For each fibre, the individual contractions meeting the relaxation time criteria were identified and their fura-2 ratios transformed into an estimate of [Ca2+]i as described in Methods. Tension was then plotted against estimated [Ca2+]i for those contractions to form the tension-[Ca2+]i relation for each contraction. Figure 2 shows, superimposed, all fifteen of the eligible contractions (5 at SL = 2·9 µm and 10 at SL = 2·2 µm) identified in Fig. 1 plotted in this way. Note that the plotted curves cluster according to SL, with the SL = 2·9 µm curves falling to the left of those obtained at SL = 2·2 µm, indicating an increase in sensitivity to [Ca2+]i at the longer length. Note also that the effect on the tension-[Ca2+]i relation of changing SL is both reversible and repeatable. The Hill equation (Hill, 1913) was fitted to each individual eligible plot and the resulting [Ca2+]50 and 
pCa were obtained as described in Methods. For the fibre shown in Figs 1 and 2, the mean [Ca2+]50 for all eight contractions (3 not shown) at SL = 2·9 µm was 0·61 ± 0·02 µM; for all fourteen contractions (4 not shown) at SL = 2·2 µm, mean [Ca2+]50 was significantly greater: 1·09 ± 0·04 µM (P < 0·001). The mean pCa values for the same contractions were 0·14 ± 0·02 (corresponding to a Hill coefficient, N, of 13·5) and 0·12 ± 0·01 (N = 16·2) for SL = 2·9 and 2·2 µm, respectively.
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Figure 2. Tension plotted against [Ca2+]i at mean sarcomere lengths (SL) of 2·2 µm and 2·9 µm from a representative fibre.
The tension records shown in Fig. 1 are normalized to 1·0 for each individual contraction and plotted here against [Ca2+] values calculated from the corresponding fura-2 ratio records. All contractions with tension relaxation times (90 to 10 %) between 10 and 30 s are superimposed. This includes the final 3 contractions at SL = 2·9 µm from Fig. 1A, the final 5 contractions at SL = 2·2 µm from Fig. 1B, the final 2 contractions at SL = 2·9 µm from Fig. 1C and the final 5 contractions at SL = 2·2 µm from Fig. 1D for a total of 10 plots at SL = 2·2 µm and 5 plots at SL = 2·9 µm. Note that the plots cluster by SL, with those from SL = 2·9 µm falling to the left (lower [Ca2+]i) of those from SL = 2·2 µm. Temperature was 3·0 °C. Fibre 970625.
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The compiled results for all six fibres studied are given in Table 1. For each of the four fibres in which more than one contraction met the tension relaxation time criteria at both SLs tested, the [Ca2+]50 was significantly reduced at SL = 2·9 µm compared with 2·2 µm (P < 0·001). When all eligible contractions from all six fibres were pooled, the mean [Ca2+]50 was 0·69 ± 0·02 µM (n = 22) at SL = 2·9 µm and significantly greater, 1·09 ± 0·02 µM (n = 61), at SL = 2·2 µm (P < 0·001). Although the mean values for pCa at SL = 2·9 µm were always larger than those at 2·2 µm for the four fibres in which more than one contraction was analysed at both SLs, statistical analysis indicated that this difference was significant for only one fibre (P was < 0·001 for that fibre and 0·127, 0·383 and 0·329 for the other three). However, when the results from all six fibres were pooled, a statistically significant (P < 0·001) increase in pCa was indicated at SL = 2·9 µm (pCa = 0·17 ± 0·01, n = 22) compared with SL = 2·2 µm (pCa = 0·12 ± 0·01, n = 61). These pCa values correspond to N = 10·9 and N = 15·4, respectively. Thus the relationship between tension and [Ca2+]i as reported by the injected K+ salt form of fura-2 is very steep, similar to that reported from a study in which fura-2 was loaded via the membrane permeant AM form (Morgan et al. 1997). The tension relaxation times at SL = 2·2 µm were not different from those at 2·9 µm for either individual fibres or for the pooled data, thus ruling out differences in relaxation times as a confounding factor in the analyses of differences in [Ca2+]50 and pCa. The consistency of the tension relaxation times was due to the careful manipulation of contraction intervals described above.
