Electrical properties of subsynaptic and nonsynaptic membranes of horizontal cells of the turtle retina

Horizontal cells of the L-type in the turtle retina were polarized by passing a steady current through extracellular electrodes. In this way controlled changes in membrane potential can be effectively produced in the region of the cell body. The hyperpolarization response of the horizontal cell to light is reversed on depolarization of the cell membrane to about the zero level. Consequently, the response of the horizontal cell to light is the result of a decrease in the EPSP, the magnitude of which remains constant in darkness. The resistance of the cell membrane depends on the membrane potential. Hyperpolarization of horizontal cells produced by bright light or by passage of a steady current was accompanied by a decrease in their membrane resistance. This nonlinearity evidently depends on the properties of the nonsynaptic membrane of the horizontal cells, whose resistance falls considerably on hyperpolarization. The results are qualitatively similar to those demonstrated previously [10] in an investigation of the horizontal cells of the fish retina.Institute for Problems in Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 5, No. 4, pp. 423–431, July–August, 1973.     

Investigation of the nature of electrical responses of horizontal cells of the fish retina

On the basis of the syncytial structure of the layer of horizontal cells of the fish retina, a method is developed which effectively shifts the membrane potential of cells by means of an electrical current. It is shown that the response of L-type horizontal cells to light and electrical stimulation of the retina is reversed when the membrane of the horizontal cells is depolarized by a direct current. The equilibrium potential of the cells was near the zero level. Consequently, the depolarization response of the horizontal cells to disconnection of the light and to electrical stimulation of the retina is an excitatory postsynaptic potential, whereas hyperpolarization of the horizontal cells to light is a decrease of this potential. It is shown that the membrane of fish horizontal cells have pronounced nonlinear properties: in the case of strong depolarization and especially in the case of hyperpolarization its impedance drops markedly. The latter probably occurs due to an increase of the permeability of the nonsynaptic membrane of the horizintal cells for K⁺. This can also explain the decrease of membrane impedance during the hyperpolarization response of the horizontal cells to bright light. The available data indicate the presence of regenerative properties of the membrane of horizontal cells.Institute of Problems of Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 3, No. 1, pp. 89–98, January–February, 1971.     

Local changes of resistance in the retinal horizontal cell evoked by changes in membrane potential

A steady current (10·10^–10–6·10^–9 A) was passed by means of a bridge circuit through a recording microelectrode inserted into a horizontal cell of the turtle retina. Illumination of the retina caused an increase in the resistance of the microelectrode circuit (by 10–80 M), causing a change in the shape of the recorded response of the horizontal cell to light. The change in resistance was shown to take place, not on the cell membrane itself, but inside the cell close to the microelectrode tip. The effect described can be reproduced by passing a current through one barrel of a double-barreled microelectrode alongside the recording barrel, but the strength required for this current was greater than that passed through the recording barrel. If the membrane potential of the horizontal cell was made equal to the equilibrium potential (by means of a steady current passed through extracellular electrodes) the hyperpolarization response to light and the effect of the increase in resistance of the microelectrode circuit disappeared simultaneously. On the other hand, artificial hyperpolarization of the cell membrane caused an increase, but depolarization caused a decrease in the resistance of the microelectrode circuit. It is postulated that the observed effect is due to blocking of the microelectrode tip by an intracellular structure whose resistance varies with a change in membrane potential.Institute of Problems in Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol.5, No.4, pp.432–441, July–August, 1973.     

Membrane potential clamping in horizontal cells of the fish retina

The membrane potential of horizontal cells of the retina was clamped by uniform polarization of the layer of these cells by a current passed through extracellular electrodes. The volt-ampere characteristic curve of the synaptic membrane of the horizontal cells in some cases had segments with negative slope. With a sharp change in the level of voltage clamping the time taken for the resistance of the membrane to change was under 20 msec. Comparison of responses to photic stimulation recorded with and without voltage clamping showed that participation of the nonsynaptic membrane in the generation of responses to photic stimulation can affect their shape substantially.Institute of Problems in Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 9, No. 4, pp. 402–407, July–August, 1977.     

