unknown, but a likely possibility is that they arise from a population of fluo-3 molecules that are sequestered inside a small organelle with elevated free [Ca2+].
In x-t images, hot spots appeared as bright streaks ("streakers") that were offset 0.5 µm from a z-line. Interestingly, streakers, when detected, were always present at the beginning of an x-t image and usually faded during the course of the image, probably because the responsible fluo-3 molecules were bleached by the high intensity light that repeatedly scanned the same spatial location. This might occur if fluo-3 molecules in the Ca2+-bound form are more readily bleached than those in the Ca2+-free form or if bleached fluo-3 cannot be replenished by diffusion. Fig 2 B shows an example of a fading streaker; the narrow band of high fluorescence at the start of the image faded to background levels over a period of
1 s. These data are shown in F units (counts per microsecond, proportional to fluorescence intensity; see scale at right). Fig 2 C shows a portion of Fig 2 B after expansion of the x- and t-axes and normalization by resting F (
F/F units). In Fig 2 D, the spatial profile of the streaker has been fitted with a Gaussian function (Equation 2) to estimate FWHMX (Equation 3); the fitted value is 0.27 µm. In eight similar streakers from five fibers, the value of FWHMX was 0.30 ± 0.01 µm (mean ± SEM). Other streakers, which had somewhat larger values of FWHMX, were not included in this analysis because of the possibility that they were out of focus. The value 0.30 µm represents an upper limit of the in vivo FWHMX of the PSF of the microscope. This value is
0.1 µm larger than the value of FWHMX estimated with 0.1 µm fluorescent beads (0.21 ± 0.01 µm; see above), probably because of the nonzero size of the organelle or other structure(s) that contains the fluo-3 molecules responsible for a streaker.
Statistics
Statistics pertaining to the spark measurements are reported as mean ± SEM The statistical significance of a difference between means was evaluated with a t test at P < 0.05.
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RESULTS |
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[Ca2+]R in Frog Intact Fibers
As discussed by F/F measured with fluo-3 in response to an action potential can be used to estimate [Ca2+]R. The estimate depends on the value of the apparent myoplasmic dissociation constant of fluo-3 for Ca2+. This has been estimated experimentally to lie in the range 1.151.65 µM (
0.01, and (2) the fraction of fluo-3 that is complexed with Ca2+ at the time of peak
F/F after an action potential is 0.7. In the present experiments, this calibration procedure gives the following estimates of [Ca2+]R: (1) before confocal recording, 3045 nM in fibers from R. pipiens (
F/F = 18.6 ± 0.9; N = 15) and 4560 nM in fibers from R. temporaria (
F/F = 14.2 ± 0.8; N = 12); (2) after confocal recording, 75105 nM for R. pipiens (
F/F = 9.1 ± 1.4; N =15) and 150200 nM for R. temporaria (
F/F = 4.7 ± 1.0; N = 6). The values before confocal recording are somewhat smaller than those previously estimated with fluo-3 in intact frog fibers from R. temporaria (100140 nM;
Resting Fluorescence Patterns
When a spark occurs in a muscle fiber, there is a change in fluorescence (F) that adds to the background fluorescence (F). Characterization of the background fluorescence is a useful first step in a quantitative analysis of sparks. Fig 3 A shows an x-t image of fluo-3 fluorescence intensity, F(x,t), compiled from a succession of line scans on a fiber from R. pipiens in normal Ringer's solution ([K+] = 2.5 mM). On the right side of Fig 3 A, the vertically oriented trace shows F(x), the time average of fluorescence at each location, plotted against x. F(x) includes
14 sarcomeres and reveals fluctuations of 1520%. These fluctuations are characterized by broad maxima (FWHM
1.2 µm) and narrow maxima (FWHM
0.6 µm). Because sparks arise at the midpoints of the broad maxima (see next section) and are known to occur at z lines in frog fibers (
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To better reveal the details of the sarcomeric periodicity, the F(x) pattern of Fig 3 A was partitioned at m-line boundaries and the intensity data from the 14 sarcomeres were averaged. Fig 3 B shows the result displayed in normalized units. The abscissa represents distance from one m-line to the next (sarcomere length, 2.96 µm) and the ordinate, denoted (F/FS)(x), was calculated as (FS(x) - Fave)/Fave, where FS(x) is the sarcomere-averaged F(x) pattern and Fave is the average value of FS(x).
F/FS has a broad plateau in its middle, which contains the z-line at its center (at 1.48 µm on the abscissa), and reaches a peak value of
0.075. The leftmost and rightmost locations, which mark the m-lines, define a secondary maximum that reaches a peak value of
0.050. The minima of (
F/FS)(x) are located
0.9 µm on either side of the z-line and have an average value of about -0.10.
