Kinetics of functional and morphological changes during decoupling and recoupling induced by glycerol in isolated muscle fibres of the crayfish

Summary The development of ultrastructural changes in the T-system of isolated muscle fibres of the crayfish by the glycerol procedure is described in correlation with the dissociation of excitation-contraction (E-C) coupling as well as with recoupling of the E-C link. The sequence of events in the process of disconnection of the tubules is as follows: dilation of the T-system tubules, disconnection of the constricted tubular segments from the surface membrane and from the T-system vesicle, disappearance of the lumen and its disintegration. The decoupled state is characterised by the presence of round vesicles uniformly distributed in the entire volume of the fibre. The volume of vesicles accounts well for the residual postglycerol volume increase (15%) of the muscle fibres. Functional and structural recovery can be induced by reapplication of glycerol to fibres decoupled and vesiculated with concentrations of glycerol300mmol · l^-1 in crayfish saline. The restitution starts with the organisation of the material of the disintegrated connecting segment of the T-system tubule into small vesicles which coalesce to form the tubule from the vesicular site. At the same time the surface membrane is invaginated toward the vesicle, thus forming the tubule from the surface membrane site. Recovery starts already in the first minute after application of glycerol and is completed within approximately 15min.     

Electromechanical coupling in tubular muscle fibers. II. Resistance and capacitance of one transverse tubule

In tubular muscle fibers of the yellow scorpion the transverse tubules are arranged in a radial symmetry. This particular morphology, enables one to derive values for electrical components of one transverse tubule (TT) by treating the TT as a core conductor rather than a complex network. The electrical properties of tubular muscle fibers were completely characterized and analyzed by measuring two independent functions of frequency, i.e., the characteristic impedance and the propagation function. The impedance of a single tubular muscle fiber was determined with microelectrodes over the frequency range 1 Hz to 1.5 kHz. The results were fitted to a possible equivalent circuit model which is based on morphological evidence. The average component values for this model are: Ri = 209 omega-cm, Rm, and RT = 980 omega-cm2 (referred to unit area of surface membrane), Cm and CT = 0.9 muF/cm2, and RL = 103 omega-cm. Relating the equivalent circuit to ultrastructure shows that the average component values are consistent with the hypothesis that the TT is open to the extracellular medium, the electrical capacity of surface and TT membranes is about 1 muF/cm2, and the spread of surface depolarization into the TT is attenuated by about 25%.     

Effect of glycerin removal on the electrical resistance of isolated muscle fiber in the frog

Fibres isolated from iliofibularis muscles of the frog Rana esculenta were studied under current-clamp conditions with a double sucrose-gap technique. An increase of membrane resistance in muscle fibres (Rm) was demonstrated during the first 10-15 min of glycerol removal in K2SO4 solution. After a 30 min treatment in glycerol-containing K2SO4 Rm was 1.40 +/- 0.12 k omega X X cm2. The transfer of muscles from the glycerol-K2SO4 solution to an isotonic K2SO4 solution resulted in a progressive increase in the Rm which after a 15 minutes removal of glycerol reached the mean value of 2.02 +/- 0.22 k omega X cm2. It is suggested that this increase may reflect detubulation of the fibres caused by glycerol removal in muscles.     

A cleft model for cardiac Purkinje strands.

Conduction of the action potential in cardiac muscle is complicated by its multicellular structure, with narrow intercellular clefts and cell-to-cell coupling. A model is developed from anatomical data to describe cardiac Purkinje strands of variable diameter and different internal arrangements of cells. The admittance of the model is solved analytically and fit to results of cable analysis. Using the extracted specific membrane and cell electrical parameters (Rm = 13 K omega cm2, Cm = 1.5 mu F/cm2, Ri = 100 mu cm, and Re = 50 omega cm), the model correctly predicted conduction velocity and filling of capacitance at the onset of a voltage step. The analysis permits more complete studies of the factors controlling conduction velocity; for instance, the effect on conduction velocity of a capacity in the longitudinal current circuit is discussed. Predictions of the impedance and phase angle were also made. Measurements of the frequency dependence of phase angle may provide a basis for separating cleft membrane properties from those of the surface membrane and may aid the measurement of nonlinear membrane properties in muscle.     

