Calcium and potassium systems of a giant barnacle muscle fibre under membrane potential control

Modeling cholinergic retinal waves: starburst amacrine cells shape wave generation, propagation, and direction bias

Stage II cholinergic retinal waves are one of the first instances of neural activity in the visual system as they are present at a developmental timepoint in which light-evoked activity remains largely undetectable. These waves of spontaneous neural activity sweeping across the developing retina are generated by starburst amacrine cells, depolarize retinal ganglion cells, and drive the refinement of retinofugal projections to numerous visual centers in the brain. Building from several well-established models, we assemble a spatial computational model of starburst amacrine cell-mediated wave generation and wave propagation that includes three significant advancements. First, we model the intrinsic spontaneous bursting of the starburst amacrine cells, including the slow afterhyperpolarization, which shapes the stochastic process of wave generation. Second, we establish a mechanism of wave propagation using reciprocal acetylcholine release, synchronizing the bursting activity of neighboring starburst amacrine cells. Third, we model the additional starburst amacrine cell release of GABA, changing the spatial propagation of retinal waves and in certain instances, the directional bias of the retinal wave front. In total, these advancements comprise a now more comprehensive model of wave generation, propagation, and direction bias.

The formation mechanism of defects, spiral wave in the network of neurons

A regular network of neurons is constructed by using the Morris-Lecar (ML) neuron with the ion channels being considered, and the potential mechnism of the formation of a spiral wave is investigated in detail. Several spiral waves are initiated by blocking the target wave with artificial defects and/or partial blocking (poisoning) in ion channels. Furthermore, possible conditions for spiral wave formation and the effect of partial channel blocking are discussed completely. Our results are summarized as follows. 1) The emergence of a target wave depends on the transmembrane currents with diversity, which mapped from the external forcing current and this kind of diversity is associated with spatial heterogeneity in the media. 2) Distinct spiral wave could be induced to occupy the network when the target wave is broken by partially blocking the ion channels of a fraction of neurons (local poisoned area), and these generated spiral waves are similar with the spiral waves induced by artificial defects. It is confirmed that partial channel blocking of some neurons in the network could play a similar role in breaking a target wave as do artificial defects; 3) Channel noise and additive Gaussian white noise are also considered, and it is confirmed that spiral waves are also induced in the network in the presence of noise. According to the results mentioned above, we conclude that appropriate poisoning in ion channels of neurons in the network acts as ‘defects’ on the evolution of the spatiotemporal pattern, and accounts for the emergence of a spiral wave in the network of neurons. These results could be helpful to understand the potential cause of the formation and development of spiral waves in the cortex of a neuronal system.

Voltage clamp methods for the study of membrane currents and SR Ca(2+) release in adult skeletal muscle fibres

Skeletal muscle excitation-contraction (E-C)(1) coupling is a process composed of multiple sequential stages, by which an action potential triggers sarcoplasmic reticulum (SR)(2) Ca(2+) release and subsequent contractile activation. The various steps in the E-C coupling process in skeletal muscle can be studied using different techniques. The simultaneous recordings of sarcolemmal electrical signals and the accompanying elevation in myoplasmic Ca(2+), due to depolarization-initiated SR Ca(2+) release in skeletal muscle fibres, have been useful to obtain a better understanding of muscle function. In studying the origin and mechanism of voltage dependency of E-C coupling a variety of different techniques have been used to control the voltage in adult skeletal fibres. Pioneering work in muscles isolated from amphibians or crustaceans used microelectrodes or 'high resistance gap' techniques to manipulate the voltage in the muscle fibres. The development of the patch clamp technique and its variant, the whole-cell clamp configuration that facilitates the manipulation of the intracellular environment, allowed the use of the voltage clamp techniques in different cell types, including skeletal muscle fibres. The aim of this article is to present an historical perspective of the voltage clamp methods used to study skeletal muscle E-C coupling as well as to describe the current status of using the whole-cell patch clamp technique in studies in which the electrical and Ca(2+) signalling properties of mouse skeletal muscle membranes are being investigated.

Identification and continuity of the distributions of burst-length and interspike intervals in the stochastic Morris-Lecar neuron

Using the Morris-Lecar model neuron with a type II parameter set and K(+)-channel noise, we investigate the interspike interval distribution as increasing levels of applied current drive the model through a subcritical Hopf bifurcation. Our goal is to provide a quantitative description of the distributions associated with spiking as a function of applied current. The model generates bursty spiking behavior with sequences of random numbers of spikes (bursts) separated by interburst intervals of random length. This kind of spiking behavior is found in many places in the nervous system, most notably, perhaps, in stuttering inhibitory interneurons in cortex. Here we show several practical and inviting aspects of this model, combining analysis of the stochastic dynamics of the model with estimation based on simulations. We show that the parameter of the exponential tail of the interspike interval distribution is in fact continuous over the entire range of plausible applied current, regardless of the bifurcations in the phase portrait of the model. Further, we show that the spike sequence length, apparently studied for the first time here, has a geometric distribution whose associated parameter is continuous as a function of applied current over the entire input range. Hence, this model is applicable over a much wider range of applied current than has been thought.

Calcium dependence of the inactivation of calcium currents in skeletal muscle fibers of an insect

Calcium currents in skeletal muscle fibers of an insect, Carausius morosus, inactivate under depolarization. This inactivation depends on the current being carried across the membrane by calcium ions, rather than strontium or bariumions.

A disturbance of nonlinear interdependence in scalp EEG of subjects with first episode schizophrenia

It has been proposed that schizophrenia arises through a disturbance of coupling between large-scale cortical systems. This "disconnection hypothesis" is tested by applying a measure of dynamical interdependence to scalp EEG data. EEG data were collected from 40 subjects with a first episode of schizophrenia and 40 matched healthy controls. An algorithm for the detection of dynamical interdependence was applied to six pairs of bipolar electrodes in each subject. The topographic organization of the interdependence was calculated and served as the principle measure of cortical integration. The rate of occurrence of dynamical interdependence did not statistically differ between subject groups at any of the sites. However, the topography across the scalp was significantly different between the two groups. Specifically, nonlinear interdependence tended to occur in larger concurrent "clusters" across the scalp in schizophrenia than in the healthy subjects. This disturbance was reflected most strongly in left intrahemispheric coupling and did not differ significantly according to symptomatology. Medication dose and subject arousal were not observed to be confounding factors. The study of dynamical interdependence in scalp EEG data does not support a straightforward interpretation of the disconnection hypothesis-that there is a decrease in the strength of functional coupling between adjacent cortical regions. Rather, it suggests a dysregulation in the organization of dynamical interactions across supraregional brain systems.

Tubular localization of silent calcium channels in crustacean skeletal muscle fibers

Ca2+-induced Ca2+ release (CICR) in the superficial abdominal flexor muscle of the crustacean Atya lanipes appears to be mediated by a local control mechanism similar to that of vertebrate cardiac muscle, but with an unusually high gain. Thus, Ca2+ influx increases sufficiently the local concentration of Ca2+ in the immediate vicinity of the sarcoplasmic reticulum Ca2+ release channels to trigger the highly amplified release of Ca2+ required for contraction, but is too low to generate a macroscopic inward current (i.e., the Ca2+ channels are silent). To determine the localization of the silent Ca2+ Channels, the mechanical, electrophysiological and ultrastructural properties of the muscle were examined before and after formamide treatment, a procedure that produces the disruption of transverse tubules of striated muscle. We found that tubular disruption decreased tension generation by about 90%; reduced inward current (measured as Vmax, the maximum rate of rise of Sr2+ action potentials) by about 80%; and decreased membrane capacitance by about 77%. The results suggest that ca. 80% of the silent Ca2+ channels are located in the tubular system. Thus, these studies provide further evidence to support the local control mechanism of CICR in crustacean skeletal muscle.