A sarcomeric periodicity in F(x) has also been found in cut fibers (85% in intact fibers) are not freely diffusible but are bound to proteins (
The middle two panels in Fig 3 show results from a second fiber in normal Ringer's (this time from R. temporaria). The results are generally similar to those of the top panel. The main difference is that the amplitude of the broad plateau in (F/FS)(x) containing the z-line is slightly smaller, rather than slightly larger, than the narrow maximum marking the m-lines. Resting patterns similar to those illustrated in the top and middle panels of Fig 3 were commonly observed in fibers from both species in normal Ringer's (see also Fig 2 A). Within the same fiber, variations in the resting pattern were common, similar to the variation illustrated by the top and middle panels of Fig 3.
In some fibers and images, the value of F/FS at the m-line was substantially larger than that at the z-line and the broad plateau of fluorescence centered at the z-line was absent. A pattern of this type was occasionally seen in fibers in normal Ringer's but was more frequently seen in fibers in elevated [K+] Ringer's. An extreme example is illustrated in the bottom two panels of Fig 3. These data were obtained from the same fiber used for the middle panel, a few minutes after the solution bathing the fiber had been changed from normal Ringer's to 30 mM [K+] Ringer's. A comparison of the middle and bottom panels reveals two obvious effects of the solution change: (1) an increase of 6570% in the mean value of F(x) (compare amplitude of F(x) traces to the right of C and E), and (2) a dramatic change in the shape of (
F/FS)(x) (D and F). The new (
F/FS)(x) pattern has a very prominent m-line maximum that exceeds the small peak at the z-line by
0.25
F/FS units. The increase in mean F(x) is expected because the depolarization produced by 30 mM [K+] Ringer's should elevate [Ca2+]R and hence F(x). Although the change in shape of (
F/FS)(x) was unexpected, it is interesting that the profile in elevated [K+] Ringer's is similar to that in normally polarized cut fibers (see above). This raises the possibility that the value of [Ca2+]R in normally polarized cut fibers is larger than that in intact fibers. Intermediate (
F/FS)(x) profiles were obtained with smaller increases in solution [K+], 7.513 mM (not shown). These changes in
F/FS usually reversed after return to normal Ringer's.
Spark Detection and Frequency
In fibers in normal Ringer's, the majority of x-t images revealed either zero or one spark. In contrast, in 13 mM [K+] Ringer's, the majority of images revealed two or more sparks. The likely cause of this increase in spark frequency is the more positive value of membrane potential associated with the higher [K+] (
Fig 4 shows images from a fiber that was bathed successively in normal Ringer's (left), 13 mM [K+] Ringer's (center), and normal Ringer's (right). The top panels show F(x,t) images in the three solutions (pseudocolor scale not shown), and the bottom panels show the same images after conversion to F/F units (see Fig 5 for amplitude calibrations). The images were analyzed for sparks by the automatic detection routine described in MATERIALS AND METHODS (detection threshold,
F/F = 0.3). No sparks were detected in either image in normal Ringer's but nine sparks were detected in the image in 13 mM [K+] Ringer's. These sparks were distributed among six different sarcomeres and each spark was centered on a z-line (midway between adjacent narrow peaks in the F(x,t) image, which mark m-lines; see Fig 3). The vertical arrowheads at the bottom of the middle panel identify the time of the two largest sparks (discussed below in connection with Fig 5).
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An important question concerning sparks is whether their distribution among sarcomeres is random. This issue is examined in a later section of RESULTS.
The protocol of Fig 4 was performed in 10 of the 15 experiments from R. pipiens and in 1 of the 12 experiments from R. temporaria. In several of the remaining experiments, similar measurements were made either without a bracketing series of measurements in normal Ringer's or in Ringer's solutions that contained 7.510 mM [K+] instead of 13 mM [K+]. Table 1 (R. pipiens) and Table 2 (R. temporaria) give information about these experiments, including the values of [K+] (column 2), the times in the different solutions (column 3), the total number of detected sparks (column 5), and the average frequencies of sparks (column 6). Although the spark frequency in any particular solution appeared to be stable, a comparison of frequencies in experiments that had both initial and final bracketing measurements in normal Ringer's suggests that, on average, spark frequency may have been increasing slowly with time. For example, for R. pipiens, the initial and final spark frequencies were 0.048 ± 0.014 and 0.102 ± 0.026 sarcomere-1 s-1, respectively (mean ± SEM, N = 10; calculated from column 6 in Table 1). For R. temporaria, the corresponding frequencies were 0.069 ± 0.026 and 0.081 ± 0.035 sarcomere-1 s-1 (N = 3; column 6 of Table 2). Although neither of these differences between initial and final frequencies is statistically significant, in both cases the second mean frequency is larger than the first.
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For the 10 fibers from R. pipiens in which the protocol of Fig 4 was used, the mean spark frequency in 13 mM [K+] Ringer's was 0.719 ± 0.127 sarcomere-1 s-1; in contrast, the average of the initial and final bracketing frequencies in normal Ringer's was 0.075 ± 0.019 sarcomere-1 s-1. For the four fibers from R. pipiens that had no final bracketing measurement in normal Ringer's, the mean frequencies were 0.556 ± 0.177 and 0.047 ± 0.025 sarcomere-1 s-1 in 13 mM [K+] Ringer's and normal Ringer's, respectively. Both of these differences are highly statistically significant and indicate that the frequency in 13 mM [K+] Ringer's is 10-fold larger than that in normal Ringer's.
