Isolated slow-twitch muscle fibres show modest changes in tetanic force and myoplasmic calcium during repeated contractions, with transient increases in mitochondrial calcium that do not appear essential for ATP production activation or cause muscle damage.
Previous studies on single fast-twitch fibres from mouse toe muscles have shown marked fatigue-induced changes in the free myoplasmic Ca2+ (Ca2+i), while mitochondrial Ca2+ remained unchanged. We have now investigated whether muscle fibres from the legs of mice respond in a similar way. Intact, single fibres were dissected from the soleus and extensor digitorum longus (EDL) muscles of adult mice. To measure Ca2+i, indo-1 was injected into the isolated fibres. Mitochondrial Ca2+ was measured using Rhod-2 and confocal laser microscopy. Fatigue was induced by up to 1000 tetanic contractions (70 Hz) given at 2 s intervals. In soleus fibres, there was no significant decrease in tetanic Ca2+i at the end of the fatiguing stimulation, whereas tetanic force was significantly reduced by about 30 %. In 10 out of 14 soleus fibres loaded with Rhod-2 and subjected to fatigue, mitochondrial Ca2+ increased to a maximum after about 50 tetani; this increase was fully reversed within 20 min after the end of stimulation. The force-frequency curve of the non-responding soleus fibres was shifted to higher frequencies compared to that of the responding fibres. In addition, eight out of nine Rhod-2-loaded EDL fibres showed similar changes in mitochondrial Ca2+ during and after a period of fatiguing stimulation. The stimulation-induced increase in mitochondrial Ca2+ was reduced when mitochondria were depolarised by application of carbonyl cyanide 4-(trifluoromethoxy)phenylhydrazone, whereas it was increased by application of an inhibitor of the mitochondrial Na+/Ca2+ exchange (CGP-37157). In conclusion, isolated slow-twitch muscle fibres show only modest changes in tetanic force and Ca2+i during repeated contractions. The increase in mitochondrial Ca2+ does not appear to be essential for activation of mitochondrial ATP production, nor does it cause muscle damage.
Bruton et al. (Fri,) studied this question.