Voltage-clamp analysis of membrane currents and excitation-contraction coupling in a crustacean muscle

A single fibre preparation from the extensor muscle of a marine isopod crustacean is described which allows the analysis of membrane currents and simultaneously recorded contractions under two-electrode voltage-clamp conditions. We show that there are three main depolarisation-gated currents, two are outward and carried by K+, the third is an inward Ca2+ current, I(Ca). Normally, the K+ currents which can be isolated by using K+ channel blockers, mask I(Ca). I(Ca) activates at potentials more positive than -40 mV, is maximal around 0 mV, and shows strong inactivation at higher depolarisation. Inactivation depends on current rather than voltage. Ba2+, Sr2+ and Mg2+ can substitute for Ca2+. Ba2+ currents are about 80% larger than Ca2+ currents and inactivate little. The properties of I(Ca) characterise it as a high threshold L-type current. The outward current consists primarily of a fast, transient A current, I(K(A)) and a maintained, delayed rectifier current, I(K(V)). In some fibres, a small Ca2+-dependent K+ current is also present. I(K(A)) activates fast at depolarisation above -45 mV, shows pronounced inactivation and is almost completely inactivated at holding potentials more positive than -40 mV. I(K(A)) is half-maximally blocked by 70 microM 4-aminopyridine (4-AP), and 70 mM tetraethylammonium (TEA). I(K(V)) activates more slowly, at about -30 mV, and shows no inactivation. It is half-maximally blocked by 2 mM TEA but rather insensitive to 4-AP. Physiologically, the two K+ currents prevent all-or-nothing action potentials and determine the graded amplitude of active electrical responses and associated contractions. Tension development depends on and is correlated with depolarisation-induced Ca2+ influx mediated by I(Ca). The voltage dependence of peak tension corresponds directly to the voltage dependence of the integrated I(Ca). The threshold potential for contraction is at about -38 mV. Peak tension increases with increasing voltage steps, reaches maximum at around 0 mV, and declines with further depolarisation.

Detection and description of non-linear interdependence in normal multichannel human EEG data

OBJECTIVES

This study examines human scalp electroencephalographic (EEG) data for evidence of non-linear interdependence between posterior channels. The spectral and phase properties of those epochs of EEG exhibiting non-linear interdependence are studied.

METHODS

Scalp EEG data was collected from 40 healthy subjects. A technique for the detection of non-linear interdependence was applied to 2.048 s segments of posterior bipolar electrode data. Amplitude-adjusted phase-randomized surrogate data was used to statistically determine which EEG epochs exhibited non-linear interdependence.

RESULTS

Statistically significant evidence of non-linear interactions were evident in 2.9% (eyes open) to 4.8% (eyes closed) of the epochs. In the eyes-open recordings, these epochs exhibited a peak in the spectral and cross-spectral density functions at about 10 Hz. Two types of EEG epochs are evident in the eyes-closed recordings; one type exhibits a peak in the spectral density and cross-spectrum at 8 Hz. The other type has increased spectral and cross-spectral power across faster frequencies. Epochs identified as exhibiting non-linear interdependence display a tendency towards phase interdependencies across and between a broad range of frequencies.

CONCLUSIONS

Non-linear interdependence is detectable in a small number of multichannel EEG epochs, and makes a contribution to the alpha rhythm. Non-linear interdependence produces spatially distributed activity that exhibits phase synchronization between oscillations present at different frequencies. The possible physiological significance of these findings are discussed with reference to the dynamical properties of neural systems and the role of synchronous activity in the neocortex.

Contribution of presynaptic calcium-activated potassium currents to transmitter release regulation in cultured Xenopus nerve-muscle synapses

Using Xenopus nerve-muscle co-cultures, we have examined the contribution of calcium-activated potassium (K(Ca)) channels to the regulation of transmitter release evoked by single action potentials. The presynaptic varicosities that form on muscle cells in these cultures were studied directly using patch-clamp recording techniques. In these developing synapses, blockade of K(Ca) channels with iberiotoxin or charybdotoxin decreased transmitter release by an average of 35%. This effect would be expected to be caused by changes in the late phases of action potential repolarization. We hypothesize that these changes are due to a reduction in the driving force for calcium that is normally enhanced by the local hyperpolarization at the active zone caused by potassium current through the K(Ca) channels that co-localize with calcium channels. In support of this hypothesis, we have shown that when action potential waveforms were used as voltage-clamp commands to elicit calcium current in varicosities, peak calcium current was reduced only when these waveforms were broadened beginning when action potential repolarization was 20% complete. In contrast to peak calcium current, total calcium influx was consistently increased following action potential broadening. A model, based on previously reported properties of ion channels, faithfully reproduced predicted effects on action potential repolarization and calcium currents. From these data, we suggest that the large-conductance K(Ca) channels expressed at presynaptic varicosities regulate transmitter release magnitude during single action potentials by altering the rate of action potential repolarization, and thus the magnitude of peak calcium current.

Effects of fatigue of rat EDL in situ on metabolism of phosphoinositides

The study was conducted to determine the effect of persistent fatigue in situ on the inositol phosphate second messenger system proposed to constitute a step in excitation-contraction coupling. Rat EDL, after stimulation in situ for 1 hr (100 Hz for 330 ms, 1/s), showed increased incorporation of myo-[3H]inositol into membrane phosphoinositides during a subsequent 4-h incubation period. The rate of hydrolysis of this pool resulting from 10 sec of tetanic stimulation, as well as the rate of production of inositol phosphates InsP, InsP2, and InsP3, were significantly reduced in fatigued muscles. These results suggest that the metabolic changes that parallel the alteration in contractile response with fatigue reflect a disruption in E-C coupling.

Properties of the ryanodine receptor present in the sarcoplasmic reticulum from lobster skeletal muscle

Microsomal sarcoplasmic reticulum (SR) fractions from lobster skeletal muscle were found to bind [3H]-ryanodine. [3H]-ryanodine binding was enhanced by AMP, Ca2+ and caffeine, and significantly diminished by ATP, Ba2+ and Sr2+. Furthermore, dantrolene and ruthenium red, two classical inhibitors of Ca2+ release from the SR, blocked [3H]-ryanodine binding. Similarly, tetracaine, known to block the charge movement associated with excitation-contraction coupling in vertebrate muscle, inhibited the binding of the alkaloid. Our lobster SR preparation exhibited a single high-affinity ryanodine binding site (Kd = 6.6 nM, Bmax = 10 pmol/mg protein). Since SDS-PAGE of the SR proteins revealed a major band c. 565 kDa which comigrated with the putative ryanodine receptor from both rat and chicken skeletal muscle, we concluded that lobster skeletal muscle is equipped with the 565 kDa ryanodine receptor. Finally, incorporation of the SR microsomal fraction from lobster into planar bilayer membranes revealed the presence of a ryanodine-sensitive Ca2+ channel activity (160 pS in symmetrical 200 mM CsCl solutions). We concluded that both the crustacean and vertebrate skeletal muscle ryanodine receptor share the relevant properties such as molecular weight and affinity for ryanodine and inositol 1,4,5 triphosphate. However, there are important differences between the two receptors including differential effects of the alkaloid on the Ca2+ release channel and modulation of the receptor by nucleotides.

Voltage-dependent calcium and potassium conductances in striated muscle fibers from the scorpion, Centruroides sculpturatus

Ionic currents responsible for the action potential in scorpion muscle fibers were characterized using a three-intracellular microelectrode voltage clamp applied at the fiber ends (8-12 degrees C). Large calcium currents (ICa) trigger contractile activation in physiological saline (5 mM Ca) but can be studied in the absence of contractile activation in a low Ca saline (< or = 2.5 mM). Barium (Ba) ions (1.5-3 mM) support inward current but not contractile activation. Ca conductance kinetics are fast (time constant of 3 msec at 0 mV) and very voltage dependent, with steady-state conductance increasing e-fold in approximately 4 mV. Half-activation occurs at -25 mV. Neither ICa nor IBa show rapid inactivation, but a slow, voltage-dependent inactivation eliminates ICa at voltages positive to -40 mV. Kinetically, scorpion channels are more similar to L-type Ca channels in vertebrate cardiac muscle than to those in skeletal muscle. Outward K currents turn on more slowly and with a longer delay than do Ca currents, and K conductance rises less steeply with voltage (e-fold change in 10 mV; half-maximal level at 0 mV). K channels are blocked by externally applied tetraethylammonium and 3,4 diaminopyridine.