Regulation of insulin-stimulated glucose transport in the isolated rat adipocyte. cAMP-independent effects of lipolytic and antilipolytic agents

This paper examines the modulation of insulin-stimulated glucose transport activity in rat adipose cells by ligands for receptors (R) that mediate stimulation (Rs; lipolytic) or inhibition (Ri; antilipolytic) of adenylate cyclase. The changes in glucose transport activity and cAMP, as assessed by 3-O-methylglucose uptake and (-/+) cAMP-dependent protein kinase (A-kinase) activity ratios, respectively, were monitored under conditions that maintain steady-state A-kinase activity ratios (Honnor, R. C., Dhillon, G. S., and Londos, C. (1985) J. Biol. Chem. 260, 15122-15129). Removal of endogenous adenosine with adenosine deaminase decreased insulin-stimulated glucose transport activity by approximately 30%, which was prevented or restored with Ri agonists such as phenylisopropyladenosine, nicotinic acid, and prostaglandin E1. These changes in transport activity were not accompanied by changes in A-kinase activity ratios, indicating that Ri-mediated effects on transport are independent of cAMP changes. Addition of an Rs ligand, isoproterenol, in the presence of adenosine increased kinase activity but did not change glucose transport activity. Conversely, upon removal of adenosine, addition of Rs ligands such as isoproterenol, adrenocorticotropic hormone, or glucagon strongly inhibited transport (approximately 50%) and stimulated kinase activity. However, subsequent addition of phenylisopropyladenosine nearly restored transport activity without alteration of A-kinase activity. These data and additional kinetic experiments suggest that Rs-mediated glucose transport modulations are also independent of cAMP. The interchangeability of ligands for both Rs and Ri receptors in modulating transport activity suggests that these cAMP-independent effects are mediated by the stimulatory (Ns) and inhibitory (Ni) guanyl nucleotide-binding regulatory proteins of adenylate cyclase. All Rs-and Ri-induced changes in transport activity occurred without a change in glucose transporter distribution, as assessed by D-glucose-inhibitable cytochalasin B binding, suggesting that Rs and Ri ligands modulate the intrinsic activity of the glucose transporter present in the plasma membrane.     

膜上相互作用对平板双分子层脂膜电性质的影响

以平板双分子层脂膜作为生物膜的简单模型,建立用平板双分子层脂膜电性质研究药物－生物膜相互作用的方法。研究以具有典型特征的物质－表面活性剂、自由基、金属手性配合物与平板膜的相互作用引起膜电性质的规律性改变;重组人Ｂ型血红细胞膜与溶液中抗Ｂ单克隆抗体发生特异相互作用时,膜电阻快速下降,下降的速率与加入的抗体量成正相关。在研究发生在平板膜上的典型反应的基础上,通过对膜电性质的监测和分析,从而确认平板双分     

Bioimpedance spectroscopy parameters of suspensions of young and old erythrocytes