For the single experiment from R. temporaria in which the protocol of Fig 4 was used, the frequency in 13 mM [K+] Ringer's was about fivefold larger than that in normal Ringer's, 0.261 vs. 0.049 sarcomere-1 s-1. For the experiments with intermediate [K+] (7.510 mM; Table 2), spark frequencies were generally intermediate between the values measured in normal and in 13 mM [K+] Ringer's.
The first spark measurements in elevated [K+] Ringer's were usually made 12 min after the solution change. In contrast, in voltage-clamp experiments on cut fibers, measurements are usually made during the first second after a depolarization. Spark frequencies immediately after depolarization in elevated [K+] Ringer's might be somewhat different from the values given in Table 1 Table 2.
The 10-fold increase in spark frequency upon depolarization with 13 mM [K+] Ringer's is probably a lower limit because of missed sparks in the 13 mM [K+] Ringer's. This happens because [Ca2+]R and therefore resting F increase with depolarization. On average, exposure to 13 mM [K+] Ringer's increased F by 1.3 (F'/F, Table 1 and Table 2, column 4), implying a roughly similar increase in [Ca2+]R. Because the associated increase in [Ca2+]R is expected to have little effect on the amplitude of
F produced by an SR Ca2+ release event of fixed amplitude and duration (unpublished theoretical analysis), the value of the
F/F is expected to be reduced by
1.3-fold. As a result, fewer sparks would be detected by our autodetection program in 13 mM [K+] Ringer's.
Estimation of Morphological Parameters
For further analysis, it is important to have a quantitative characterization of the temporal and spatial features of sparks. Fig 5 A shows zoomed F/F images of the two largest sparks identified in the middle panel of Fig 4. Both sparks have a similar appearance. In Fig 5B and Fig C, the asterisks show extracted time and space profiles, respectively, of these sparks, and the curves show the least-squares fits of Equation 1 and Equation 2 to the profiles (MATERIALS AND METHODS). From the fits, estimates were obtained for the main morphological parameters considered below: rise time, peak amplitude, decay time constant, FDHM, late offset, FWHM, and mass (see Fig 5 and legend for information on the fitted values of these and other sparks in Fig 4).
Because [Ca2+]R and consequently resting fluorescence was larger in elevated [K+] Ringer's than in normal Ringer's (see preceding section), F/F amplitudes of sparks measured in 13 mM [K+] Ringer's were scaled by the factor 1.3 (= F'/F) for subsequent analysis to make these amplitudes comparable to those measured in normal Ringer's. For example, after the 1.3-fold scaling, the amplitudes of the two sparks analyzed in Fig 5 are 1.30 and 1.05 instead of 1.00 and 0.81. For sparks in 10 and 7.5 mM [K+] Ringer's, fitted amplitudes were scaled by smaller factors, 1.2 and 1.1, respectively (Table 2, column 4). With these corrections, sparks produced in the different solutions by similar Ca2+ release events are expected to have similar
F/F amplitudes.
(Note: for several reasons, the F'/F correction procedure provides only an approximate method for the comparison of F/F amplitudes in solutions with different [K+]. First, in some but not all experiments, the value of F'/F varied somewhat with time, being larger for the change from normal to elevated [K+] Ringer's than for the change from elevated [K+] back to normal Ringer's. Second, at any particular [K+], there was undoubtedly some fiber to fiber variation in [Ca2+]R and, therefore, in the resting fluorescence intensity per unit concentration of fluo-3. Third, it is possible that other factors, such as the degree of Ca2+ loading of the SR, may have contributed to fiber to fiber variation in spark amplitudes.)
Table 3 gives the mean values of the morphological parameters of sparks in normal Ringer's and in elevated [K+] Ringer's for the fibers from R. pipiens and R. temporaria. For two reasons, the data in the Table were restricted to "larger" sparks, defined as sparks with a fitted peak amplitude of at least 0.7 F/F (after F'/F scaling). First, with larger sparks, estimates of morphological parameters are influenced less by photon and instrumentation noise. Second, larger sparks are likely to have been detected with a similar, high probability in both elevated [K+] and normal Ringer's. (In contrast, smaller release events are less likely to have been detected in elevated [K+] Ringer's than in normal Ringer's because of the difference in resting F and hence
F/F; see final paragraph of preceding section.)
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The mean morphological parameters in Table 3 characterize the basic properties of sparks in amphibian intact fibers under these experimental conditions. Although the parameters are quite similar for the two species and the two recording solutions, there are some small but significant differences. A superscript a (a) in column 3 of Table 3 identifies a morphological parameter with a mean value that is significantly different in normal and elevated [K+] Ringer's. For R. pipiens, three parameters were slightly larger in 13 mM [K+] Ringer's than in normal Ringer's. The percent increases are as follows: 13% for rise time, 10% for FDHM, and 7% for FWHM. For R. temporaria, rise time and FDHM were also slightly larger in elevated [K+] Ringer's (by 17% and 9%, respectively), although FWHM was not significantly different. Peak amplitude was slightly smaller in elevated [K+] Ringer's (by 9%).