Table 1. Summary of relaxation time, [Ca2+]50 and pCa results for all fibres tested
| | SL = 2·2 µm | SL = 2·9 µm |
| Fibre no. | Relaxation time (s) | [Ca2+]50 (µM) | pCa | No. of contractions | Relaxation time (s) | [Ca2+]50 (µM) | pCa | No. of contractions |
| 970416 | 17·6 ± 2·0 | 0·98 ± 0·04 | 0·10 ± 0·01 | 9 | - | - | - | - |
| 970425 | 24·0 ± 1·0 | 1·25 ± 0·07 | 0·16 ± 0·01 | 8 | 27·7 | 0·92 | 0·22 | 1 |
| 970507 | 19·5 ± 2·3 | 1·10 ± 0·02 | 0·10 ± 0·02 | 8 | 21·6 ± 2·4 | 0·70 ± 0·05 * | 0·16 ± 0·01 | 3 | | |
| 970515 | 20·0 ± 2·1 | 0·99 ± 0·01 | 0·17 ± 0·01 | 7 | 15·1 ± 1·1 | 0·80 ± 0·01 * | 0·19 ± 0·01 | 3 |
| 970619 | 15·8 ± 1·3 | 1·09 ± 0·05 | 0·11 ± 0·01 | 15 | 12·5 ± 0·5 | 0·70 ± 0·01 * | 0·21 ± 0·01 * | 7 |
| 970625 | 17·6 ± 1·4 | 1·09 ± 0·04 | 0·12 ± 0·01 | 14 | 18·5 ± 2·5 | 0·61 ± 0·02 * | 0·14 ± 0·02 | 8 |
| Pooled | 18·5 ± 0·7 | 1·09 ± 0·02 | 0·12 ± 0·01 | 61 | 17·0 ± 1·3 | 0·69 ± 0·02 * | 0·17 ± 0·01 * | 22 |
* Significantly different from the value obtained at mean sarcomere length (SL) of 2·2 µm.
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DISCUSSION |
Effect of length on Ca2+ sensitivity of tension
The results show clearly that the sensitivity of tension generation to [Ca2+]i in intact twitch skeletal muscle fibres from frogs increases as SL is increased over the descending limb of the length-tension relation. Such an increase has been reported to occur in skinned twitch fibres from both amphibian (Endo, 1972, 1973; Moisescu & Thieleczek, 1979; Stephenson & Williams, 1983) and mammalian (Stephenson & Williams, 1982) skeletal muscle, but has not before been demonstrated in intact fibres. Balnave & Allen (1996) reported no increase in the sensitivity of tension to [Ca2+]i with increasing fibre length over the descending limb of the length-tension relation in intact mammalian fibres. In that study, no attempt was made to slow the rate of change of [Ca2+]i in order to improve the likelihood that tension and [Ca2+]i were near steady state. Morgan et al. (1997) presented evidence suggesting that, in frog fibres at 3·0°C, such a condition required tension relaxation times that were at least 10 s in duration, which could not be achieved in a fibre that had not been treated with a sarcoplasmic reticulum Ca2+-uptake pump inhibitor such as CPA. Thus the apparent discrepancy between intact frog and mammalian fibres could be due to a difference in the degree to which a steady state between tension and [Ca2+]i was maintained; alternatively there could be a real difference in the way fibres from the two species respond.
In tetanized intact skeletal muscle fibres, tension generation is proportional to the degree of overlap of thick and thin filaments, and this property is responsible for the linear 'descending limb' of the length-tension relation (Gordon et al. 1966). Filament overlap does not, however, appear to be the sole determinant of tension generation under conditions expected to result in submaximal activation in intact skeletal muscle preparations. Such conditions include twitch contractions (Rack & Westbury, 1969; Close, 1972), contractions resulting from stimulation at relatively low rates (Balnave & Allen, 1996), and contractions in the presence of dantrolene sodium (Wendt & Barclay, 1980). Under these circumstances, the optimum of the length- tension relation is shifted to longer lengths such that, over part of the relation, tension generation is increasing as overlap is decreasing. This apparent paradox could be explained, at least in part, by the findings confirmed here. That is, as fibre length is increased under conditions resulting in submaximal activation, the attendant reduction in filament overlap could be more than compensated for by the increase in sensitivity of tension to [Ca2+]i that results.
