The effect of low-level activation on the mechanical properties of isolated frog muscle fibers

The mechanical properties, as revealed by minute length changes, of isolated twitch fibers of the frog have been studied at rest and during low-level activation. Resting tension is 77 ± 23 mN/cm² (mean ± SD) at 2.2 µm sarcomere length.¹ The slope of the tension curve (ΔP/ΔL) recorded during a constant-speed length change of a resting fiber is initially large. At length changes exceeding about 0.18 % of the initial length of the fiber ΔP/ΔL falls abruptly and remains close to zero during the rest of the length change. The amplitude of the tension response is reduced after a length change and returns to normal in about 3 min. Hypertonic sucrose-Ringer solutions cause a small, maintained rise in tension up to 1.4–1.6 times normal osmotic strength. Higher sucrose concentrations cause relatively large, transient tension responses. The initial ΔP/ΔL is increased in moderately hypertonic solutions; it may be reduced in more strongly hypertonic solutions. Elevated [K]_o (range 10–17.5 mM) causes a marked reduction in ΔP/ΔL. In this range of [K]_o the reduction is not accompanied by changes in resting tension. Addition of 1–1.5 mM caffeine to the Ringer solution affects the resting tension very little but also reduces ΔP/ΔL. The results suggest that stiffness and tension development are not related in a simple way.     

Actions of some cations on the electrical properties and mechanical threshold of frog sartorius muscle fibers

With the use of a point voltage-clamp technique, the effects of Zn²⁺, UO₂ ²⁺, tetraethylammonium, and several other homologous quaternary ammonium ions on the electrical properties of the frog sartorius muscle and its mechanical threshold were studied. None of the agents separated the voltage thresholds for mechanical activation and delayed rectification. However, Zn²⁺, UO₂ ²⁺, and TEA, which are known to potentiate the twitch, caused some inhibition of the normal increase in potassium conductance during delayed rectification. Zn²⁺ and UO₂ ²⁺ also slowed the rate of development of the outward current. A strength-duration relation was studied for depolarization pulses capable of initiating contraction. With a depolarizing pulse of 2.5 msec the mechanical threshold is about -13 mv at about 20°C. UO₂ ²⁺, 0.5 µM, which markedly reduced the outward current produced by such a short pulse, did not raise the mechanical threshold. All findings indicate that there is no direct causal relation between delayed rectification and mechanical activation.     

Effect of tetraethylammonium ions on electrical activity of the isolated frog muscle spindle

Changes in electrical activity of the isolated frog muscle spindle in Ringer's solution containing tetraethylammonium (TEA) ions were studied. An increase in the frequency of spontaneour activity was observed, but with continued perfusion with TEA solution both spontaneous afferent impulses and action potentials generated during stretching of the muscle receptor were blocked. The dynamic component of the depolarization phase of the receptor potential was reduced in amplitude and increased in duration. Rinsing the receptor in normal physiological saline did not restore its responses completely.Institute of Physiology, Leningrad State University. Translated from Neirofiziologiya, Vol. 4, No. 2, pp. 208–215, March–April, 1972.     

The dual effect of rubidium ions on potassium efflux in depolarized frog skeletal muscle

Summary The effects of external Rb⁺ on the efflux of⁴²K⁺ from whole frog sartorius muscles loaded with 305mm K⁺ and 120mm Cl^– were studied. K⁺ efflux is activated by [Rb⁺] _o less than about 40mm according to a sigmoid relation similar to that for activation by [K⁺] _o . At [Rb⁺]_o greater than 40mm, K⁺ efflux declines, although at [Rb⁺] _o =300mm it is still greater than at [Rb⁺] _o =0mm. For low concentrations, the increment in K⁺ efflux over that in K⁺- and Rb⁺-free solution, k, is described by the relation k=a[X⁺] _o ⁿ , for both K⁺ and Rb⁺. The value ofa is larger for Rb⁺ than for K⁺, while the values ofn are similar; the activation produced by a given [Rb⁺] _o is larger than that by an equal [K⁺] _o for concentrations less than about 40mm. Adding a small amount of Rb⁺ to a K⁺-containing solution has effects on K⁺ efflux which depend on [K⁺] _o . At low [K⁺] _o , adding Rb⁺ increases K⁺ efflux, the effect being greatest near [K⁺] _o =30mm and declining at higher [K⁺] _o ; at [K⁺] _o above 40mm, addition of Rb⁺ decreases K⁺ efflux. At [K⁺] _o above 75mm, where K⁺ efflux is largely activated, Rb⁺ reduces K⁺ efflux by a factorb, described by the relationb=1/(1+c[Rb⁺] _o ). Activation is discussed in terms of binding to at least two sites in the membrane, and the reduction in K⁺ efflux by Rb⁺ at high [K⁺] _o in terms of association with an additional inhibitory site.     