For both R. pipiens and R. temporaria, the largest significant parameter difference is for rise time (1317% larger in elevated [K+] Ringer's). This difference may arise because the rate of voltage-sensor deactivation at the membrane potential of normal Ringer's is faster than that of elevated [K+] Ringer's (
We also looked for significant differences between sparks in fibers from R. pipiens and R. temporaria. A superscript b (b) in Table 3 indicates a statistically significant difference between species. The mean values of peak amplitude and decay time constant were significantly different in both normal and elevated [K+] Ringer's, whereas the mean spark mass was significantly different only in elevated [K+] Ringer's. Spark amplitude was 1530% larger, mass was 3045% larger, and decay time constant was 1015% smaller in R. pipiens than in R. temporaria. Interestingly, the peak value of F/F elicited by an action potential (measured on the optical bench apparatus a few minutes after the fluo-3 injection; MATERIALS AND METHODS) was 4050% larger in R. pipiens than in R. temporaria (see first section of RESULTS). Although the underlying reason(s) for all of these differences is not clear, the larger spark amplitude (and consequently spark mass) in R. pipiens may be due to a smaller value of [Ca2+]R.
Spark Properties with a Line Scan Period of 1 ms
The data in Table 3 were obtained with the standard line scan period of this study, 2.048 ms (MATERIALS AND METHODS). Because the mean value of spark rise time (4 ms) is only about twice the scan period, the rising phase of the spark was not well resolved; consequently, estimates of rise time may have some systematic error. To test for this possibility, four experiments were performed with line scan periods of both 1 and 2 ms. Fibers were bathed in 13 mM [K+] Ringer's to induce sparks and three sets of images were recorded: first with a line scan period of 2.048 ms, then with 1.024 ms, and then again with 2.048 ms. With the 1.024-ms scan period, it was necessary to reduce the excursion of the scan mirror from a useful length of 43.0 µm at the fiber to 17.3 µm. Both this reduction and the shorter scan period decreased the mean number of sparks detected per image. In each experiment, the spark frequency (units of sarcomere-1 s-1) was similar during the three recording periods. Fig 6 and Fig 7 give examples of the images recorded and morphological fits obtained in these experiments. Table 4 summarizes the morphological parameters tabulated by scan period; the values from the initial and final sets of measurements with the 2.048-ms scan period were similar (not shown). Although the mean parameter values from the two scan periods are quite similar, four of the six means are statistically different (indicated by superscript a; column 3). In each case, the mean value with the 2.048-ms scan period is slightly larger than that with the 1.024-ms scan period; the percent increases are 15% for rise time, 8% for FDHM, 9% for FWHM, and 33% for mass.
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Numerical analysis of simulated sparks (not shown) was also used to evaluate possible errors in the estimation of morphological parameters with the 2-ms scan period. The time course of simulated sparks was assumed to satisfy Equation 1. Random noise was added to the waveform to approximate the photon noise in the measurements. Variability was also introduced to simulate uncertainty in the time of spark onset relative to spark sampling (uncertainty assumed to be distributed uniformly between ± 0.5 time pixels). The analysis indicated that, if the actual spark rise time is 4 ms, the use of a 2-ms line scan period overestimates mean rise time by 5%; if the actual rise time is 3 ms, the overestimate is
20%. With a 1-ms scan period, the overestimates are smaller, 0 and 5%, respectively. These results are in reasonable agreement with the results in Table 4, where the mean rise time with the 2-ms scan period is
15% larger than that with the 1-ms scan period. The combined results of Table 4 and the numerical analysis support the conclusion that the rise times in Table 3 and Table 4 are reasonably accurate, although the values obtained with the 2-ms scan period may be overestimated by 1020% if the actual spark waveform is accurately described by the theoretical spark waveform.
Spark Properties with y-t Scanning
In the experiments described above, the spatial spread of a spark was measured in only the x direction (along the fiber axis). In cardiac myocytes, however, the spatial spread of a spark depends on direction; at the time of the peak of a spark, FWHM in y (the direction perpendicular to the fiber axis and to the light path) is 15% (
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Table 5 presents a summary of the morphological parameters obtained from the x-t and y-t images (columns 2 and 3, respectively). Only the values of FWHM are statistically significantly different and the difference is only 6%. These results support the conclusion that the diffusion of free Ca2+, fluo-3, and the other mobile Ca2+ buffers that affect the spatial spread of a spark occurs almost isotropically in frog myoplasm.
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Late F/F Phase of a Spark
In their study of sparks in cut fibers, F/F signal had an amplitude of 0.10.2 (relative to the prespark baseline) and a FWHM of
1 µm.
To determine the properties of such late signals in intact muscle fibers, an average x-t image was formed from 1,767 sparks recorded in 13 mM [K+] Ringer's and aligned at the time of peak. Fig 10 A shows the average F(x,t) image displayed at high gain. This image reveals the average spark superimposed on the average resting fluorescence pattern. The F(x) signal from the prespark period is shown at the left, where the tall narrow peaks mark m-lines. As expected, the average spark is highly symmetric about the central z-line. Fig 10B and Fig C, show F/F images of the average spark at low and high gain, respectively (see Fig 11 for amplitude calibrations).
