Effects of caffeine on the intracellular distribution of calcium in frog sartorius muscle

The influence of caffeine on the intracellular distribution of calcium in the frog sartorius muscle was studied by differential centrifugation in an attempt to identify the locus of action of this alkaloid. The problem was approached in two ways. In the first, the locus of action was sought by relating the kinetic functions of ⁴⁵Ca washout curves of muscles to changes in the distribution of ⁴⁵Ca in the isolated fractions from the same muscles. It was not possible to make any correlation of the ⁴⁵Ca-washout curves to the activity in the fractions; the relative distribution of this nuclide remained essentially unchanged at 1-, 2-, and 3-hour intervals along the curve. The washout curves appear to be the net effect of a complex interaction of the calcium in pools containing both readily exchangeable calcium and calcium which has a slow exchange or turnover rate. The second approach centered upon the examination of the effect of caffeine on the intracellular distribution of ⁴⁵Ca and of calcium among the cellular fractions. Caffeine treatment resulted in a distinct increase in the calcium content of the mitochondrial fraction and a decrease in the calcium of the microsomal fraction. Electron micrographic studies revealed significant morphological changes in the whole muscle and in the isolated mitochondrial fraction after the muscle had been exposed to caffeine in a concentration producing irreversible contracture or rigor (10 mM). The increase in calcium content of the mitochondrial fraction after caffeine treatment may be due to an actual accumulation of calcium by the mitochondria or may be the consequence of the appearance of granular vesicles in the fraction.     

Differential effects of tetracaine on charge movements and Ca2+ signals in frog skeletal muscle

The effects of tetracaine on charge movements and on antipyrylazo III signals monitoring intracellular delta [Ca2+] were compared in cut frog semitendinosus muscle fibers in a single vaseline gap-voltage clamp. Low tetracaine concentrations (25-40 microM) markedly reduced delta [Ca2+] signals and shifted the rheobase. However, they neither influenced charge movement nor that peak delta [Ca2+] value associated with the contractile threshold. Higher tetracaine concentrations (100-200 microM) partly inhibited charge movements in cut fibers. They separated a steeply voltage-sensitive charge, some of whose features resembled 'q gamma' reported in intact fibers, and whose movement preceded delta [Ca2+] signals at threshold. These findings: (a) directly confirm an earlier suggestion that tetracaine acts on steps in excitation-contraction coupling rather than myofilament activation; (b) show that tetracaine at low concentrations can directly interfere with sarcoplasmic reticular calcium release without modifying charge movement; (c) show that the tetracaine-sensitive charge, first found in intact fibers, also exists in cut fibers; and (d) make it unlikely that tetracaine-sensitive charge transfer is a consequence of Ca2+ release as suggested on earlier occasions.     

Local movement in stimulated frog sartorius muscle

Local movement was recorded in tetanically contracting frog sartorius muscle to estimate the nonuniformity in the distribution of compliance in the muscle preparation and the compliance that resides in the attachments of the preparation to the measuring apparatus. The stimulated muscle was also subjected to rapid length changes, and the local movements and tension responses were recorded. The results indicate that during tension development at resting length the central region of the muscle shortens at the expense of the ends. After stimulation the "shoulder" in the tension, which divided the relaxation into a slow decline and a subsequent, rather exponential decay toward zero, was accompanied by an abrupt increase in local movement. We also examined the temperature sensitivity of the two phases of relaxation. The results are consistent with the view that the decrease in tension during relaxation depends on mechanical conditions. The local movement brought about by the imposed length changes indicates that the peak value of the relative length change of the uniformly acting part was approximately 20% less than the relative length change of the whole preparation. From these observations, corrections were obtained for the compliance data derived from the tension responses. These corrections allow a comparison with data in the literature obtained from single fiber preparations. The implications for the stiffness measured during the tension responses are discussed.     