The mechanism responsible for the apparent increase in Ca2+ sensitivity with increasing sarcomere length in twitch fibres has not yet been identified. One possibility often proposed is the increased effective concentration of myosin heads in the vicinity of the thin filament due to the reduction in interfilament distance that results from stretch in skinned fibres (e.g. Endo, 1972, 1973). Since the volume of an intact skeletal muscle fibre remains constant with stretch, the distance between filaments decreases as the inverse square root of fibre length (Huxley, 1953). Hence explanations based upon the reduction in interfilament distance resulting from stretch are equally applicable to intact fibres. An alternative explanation is based on our previous report that, for models with strongly co-operative binding of Ca2+ and myosin to thin filaments, the tension-Ca2+ relation shifts towards lower [Ca2+] as the myosin off-rate is decreased (Morgan et al. 1997). It is reasonable to expect that the stabilizing effects of passive stiffness would tend to reduce internal movement and, consequently, the myosin off-rate at long fibre lengths. Thus the apparent increase in Ca2+ sensitivity at long length could be a manifestation of myosin-Ca2+ co-operativity brought about by increased passive stiffness. Neither of these possible mechanisms, however, can be reconciled with the finding of Stephenson & Williams (1983) that, contrary to results from twitch fibres from amphibians and both fast and slow fibres from mammals, amphibian slow fibres exhibit a decrease in Ca2+ sensitivity with stretch.
Another factor that must be considered in intact preparations is the effect of sarcomere length on the intracellular Ca2+ transient (ICT) that results from stimulation. We have shown previously that increasing SL from 2·2 to 2·8 µm does not affect the peak amplitude of the ICT, but does prolong significantly its duration in intact fibres (Claflin, Vandenboom, Morgan & Julian, 1997). Others have shown that twitch tension generation is closely correlated with ICT duration; longer duration results in greater tension (Jiang, Johnson & Rall, 1996; Sun, Lou & Edman, 1996; Johnson, Jiang & Flynn, 1997). Thus the increase in ICT duration observed with increased fibre length over the descending limb of the length-tension relation could be contributing to the reported shift in the optimum towards longer lengths in intact fibres that are less than fully activated.
It is likely that the long contractions required for these experiments are associated with an accumulation of metabolites in the myoplasm. Furthermore, the accumulation might be expected to be greater at SL = 2·2 µm than at SL = 2·9 µm due to increased opportunity for cross-bridge interaction with the thin filament at the shorter length, and this difference could be contributing to the results reported here. For example, phosphate has been shown to shift the tension-Ca2+ relation towards higher [Ca2+] in skinned skeletal muscle fibres (Millar & Homsher, 1990). We do not believe such accumulations are affecting our results for the following reasons. We have shown (Fig. 4 in Morgan et al. 1997) that the tension-[Ca2+]i curve obtained during a slow rise in tension closely coincides with that obtained during the fall. This is evidence against effects due to accumulation during a single contraction. The consistency of the results shown in Figs 1 and 2 are evidence against effects due to accumulation during the course of a 10 min series of contractions.
Steepness of the tension-[Ca2+] relation
Morgan et al. (1997) reported that the tension-[Ca2+]i relation in intact skeletal muscle fibres is much steeper than those reported in skinned fibres. In that study, [Ca2+]i was monitored using fura-2 loaded via the membrane permeant AM form and 20-50 % of the loaded fluorescence remained after treatment with saponin, suggesting that membrane-enclosed intracellular compartments had been loaded in addition to the myoplasm. Several potential consequences of this saponin-resistant fluorescence were considered and it was concluded that, even making worst-case assumptions, the tension-[Ca2+]i relation was still very steep (Morgan et al. 1997, Appendix II). In the present study, fura-2 was loaded in the K+ salt form by iontophoretic injection and all added fluorescence was released within minutes by treatment with saponin. The finding in the present study that the tension-[Ca2+]i relation is very steep, uncomplicated by considerations of dye-loaded intracellular compartments, confirms our previous finding and supports the hypothesis that tension generation is a highly co-operative process in intact skeletal muscle fibres.
Effect of length on tension-[Ca2+] steepness
The results suggest that the tension-[Ca2+]i relation is less steep at SL = 2·9 µm than at SL = 2·2 µm. If so, this could be due to a true decrease in co-operativity at the longer length, perhaps due to reduced myosin-Ca2+ or myosin- myosin co-operativity due, in turn, to reduced overlap. Alternatively, the extreme steepness of the relation at full overlap could be due to increasing internal movement as relaxation proceeds, as suggested by Morgan et al. (1997). According to this model-based explanation, more internal movement causes a greater mean cross-bridge detachment rate which, due to myosin-Ca2+ co-operativity, causes a shift in the tension-[Ca2+] relation to the right (towards higher [Ca2+] - see Fig. 7 in Morgan et al. 1977). If internal movement increases during relaxation, then a single tension-[Ca2+] curve can no longer be used to describe the relationship. Instead, a hybrid relationship would be more appropriate, constructed by beginning on the curve corresponding to relatively little internal movement and moving continuously to curves corresponding to more internal movement as relaxation proceeds. Because the curves shift to the right with increasing internal movement, the hybrid relationship will be steeper than any of the constituent curves. Extending this, reduced steepness at SL = 2·9 µm could be due to a reduced rate of increase of internal motion during relaxation due, in turn, to the stabilizing effects of the increased passive stiffness present at long lengths. That is, the steepness of the tension-[Ca2+]i relation at SL = 2·9 µm would be closer to indicating the co-operativity of the tension generating process of a truly isometric fibre.