Peculiarities of synaptic transmission between photoreceptors and horizontal cells

A previously advanced hypothesis, according to which the transmitter which depolarizes the membrane of horizontal cells is continually liberated in the dark, and ceases to be liberated in the light, is tested experimentally. The data presented show that a current acting on presynatic receptor endings evokes a depolarizing response in horizontal cells to short current impulses passing through the retina (anode on receptor surface, cathode in vitreous body). These receptor endings are depolarized, which evidently leads to liberation of the transmitter from the receptors. Experiments with electrical stimulation of the retina have shown that treatment of the retina with potassium cyanide disrupts synaptic transmission between the receptor and horizontal cell. A potential equal to their membrane potential is established in horizontal cells in bright light; this potential is evidently the true rest potential of these cells. The relative stability of the membrane potential of horizontal cells in light with change in temperature is evidence in support of this assumption. In the dark, the membrane potential increases considerably with increase in temperature; this effect is possibly due to a rise in the rate of decomposition of the depolarizing transmitter. Evidence in support of this hypothesis is the rise in steepness of the falling phase of the response of the horizontal cells to electrical stimulation observed on elevation of the temperature.Institute for Problems of Information Transmission of the Academy of Sciences of the USSR, and Institute of Higher Nervous Activity and Neurophysiology of the Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 2, No. 1, pp. 79–86, January–February, 1970.     

Changes in direct current input resistance in horizontal cells of fish retina during excitation

The input resistance of pike retinal horizontal cells was measured by means of coaxial electrodes under various conditions of illumination. With moderate intensities of illumination, the resistance (determined from a potential drop caused by the current passed through the microelectrode) increases, whereas at high saturating intensities it decreases, as compared with its value in darkness. Such changes in resistance of the horizontal cells explain the effects of input signals interaction in these cells, such as enhancement and complete saturation, observed earlier. Some properties of the horizontal cell response permit us to assume that the "active" cell response to polarization makes a substantial contribution to the measured resistance of these cells. Possible mechanisms of such changes in input resistance of horizontal cells are discussed.Institute of Problems in Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 3, No. 2, pp. 210–216, March–April, 1971.     

Measurement of the latent period of the response of the turtle horizontal retinal cell to electrical stimulation

We have measured the latent period of the depolarization reaction occurring in horizontal cells in response to short bursts of current sent through the retina (anode on sclera, cathode in vitreous). The latent period varied in different experiments from 3 to 7 msec. It is thought that the current acts directly on the presynaptic membrane of the receptors, and that the measured value of the latent period comprises the time of synaptic delay in the transmission of the signal from the receptors to the horizontal cells. The value of the latent period is close to the time interval between the onset of the distal and proximal subcomponents of P_III, as measured by Murakami et al [7, 8], an interval which probably represents time between the onset of the receptor potential and the development of the electrical response of the cells of the inner nuclear layer.Institute of Problems of Transmission of Information, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 2, No. 1, pp. 87–90, January–February, 1970.     

The Spatial Variation of Membrane Potential Near a Small Source of Current in a Spherical Cell

A theoretical analysis is presented of the change in membrane potential produced by current supplied by a microelectrode inserted just under the membrane of a spherical cell. The results of the analysis are presented in tabular and graphic form for three wave forms of current: steady, step function, and sinusoidal. As expected from physical reasoning, we find that the membrane potential is nonuniform, that there is a steep rise in membrane potential near the current microelectrode, and that this rise is of particular importance when the membrane resistance is low, or the membrane potential is changing rapidly. The effect of this steep rise in potential on the interpretation of voltage measurements from spherical cells is discussed and practical suggestions for minimizing these effects are made: in particular, it is pointed out that if the current and voltage electrodes are separated by 60°, the change in membrane potential produced by application of current is close to that which would occur if there were no spatial variation of potential. We thus suggest that investigations of the electrical properties of spherical cells using two microelectrodes can best be made when the electrodes are separated by 60°.     

Reversal potential for monosynaptic EPSP in frog motoneurons

Experiments were conducted on brain isolated from the frogRana ridibunda using a current chop technique of transmembrane polarization and discrete measurement of membrane potential by a single microelectrode during intervals between waves of current. It was found that the current-voltage relationship of the motorneuron is non-linear; i.e., membrane resistance decreases considerably in step with increased depolarizing current. After the initial reduction, membrane resistance began to climb back when a more protracted current lasting 1–2 min was applied; consequently membrane potential level shifted towards more positive values of +50 mV and above at current levels of 40–60 nA. It then became possible to bring about complete reversal of monosynaptic EPSP produced in the lumbar motoneurons by stimulation of the brainstem reticular formation or by microelectrode stimulation of the ventrolateral tract descending fibers and to measure reversal potential of these EPSP directly, without resorting to computing or extrapolation. Measurements varied mainly between 0 and –10 mV.I. M. Sechenov Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 18, No. 4, pp. 534–542, July–August, 1986.     