Phosphoinositides in giant barnacle muscle fibers: a quantitative analysis at rest and following electrical stimulation

Quantitative data are presented on the composition of the major phospholipids in isolated giant barnacle muscle fibers. It is shown, using internal perfusion techniques, that the high specific activity of labeling of polyphosphoinositides in vivo is attained by the activities of specific kinases. Electrical stimulation causes a reduction in the specific activity of labeling of PtdInsP2. This phospholipid, which is the immediate precursor for the release of InsP3, is found at a significant concentration (40 nmol/g wet weight) in single barnacle muscle fibers, sufficient to support a role as precursors of second messengers. The rapid catabolization of PtdInsP2 in the absence of external Ca2+ suggests that E-C coupling in barnacle muscle may be associated with a voltage-dependent, Ca(2+)-independent, activation of the breakdown of polyphosphoinositides.

Barnacle muscle: Ca2+, activation and mechanics

In this review, aspects of the ways in which Ca2+ is transported and regulated within muscle cells have been considered, with particular reference to crustacean muscle fibres. The large size of these fibres permits easy access to the internal environment of the cell, allowing it to be altered by microinjection or microperfusion. At rest, Ca2+ is not in equilibrium across the cell membrane, it enters the cell down a steep electrochemical gradient. The free [Ca2+] at rest is maintained at a value close to 200 nM by a combination of internal buffering systems, mainly the SR, mitochondria, and the fixed and diffusible Ca(2+)-binding proteins, as well as by an energy-dependent extrusion system operating across the external cell membrane. This system relies upon the inward movement of Na+ down its own electrochemical gradient to provide the energy for the extrusion of Ca2+ ions. As a result of electrical excitation, voltage-sensitive channels for Ca2+ are activated and permit Ca2+ to enter the cell more rapidly than at rest. It has been possible to determine both the amount of Ca2+ entering by this step, and what part this externally derived Ca2+ plays in the development of force as well as in the free Ca2+ change. The latter can be determined directly by Ca(2+)-sensitive indicators introduced into the cell sarcoplasm. A combination of techniques, allowing both the total and free Ca2+ changes to be assessed during electrical excitation, has provided valuable information as to how muscle cells buffer their Ca2+ in order to regulate the extent of the change in the free Ca2+ concentration. The data indicate that the entering Ca2+ can only make a small direct contribution to the force developed by the cell. The implication here is that the major source of Ca2+ for contraction must be derived from the internal Ca2+ storage sites within the SR system, a view reinforced by caged Ca2+ methods. The ability to measure the free Ca2+ concentration changes within a single cell during activation has also provided the opportunity to analyse, in detail, the likely relations between free Ca2+ and the process of force development in muscle. The fact that the free Ca2+ change precedes the development of force implies that there are delays in the mechanism, either at the site of Ca2+ attachment on the myofibril, or at some later stage in the process of force development that were not previously anticipated.(ABSTRACT TRUNCATED AT 400 WORDS)

Sulfhydryl alkylating agents induce calcium current in skeletal muscle fibers of a crustacean (Atya lanipes)

Voltage-clamp experiments using the three-microelectrode voltage clamp technique were performed on ventroabdominal flexor muscles of the crustacean Atya lanipes. Potassium and chloride currents were found to underlie the normal, passive response of the muscle. Blocking potassium currents with tetraethylammonium and replacing chloride ions with methanesulfonate did not unmask an inward current. By treating the muscle with the sulfhydryl-alkylating agent 4-cyclopentene-1,3-dione an inward current was detected. The current induced by the agent is carried by Ca2+, since it is abolished in Ca(2+)-free solutions. The induced Ca2+ current is detected at about -40 mV and reaches a mean maximum value of -78 microA/cm2 at ca. -10 mV. At this potential the time to peak is close to 15 msec. The induced Ca2+ current inactivated with 1-sec prepulses which did not elicit detectable Ca2+ current; the fitted hx curve had a midpoint of -38 mV and a steepness of 5.0 mV. Measurements of isometric tension were performed in small bundles of fibers, and the effects of the sulfhydryl-alkylating agents 4-cyclopentene-1,3-dione and N-ethylmaleimide were investigated. Tetanic tension was enhanced in a strictly Ca(2+)-dependent manner by 4-cyclopentene-1,3-dione. The amplitude of K+ contractures increased after treatment with N-ethylmaleimide. It is concluded that Ca2+ channels are made functional by the sulfhydryl-specific reagents and that the increase in tension is probably mediated by an increase in Ca2+ influx through the chemically induced Ca2+ channels.

Ultrastructural and mechanical properties of electrically inexcitable skeletal muscle fibers of the crustacean Atya lanipes

Examination of the ultrastructure and mechanical activation of the ventro-abdominal flexor muscle of the freshwater crustacean Atya lanipes shows that the fibers are of the long sarcomere, tonic type. The fibers possess an ample and well-organized internal membrane system, with extensive regions of T/SR dyad contacts near the ends of the A bands. An orbit of 10-12 thin filaments surrounds each thick filament. The lanthanum tracer method reveals a highly regular organization of the T-system, Z-tubules, and multiple internal clefts. Tension generation responds to extracellular potassium in a concentration dependent manner and is very slow. Mechanical activation is strictly dependent on extracellular Ca2+, even though these muscle fibers do not generate Ca2+ currents when depolarized. Tension development responds to caffeine and is also dependent on extracellular Na+, suggesting that Ca2+ release from the SR and Ca2+ influx via the Na/Ca exchanger intervene in mechanical activation.

Release of dopamine and chemoreceptor discharge induced by low pH and high PCO2 stimulation of the cat carotid body

1. Cat carotid bodies were incubated with the precursor [3H]tyrosine to label the catecholamine deposits and then mounted in a superfusion chamber which allowed simultaneous collection of the released [3H]dopamine (DA) and recording of action potentials from the carotid sinus nerve. 2. Low pH (7.2-6.6) superfusion of the carotid bodies for periods of 10 min produced a parallel increase in the release of [3H]DA and chemoreceptor discharge. 3. Carotid sinus nerve denervation of the carotid body 12-15 days prior to the experiments did not modify the release of [3H]DA elicited by low pH. 4. Superfusion of the carotid bodies with Ca(2+)-free, high-Mg2+ (1.6 mM) media reduced basal release of [3H]DA and chemoreceptor discharge by about 30%. Release evoked by low pH was reduced by 82%. Peak and average chemoreceptor discharge recorded in response to low pH were reduced by 28%. 5. Solutions containing weak acids (sodium acetate, 10 mM), adjusted at pH 7.4, elicited release of [3H]DA and increased chemoreceptor discharge. 6. With HCO3-CO2-buffered superfusion media, a reduction of bicarbonate to 5.6 mM (pH 6.8), an increase in CO2 to 20% (pH 6.8), or a simultaneous increase in CO2 to 20% and bicarbonate to 90 mM (pH 7.4), resulted in all cases in a corresponding increase in [3H]DA release and chemoreceptor discharge. The most effective stimulus was 20% CO2-pH 6.8 and the least effective 5% CO2-5.6 mM-HCO3-pH 6.8. 7. Inhibition of carbonic anhydrase with acetazolamide while perfusing the carotid bodies with a 20% CO2-equilibrated (pH 7.4) solution resulted in comparable reductions in the release of [3H]DA and chemoreceptor discharge. 8. It is concluded that the effective acidic stimulus at the carotid body chemoreceptors is an increase in hydrogen ion concentration in type I cells. It is also concluded that DA plays a critical role in the genesis of carotid sinus nerve discharges.

