Electrical properties ofValonia ventricosa

Summary The cytoplasmic electrical potential and membrane resistance of mature cells ofValonia ventricosa have been measured by inserting a microelectrode concentric with another electrode into the vacuole of the cell. The cytoplasmic region was investigated by advancing the microelectrode into the cell wall from the vacuolar side.The results revealed a unique region where the vacuolar electric potential and membrane resistance changed in a simultaneous single step to values close to zero. The measured potential always remained positive immediately after the step.At no time was a highly negative potential region encountered. Further penetration of the microelectrode revealed a low resistance negative potential region of –12.6±1.1 mV associated with the cell wall. Experiments were also carried out on aplanospores ofV. ventricosa to compare mature and immature cells. The chemical composition of the vacuolar and protoplasmic phases of mature cells was determined. The results agreed with previous results except that the Cl^– ion content of the protoplasm was significantly higher at 381±20 mmoles/liter (H₂O). It was concluded that mature cells ofValonia are significantly different from immature cells in that no highly negative potential cytoplasmic region was found in mature cells.It was considered that the measured step change in electric potential and membrane resistance occurred at the plasmalemma and that the tonoplast was a region of very low resistance. The implications of these findings in terms of models of ion transport intoValonia are discussed.     

Electric discharges of two species of stargazers from the South China Sea (Uranoscopidae,Perciformes)

Experimentally, the specialized electrogenerative activity is discovered in two representatives of the family Uranoscopidae (Uranoscopus bicinctus and U. affinis) living in the coastal zone of Nha Trang Bay of the South China Sea (Vietnam). For the first time, the electric discharges of duration up to 100 ms are recorded in U. bicinctus and up to 300 ms in U. affinis. The discharges are monopolar oscillations of the potential with electronegativity in the area of the fish head. Distribution of potentials on the body surface of the stargazer was investigated. It is shown that the electric field during the discharge has dipole characteristics and the zone of the “null” equipotential is situated in the area of the soft dorsal fin. Electrophysiological experiments, using the method of microelectrode stimulation of different regions of the brain, demonstrated that stable electric discharges are caused by stimulation of the medial zone of the bottom of the fourth ventricle in medulla oblongata. The discharges caused in such way are fully analogous to those generated spontaneously and under mechanical stimulation of the skin. Thus, the conclusion could be made on localization of the stargazer’s electromotor center in this zone.     

The Receptor Potential of the Taste Cell of the Rat

The electrical responses of the taste cell of the rat to chemical stimuli were studied by means of microelectrode techniques. Although large positive potential changes in the taste cell were usually elicited by taste stimuli, the response was a small negative potential change with respect to surrounding tissues if the microelectrode was thrust deeply into the taste bud. Both FeCl₃ and cocaine produced a positive change in the steady potential. If this new potential is larger than a certain equilibrium potential, reversal of the polarity of the potential change caused by a taste stimulus is observed. Gamma-aminobutyric acid and acetylcholine had no effect on the receptor steady potential nor on the receptor responses elicited by taste stimuli.     

Measurement of Extracellular Ion Fluxes Using the Ion-selective Self-referencing Microelectrode Technique

Cells from animals, plants and single cells are enclosed by a barrier called the cell membrane that separates the cytoplasm from the outside. Cell layers such as epithelia also form a barrier that separates the inside from the outside or different compartments of multicellular organisms. A key feature of these barriers is the differential distribution of ions across cell membranes or cell layers. Two properties allow this distribution: 1) membranes and epithelia display selective permeability to specific ions; 2) ions are transported through pumps across cell membranes and cell layers. These properties play crucial roles in maintaining tissue physiology and act as signaling cues after damage, during repair, or under pathological condition. The ion-selective self-referencing microelectrode allows measurements of specific fluxes of ions such as calcium, potassium or sodium at single cell and tissue levels. The microelectrode contains an ionophore cocktail which is selectively permeable to a specific ion. The internal filling solution contains a set concentration of the ion of interest. The electric potential of the microelectrode is determined by the outside concentration of the ion. As the ion concentration varies, the potential of the microelectrode changes as a function of the log of the ion activity. When moved back and forth near a source or sink of the ion (i.e. in a concentration gradient due to ion flux) the microelectrode potential fluctuates at an amplitude proportional to the ion flux/gradient. The amplifier amplifies the microelectrode signal and the output is recorded on computer. The ion flux can then be calculated by Fick’s law of diffusion using the electrode potential fluctuation, the excursion of microelectrode, and other parameters such as the specific ion mobility. In this paper, we describe in detail the methodology to measure extracellular ion fluxes using the ion-selective self-referencing microelectrode and present some representative results.     