Interactions between a membrane sialoglycoprotein and planar lipid bilayers

Summary Bilayer membranes formed from lipids dissolved in decane were exposed to glycophorin, a sialoglycoprotein which had been extracted from human red cell membranes. The interaction with the bilayer produced an increase in the steady state electrical conductance of the membrane proportional to the amount added. Fluctuations in membrane current when the electrical potential difference was constant were observed concommitantly with this increase in membrane conductance. The minimum size of the fluctuations corresponds to a conductance of 10^–10 mho. The increase in conductance as well as the current fluctuations persisted after extensive washout of the chamber containing the protein (cisside). Subsequent addition of lectins (wheat germ agglutinin and phytohemoagglutinin) to the cis-side produced rupture of the membranes, whilst these hemoagglutinins added to the trans-side failed to produce an effect. Measurements of changes in surface potential using K⁺ nonactin as a probe indicated that glycophorin induces a negative surface charge. At high protein concentrations, the magnitude of the induced surface potential became independent of glycophorin concentration. The maximum number of charges introduced onto the membrane under these conditions was 1.4×10⁵/m². Cis (but not trans)-side addition of neuraminidase abolished these charges, indicating that they can be ascribed to the sialic acid residues that the protein bears. These results suggest that glycophorin incorporates into bilayer membranes with its N-terminal end (where the sialic acid and carbohydrates are located) facing the cis-side. Spectrin reversibly lowered the glycophorin-induced membrane conductance when added to the trans-side. Cis-side additions failed to produce an effect. Trypsin present on the trans-side irreversibly lowered the membrane conductance. These results indicate that parts of the glycophorin molecule, probably the C-terminal end, are accessible to reagents in the solution bathing the trans-side of the membrane. Thus glycophorin spans the planar bilayer in much the same way as it spans the red cell membrane.     

Effect of intracellular injection of cyclic amp on electrical characteristics of identified neurons in Helix pomatia

The effect of intracellular iontophoretic injection of cyclic AMP on electrical activity of neurons RPa1, RPa3, LPa2, LPa3, and LPl1 in the corresponding ganglia ofHelix pomatia was investigated. Injection of cyclic AMP into neuron LPl1 was found to cause the appearance of rhythmic activity (if the neuron was originally "silent"), an increase in the frequency of spike generation (if the neuron had rhythmic activity), and a decrease in amplitude of waves of membrane potential, in the duration of the interval between bursts, and in the number of action potentials in the burst (if the neuron demonstrated bursting activity). In the remaining "silent" neurons injection of cyclic AMP led to membrane depolarization. Injection of cyclic AMP into neurons whose membrane potential was clamped at the resting potential level evoked the development of an inward transmembrane current (cyclic AMP current), the rate of rise and duration of which increased proportionally to the size and duration of the injection. Theophylline in a concentration of 1 mM led to an increase in the amplitude and duration of the cyclic AMP current by about 50%. It is concluded that a change in the cyclic AMP concentration within the nerve cell may modify the ionic permeability of its membrane and, correspondingly, its electrical activity.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 12, No. 5, pp. 517–525, September–October, 1980.     

Model feedback mechanism between horizontal cells and photoreceptors of the vertebrate retina

A model with nonlinearity of the photoreceptor presynaptic membrane as its important distinguishing feature was created on the basis of the hypothesis that feedback between the horizontal cells and photoreceptors is effected by a current generated by the subsynaptic membrane of the horizontal cells and leaking partly into the photoreceptors. Measurements with the model also reproduced experimental observations such as depolarization of the cone during hyperpolarization of the horizontal cell in response to the showing of a ring of light or passage of an electric current, and also certain special features of the current-voltage curves of the cones.Institute of Problems in Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 9, No. 1, pp. 86–94, January–February, 1977.     

Effects of Temperature on the Generator and Action Potentials of a Sense Organ

Charge transfer through the receptor membrane of the nonmyelinated ending of Pacinian corpuscles is markedly affected by temperature. The rate of rise and the amplitude of the generator potential in response to a constant mechanical stimulus increase with temperature coefficients of 2.5 and 2.0 respectively. The duration of the falling phase, presumably a purely passive component, and the rise time of the generator potential are but little affected by temperature. The following interpretation is offered: Mechanical stimulation causes the conductance of the receptor membrane to increase and ions to flow along their electrochemical gradients. An energy barrier of about 16,000 cal/mole limits the conductance change. The latter increases, thus, steeply with temperature, causing both the rate of rise and the intensity of the generator current to increase. The membrane of the adjacent Ranvier node behaves in a distinctly different manner. The amplitude of the nodal action potential is little changed over a wide range of temperature, while the durations of its rising and falling phases increase markedly. The electrical threshold of the nodal membrane is rather constant between 40 and 12°C. Below 12°C the threshold rises, and the mechanically elicited generator current fails to meet the threshold requirements of the first node. Cold block of nerve impulse initiation then ensues, although the receptor membrane still continues to produce generator potentials in response to mechanical stimulation.     