The bioimpedance spectroscopy (BIS) parameters of the suspensions of young and old erythrocytes were studied. The separation of the erythrocytes by age was made by density gradient. The BIS parameters: extracellular (Re) and intracellular (Ri) fluid resistance, characteristic frequency (Fchar), cell membranes capacitance (Cm) and Alpha parameter of concentrate suspensions of young and old erythrocytes were measured on the BIA analyzer ABC-01 "Medass" in the frequency range 5-500 kHz. It was found that Re (300.4 +/- 30.0 Ohm and 261.2 +/- 21.8 Ohm for old and young respectively, p < 0.05), Ri (86.6 +/- 9.1 Ohm and 73.4 +/- 7.3 Ohm for old and young respectively, p < 0.001) and Alpha (0.305 +/- 0.003 and 0.302 +/- 0.001 for old and young respectively, p < 0.05) of the old erythrocytes suspensions were higher, than of the young one, and Fchar (308.3 +/- 42.0 kHz and 347.4 +/- 48.0 kHz for old and young respectively, p <0.05) and Cm (99.3 +/- 10.1 pF and 112.8 +/- 6.3 pF for old and young respectively, p < 0.01) of the old erythrocytes were lower, than of the young one. The found differences between electrical properties of the suspensions of young and old erythrocytes were obviously determined by the alterations of the red blood cells during aging (growth of intracellular hemoglobin concentration, erythrocytes rapprochement because of diminishing of surface negative charge, increase of red blood cell sphericity and cell membrane permeability for ions). Thus the BIS parameters are related to the erythrocyte aging.     

Comparison of the effects of dDAVP and AVP on the sodium transport in the frog skin

The effect of 1-deamino-8-D-arginine-vasopressin, dDAVP, the synthetic analogue of vasopressin, upon the active sodium transport across the frog skin was studied using standard microelectrode technique and compared with the effect of synthetic arginine-vasopressin, AVP. dDAVP applied to the basolateral side of the epithelium stimulated the active sodium transport as reflected by the increase of short-circuit current, Isc, and transepithelial electrical potential difference, Voc. Potential difference across both the apical, Vo, and the basolateral, Vi, cell membranes decreased. The driving force of transepithelial sodium transport, ENa, did not change. The transepithelial electrical resistance, Rt, ohmic resistance of the active sodium transport, RNa, and apical cell membrane resistance, Ro, rapidly decreased, while the resistance of the basolateral cell membrane, Ri, and the resistance of the shunt pathway, Rs, remained unchanged. It is concluded that dDAVP primarily increases sodium permeability of the apical cell membrane which subsequently stimulates sodium pump activity. This action is similar to that of AVP.     

Voltage clamp simulations for multifiber bundles in a double sucrose gap: radial vs. longitudinal resistance effects

Voltage clamp responses of a single excitable fiber were simulated using a core conductor model including a high external resistance (Rs) in series to the fiber membrane to allow for intercellular clefts in a multifiber preparation. In terms of specific resistance, Rs was between 68 and 264 omega cm2. Internal resistivity (Ri) was taken to be zero or 200 omega cm. The aim of the study was to quantify the expected antagonistic effects of external and internal resistances on Na current measurements. With Ri = 0, the external resistance was found to cause a strong depression of fast inward current compared to an ideal space clamp at command potentials between -30 and 30 mV. With Ri = 200 omega cm, the depression of inward current was partially removed. The effects of Rs and Ri on membrane current measurement were illustrated by cable analysis assuming a quasi-steady state of the fiber at peak time of inward current.     

Influence of anaesthetics on the movement of the mobile charges in the algal cell membrane of Valonia utricularis

Voltage relaxation studies in the presence of anaesthetics were performed on cells of the giant marine alga Valonia utricularis using intracellular microelectrodes. From the decay of the initial membrane voltage which can be described by two relaxation processes the conclusion can be drawn that protein-linked, mobile charges are present which are probably involved in turgor-pressure-dependent potassium transport (Büchner, K.-H., Rosenheck, K. and Zimmermann, U. (1985) J. Membrane Biol. 88, 131-137). The anaesthetics halothane and chloroform were found to affect reversibly, procaine and tetracaine irreversibly the translocation rate k of the mobile charges at concentrations which were equal to (for halothane and chloroform) or significantly below (for procaine and tetracaine) clinical and nerve blocking levels. The concentration of the mobile charges Nt as well as the specific membrane resistance Rm and the specific membrane capacitance Cm remained unchanged in these concentration ranges. The data suggest a specific interaction of anaesthetics with specialized target sites of a transport protein to which the mobile charges are coupled.     