Intracellular pH of frog sartorius muscle

A weak base, morpholine, has been labelled with ³H and tested for its suitability as an indicator for intracellular pH, by distribution in the tissue water of frog sartorius muscle in the species Hyla litoria. Its pK'a at 20°C in a solution of the same of ionic strength as frog Ringer was found to be 8.45 ± 0.02, which is in the range of maximal sensitivity. Morpholine equilibrated with the tissue in 17 h; it was shown that it was not bound to intracellular constituents, that it was not metabolised nor toxic in the concentrations used; it was therefore judged suitable as a pH indicator. Intracellular pH was then measured by distribution of morpholine (6.985 ± 0.08), nicotine (6.915 ± 0.03) and the weak acid 5,5′-dimethyl-2,4-oxazolidinedione (7.10 ± 0.05) and with pH-sensitive microelectrodes (5.9, the equilibrium value). It was shown that the four significantly different values could not be reconciled in terms of experimental error, heterogeneity of intracellular pH, liquid junction potential differences, or binding of indicator molecules inside the fibre. They could, however, be reconciled if the fibre water had different structure and solvent properties from the extracellular water and ions were distributed across the membrane as between two liquid phases containing different solvents. Then the H⁺ would be in equilibrium, as shown by the microelectrode measurement, but intracellular pH would be indeterminable and probably greater than 6.     

Satellite and invasive cells in frog sartorius muscle

The occurrence and distribution of two cell types associated with normal and denervated frog skeletal muscle fibers are described. The first is the satellite cell. The general appearance and the number of satellite cells are not affected by long-term denervation. The second type of cell is the invasive cell. Invasive cells penetrate across the basal lamina and up to the core of the muscle fiber, without fusing with it. It is suggested that the origin of invasive cells is extramuscular, probably circulatory. Although invasive cells are more numerous in some denervated muscle, it is established that this is not a direct effect of denervation.     

The effects of pH on the kinetics of fatigue and recovery in frog sartorius muscle

The effects of pH on the kinetics of fatigue and recovery in frog sartorius muscle were studied to establish whether the pH to which muscles are exposed (extracellular pH) has an effect on both the rate of fatigue development and recovery from fatigue. When frog sartorius muscles were stimulated with short tetanic stimuli at rates varying from 0.2 to 2.0 trains/s, a time- and frequency-dependent decrease in force development was observed, but extracellular pH had comparatively little effect. The recovery of tetanic force was dependent on the extracellular pH. This effect was characterized by a rapid recovery in force at pH 8.0 and an inhibition of recovery at pH 6.4 even when force decreased by only 25% during stimulation. Even when muscles were fatigued at pH 8.0 the rate of force recovery was still very small at pH 6.4. A model is proposed in which a step of the contraction cycle changes from a normal to a fatigued state. The rate of this transition is a function of the stimulation frequency and not pH. The reverse transition, from a fatigued to normal state is pH dependent; i.e., it is inhibited by H+. Measurements of resting and action potentials show that extracellular pH influences these parameters in the fatigue state, but there is no evidence that these changes are directly responsible for the pH-dependent step in the reversal of fatigue.     

Regulatory effects of ATP and calcium on the myofibrillar ATPase of frog sartorius muscle

The ATPase activity of frog sartorius myofibrils has been studied at 1.5°C using different concentrations of ATP and calcium. The progressive activation of the ATPase activity at Ca-concentrations between pCa 8 and pCa 4 is paralleled by increases in Ca-binding. Similar to the findings of Weber and Bremel (1972) on rabbit psoas myofibrils more calcium is bound at pCa 5 – 7 in presence of 10 μM ATP than at 2 mM ATP. The observation, that in presence of 2 mμM N-ethyl maleimide/mg myofibrillar protein Ca-binding is essentially abolished at the lower calcium levels and becomes reduced by 30 – 40% at pCa 4 – 6, has been explained in terms of a Ca-binding site on the myosin. Using carbon-14-labelled ATP it could be demonstrated that the lower ATPase activity at pCa 7 or pCa 9 is associated with an increase in nucleotide binding, which is much reduced at a pCa of 4. However, removal of calcium from the medium does not increase the number of nucleotide binding sites as has been reported for rabbit myofibrils. A kinetic interpretation of the ATPase and ligand binding studies is offered.     

Intracellular pH of frog sartorius muscle.