Ca2+ release from the sarcoplasmic reticulum of barnacle myofibrillar bundles initiated by photolysis of caged Ca2+

1. Ca2(+)-induced Ca2+ release (CICR) from the sarcoplasmic reticulum was measured by isometric tension recording from barnacle myofibrillar bundles. Laser-induced photolysis of the caged calcium molecule, nitr-5, was used to generate a rapid jump in free Ca2+ (within 1 ms) at the site of the sarcoplasmic reticulum, thus overcoming delays due to Ca2+ diffusion from the bathing solution. 2. The method consisted of equilibrating a myofibrillar bundle (100 micrograms diameter) in a solution containing 0.1 mM-nitr-5 (initial pCa 6.8-6.6) and then exposing it to a UV laser pulse. The resulting phasic contraction had an amplitude of up to 100% maximum tension (P0) in some preparations and a mean half-time for the rise of tension of 2.3 s at 12 degrees C. Longer half-times were obtained at low pulse energies. 3. Pre-treatment of the myofibrillar bundles with ryanodine (10(-4) M) or the detergent Triton X-100 abolished a large part of the phasic contraction, confirming its dependence on SR Ca2+ release. The small tonic response which remained had a shorter rise half-time than the Ca2(+)-induced Ca2+ release response and was attributed to direct activation of the myofibrils by Ca2+ released from the nitr-5. 4. The size of the photolytic Ca2+ jump was estimated from the amplitude of the fast tension component. By increasing the laser pulse energy or the initial Ca2+ loading of the nitr-5, the post-photolysis pCa was varied from 6.7 to 6.0; the CICR response increased in size over this pCa range. 5. Direct activation of Triton-treated myofibrils by photolysis of 2.0 mM-nitr-5 (initial pCa 6.4) gave contractions of up to 100% P0 and a mean rise half-time of 164 ms at 12 degrees C (n = 9 for contractions greater than 40% P0). Both the amplitude and the rate of these contractions were dependent on the laser pulse energy. 6. The Ca2(+)-induced Ca2+ release responses obtained with nitr-5 photolysis were significantly slower than the fastest rate of tetanus development which has been recorded from intact fibres of barnacle muscle (mean half-time = 177 ms at 12 degrees C). This could mean that either Ca2(+)-induced Ca2+ release is less efficient in isolated myofibrillar bundles than in intact fibres or that Ca2(+)-induced Ca2+ release is not the primary Ca2+ releasing mechanism in excitation-contraction coupling in barnacle muscle.

Mechanical characteristics of skinned and intact muscle fibres from the giant barnacle, Balanus nubilus

Intact muscle fibres from Balanus nubilus develop tensions of up to 600 kN.m-2 during electrical stimulation. The rise of tension occurs with a half-time (177 ms at 12 degrees C) about fivefold longer than that of tetanised frog muscle at the same temperature. The response of myofibrillar bundles to a rapid stretch resembles that of frog muscle but has a yo value (i.e. the size of an instantaneous release necessary to just discharge tension) which is ca. 2.5 times smaller, and phase 2 of the tension transient (the "quick phase") occurs at a rate comparable to that of frog muscle. In contrast, the ATPase activity (0.018 mmoles.kg wet weight-1.s-1) of this preparation and its maximum shortening velocity (0.15-0.16 muscle lengths.s-1) are both at least fivefold slower than frog muscle. These findings can be accounted for by a cross-bridge cycle in barnacle muscle in which events prior and subsequent to the tension generating step(s) occur at a rate at least fivefold slower than comparable steps in frog muscle, but the step(s) associated with tension development occur at similar rates in the two preparations. Since the rate of mechanical relaxation in barnacle muscle is modified in the presence of intracellular calcium buffers and by depolarisation-induced elevation of the free calcium during the relaxation phase, it is proposed that the time course of relaxation is not determined exclusively by the kinetics of the cross-bridge cycle, but is also dependent on the free calcium concentration during relaxation.

A single-ended perfusion method for large, cylindrical cells

This article describes a method for the intracellular perfusion of large, cylindrically shaped cells with access to the intracellular compartment at only one point. A single cut is made in the cell membrane at some distance from the site to be studied. A glass cannula is then inserted into the cut and the tip is advanced to the study site. Intracellular perfusion solution flows out of the tip and fills the cell as it washes back along the outside of the cannula, to finally exit through the original cut. The technique is applicable to long cells with blind ends, such as segmented axons. It is also useful for the study of synapses which occur between pairs of cells because the minimal dissection required by the technique tends to leave the synaptic structure undisrupted. The method of fabrication of the glass cannula is discussed, along with applicability to electrophysiological methods such as voltage clamp. Examples are presented of perfused axons from the crayfish and earthworm ventral nerve cords.

Ultrastructural investigations on the muscular systems in the barnacle, Tetraclita squamosa japonica

Four muscular systems of the Tetraclita squamosa barnacle were observed by means of an electron microscope and it was revealed that these systems each bore different types of muscle cells. The four systems were the adductor (A), the lateral scutal depressor (LSD), the ventral scutal depressor (VSD), and the tergal depressor (TD). The A-system included cross stiated muscle cells which showed long sarcomeres (about 10 mum) and rather disordered arrays of myofilaments. The LSD-system included cross striated muscles which had medium length sarcomeres (about 6.7 mum) and rather ordered myofilamental arrays. The VSD-system was constructed of cross striated muscle cells which bore shorter sarcomeres (4.6 mum) than the previous three systems and ordered myofilamental arrays. This last type of cell also bore well-developed sarcoplasmic reticular systems. The TD-system included smooth muscle cells which showed rather ordered arrays of myofilaments and dense-bodies. Each muscular system, as described above, included to its advantage one type of cross striated or smooth muscle cell for its characteristic contraction. The relations between ultrastructures and functions of each muscular system will now be discussed.

Ca-dependent slow action potentials in human skeletal muscle

Slow Ca-action potentials (CaAP) were studied in normal human skeletal muscle fibers obtained during surgery (fibers with both ends cut). Control studies also were carried out with intact as well as cut rat skeletal muscle fibers. Experiments were performed in hypertonic Cl-free saline with 10 or 84 mM Ca and K-channel blockers; muscles were preincubated in a saline containing Cs and tetraethylammonium. A current-clamp technique with two intracellular microelectrodes was used. In human muscle, 14.5% of the fibers showed fully developed CaAPs, 21% displayed nonregenerative Ca responses, and 64.5% showed only passive responses; CaAPs were never observed in 10 mM Ca. In rat muscle, nearly 90% of the fibers showed CaAPs, which were not affected by the cut-end condition. Human and rat muscle fibers had similar membrane potential and conductance in the resting state. In human muscle (22-32 degrees C, 84 mM Ca), the threshold and peak potential during a CaAP were +26 +/- 6 mV and +70 +/- 3 mV, respectively, and the duration measured at threshold level was 1.7 +/- 0.5 sec. In rat muscle, the duration was four times longer. During a CaAP, membrane conductance was assumed to be a leak conductance in parallel with a Ca and a K conductance. In human muscle (22-32 degrees C, 84 mM Ca, 40 micron fiber diameter), values were 0.4 +/- 0.1 microS, 1.1 +/- 0.7 microS, and 0.9 +/- 0.4 microS, respectively. Rat muscle (22-24 degrees C, 84 mM Ca) showed leak and K conductances similar to those found in human fibers. Ca-conductance in rat muscle was double the values obtained in human muscle fibers.