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Fig 11 A shows two temporal profiles extracted from the F/F image of Fig 10. The asterisks show the profile measured at the central z-line; this signal-averaged profile is much less noisy than that of a typical spark (Fig 5 B, 7 B, and 9 B). The squares show the average of the profiles measured at the two immediately adjacent m-lines. The m-line signal has an amplitude that is
7% of that of the z-line signal and reaches a peak
4 ms after the z-line signal. The curve in Fig 11 A shows the fit of Equation 1 to the z-line signal. As expected, the parameter values obtained from the fit (see legend) are close to the mean values in column 3 of Table 3 R. pipiens.
Fig 11 C shows two spatial profiles from the F/F image of Fig 10, one obtained at the time of peak of the spark (t = 0 ms; asterisks) and the other at the time of the late signal as studied by
F/F and 0.96 µm (Fig 11 C) and 0.018
F/F and 2.94 µm (Fig 11 E). The late signal in intact fibers is substantially different from that described in cut fibers: the amplitude is
0.2 times that found by
Fig 11 (B and D) shows the time courses of the amplitude and FWHM of F/F, estimated from fits of Equation 2 to spatial profiles derived from Fig 10 (as in Fig 11C and Fig E). The amplitude decreases progressively after the peak, as expected from Fig 11 A, whereas the value of FWHM increases (note the different vertical gains in Fig 11A and Fig B). Fig 11 F shows the time course of spark mass (Equation 8). As mentioned in MATERIALS AND METHODS, the product of spark mass times [Ffluo]R approximates the total increase in Ca-fluo-3 (in moles) if the Ca2+ spark is at the scan line. Interestingly, at the time of peak of the average spark (t = 0 ms), which is thought to mark the termination of Ca2+ release (
5 ms later (two to three data points). Although the Ca2+ source is not centered at the scan line for all larger sparks, this increase in spark mass after the peak likely reflects increased binding of Ca2+ to fluo-3 after Ca2+ release has ceased. A delay of this type is expected because of the kinetic delay in the reaction between Ca2+ and fluo-3 in the myoplasmic environment (
Although the data in Fig 11 B were obtained from Gaussian fits, they essentially superimpose, within the noise, the asterisk data in Fig 11 A at t > 2 ms. The curve in Fig 11 B is the same as that in Fig 11 A. For 14 < t < 38 ms, the data lie above the fitted curve, whereas, for t > 46 ms, the data lie below the curve (Fig 11 B). The discrepancy between the data and curve suggests that the falling phase of a spark contains an additional slow component. Therefore, it was of interest to refit the asterisk data of Fig 11 A with a modified version of Equation 1 in which the decay of a spark follows a double-exponential (rather than a single-exponential) time course. This fit was performed both with and without the inclusion of a baseline offset. In both fits, the data were well described by a double-exponential decay. The time constant of the fast component was 4.6 ms and that of the slow component was 2535 ms; the fractional amplitudes of the fast and slow components were 0.93 and 0.07, respectively (both fits). These results indicate that the decay phase of a spark has a small slow component whose time constant is severalfold larger than that of the large fast component, and that the positive baseline offset estimated in the fits with Equation 1 (Tables IIIVI) reflects the presence of this slow component.
Early F/F Phase of a Spark
To further explore the idea that the Ca2+ released by one RYR might serve as the immediate trigger of a cluster of RYRs responsible for a spark (F/F at the central location of the average spark is close to baseline during the prespark period (t = -50 to -4 ms). Thus, any early increase in fluorescence reflective of putative trigger activity is likely to be small. To study this further, a new average x-t image was formed, in which spark alignment was based on time of onset rather than time of peak. The voltage-activated sparks used for this new image were the same as those used for Fig 10. The baseline used to correct the
F/F signal was formed from the average of the first 11 line scans in the image (t = -47 to -27 ms). Fig 12 A shows the central time profile from this
F/F image.
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To examine the onset of the spark, three spatial profiles were extracted from the average x-t image. These profiles (Fig 12 B, squares) correspond to the scan line at the nominal time of spark onset (t = 0 ms; top profile) and to the two scan lines immediately preceding spark onset (t = -2.048 ms and t = -4.096 ms; middle and bottom profiles, respectively). The curves in Fig 12 B are the best fits of the usual Gaussian function (Equation 2). From these fits, the following values of F/F and FWHM were obtained: 0.032 and 1.34 µm, 0.009 and 1.51 µm, and 0.014 and 1.50 µm, respectively. At the nominal time of spark onset (t = 0 ms), the small positive
F/F that is detected is
3% of peak. This small signal might conceivably reflect a trigger phase of
F/F. At t < 0 ms, the fitted values of amplitude are within the noise of the baseline (mean ± SD = 0.001 ± 0.008
F/F, obtained from similar fits to the first 11 line scans); thus, a reliable signal was not detected at t < 0 ms. Overall, the small positive amplitude detected at t = 0 ms (3% of peak) implies that any trigger phase preceding a voltage-activated spark must be very small in comparison with the spark itself.