Fura-2 calibration
Estimates of the parameters required to interpret fura-2 fluorescence changes in terms of changes in absolute Ca2+ concentrations are subject to considerable uncertainty in intact skeletal muscle fibres (see Morgan et al. 1997 for a discussion of some of the difficulties). For the present study, the value used for KD
was that obtained from an in vitro calibration of fura-2 performed using the same optical set-up used for the fibre studies. The value used for Rmin was Rrest, the R in a freshly loaded fibre before any stimulation. Although the KD value measured in vitro is likely to be lower than that measured in myoplasm (Baylor & Hollingworth, 1988), any inaccuracy in estimates of [Ca2+]i that result from this approximation do not affect our conclusions regarding the effect of SL on [Ca2+]50. This is because KD simply scales the estimates of [Ca2+]i and would have the same effect at both SLs. Furthermore, because the steepness of the tension-[Ca2+]i relation is a function of the ratio of two [Ca2+]i values, it is not affected by the value of KD. Rrest (0·56) represents an upper limit for Rmin. To determine the sensitivity of our conclusions to inaccuracies in this estimate, sample calculations were performed using a very conservative estimate of 0·30 for the lower limit of Rmin. With Rmin = 0·30, the difference between the [Ca2+]50 values at the two SLs tested was reduced by only 8·6 % (in terms of pCa units) compared with the values obtained with Rmin = 0·56. The sensitivity of steepness (pCa) to Rmin was even smaller.
Conclusions
We conclude that the increase in sensitivity of tension to [Ca2+] with increasing fibre length that is a feature of skinned twitch skeletal muscle fibres also occurs under the more physiological conditions found in intact fibres from frogs. In addition, we conclude that the very steep tension-[Ca2+] relation that is reported to exist in intact skeletal muscle fibres from frogs is not an artifact attributable to the technique used to load the [Ca2+] reporter, fura-2. Finally, our results suggest that the steepness of the tension-[Ca2+] relation is reduced at long sarcomere lengths, consistent with hypotheses that include strong co-operativity between Ca2+ and myosin binding to thin filaments.
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Acknowledgements
This study was supported by National Institutes of Health grant HL 35032 (F. J. J.).
Corresponding author
D. R. Claflin: Department of Anesthesia Research Laboratories, Harvard Medical School, Brigham & Women's Hospital, 75 Francis Street, Boston, MA 02115-6195, USA.
Email: claflin{at}zeus.bwh.harvard.edu
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Top
Introduction
when filled with 3 M KCl. For dye injection, micropipettes were filled at the tip with 1 µl of 10 mM fura-2 dissolved in distilled water and then backfilled with 150 mM KCl. The potential at the tip of the micropipette was monitored to confirm fibre impalement. Upon impalement, indicated by a sudden drop in potential, a current of -15 nA was passed for 4-5 min. One fibre was treated with saponin (50 µg ml-1) after injection of fura-2, and its fluorescence response to excitation at the isosbestic wavelength for fura-2 (358 nm in our system) was monitored. The saponin solution was exchanged every 2 min and fluorescence fell to background levels immediately after the fourth exchange, indicating that the dye had not entered membrane-enclosed intracellular compartments such as mitochondria or sarcoplasmic reticulum (Endo & Iino, 1980). This is in contrast to the response of fibres loaded via the AM form of fura-2, in which saponin reduced isosbestic fluorescence by only 50-80 % (Morgan et al. 1997).
2·8 µm) in the dissection dish and supported from below by a section of glass capillary tubing, 1 mm square, placed on its side. The fibre was impaled near the point where it met the capillary tubing, always within 2 mm of one of the tendons. Injection took place at room temperature. After injection of the dye, the fibre was tied into the experimental chamber and cooled to 3·0°C. Autofluorescence was measured 4-5 mm from the site of injection where there was no contribution from the injected dye. After Rrest was determined, the fibres were soaked for 2 h in Ringer solution containing 1 µM CPA.