Carbachol and KCl-induced changes in intracellular free calcium concentration in isolated, fura-2 loaded smooth-muscle cells from the anterior byssus retractor muscle of Mytilus edulis

Intracellular free calcium concentration [( Ca2+]1) was measured in suspensions of fura-2 loaded smooth-muscle cells isolated from the anterior byssus retractor muscle of Mytilus edulis. Successive application of 5mM carbachol (CCh) and 100mM KCl to the cells transiently elevated [Ca2+]1 from the resting value of 124 +/- 4.5nM (mean +/- S.E., n = 14) to 295 +/- 15.3 and 383 +/- 20.5 nM, respectively. The response to CCh was concentration-dependent with an ED50 of 10(-5) M. Under the microscope, 67 +/- 3.0 and 83 +/- 1.3 % of fura-2 loaded cells contracted on the addition of 5mM CCh and 100mM KCl, respectively. In Ca2+ -free sea water, the CCh induced change in [Ca2+]1 was partially suppressed whereas that induced by KCl was completely abolished, suggesting an agonist-evoked release of stored Ca2+.

Voltage-dependent intracellular pH in Helix aspersa neurones

1. The intracellular pH (pHi) of large nerve cells from the mollusc, Helix aspersa, was measured with pH-sensitive micro-electrodes. Cells were held under voltage clamp and the effect on pHi of different holding potentials was determined. 2. Depolarization of the cell from the resting potential (about -50 mV) to -10 mV produced a fall in pHi that could be reduced by bathing the cell in nominally Ca2+-free saline. 3. At positive holding potentials pHi increased to a steady level that depended upon the electrochemical gradient for H+ across the cell membrane; it shifted by about 1 unit when the external pH was increased from 7 to 8 (or when the membrane potential increased by 58 mV, Thomas & Meech, 1982). 4. The depolarization-induced increase in H+ permeability was insensitive to SITS (4-acetamido-4'-isothiocyanostilbene-2,2'-disulphonic acid, 20 microM), which blocks pHi regulation at the resting potential in these cells (Thomas, 1976). When pHi was displaced from a steady level by ionophoretic injection of HCl, there was a rapid recovery at depolarized potentials even in the presence of SITS. The H+ pathway appeared to be little affected by prolonged periods at positive membrane potentials. 5. The depolarization-induced H+ efflux was insensitive to the metabolic inhibitor CCmP (carbonyl cyanide-m-chlorophenylhydrazone, 20 microM) and persisted in cells bathed in pH-buffered n-methyl glucamine-gluconate. It was also insensitive to DCCD (N, N'-dicyclohexylcarbodiimide, 10-100 microM) and oligomycin (2-10 micrograms/ml). 6. The H+ pathway could be fully blocked by 1 mM-ZnCl2, 1 mM-LaCl3, 1 mM-CuCl2, 2 mM-CdCl2 or 10 mM-CoCl2. Other divalent ions such as BaCl2 (10 mM) produced a block at membrane potentials near 0 mV but the block was released at more positive potentials. Low levels of LaCl3 (0.1 mM), the organic Ca2+ channel antagonist D600 (100 mg/ml) and high levels of the K+ channel blocker TEA (50 mM) all had similar effects to Ba2+. 7. The K+ channel blocker 4-aminopyridine (10 mM), which blocks H+ currents in perfused Lymnaea neurones (Byerly, Meech & Moody, 1984), has a complex action.(ABSTRACT TRUNCATED AT 400 WORDS)

Interactions of divalent cations with single calcium channels from rat brain synaptosomes

Voltage-dependent calcium channels from a rat brain membrane preparation ("synaptosomes") were incorporated into planar lipid bilayers. The effects of calcium, barium, strontium, manganese, and cadmium ions on the amplitudes and kinetics of single channel currents were examined. The order of single channel conductances was gBa greater than gSr greater than gMn, which was the inverse of the order of the mean channel open times: TMn greater than TCa = TSr greater than TBa. In contrast, the identity of the charge carrier had little or no effect on the mean closed times of the channel. Manganese, in the absence of other permeant ions, can pass through single channels (gMn = 4 pS). However, when added to a solution that contained another type of permeant divalent cation, manganese reduced the single channel current in a voltage-dependent manner. Cadmium, a potent blocker of macroscopic "ensemble" calcium currents in many preparations, reduced the current through an open channel in a manner consistent with Cd ions both not being measurably permeant and interacting with a single site. The permeant ions competed with cadmium for this site with the following order: Mn greater than Sr = Ca greater than Ba. These results are consistent with the existence of no less than one divalent cation binding site in the channel that regulates ion permeation.

Simultaneous monitoring of electrical and secretory activity in peptidergic neurosecretory terminals of the crab

Intracellularly recorded responses of peptidergic neurosecretory terminals and somata were correlated with their secretory responsiveness to elevation of the external K concentration ([K+]o). The experiments were performed on in vitro X-organ sinus gland neurosecretory systems from the eyestalk of the crab Cardisoma carnifex. Elevated-K-evoked release was followed in preparations exposed to a pulse-chase radiolabelling regime. The release of [3H]leucine incorporated into neurosecretory peptides could be followed by collecting the separate perfusates of the somata and terminal regions. Elevation of the [K+]o evoked terminal depolarization, an increase in impulse firing frequency and a decrease (50%) in terminal input resistance. Impulse firing ceased (in ca. 2 min) as depolarization reached a sustained maximum level (-17.6 +/- 3.57 mV, n = 9, absolute potential). The terminal depolarization and decreased input resistance were maintained throughout the period of elevated-K treatment. Release from the terminal region of incorporated 3H label paralleled the simultaneously monitored terminal depolarization. Maintained exposure to elevated-K saline was accompanied by sustained high levels of 3H release continuing beyond the loss of regenerative membrane responses. Release declined with a half-time of 47.1 +/- 13.5 min (n = 7). In contrast, terminal release of red pigment concentrating hormone (RPCH) was transitory, reaching peak values and declining to base line within a 10 min period. Removal of external Ca or addition of the Ca antagonists, Cd or Mn, blocked the stimulated 3H release. Addition of Cd or Mn, prior to or during an elevated-K-evoked 3H release produced a reversible suppression of the secretory response. Stimulation in the absence of external Na, under normal Ca conditions, resulted in a normal secretory response. The amplitude and duration of the elevated-K-evoked terminal depolarization was unaffected by nominally Ca- or Na-free saline or addition of Cd. Cd (1mM) and Na-free saline were effective in removing a Ca and Na component, respectively, of spontaneous or evoked terminal action potentials. Somatic responses to direct application of elevated K exhibited membrane depolarization and an accompanying increase in impulse firing. In contrast to recordings from the terminals in elevated K, fast regenerative potentials, electrotonically conducted from the distal axon, persisted in the somatic records. Somatic secretion of RPCH was below detectable limits (less than 0.2 fmol min-1). 3H release was an order of magnitude less than from the terminal region under similar conditions.(ABSTRACT TRUNCATED AT 400 WORDS)

Rapidly activating hydrogen ion currents in perfused neurones of the snail, Lymnaea stagnalis

Cells from the circumoesophageal nerve ring of the pond snail Lymnaea stagnalis were internally perfused with solutions containing Cs aspartate, EGTA and pH buffers. Time-dependent, voltage-dependent 'residual' outward currents were observed at positive potentials. They were found to be carried largely by H+. The outward H+ currents were reduced by high internal pH, low external pH, external Cd2+ and 4-aminopyridine. External tetraethylammonium ions reduced the H+ currents but had a more effective blocking action on the K+ currents in these cells. All five agents reduced the maximum H+ conductance. In addition Cd2+, low external pH and high internal pH were found to shift the voltage dependence of the H+ current to more positive potentials. There was no significant difference between H+ currents recorded with the internal pCa2+ about 7 and those recorded with the internal pCa2+ near 5. It is likely that the H+ channel described here provides the basis for the increase in H+ permeability described by Thomas & Meech (1982) in depolarized Helix neurones. As judged by their sensitivity to different antagonists, H+ channels are unlike any other previously described channel. They are highly selective for protons and we suggest that their role in molluscan neurones is to compensate for the rapid intracellular acidification which is generated by trains of action potentials (Ahmed & Connor, 1980).