Stereologic analysis of vacuolization of the T-system of frog muscle fibers, detected using confocal fluorescence microscopy

The confocal fluorescence microscopy has been used for quantitative evaluation of the T-system reversible vacuoles produced by efflux of 80-120 mM glycerol from frog skeletal muscle fibers. The fibers were stained by membrane probe RH414 and by water-soluble dye fluorescein dextran that marks the vacuolar lumen. Using morphometrical and stereological methods the volume and surface densities of vacuoles were measured on single optical sections and Z-series during a 30 min glycerol efflux. Various methods of measurements (three-dimensional reconstruction of vacuoles, computer morphometry, point counting method) applied to the same Z-series provide similar results. The vacuolar membranes stained by RH414 look like bright rings 0.3-0.4 micron in width. It is concluded that the real position of vacuolar membrane corresponds to the middle of the vacuolar envelope. The measurements of the external dimensions of the envelope overestimate the stereological parameters up to 50%. The volume density of vacuoles reaches 10% within 20-30 min of glycerol efflux. It means that the volume of the T-system may increase by 25-30 times compared to the control value (0.3-0.4%). The surface density of vacuoles during reversible vacuolation is equal to 0.20-0.35 micron-1 and does not exceed the surface density of normal T-system. The sufficiency of membrane material for the T-system reversible vacuolation is discussed in addition to the role of geometrical factor in this phenomenon.     

Observations on “Detubulated” Muscle Fibres

GLYCEROL treatment of striated muscle^1–3 has been widely assumed to be a means of disconnecting the transverse tubular system from the surface membrane. Exposure of a sartorius muscle to Ringer plus 400 mM glycerol followed by a return to Ringer, reduces the membrane capacity of superficial fibres and the muscle is mechanically inactive even though the fibres can transmit action potentials; both these effects might be expected if the transverse tubular system was destroyed or disconnected from the extracellular fluid. We have studied this mechanical decoupling on isolated muscle fibres from the semitendinosus, examining the effects of glycerol concentration. Our results suggest that decoupling may be a complex process and in particular they show that under some circumstances both the depolarization and the loss of the twitch can be reversed by re-exposure to glycerol.     

The methanoreductosome: a high-molecular-weight enzyme complex in the methanogenic bacterium strain Gö1 that contains components of the methylreductase system.

The methanogenic bacterium strain G?1 harbors a high-molecular-weight enzyme complex containing methyl coenzyme M methylreductase as revealed by immunoelectron microscopy. This complex consists of a spherelike, hollow head piece, in the wall of which a number of copies of the methyl coenzyme M methylreductase are located. It is named Rc (c indicates collector). Intimately bound to it is a group of additional subunits of unknown composition referred to as Rm (m indicates mediator). Electron microscopy of negatively stained samples indicated that Rm contains a functional pore or channel which connects the internal volume of Rc with the outside. The RcRm complex is named Rs (s indicates spherelike). This complex was often found detached from the inside of the cytoplasmic membrane when membrane vesicles were investigated. However, Rs was also seen attached to a third component of the complex located in the membrane, the attachment being mediated by Rm. This membrane part of the complex is designated Rt (t indicates translocator). It consists of subunits with unknown composition. When Rs is attached to the membrane, the pore in Rm appears to be plugged by Rt. This indicates that the internal volume in Rc is in contact, via the pore in Rm, with Rt. The RcRmRt complex is referred to as methanoreductosome. Functional implications of the structural organization of the methylreductase system are discussed in view of methane formation and the creation of a transmembrane proton gradient used by the cell for ATP synthesis.     