Repetitive Spark Activity within Individual Sarcomeres
0.7; consequently, they contributed to the average values in column 3 of Table 3 R. pipiens. In this experiment, 558 sarcomeres were studied and the mean frequency of sparks with amplitude
0.7 was 0.25 per sarcomere per 1.571s image. Under the hypothesis that the distribution of sparks among sarcomeres is random, the probability of finding a sarcomere with 10 or more sparks out of 558 sarcomeres is extremely low, <10-9 (calculated from the Poisson distribution with a mean frequency of 0.25; see next paragraph). Thus, sparks do not occur with a fixed probability that is equal among all sarcomeres.
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To obtain some measure of the distribution of sparks among sarcomeres, the 3,176 voltage-activated sparks of R. pipiens (F/F
0.7; Table 3, column 3) were sorted according to the number of sparks per sarcomere. The asterisks in Fig 13 A show Pn, the fraction of sarcomeres that had n sparks per sarcomere in 1.571 s, plotted as a function of n (= 0, 1, 2,...12; 12 being the maximum number of sparks detected for any sarcomere). Fig 13 B shows the same data plotted at higher vertical gain. The open squares in Fig 13 (A and B) show the values of Pn expected for a random distribution of sparks among sarcomeres; these were calculated from a Poisson probability distribution constrained to match P0, 0.65 (Fig 13, legend). Compared with the values obtained from the Poisson probability distribution, the data reveal a deficit of sparks for n = 1 and an excess of sparks for n
2.
A possible reason for the difference between the asterisks and open squares in Fig 13 is a nonuniform spatial distribution of RYRs in the y-z plane. 150. In making these estimates, the authors approximated the PSF in the y-z plane of the scan as a rectangle of size 0.5 µm in y and 1.0 µm in z. We have reanalyzed the images for frog skeletal muscle from their Fig 5 using a rectangle of 0.2 µm in y and 0.5 µm in z, values close to those for FWHM of our measured PSF. In this analysis,
10% of scanned sarcomeres are estimated to have zero RYRs, the maximum number of RYRs in any scanned sarcomere is
80, and the mean number of RYRs per scanned sarcomere is 21. In Fig 13, the open circles show the expected distribution for Pn calculated from our estimate of the spatial distribution of RYRs and the assumption that the number of sparks within a sarcomere follows a Poisson distribution with a mean frequency of 0.023 per 1.571 s per RYR. This is the frequency that gives the observed fraction of sarcomeres without sparks, 0.65. The open circles lie between the open squares and the experimental data (asterisks). Although a nonuniform spatial distribution of RYRs helps explain the observed number of sparks per sarcomere, there is still a deficit of sarcomeres for n = 1 and an excess for n > 2. Thus, both forms of the Poisson analysis support the conclusion that sparks do not occur with a fixed probability that is equal among all sarcomeres. For example, different sarcomeres may have different fixed probabilities or the probability of spark occurrence within one sarcomere might increase as a result of previous spark activity.
In Fig 13 B, the observed values of Pn decrease along a smooth trajectory, with no obvious indication of a specific value of n that might be used as a threshold for identifying repetitive vs. nonrepetitive sparks. Thus, repetitive sparks of the type illustrated in Fig 14 A may simply reflect an extreme result of an underlying mechanism that favors the recurrence of sparks at sites where sparks have already occurred.
A similar analysis (not shown) was also performed on the 237 sparks in normal Ringer's from R. pipiens (Table 3 R. pipiens, column 2). These sparks were distributed among 192 out of a total of 4,564 sarcomeres in 334 images. Analogous to the procedure used in Fig 13, the plot of Pn against n was compared with the two Poisson distributions calculated from the observed value of P0, 0.96 (= (4,564 -192)/4,564). As in Fig 13, Pn for both distributions revealed a deficit of sparks for n = 1 and an excess of sparks for n > 2. Thus, for both resting sparks and voltage-activated sparks, the results deviate from the simplest forms of the Poisson analysis.
We also explored the possibility that the values of spark morphological parameters might depend on n. The 3,176 sparks used for Fig 13 were divided into three subgroups: (1) n = 1 (998 sparks); (2) n = 24 (1,564 sparks); (3) n = 512 (614 sparks). As shown in Table 6, the mean values of the parameters are similar for all three groups. As indicated by the superscript a in column 4, the small increases for rise time, peak amplitude, decay time constant, and FDHM are statistically significant. These results are generally consistent with the findings of
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Atypical Events
The vast majority of events observed in these experiments were narrowly confined in space and time, i.e., were unambiguously "sparklike" (Fig 4 Fig 5 Fig 6 Fig 7 Fig 8 Fig 9 Fig 10). However, a few images revealed fluorescence increases that were different. These atypical events usually had a normal spatial spread but a duration that was unusually prolonged. Unlike streakers (Fig 2 B), these events occurred at the same location as sparks (i.e., at z-lines), suggesting that they reflect the release of Ca2+ through active RYRs. Fig 14 (BD) shows three examples. In Fig 14 B, the maintained activity (middle sarcomere of the image) appeared to begin as repetitive sparks but, at later times, changed to more sustained and less sparklike events. This pattern probably reflects atypical closings and reopenings of the same RYR or cluster of RYRs. Fig 14C and Fig D, shows sustained nonsparklike activity of long and short duration, respectively (second sarcomere from the top in each image). Although these rare events were not analyzed in detail, their presence is expected to have had negligible influence on the estimation of spark properties as given in Table 1 Table 2 Table 3 Table 4 Table 5 Table 6.