Investigation of the mechanism of temperature sensitivity of the electroreceptors of ampullae of lorenzini

In experiments on Black Sea skates (Raja clavata), the potential of the receptor epithelium of the ampullae of Lorenzini and spike activity of single nerve fibers connected to them were investigated during electrical and temperature stimulation. Usually the potential within the canal was between 0 and –2 mV, and the input resistance of the ampulla 250–400 k. Heating of the region of the receptor epithelium was accompanied by a negative wave of potential, an increase in input resistance, and inhibition of spike activity. With worsening of the animal's condition the transepithelial potential became positive (up to +10 mV) but the input resistance of the ampulla during stimulation with a positive current was nonlinear in some cases: a regenerative spike of positive polarity appeared in the channel. During heating, the spike response was sometimes reversed in sign. It is suggested that fluctuations of the transepithelial potential and spike responses to temperature stimulation reflect changes in the potential difference on the basal membrane of the receptor cells, which is described by a relationship of the Nernst's or Goldman's equation type.I. P. Pavlov Institute of Physiology, Academy of Sciences of the USSR, Leningrad. I. M. Sechenov, Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Pacific Institute of Oceanology, Far Eastern Scientific Center, Academy of Sciences of the USSR, Vladivostok. Translated from Neirofiziologiya, Vol. 12, No. 1, pp. 67–74, January–February, 1980.     

A synthetic strand of cardiac muscle: its passive electrical properties

The passive electrical properties of synthetic strands of cardiac muscle, grown in tissue culture, were studied using two intracellular microelectrodes: one to inject a rectangular pulse of current and the other to record the resultant displacement of membrane potential at various distances from the current source. In all preparations, the potential displacement, instead of approaching a steady value as would be expected for a cell with constant electrical properties, increased slowly with time throughout the current step. In such circumstances, the specific electrical constants for the membrane and cytoplasm must not be obtained by applying the usual methods, which are based on the analytical solution of the partial differential equation describing a one-dimensional cell with constant electrical properties. A satisfactory fit of the potential waveforms was, however, obtained with numerical solutions of a modified form of this equation in which the membrane resistance increased linearly with time. Best fits of the waveforms from 12 preparations gave the following values for the membrane resistance times unit length, membrane capacitance per unit length, and for the myoplasmic resistance: 1.22 plus or minus 0.13 x 10-5 omegacm, 0.224 plus or minus 0.023 uF with cm-minus 1, and 1.37 plus or minus 0.13 x 10-7 omegacm-minus 1, respectively. The value of membrane capacitance per unit length was close to that obtained from the time constant of the foot of the action potential and was in keeping with the generally satisfactory fit of the recorded waveforms with solutions of the cable equation in which the membrane impedance is that of a single capacitor and resistor in parallel. The area of membrane per unit length and the cross-sectional area of myoplasm at any given length of the preparation were determined from light and composite electron micrographs, and these were used to calculate the following values for the specific electrical membrane resistance, membrane capacitance, and the resistivity of the cytoplasm: 20.5 plus or minus 3.0 x 10-3 omegacm-2, l.54 plus or minus 0.24 uFWITHcm-minus 2, and 180 plus or minus 34 omegacm, respectively.     

Calcium-activated and voltage-dependent potassium conductances in clonal pituitary cells

Voltage clamp recordings of GH3/B6 pituitary cells reveal the presence of non linear steady state membrane properties at the level of the resting potential (about ?41 mV). Clamping the cells to potentials more depolarized than ?60 mV is associated with a potential dependent increase in membrane conductance and membrane current variance. Tetra-ethylammonium (TEA), Cobalt (Co²⁺) and methoxy-verapamil (D-600) each attenuate these potential-dependent changes. Spectral analysis of membrane current fluctuations shows that power spectral densities calculated for fluctuations occuring over the ? 70 to ? 40 mV range declin? monotonically as a function of frequency, while spectra derived from fluctuations obtained over the ? 20 mV to 0 mV range decline as the square of frequency and are usually well fitted by a single Lorentzian equation. The half-power frequency of these spectra varies from 45 to 65 Hz. If we assume that the activities of two-state (open-closed) ion channels underlie the electrical behaviour of the membrane at the resting potential and at more depolarized levels, then the results suggests the presence of K⁺ ion channels whose activation depends both on potential and Ca²⁺ ions. These K⁺ ion channels have estimated electrical properties (conductance : 15 ps ; duration : 3 msec) similar to those present in other excitable membranes.     