Effect of microwave electromagnetic field on skeletal muscle fibre activity

The aim of the present study was to investigate the influence of microwave irradiation on fatiguing activity of isolated frog skeletal muscle fibres. The changes in the electrical and mechanical activity were used as criteria for the exposure effects. Repetitive suprathreshold stimulation with interstimulus interval of 200 ms for 3 min was applied. Intracellular (ICAP) and extracellular (ECAP) action potentials and twitch contractions (Tw) of muscle fibres after 1 hour microwave exposure (2.45 GHz, 20 mW/cm( 2) power density) were compared with those recorded after one hour sham exposure (control). The duration of uninterrupted activity in the trial (endurance time; ET) was not significantly affected by microwave field exposure. After microwave irradiation, the ICAP amplitude was higher, the rising time was shorter, and the resting membrane potential was more negative compared to controls. There was a slower rate of parameters changes during ET in potentials obtained from irradiated fibres. Microwave exposure increased the propagation velocity of excitation, the ECAP and Tw amplitudes, as well as shortened their time parameters. We concluded that a 2.45 GHz microwave field possesses a stimulating effect on muscle fibre activity, which is in part due to its specific, non-thermal properties. The microwave induced-changes in muscle fibre activity may reduce development of skeletal muscle fatigue.     

Cholera and pertussis toxins modify regulation of glucose transport activity in rat adipose cells: evidence for mediation of a cAMP-independent process by G-proteins.

Adenylyl cyclase in rat adipose cells is stimulated by ligands for Rs receptors (e.g. isoproterenol) and inhibited by ligands for Ri receptors (e.g. adenosine). In contrast, Rs receptors mediate inhibition and Ri receptors mediate augmentation of insulin-stimulated glucose transport activity by a process independent of changes in cellular cAMP-dependent protein kinase activity [Kuroda M., Honnor R. C., Cushman S. W., Londos C. and Simpson I. A. (1987) J. biol. Chem. 262, 245-253]. The present study examines the possible role of G-proteins in the regulation of insulin-stimulated glucose transport activity by Rs and Ri receptors. First, conditions were established that permit intoxication of isolated rat adipocytes by cholera and pertussis toxins without compromising cell integrity. Effectiveness of toxin treatment was monitored by examining adenylyl cyclase activity in isolated plasma membranes. Secondly, neither toxin interfered with the ability of a maximal concentration insulin to initiate the glucose transport response. Thirdly, pertussis toxin eliminated the augmenting effects of adenosine on insulin-stimulated glucose transport activity, but enhanced the inhibitory effects of isoproterenol. Findings with ligands for other Ri receptors (nicotinic acid and prostaglandin E2) mirrored those with adenosine. Finally, cholera toxin elicited a modest depression of transport activity, and only in the absence of an Ri ligand (e.g. adenosine). Furthermore, in contrast to the enhanced stimulation of adenylyl cyclase by isoproterenol and GTP, cholera toxin eliminated the inhibitory effect of isoproterenol on transport activity. The augmentative effects of adenosine on transport activity were unchanged. Measurements of (-/+cAMP) cAMP-dependent protein kinase activity ratios reinforce the notion that modulation of glucose transport activity is independent of changes in cAMP. We conclude that regulation of glucose transport activity by Rs and Ri receptors is mediated by the G-proteins, Gs and Gi (or other toxin substrates), respectively. Inasmuch as such regulation occurs at the plasma membrane and appears to be cAMP-independent, it is suggested that glucose transporters may be direct targets for receptor: G-protein interactions.     

Osmotic and pharmacological effects of formamide on capacity current, gating current, and sodium current in crayfish giant axons.

