Myoplasmic free Mg2+ concentration during repetitive stimulation of single fibres from mouse skeletal muscle.

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Myoplasmic free Mg2+ concentration during repetitive stimulation of single fibres from mouse skeletal muscle.

H Westerblad and D G Allen

Department of Physiology, University of Sydney, NSW, Australia.

1. The role of the myoplasmic free Mg2+ concentration ([Mg2+]i)in fatigue was studied in intact single fibres isolated frommouse skeletal muscle. Fatigue was produced by repeated tetanicstimulation. The fluorescent Mg2+ indicator furaptra was pressureinjected into fibres. In vivo calibrations were performed toconvert fluorescence signals into [Mg2+]i. 2. [Mg2+]i at restwas 0.78 +/- 0.05 mM (mean +/- S.E.M., n = 14). An increaseof the extracellular [Mg2+] from 0.5 to 20 mM resulted in asmall elevation of [Mg2+]i (86 microM in 5 min). Removal ofextracellular Na+ did not affect [Mg2+]i. An intracellular alkanizationof about 0.6 pH units gave a [Mg2+]i reduction of 65 microM.3. During fatiguing stimulation [Mg2+]i initially remained almostconstant and it then suddenly started to rise towards the endof the stimulation period. The onset of the [Mg2+]i rise wasalways followed by a rapid tension decline. In fatigue [Mg2+]iwas approximately twice as high as at rest. 4. Fibres were injectedwith MgCl2 to study if the rise in [Mg2+]i could explain thetension decline in fatigue. An elevation of [Mg2+]i was accompaniedby a tension reduction but the [Mg2+]i for a given tension wasgenerally much higher in rested fibres injected with MgCl2 thanin fatigued fibres. Thus the rise in [Mg2+]i as such cannotexplain the tension reduction in fatigue. 5. Injection of MgCl2was also used to assess the intracellular Mg2+ buffering. Themean Mg2+ buffer power (i.e. the ratio of the change in [Mg2+]ito the amount of Mg2+ added) was 0.62. 6. ATP is the quantitativelymost important binding site for Mg2+ at rest and ATP breakdownis then a likely source of the [Mg2+]i increase in fatigue.The role of ATP breakdown in the increase of [Mg2+]i was studiedwith metabolic inhibition: fibres were exposed to iodoaceticacid to inhibit glycolysis and cyanide to inhibit oxidativephosphorylation. The pattern during metabolic inhibition wassimilar to that observed during fatigue. After remaining almostconstant during a lengthy period, [Mg2+]i rose rapidly and thisrise preceded a period of rapid tension decline. The fibresthereafter went into rigor and [Mg2+]i stabilized at an elevatedlevel; the mean [Mg2+]i increase in rigor was 1.30 mM. 7. Wehave used modelling to determine the likely change in the intracellularATP concentration ([ATP]i) for the observed changes in [Mg2+]i.(ABSTRACTTRUNCATED AT 400 WORDS)

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