Sodium pump stoicheiometry determined by simultaneous measurements of sodium efflux and membrane current in barnacle

Ouabain-sensitive Na efflux, membrane potential and membrane current were measured in single, perfused muscle cells taken from the giant barnacle, Balanus nubilus. This preparation permits control of the intracellular and extracellular solution composition as well as control of the membrane potential while measuring ion fluxes across the plasma membrane. The addition of ouabain (10(-4) M) to the extracellular solution produces a rapid depolarization of membrane potential (1-4 mV) and a simultaneous and proportional reduction of Na efflux (10-40 pmol/s). Ouabain-induced changes in membrane potential or Na efflux do not depend on the presence of extracellular Na. Under voltage control, the application of ouabain (10(-4) M) produces a rapid monotonic fall in outward current (1-3 microA) and a simultaneous fall in Na efflux (10-40 pmol/s). The fraction of ouabain-dependent Na efflux that appears as outward current is constant in any given preparation as the Na-pump turnover rate varies. Over a limited range, changes in membrane potential do not affect ouabain-sensitive Na efflux. The ouabain-sensitive Na efflux and membrane current are not altered by the presence of 50 mM-internal tetraethylammonium (TEA) ions. We conclude that the Na pump is electrogenic in barnacle muscle and that 49 +/- 10% of the extruded Na+ leaves the intracellular compartment as uncompensated charge. We find that the transport stoicheiometry of Na:K, calculated from the ouabain-dependent changes in membrane current and Na efflux, is between 3:2 and slightly more than 2:1.

Comparison of properties of calcium channels between the differentiated 1-cell embryo and the egg cell of ascidians

In the ascidians Halocynthia roretzi and H. aurantium the Ca channels in the differentiated embryo whose cleavage was arrested with cytochalasin B at the 1-cell stage and in the unfertilized egg were studied using the voltage-clamp technique. In the cleavage-arrested 1-cell embryo, which differentiates into a cell of epidermal type after culturing until the time of hatching of the control larvae, Ca channel and Ca-induced K channel currents were observed upon depolarization of the membrane. Inward current through Ca channels in the embryo was analysed after suppressing Ca-induced K current by intracellular injection of EGTA. Sr or Ba ions could substitute for Ca ions as the charge carrier through Ca channels both in the cleavage-arrested embryo and in the egg. The selectivity ratios among these cations at their respective maximum inward currents were 1.0 (Ca):2.0 (Sr):4.5 (Ba) for the Ca channel in the embryo and 1.0 (Ca):1.9 (Sr):1.1 (Ba) for that in the egg. The time course of inactivation of Ca channels in Ca artificial sea water (ASW) was different from that in Sr or Ba ASW in the cleavage-arrested embryo. Fast inactivation was observed only in Ca ASW, and slight and slow inactivation was seen in Ba or Sr solution. In the egg, Ca, Sr and Ba currents through Ca channels all showed a similar time course of inactivation. The time course and voltage dependence of inactivation in Ca ASW were studied by measuring Ca tail current at a constant potential level of -28 mV. In the cleavage-arrested embryo the inactivation became slower and smaller in accordance with the decrease in inward Ca current when the potential level of the command pulse was increased in the positive direction from 10 to 80 mV. In the egg the time course of inactivation became faster when the potential level was similarly increased. The experimental results in (4) and (5) above suggest that the inactivation of the Ca channel in the cleavage-arrested embryo was dependent on Ca inward current while that in the egg was potential dependent. The developmental changes of Ca channels from egg type to epidermal type were studied in the cleavage-arrested 1-cell embryo. The epidermal-type Ca channels appeared at about 40 h after fertilization at 9 degrees C. The Ca channels in those blastomeres which differentiated to a cell of muscular type in the cleavage-arrested 8- or 16-cell embryo were studied after suppressing the outward current by tetraethylammonium and by intracellular injection of both Cs ions and EGTA.(ABSTRACT TRUNCATED AT 400 WORDS)

Muscle calcium transient. Effect of post-stimulus length changes in single fibers

We examined the effects of post-stimulus length changes on voltage-clamped, aequorin-injected single muscle fibers from the barnacle Balanus nubilus. Extra light (extra calcium) is seen when the fiber is allowed to shorten (a small percentage) during the declining phase of the calcium transient. The opposite is observed when the fiber is stretched. Increasing the extent of shortening increases the amount of extra calcium, as does decreasing the temperature. The extra calcium probably comes from the myofilaments and not from the sarcoplasmic reticulum because (a) there is a strong correlation between the extra calcium and the level of activation; (b) there is a strong correlation between the extra calcium and the amount of force redeveloped after a length change; and (c) the time course of the appearance of the extra calcium is intermediate between that of the free calcium concentration and that of force. We suggest (a) that the calcium binding to the activating myofibrillar proteins is sensitive to muscle length or muscle force, and (b) that there is a pool of bound calcium (activating calcium) that waxes and wanes with a time course intermediate between the free calcium concentration and force.

Effects of extracellular sodium on calcium efflux and membrane current in single muscle cells from the barnacle

The actions of extracellular sodium (Nao) on membrane potential, membrane current, membrane conductance and Ca efflux were examined in single muscle cells from the giant barnacle, Balanus nubilus. The intracellular compartment was perfused to facilitate the control of intracellular constituents including calcium ions (Ca2i+). Changing Nao has no large effect on Ca efflux when free intracellular calcium activity, [Ca2+]i, is low (about 0.1 microM). However, increasing [Ca2+]i leads to the development of Nao-dependent Ca efflux as well as to an augmentation in Nao-independent Ca efflux. Reducing Nao (using Li+ as a substitute cation) leads to a depolarization of the membrane when [Ca2+]i is low (about 0.1 microM). Increasing [Ca2+]i causes the membrane to depolarize. With [Ca2+]i at about 10.0 microM, reduction of Nao produces a hyperpolarization of the membrane. Significant Nao-dependent inward current is seen when [Ca2+]i is high. This current is large with respect to the Nao-dependent changes in Ca efflux (about 1 microA per p-mole/sec). The Ca2i+-activated, Nao-dependent changes in Ca efflux and membrane current are not sensitive to La3o+. However, Lao3+ does inhibit a fraction of the Cai2+-activated changes in membrane current and Ca efflux which are not dependent on Nao. Over a limited range of membrane potential Ca efflux is not voltage-dependent. Possible relationships between the Nao-dependent changes in Ca efflux and Nao-dependent changes in membrane potential or current are discussed. We find that these changes cannot be readily interpreted in terms of a single transport mechanism.

Modulation of membrane conductance in rods of Bufo marinus by intracellular calcium ion

Double-barrel micropipettes were used to pressure-inject EGTA into the outer segments of rods in the isolated retina of Bufo marinus. We used these pipettes to point voltage clamp the cell to its resting membrane voltage during the injection of EGTA in order to prevent changes in membrane voltage from occurring. The input conductance of the rod was assessed by measuring the incremental membrane current required to hyperpolarize the membrane by less than or equal to 10 mV. When the retina was bathed in normal Ringer solution, the injection of EGTA during point voltage clamp evoked an inward membrane current and in increase in input conductance. This observation is consistent with an EGTA-evoked increase in conductance for an ion with an equilibrium potential more depolarized than the resting membrane potential. Injections of control solutions that did not contain EGTA had no effect. The effects of injected EGTA were not altered by variations in the pH or buffering capacity of the injection solution, or by the addition of equimolar Mg2+. Furthermore, injections of a solution containing equimolar Ca2+ and EGTA were without effect. Thus, the observed effects of injected EGTA were due to the lowering of the [Ca2+]i. Replacement of extracellular Na+ with choline+ abolished both the response to light and the EGTA-evoked increase in input conductance. A low [Na+]o solution containing 10(-8) M-Ca2+ reduced the response to injected EGTA by approximately the same amount as it reduced the response to light. Replacement of extracellular Cl- by methanesulphonate was without significant effect on either the response to light or to injected EGTA. These results are consistent with the interpretation that a lowered [Ca2+]i increases primarily the sodium conductance, gNa, of the plasma membrane of the rod outer segment. The conductance that is affected by a lowered [Ca2+]i appears to have the same specificity as the light-dependent conductance. This conclusion is consistent with a hypothesis for visual transduction involving modulation of gNa by light-evoked changes in the [Ca2+]i.