Internal perfusion with solutions made hyperosmolar by 10% formamide selectively reduces the initial fast component of ON gating current (fast Ig) in crayfish axons. This result parallels the effects of formamide perfusion seen in Myxicola giant axons (Schauf, C. L., and M. A. Chuman. 1986. Neural Membranes. Alan R. Liss, Inc., New York. 3-23). However, our findings do not confirm their conclusion that internal formamide has a specific pharmacological effect on fast Ig. Formamide-induced suppression of fast Ig is always associated with changes in linear capacity current, indicating a reduction in the rate of rise of the voltage clamp. Furthermore, this suppression of fast Ig can be reversed when clamp rise time is returned to its control rate by increasing compensation for series resistance (Rs) during formamide perfusion. Increases in Rs during 10% formamide perfusion of up to 5 omega.cm2 were measured by evaluating the increase in Rs compensation required to return the following parameters to their control levels: (a) peak capacity current, (b) peak gating current, (c) the voltage maximum of the /Na-V curve, and (d) "tau h". We conclude that hyperosmolar internal formamide increases Rs, reduces clamp speed, and thus selectively suppresses fast Ig. On the other hand, the reversible block of sodium ionic current by internal formamide, reported by Schauf and Chuman, is not eliminated by correcting for series resistance changes during formamide perfusion.     

Localization of ionic conductances in crayfish muscle fibers

Summary Analysis of the changes in membrane potential and conductance of isolated crayfish muscle fibers caused by rapid solution changes leads to the following conclusions. First, the extensive invagination system of this fiber presents a barrier for diffusion between bath and sarcolemma that accounts for the time lag of electrical responses to changes in bath chloride concentration. Morphological data regarding these invaginations were used in a model which simulated the fiber response on an analog computer. Second, the potassium conductance is effectively localized on the sarcolemma in direct contact with the bath (superficial sarcolemma), whereas the chloride conductance is restricted to the invaginations. This distribution of conductances is the reverse of that found in frog muscle.     

Electromechanical stability of planar lipid membranes from bipolar lipids of the thermoacidophilic archebacterium Sulfolobus acidocaldarius

Stable planar membranes have been obtained from the bipolar lipid glycerol dialkyl nonitol tetraether (GDNT) extracted from the thermoacidophilic archebacterium Sulfolobus acidocaldarius. The electric capacity Cm, the resistance Rm and tension sigma of these membranes were measured. The dependence of the bipolar lipid membranes mean life time tau 1 on voltage was investigated. It was shown that the irreversible electric breakdown of membranes from GDNT and usual phospholipids is due to the same mechanism, viz., due to formation of a hydrophilic pore with an overcritical radius. Under electric field the GDNT molecules take U-shape, and the polar headgroups of such molecules cover the pore's interior.     

Action Potentials, Afterpotentials, and Excitation-Contraction Coupling in Frog Sartorius Fibers without Transverse Tubules

In frog sartorius muscle fibers in which the transverse tubular system has been disrupted by treatment with glycerol, action potentials which are unaccompanied by twitches can be recorded. These action potentials appear to be the same as those recorded in normal fibers except that the early afterpotential usually consists of a small hyperpolarization of short duration. After a train of action potentials no late afterpotential is seen even when the membrane potential is changed from the resting level. In fibers without transverse tubules hyperpolarizing currents do not produce a creep in potential. The interruption of excitation-contraction coupling, the changes in the afterpotentials, and the disappearance of creep are all attributed to the lack of a transverse tubular system.     

Effects of cortisone on mechanical activity and membrane ionic currents in frog auricular fibres.

The influence of cortisone on the mechanical and electrical activity of frog auricular fibres was investigated under voltage clamp conditions. 1. Cortisone exerted in vitro an inotropic action depending on concentration; a maximal positive inotropic effect was observed with 2 x 10(-4) g/ml of cortisone. 2. The positive inotropic effect of cortisone might be either an indirect sympathomimetic effect or an adrenaline-like effect. 3. The positive inotropic action of cortisone was correlated with modifications of the cardiac action potential: the amplitude of the action potential was enhanced while the resting membrane potential was unchanged; the amplitude and duration of the plateau were increased and the duration of the action potential was lengthened. 4. The electrical changes were related to an increase in the slow calcium current intensity resulting from an increase in the slow calcium conductance.