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DISCUSSION |
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This article describes the first detailed study of resting and voltage-activated Ca2+ sparks in frog intact skeletal muscle fibers. The use of intact muscle fibers for studies of excitation-contraction coupling is important because the physiological environment is expected to be as close to normal as is possible outside the whole animal. The experiments were performed with a home-built confocal microscope that has excellent spatial resolution. The values of FWHM of the microscope's point-spread function, 0.21 µm in x and y and 0.51 µm in z, are smaller than those from previous spark studies in frog cut skeletal fibers, 0.40.5 µm in x and y and 0.81.4 µm in z ( 0.3 µm; Fig 2, BD), intrasarcomeric periodicities in the resting fluorescence of fluo-3 (e.g., FWHM of m-line fluorescence
0.6 µm; Fig 3), and sparks themselves (FWHM
1.0 µm; Tables IIIVI).
Fluo-3 Resting Fluorescence
In intact fibers, F(x), fluo-3's resting fluorescence along the fiber axis, revealed an oscillation with a well-defined substructure. In normal Ringer's, fluorescence at the m-line was usually similar to that at the z-line (Fig 2 B and Fig 3A and Fig B). In elevated [K+] Ringer's, m-line fluorescence was usually larger than z-line fluorescence (e.g., Fig 3 C and Fig 10 A). This increase may be a consequence of an increase in [Ca2+]R caused by the membrane depolarization in elevated [K+]. In cut fibers at the normal holding potential (-90 mV), m-line fluorescence is also larger than z-line fluorescence (
Spark Frequency and Morphology
When the solution bathing an intact fiber was changed from normal Ringer's to 13 mM [K+] Ringer's, the mean spark frequency increased by about an order of magnitude and the elevation in frequency persisted at an approximately constant level for many tens of minutes. Thus, exposure of fibers to moderately elevated [K+] Ringer's provides a reliable method to induce voltage-activated sparks at a useful frequency for measurement. In both normal Ringer's and 13 mM [K+] Ringer's, a statistical analysis indicated that sparks do not occur with a fixed probability that is equal among sarcomeres (see Repetitive Spark Activity within Individual Sarcomeres).
Spark waveforms in time and space were fitted with standard functional forms (Equation 1 and Equation 2) to estimate the morphological characteristics of sparks (Fig 5, Fig 7, and Fig 9 and Tables IIIVI). The waveforms extracted from individual sparks appeared to be well-fitted by Equation 1 and Equation 2, although the noise in the data was sufficiently large that a systematic deviation between the data and the functional forms cannot be ruled out. In fact, two such deviations became apparent in the fits of Equation 1 and Equation 2 to the average F/F that was complied from 1,767 sparks (Fig 11). In Fig 11 (A and B), the falling phase of
F/F does not exactly follow a single exponential decay to a baseline offset. Similarly, the best fit of a Gaussian function to the spatial profile of a
F/F at the time of peak (Fig 11 C, curve and asterisks) reveals deviations; the fit overestimates the spark profile at half amplitude and underestimates the peak of the spark and the values at |x|
0.8 µm. These deviations are not surprising, since, as mentioned in MATERIALS AND METHODS, Equation 1 and Equation 2 are not expected to exactly describe the time course and spatial spread of a spark.
Comparison of Spark Morphology in Intact and Cut Fibers from R. Pipiens
Sparks in frog intact fibers are remarkable for their small values of FDHM and FWHM (6 ms and
1.0 µm, respectively; Tables IIIVI). Both of these values are substantially smaller than the corresponding values measured in other adult muscle preparations, such as frog cut skeletal fibers (915 ms and 1.32.3 µm; see next paragraphs), mouse enzyme-dissociated skeletal fibers (40 ms and 2.0 µm;
Table 7 compares values of spark morphological parameters in frog intact fibers and in frog cut fibers under several conditions. Results from cut fibers are included only if the nominal value of free [Mg2+] was 0.51.0 mM, which is close to the physiological range. The F/F threshold values for spark selection are indicated in parentheses after each entry in the Table. Two threshold values, 0.5 and 1.0, were used for intact fibers to allow comparison with results from cut fibers; these values are different from the 0.7 threshold used for Table 3 Table 4 Table 5 Table 6. Columns 2 and 3 of Table 7 give mean parameter values for voltage-activated sparks in intact and cut fibers, respectively; column 4 gives mean values for spontaneous sparks in cut fibers that were permanently depolarized by notching or saponin permeabilization.