An electrophysiological study of the non-junctional membrane of epidermal cells in Tenebrio molitor

The contribution of K and Cl to the membrane potential of the epidermal cells of the recently-ecdysed larva of the mealworm was examined. The ionic basis for the membrane potential is complex. Although increasing the external K level depolarized the cell membrane, the relationship obtained suggests that ions other than K contribute largely to the recorded membrane potential. In particular, exposing the cells to K concentrations below the normal level of 40 mM has only slight effects on membrane potential, irrespective of whether K is lowered by direct substitution with Na or under conditions in which Na and Cl levels are held constant. Increasing the external Cl levels from 4 mM to 154 mM while holding K and Na levels constant resulted in a 10 mV hyperpolarization. The slight hyperpolarizing effects of high external Cl could be mimicked by citrate, but not by acetate, the latter drastically hyperpolarizing the cell membrane at levels of K that normally maintain a reduced membrane potential. External Na has little effect on the membrane potential at normal physiological levels of K, but may depolarize the cell at low K levels. The results suggest that several inorganic ions, and possibly organic acids, participate in generating the membrane potential of the epidermal cell. The passive ionic properties of non-junctional epidermal membrane and muscle membrane appear to the similar in this insect.The electrical resistance on the non-junctional membrane is highly dependent on the external K level, and can be reduced by three orders of magnitude by increasing external K from 1 mM to 120 mM. The resistance of the junctional membrane remains constant over this range of external K concentrations.     

The fertilization potential is not necessary for the block to polyspermy or the activation of development in the medaka egg

The egg of the medaka, Oryzias latipes, was impaled with two microelectrodes so that its membrane potential could be clamped at a constant level during fertilization. Fertilization occurred at all membrane potentials between ?80 and +48 mV. Therefore, there is apparently no electrical block to polyspermy in this egg. In 16 of these eggs the membrane potential was also clamped at a constant level during the 6- to 14-min period after fertilization and the eggs' subsequent development was studied. All of these eggs developed normally up to at least the beating heart stage. Therefore, the fertilization potential is not necessary for further development. When the egg is clamped at levels more negative than ?25 mV, the injected clamping current is usually biphasic just after fertilization with an inward current phase preceding a longer outward phase. The inward current phase corresponds well in time with the membrane depolarization normally triggered by fertilization. The outward current phase was observed in all eggs studied and the more positive the holding potential, the longer was the outward current duration.     

Passive Electrical Properties of Paramecium and Problems of Ciliary Coordination

Potential recordings made simultaneously from opposite ends of the cell indicate that the cytoplasmic compartment of P. caudatum is nearly isopotential. Measured decrements of the spread of steady-state potentials are in essential agreement with calculated decrements for a short cable model of similar dimensions and electrical constants. Action potentials and passively conducted pulses spread at rates of over 100 µm per msec. In contrast, metachronal waves of ciliary beat progress over the cell with velocities below 1 µm per msec. Thus, electrical activity conducted by the plasma membrane cannot account for the metachronism of ciliary beat. The electrical properties of Paramecium are responsible, however, for coordinating the reorientation of cilia (either beating or paralyzed by NiCl₂) which occurs over the entire cell in response to current passed across the plasma membrane. In response to a depolarization the cilia assume an anteriorly directed orientation ("ciliary reversal" for backward locomotion). The cilia over the anterior half of the organism reverse more strongly and with shorter latency than the cilia of the posterior half. This was true regardless of the location of the polarizing electrode. Since the membrane potential was shown to be essentially uniform between both ends of the cell, the cilia of the anterior and posterior must possess different sensitivities to membrane potential.     

Voltage-dependence of cobalt-induced blockade of synaptic transmission between photoreceptors and horizontal retinal cells

Synaptic transmission between photoreceptors and horizontal cells in the turtle retina blocked by Co²⁺ ions can be restored by passing constant radial current through the retina which depolarizes presynaptic receptor terminals. This finding is unassociated with current action on horizontal cells themselves, since polarization of these cells via an intracellular microelectrode did not restore response to light. The unblocking effect of depolarization at the receptor synaptic endings consists of two components: the opening of additional calcium channels not blocked by Co²⁺ at the presynaptic membrane and cobalt-induced voltage-dependent blockade of clacium channels. The latter may explain the paradoxical phenomenon of increased response to the action of moderate light in horizontal cells during cobalt-induced partial blockade of synaptic transmission.Institute for Research into Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 20, No. 3, pp. 374–383, May–June, 1988.