Effects of calcium on membrane potential and sodium influx in barnacle muscle fibers

The influence of internal and external Ca2+ on membrane potential and 22Na influx were tested in internally perfused giant barnacle muscle fibers. The fibers depolarized by about 2-3 mV, and Na+ influx increased when external Ca2+ was removed. These effects were inhibited and reversed by adding 2 mM La3+ externally but not by tetrodotoxin (TTX). Ca2+ channel blockers did not prevent the depolarization. Increasing internal free Ca2+ ([Ca2+]i) from 10(-7) to 10(-5) M also stimulated Na+ influx and depolarized the fibers by a few millivolts. Neither external La3+ nor TTX prevented the effects of raising [Ca2+]i; however, internal tetrabutylammonium ions depolarized the fibers and attenuated the internal Ca2+-dependent effects. These data are consistent with the idea that removal of external Ca2+ activates a La3+-sensitive channel that is permeable to Na+; raising [Ca2+]i activates a La2+-insensitive, Na+-permeable channel that may be similar to the internal Ca2+-activated nonselective cation channels observed in cardiac muscle. The results demonstrate that all Na+ (and Ca2+) fluxes that do not contribute to Na-Ca exchange must be carefully identified before the exchange stoichiometry can be determined from Na+ and Ca2+ flux measurements.

Insulin regulation of sugar transport in giant muscle fibres of the barnacle

1. Sugar transport in the giant muscle cells of Balanus nubilus is accelerated during contractile activity and exposure to porcine insulin. The characteristics of hexose-transfer regulation in the giant muscle cells have been examined by studying the transport of 3-O-methylglucose (a non-metabolized sugar) in both intact giant fibres and fibres subjected to internal solute control by internal dialysis.2. Sugar transport in barnacle muscle is mediated by a saturable process which is inhibited by both phloretin and cytochalasin B. Insulin increases the capacity of the transport system with little effect on its apparent affinity for sugar. Under the same conditions insulin increases 3-O-methylglucose-displaceable cytochalasin B binding. The effects of insulin on transport are half-maximal at 5 muM-insulin and are abolished by both insulin antibody and phloretin. The intact barnacle releases an insulin-like material in response to a rise in blood glucose levels.3. Insulin increases the cyclic GMP (cGMP) content and reduces the cyclic AMP (cAMP) content of barnacle muscle. Experiments with fibres injected with aequorin show that insulin also lowers cytosolic ionized Ca levels. The changes in cyclic nucleotide levels induced by insulin precede the effects on sugar transport and cytosolic ionized Ca. During repetitive contractile activity, cAMP, cGMP and ionized Ca levels are raised.4. Agents which raise the cAMP content of barnacle muscle normally inhibit sugar transport. Dibutyryl cAMP also inhibits transport. Alterations in cytosolic ionized Ca levels in intact fibres are without effect on sugar transport. Nevertheless, stimulation of transport by insulin is blunted when cytosolic ionized Ca is lowered by intracellular injection of the Ca-chelating agent, EGTA.5. Sugar uptake in the internally dialysed fibre is inhibited by intracellular application of cAMP. Internal application of Ca and cGMP stimulate sugar uptake in the dialysed fibre. Cyclic AMP reduces the capacity of the transport system whereas Ca and cGMP increase the capacity of the saturable transfer system. Cyclic AMP and cGMP act at kinetically independent sites. Internal ATP (2 mM) inhibits sugar uptake in the dialysed fibre by some 40%, possibly through the production of cAMP.6. External insulin stimulates sugar uptake in the dialysed fibre even when ionized Ca levels are buffered using EGTA. Stimulation by insulin requires the presence of cytosolic ATP and is potentiated by internal application of 1 mM-GTP. In the dialysed fibre stimulation of transport by insulin is greater than that brought about by Ca and cGMP.7. The stimulation of transport by insulin in the intact fibre and its inhibition by dibutyryl cAMP are abolished by intracellular injection of Gpp(NH)p. Injection of intact fibres with GTPgammaS potentiates the stimulation of transport by insulin and renders insulin-activation of transport irreversible. Injection of intact fibres with ATPgammaS leads to the irreversible inhibition of transport.8. Injection of intact fibres with cAMP phosphodiesterase lowers cAMP levels close to zero and stimulates sugar transport. Application of insulin to diesterase-injected fibres still stimulates transport in the absence of altered cytosolic cAMP.

Excitation-contraction coupling: role of K-activation within the transverse tubular system

Long-duration Ca action potentials induced in crustacean muscle fibers after prolonged exposure to quaternary ammonium ions are accompanied by attenuated tensions with unique time courses. The tensions have three phases. The initial phase, correlated with the upstroke of the spike, is a rapid increase in tension followed by relaxation to or near to resting level (on-tension). In the second phase, tension rises slowly as the spike plateau declines. The final phase is another rapid increase and decay in tension that is correlated with termination of the action potential (off-tension). To observe these tensions, fibers must be exposed to 50-100 mM tetrabutylammonium ion for about 1 hr or to lower concentrations for longer periods (e.g., 5 mM for 20-30 hr). To obtain a similar response in fibers treated with tetraethylammonium ion, higher concentrations or longer soaking periods, or both, are required. Because neither caffeine-induced tensions in intact fibers nor contractile protein and sarcoplasmic reticulum function in skinned fibers were modified by quaternary ammonium ions, their site of action appears to be limited to surface or transverse tubular system membranes, or both. The unique tensions can be explained by considering the mode by which quaternary ammonium ions block K channels in conjunction with a scheme in which activation of K channels within the transverse tubular system controls the driving force for influx of Ca ions.