A weak base, morpholine, has been labelled with 3H and tested for its suitability as an indicator for intracellular pH, by distribution in the tissue water of frog sartorius muscle in the species Hyla litoria. Its pK'a at 20 degrees C in a solution of the same ionic strength as frog Ringer was found to be 8.45 +/- 0.02, which is in the range of maximal sensitivity. Morpholine equilibrated with the tissue in 17 h; it was shown that it was not bound to intracellular constituents, that it was not metabolised nor toxic in the concentrations used; it was therefore judged suitable as a pH indcator. Intracellular pH was then measured by distribution of morpholine (6.985 +/- 0.08), nicotine (6.915 +/- 0.03) and the weak acid 5,5'-dimethyl-2,4-oxazolidinedione (7.10 +/- 0.05) and the pH-sensitive microelectrodes (5.9, the equilibrium value). It was shown that the four significantly different values could not be reconciled in terms of experimental error, heterogeneity of intracellular pH, liquid junction potential differences, or binding of indicator molecules inside the fibre. They could, however, be reconciled if the fibre water had different structure and solvent properties from the extracellular water and all ions were distributed across the membrane as between two liquid phases containing different solvents. Then the H+ would be in equilibrium, as shown by the microelectrode measurement, but intracellular pH would be indeterminable and probably greater than 6.     

Effect of length and caffeine on isometric tetanus relaxation of frog sartorius muscles

In an isometric tetanus of frog sartorius muscle the total relaxation time increased linearly with change in length from 0.7 to 1.4 times rest length. Maximal rate of relaxation, measured from the time derivative (dp/dt) of tension decay, decreased with both decrease and increase from rest length in correlation with the generated tetanus tension. Stretching the muscle did not significantly affect the times to maximal rate, positive and negative inflexion points but greatly increased the time to total relaxation from the negative inflexion point. Caffeine at 2 mM, acting on muscles at rest length, also slowed the relaxation and decreased the maximal rate of tension decay. However, caffeine increased the times to maximal rate, positive and negative inflexion points without significantly affecting time to total relaxation from the negative inflexion point. These results suggest that caffeine slows an earlier step in relaxation, while stretch slows a later step. It is proposed that muscle relaxation is a two step process: an initial step that is regulated by the rate of Ca2+ uptake by sarcoplasmic reticulum, and a later step that is mostly controlled by the speed of dissociation of remaining cross-bridges.     

K+ depolarization and phospholipid metabolism in frog sartorius muscle

K+ depolarization evokes phosphatidylinositol response, i.e. the increased 32P orthophosphate labelling of phosphatidylinositol in frog sartorii muscles. The phosphatidylinositol response seems to be closely related to K+ depolarization and not to the transient Ca2+ release at the beginning of depolarization. It ceases as soon as the muscles depolarized by 90 mmol/l KCl for a short period of time are repolarized, while it continues when the depolarization is maintained. When the muscles are depolarized with 20 mmol/l KCl, the phosphatidylinositol response is also observed. This response is not suppressed by drugs that block Ca2+ mobilization. Other agents like caffeine, azide or EGTA which induce some effects similar to that of K+ depolarization, do not evoke phosphatidylinositol response. Rather, they simply cause a decrease in the labelling of phospholipids, phosphatidylinositol being the least affected. In muscles derived from frogs maintained under healthy conditions Ca2+ release in the early phase of K+ depolarization does not cause significant changes in phospholipid labelling. However, in muscles from frogs starving for many months, a large decrease in the labelling of phospholipids is observed in the early phase of K+ depolarization. It is postulated that the changes in the physicochemical state of the membrane and not Ca2+ gating mechanism or free cell Ca2+ level are crucial in the phosphatidylinositol response in the frog sartorii muscles depolarized by high K+.     

Series elasticity in frog sartorius muscle during release and stretch

When a stretch is applied to an isolated muscle during tetanic stimulation, the force developed is higher than the maximal isometric tension (Po). This force puts the series elastic component (SEC) under tension and in a domain which is not well defined in terms of tension-extension curve. In the present work, an attempt was made to determine the stiffness of the SEC for tensions greater than Po, using the sartorius muscle of the frog. For this purpose, rapid releases and stretches of different amplitudes were given during maximal isometric contractions. Plotting normalized tension (P/Po) against normalized length changes (negative or positive extensions, delta L/Lo.10(2] produced a tension-extension curve. The slopes of the linear part of each relationship on both sides of Po indicated an increase in SEC stiffness when the muscle was rapidly stretched. Furthermore, the transient character of the increase in stiffness was studied by measuring SEC stiffness during rapid releases applied at various time intervals after stretches: the muscle was found to be stiffer as the time interval was shorter. The results are discussed in terms of (i) non-linear behaviour of the passive and active parts of the SEC, (ii) enhancement of storage and release of potential energy.