The effect of polyphosphates and magnesium on the mechanical properties of extracted muscle fibers

Loading of extracted muscle fibers causes a small, sudden lengthening, followed by a slower, plastic extension, which is reversed only by active contraction. Polyphosphates in the presence of Mg strongly accelerate plastic extension, but elastic changes in length remain the same as during rigor. The modulus of elasticity on the average is about 6.2 x 10⁷ dynes per cm.² This value is about 40 times larger than that of rubber, if compared on a water-free basis. Extension of muscle, therefore, is almost entirely due to plastic deformation. Mg is essential for the softening action of adenosinetriphosphate (ATP) and can produce partial relaxation in the absence of a relaxation factor. After partial removal of bound Mg, ATP causes strong contraction, but only slight softening. The same condition is produced by very low concentrations of ATP in the presence of phosphocreatine. These observations show that during contraction passive mechanical properties may remain essentially like those during rigor. The constancy of elastic extensibility distinguishes contraction produced by ATP from contraction induced by non-specific agents in various fibrous structures and caused by an increase in configurational entropy.     

The effect of the ionophore A23187 on the ultrastructure and electrophysiological properties of frog skeletal muscle

Summary The divalent cation ionophore A23187 has three major effects on the thin cutaneous pectoris muscle of frog: (1) The membrane potential is depolarized, an action that is found only when the [Ca²⁺] of the bathing saline is very low. (2) It causes an increase in resting tension and the development of contraction. This action is produced at both normal and low values of [Ca²⁺]_o and is, therefore, independent of Ca²⁺ entry and of changes in E_m. The ionophore is believed to act primarily by releasing Ca²⁺ from intracellular stores. (3) It causes major ultrastructural damage to the muscle filaments. It is believed that this damage is the result of the action of A23187 on the sarcoplasmic reticulum and the elevation of [Ca²⁺]_i and we suggest that the action of this ionophore may serve as a useful model for the study of certain myopathies.     

The effects of the antibiotics gramicidina,amphotericin B,and nystatin on the electrical properties of frog skeletal muscle

The antibiotics gramicidin A, amphotericin B, and nystatin drastically decrease the membrane resistance of frog skeletal muscle fibers without changing the total capacitance. The resting potential of muscle fibers treated with these antibiotics is essentially normal if the Ringer solution does not contain Na⁺.     

Acontine-induced repetitive firing in frog skeletal muscle and the effect on cable properties

The repetitive firing in curarized frog sartorius muscle caused by aconitine was found to be associated with a dose-dependent membrane depolarization and a decrease in membrane resistance (R_m). Shortly after aconitine treatment, when repetitive discharges began to occur spontaneously in a few fibers (the pre-burst state), the muscle fibers were hypersensitive to mechanical and electrical stimulation. After a repetitive discharge (the post-burst state), the membrane potential fell to the 40–50 mV range. Cable measurements demonstrated that R_m decreased by 27% in the pre-burst state and by 47% in the post-burst state. Substitution of choline for sodium in the post-burst state restored the membrane potential to normal and raised the R_m toward the control level. It is proposed that aconitine's production of repetitive discharges in skeletal muscle is partly the result of maintaining the sodium conductance g_Na at a higher-than-normal level once excitation has been initiated.     

The electrical and mechanical properties of the proleg retractor muscle of the Chinese oak silkmoth larva

ABSTRACT. The main proleg retractor muscle (y) of Antheraea pernyi Guer. (Lepidoptera, Saturniidae) larvae consists of three layers of fibres. The innermost layer of fibres is dually innervated. Cobalt backfills of the two motor neurones, in nerve 2d, showed the somata to be situated ventrally and anteriorly in the same segmental ganglion, ipsilateral to the filled nerve. Intramuscular microelectrode recordings showed excitatory junction potentials (EJPs) of two distinct amplitudes, both of which were relatively slow. However, 26% of the larger amplitude EJPs had an active membrane response. The EJPs and mechanical responses both summated at low stimulation frequencies. Large EJPs resulted in a much greater development of tension than small ones. Extracellular stimulation of nerve lbiii modulated peak tension and peak rate of relaxation.     

Effect of ryanodine on the electrical and mechanical activity of frog atrial fibers

The effect of ryanodine on the action potential, slow inward current and mechanical activities of frog atrial fibres was studied by means of the double sucrose gap technique. Ryanodine was shown to reduce the amplitude of the slow inward current, to cause an intracellular Ca accumulation and to decrease the tonic component of the tension.