Sodium and calcium channels in bovine chromaffin cells

1. Inward currents in chromaffin cells were studied with the patch-clamp technique (Hamill, Marty, Neher, Sakmann & Sigworth, 1981). The intracellular solution contained 120 mM-Cs(+) and 20 mM-tetraethylammonium (TEA(+)). Na(+) currents were studied after blockade of Ca(2+) channels with 1 mM-Co(2+) applied externally. Ca(2+) currents were recorded after eliminating Na(+) currents with tetrodotoxin (TTX). The current recordings were obtained in cell-attached, outside-out and whole-cell recording configurations (Hamill et al. 1981).2. Single channel measurements gave an elementary current amplitude of 1 pA at -10 mV for Na(+) channels. This amplitude increased with hyperpolarization between -10 and -40 mV, but did not vary significantly between -40 and -70 mV.3. The mean Na(+) channel open time was 1 ms at -30 mV. This open time decreased both with depolarization and hyperpolarization. Its value was close to the time constant of inactivation, tau(h), above -20 mV.4. Ensemble fluctuation analysis of Na(+) currents gave results consistent with those of single channel measurements. Noise power spectra obtained between -35 mV and 0 mV could be fitted with a single Lorentzian. A range of Na(+) channel densities of 1.5-10 channels per mum(2) was calculated.5. Cell-attached single Ca(2+) channel recordings were obtained in isotonic BaCl(2) solution. The single channel amplitude was 0.9 pA at -5 mV, and it became smaller for positive potential values.6. At -5 mV, single Ba(2+) currents appeared as bursts of 1.9 ms mean duration containing on the average 0.6 short gaps. The burst duration was larger at positive potentials.7. Ensemble fluctuation analysis of Ca(2+) channels was performed on whole-cell recordings in external solutions containing isotonic BaCl(2) or external Ca(2+) (Ca(o)) concentrations of 1 and 5 mM. The unit amplitude calculated in the former case was similar to that obtained in single channel measurements.8. Noise power spectra of Ca(2+) or Ba(2+) currents could be fitted by the sum of two, but not one, Lorentzian components.9. Tail currents could be fitted by the sum of two exponential components. The corresponding time constants had values close to those obtained with noise analysis.10. The rising phase of Ca(2+) and Ba(2+) currents was sigmoid. It could be fitted by the sum of three exponentials. The time constant of the largest amplitude component, tau(1), was similar to the time constants of the slow component observed in noise and tail experiments. This time constant also corresponded to the burst duration obtained in single channel measurements.11. The value of tau(1) was larger in 5 mM-Ca(o) and in isotonic Ba(2+) than in 5 mM-Ba(o). Thus, the kinetic properties of Ca(2+) channels depend on the nature and concentration of the permeating ion.12. A simple kinetic scheme is proposed to model the activation pathway of Ca(2+) channels.13. Currents in 1 mM-Ca(o) and 5 mM-Ca(o) showed clear reversals around +53 mV and +64 mV respectively. The outward currents observed above these potentials are most probably due to Cs(+) ions flowing through Ca(2+) channels.14. The instantaneous current-voltage relation was obtained from tail current data in the range -70 to +100 mV in 5 mM-Ca(o). The resulting curve displayed an inflexion point around the reversal potential.15. Very little inactivation of Ca(2+) currents was observed. However, a slow current decline was observed in some cells above +10 mV.16. Conditioning prepulses to positive potentials had potentiating or depressing effects on Ca(2+) currents depending on whether the test pulse lay below or above the maximal current potential. The potentiating effect may be linked to the slowest component of the current rise observed below +10 mV. The depressing effect may be related to the slow decline obtained above +10 mV.17. Analysis of ensemble variance and of tail current amplitudes suggested that the opening probability of Ca(2+) channels was at least 0.9 above +40 mV.18. A slow rundown of Ca(2+) currents was observed in whole-cell recordings. The speed of the rundown was dependent on intracellular Ca(2+) concentration. The rundown was apparently due to a progressive elimination of the channels available for activation.19. The density of Ca(2+) channels (before rundown) was estimated at 5-15/mum(2).20. In cell-attached experiments, inward current channels were often seen to follow action potentials. These events did not appear to be the usual Na(+) and Ca(2+) currents. They were probably due to cation influx of either Na(+) or Ba(2+), depending on the pipette solution, through Ca(2+)-dependent channels. Voltage-independent single channel activity observed in whole-cell and outside-out recordings may be due to the same channels.

[The effect of tetraethylammonium and the decrease in the extracellular chloride concentration on membrane depolarization and contraction of skeletal muscle fiber induced by a hyperpotassium solution]

1.--The tetraethylammonium (TEA) effects on K+ contracture and membrane depolarization are compared in both crab and frog skeletal muscle fibres. 2.--The mechanical tension of the contracture is reduced by the TEA in frog skeletal muscle fibre; it is increased in crab skeletal fibre. 3.--When no mechanical phenomenon is observed in frog skeletal muscle, the amplitude and the velocity of membrane depolarization induced by an increase of outward K+ concentration is reduced by the TEA. These effects are in opposition in crab muscle fibre. 4.--In crab muscle fibre, the results obtained tend to show that the C1-ions are not distributed on each side of the membrane according to Donnan equilibrium.

Calcium inactivation in skeletal muscle fibres of the stick insect, Carausius morosus

1. Inactivation of Ca currents in skeletal muscle fibres of the stick insect, Carausius morosus, was studied using a three-electrode voltage-clamp method. 2. The extent of inactivation showed a voltage-dependence similar to that of the Ca current, inactivation being absent in the absence of a Ca current, maximal at potentials where Ca currents are largest, and reduced at potentials close to ECa. 3. Ca currents inactivated along a double exponential time course, both when measured from the decline of Ca current during a single pulse and when measured using a two pulse protocol. In 20 mM-Ca-Ringer the fast time constant of inactivation had a mean value of 27 msec and that of the slow time constant was 134 msec, at O mV and 5 degrees C. 4. The rate of inactivation was slowed, and its extent reduced, in low [Ca]o, where Ca currents are smaller. Similarly, inactivation was faster and more complete in high-Ca-Ringer. 5. The rate of recovery from inactivation also followed a double exponential time course, with time constants of 638 msec and 4 sec following a 500 msec inactivating pulse in 20 mM-Ca-Ringer at 5 degrees C. Recovery appeared to be related to the amount of Ca entry during the inactivating pulse, being slower in high [Ca]o and following longer inactivating pulses. 6. Inactivation was slowed and reduced in extent when Ba2+ or Sr2+ carried current. Inactivation in Ba solutions may be due to depletion of Ba2+ from the lumen of the transverse tubules. 7. Ba2+ does not compete with Ca2+ for the inactivation mechanism. 8. It is concluded that inactivation of Ca currents in stick insect muscle fibres is primarily mediated by Ca2+ entry.

Measurement of GABA-evoked conductance changes of lobster muscle fibres by a three-microelectrode voltage clamp technique

The effective membrane conductance and capacity of lobster muscle fibres was measured by a three-intracellular-microelectrode voltage clamp technique. Conductance values agreed well with those determined under current clamp, by means of the 'short' cable equations. Reversible increases in conductance evoked by gamma-aminobutyric acid (GABA) were reflected by differences (delta V) in electrotonic potential amplitude recorded at the centre, and midway between the centre and fibre end respectively. GABA dose--conductance curves derived from cable theory or from delta V measurements were virtually identical. The effective capacity (ceff), determined from the area beneath the 'on' delta V capacity transient, yielded values of the membrane time constant consistently lower than those obtained by the graphical method of E. Stefani & A.B. Steinbach (J. Physiol., London. 203, 383-401 (1969)); one possible explanation for this discrepancy is discussed. In the presence of GABA, the effective capacity was reduced in a dose-related manner. The results were interpreted in terms of an equivalent circuit in which surface membrane was arranged in parallel with cleft-tubular membrane of finite conductance, charged through an access resistance. GABA was though to be decreasing ceff by selectively increasing the conductance of the cleft-tubular membranes.

Calcium and potassium currents in muscle fibres of an insect (Carausius morosus)

1. A three electrode voltage-clamp was used to investigate membrane currents in the skeletal muscle fibres of the stick insect, Carausius morosus. Contraction was blocked by hypertonic solutions. 2. Membrane currents elicited by step depolarizations consisted of an inward current, an early outward current and a delayed outward current. 3. The reversal potential of the delayed outward current did not change when SO4(2-) was substituted for Cl-, but shifted by 14.1 mV when [K]0 was increased from 20 mM to 40 mM in SO4(2-) solution, suggesting that the delayed current is carried by K+. Both early and delayed outward currents were substantially reduced by 120 mM-tetraethylammonium (TEA) ions. 4. The small size of the shift in the reversal potential of the delayed outward current with increased pulse duration suggests that the delayed current measured flows mainly across the surface membrane. 5. Increasing [Ca]o made the apparent reversal potential for the inward current (120 mM-TEA Ringer) more positive and increased the size of the maximum inward current. However, Ca-currents showed saturation with increasing [Ca]o, indicating that there is a site to which Ca ions bind during their passage through the membrane. The dissociation constant of this site was 7.3 mM at 0 mV and was voltage-dependent. 6. Inward currents were blocked by 1 mM-La3+ or Cd2+, or by substitution of Co2+ or Ni2+ for Mg2+. Strontium and barium were able to permeate the channel but Na+ and Mg2+ appear impermeant. 7. As expected from the low intracellular Ca concentration, the instantaneous current-voltage relation of the Ca current rectified strongly in the inward direction. 8. Both constant field theory and the simplest, single site, Eyring rate theory model predict the rectification of the instantaneous current-voltage relation. The rate theory model also predicts saturation of the Ca current with [Ca]o.