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The rise time of voltage-activated sparks is similar in both intact and cut fibers, 3.94.8 ms (columns 23), whereas the rise time of spontaneous sparks in permanently depolarized cut fibers is larger, 5.18.7 ms (column 4). At comparable detection thresholds, the amplitude of voltage-activated sparks is similar in intact fibers and in the cut fibers studied in the Schneider laboratory (Table 7, refs. a and c); the amplitude reported by the Ríos laboratory is almost twofold larger (ref. e). In comparing these values of F/F, it is important to consider possible differences in the values of [Ca2+]R and hence resting F from the different laboratories. If [Ca2+]R is smaller in intact fibers than in cut fibers (as suggested above), the amplitude of
F in intact fibers may be smaller than those from both the Schneider laboratory and the Ríos laboratory.
The other morphological parameters reveal substantial differences between intact and cut fibers. The value of FDHM, which depends on both rise time and decay time constant, is about twofold larger in cut fibers (915 ms) than in intact fibers (6 ms). The larger value in cut fibers is due mainly to a larger value of decay time constant (8.5 ms at 2023°C vs. 4.9 ms at 1719°C). The reason for this difference is unknown.
FWHM is also larger in cut fibers (1.32.3 µm) than in intact fibers (1.0 µm). Factors that might contribute to the larger FWHM in cut fibers include the following: (1) larger values for the variance of the microscope point-spread function (see above); (2) slightly larger values of rise time, which are associated with larger values of FWHM (
1.0 µm for spark rise times in the range of 412 ms (
For a given set of model assumptions (i.e., values of the concentrations of myoplasmic Ca2+ buffers and their reaction kinetics, of the diffusion constants of Ca2+ and its buffers, of [Ca2+]R, etc.), spark simulations also indicate that spark mass at the time of the peak of an in-focus spark (compare Equation 8) increases with the amount of Ca2+ that has been released from the SR (3-fold for voltage-activated sparks (Table 7, columns 2 and 3) and up to 10-fold larger for the comparison between permanently depolarized cut fibers and voltage-activated intact fibers (Table 7, columns 2 and 4). These factors would be even larger if [Ca2+]R is smaller in intact fibers than in cut fibers (see above). Part of the increase in mass in cut fibers, especially in permanently depolarized cut fibers, may be caused by the longer duration of channel opening and the expected increase in Ca2+ release. With similar channel open times, a larger spark mass could arise from (1) a reduction in the apparent Ca2+ buffering power of myoplasm or (2) an increased flux of Ca2+ at the source. The apparent Ca2+ buffering power could be reduced by the diffusional loss of Ca2+ buffers from the ends of a cut fiber or by loss of factors that facilitate Ca2+ removal from the myoplasm. An increase in Ca2+ flux could arise from an increase in the Ca2+ release current per RYR or an increased number of active RYRs (such as might occur if, during a spark, Ca2+-induced Ca2+ release contributes to RYR activation [
Late Phase of a Spark
Voltage-activated sparks in intact fibers reveal a barely detectable fluorescence increase 2848 ms after the peak (F/F
0.02, FWHM
3 µm; Fig 10 Fig 11). This signal is smaller and broader than the signal studied by
F/F
0.10.2, FWHM
1 µm; also measured 2848 ms after peak).
Another explanation for the small late F/F signal is an elevation of free [Ca2+] caused by the dissociation of Ca2+ from buffer sites that captured Ca2+ at earlier times during the spark. For example, the Ca2+ regulatory sites on troponin, which are located on the thin filament in the immediate neighborhood of the RYRs, are expected to bind significant amounts of Ca2+ early in the spark and to release this Ca2+ later in the spark. This release should produce a small, long-lasting elevation in [Ca2+] and hence
F/F.
Conclusions
Depolarization by 1015 mM [K+] Ringer's provides a simple method to elicit voltage-activated sparks in frog intact muscle fibers. Compared with cut fibers, sparks in intact fibers have smaller values of decay time constant, FDHM, FWHM, and spark mass. In addition, the late phase of voltage-activated sparks is smaller and broader in intact fibers than in cut fibers. The large difference in spark mass between intact and cut fibers suggests that the apparent Ca2+ buffering power of myoplasm is smaller in cut fibers or that the flux of Ca2+ during release is larger. These and other results emphasize the importance of studying Ca2+ signaling mechanisms in the native environment.
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Footnotes |
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* Abbreviations used in this paper: F/F, change in fluorescence divided by resting fluorescence; [Ca2+]R, resting myoplasmic free [Ca2+]; FDHM, full duration at half maximum; FWHM, full width at half maximum; PSF, point-spread function.
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Acknowledgements |
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We thank Dr. Gil Wier for advice about construction of a home-built microscope. We thank Dr. Clara Franzini-Armstrong for making available an early version of Franzini-Armstrong et al., 1999.
This work was supported by grants from the National Institutes of Health to S.M. Baylor (NS 17620) and W.K. Chandler (AM 37643).
Submitted: 30 July 2001
Revised: 14 September 2001
Accepted: 1 October 2001
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References |
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