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.     

Studies on the electrogenic action of acetylcholine with Torpedo marmorata electric organ: I. Pharmacological properties of the electroplaque

The membrane potential (average = ?52 mV) of a freely exposed electroplaque from a dissected prism of Torpedo marmorata electric organ is recorded with an intracellular glass microelectrode. The resting potential decreases with external potassium concentration. Acetylcholine (in the presence of O,O′-diethyl S-(β-diethylamino)ethyl phosphorothiolate), decamethonium, phenyltrimethyl-ammonium and carbamylcholine added to the bath cause a decrease of membrane potential, i.e. behave as agonists. Their effect is blocked in a competitive manner by d-tubocurarine, gallamine and hexamethonium, and in a non-competitive way by prilocaine; 1 μg Erabutoxin/ml completely abolishes the response to carbamylcholine. The apparent dissociation constants for seven cholinergic ligands are determined from the dose-response curves, and found to be closely related to those previously determined with Electrophorus electricus electroplaque with, however, a few differences. During these experiments it was noticed that potassium ions affect, in a differential manner, the response of T. marmorata electroplaque to carbamylcholine and decamethonium.     

Electric current precedes emergence of a lateral root in higher plants

Stable electrochemical patterns appear spontaneously around roots of higher plants and are closely related to growth. An electric potential pattern accompanied by lateral root emergence was measured along the surface of the primary root of adzuki bean (Phaseolus angularis) over 21 h using a microelectrode manipulated by a newly developed apparatus. The electric potential became lower at the point where a lateral root emerged. This change preceded the emergence of the lateral root by about 10 h. A theory is presented for calculating two-dimensional patterns of electric potential and electric current density around the primary root (and a lateral root) using only data on the one-dimensional electric potential measured near the surface of the primary root. The development of the lateral root inside the primary root is associated with the influx of electric current of about 0.7 μA·cm⁻² at the surface.     

Simultaneous Measurement of the Bioelectric Potential of the Cell Wall and the Vacuoles during the Oscillatory Response to the Nitella Cell

Simultaneous measurements of bioelectric potentials of the vacuole and cell wall in cells of Nitella mucronata were made by inserting glass microelectrodes into the vacuole and cell wall respeclively. During the oscillation of the bioelectric potential of the vacuole. induced by sudden changes of the external bathing solution or by the impalement of the cell with a microelectrode. the cell wall potential also exhibited fluctuations of variable intensities in phase and concomitant with spikes of the vacuolar potential oscillation. However, the polarity of the pulses of the cell wall potential was reverse to that of the spikes of the vacuolar potential. These results suggest that the same event is registered at both sides of the plasmalemma membrane across which these phenomena are occurring. The results also support the voltage clamp and tracer flux measurements on these cells which indicate that during the generation of single action potentials, induced by current, the plasma lemma transiently increases its permeability to Cl^? and K⁺ ions expelling them from the cell. The variable intensity of the transient hyperpolarizations of the cell wall potential is explained by the distance of the microelectrode in the cell wall from the plasmalemma.     

Taking the time to make important decisions: The checkpoint effector kinases Chk1 and Chk2 and the DNA damage response

The cellular DNA damage response (DDR) is activated by many types of DNA lesions. Upon recognition of DNA damage by sensor proteins, an intricate signal transduction network is activated to coordinate diverse cellular outcomes that promote genome integrity. Key components of the DDR in mammalian cells are the checkpoint effector kinases Chk1 and Chk2 (referred to henceforth as the effector kinases; orthologous to spChk1 and spCds1 in the fission yeast S. pombe and scChk1 and scRad53 in the budding yeast S. cerevisiae). These evolutionarily conserved and structurally divergent kinases phosphorylate numerous substrates to regulate the DDR. This review will focus on recent advances in our understanding of the structure, regulation, and functions of the effector kinases in the DDR, as well as their potential roles in human disease.     

Mauthner cell-initiated abrupt increase of the electric organ discharge in the weakly electric fishGymnotus carapo

Stimulation of the spinal cord of the electric fish Gymnotus carapo, evoked an abrupt increase in the discharge rate of the electric organ. At the maximum of this response, the rate increased an average of 26 ± 11.8%. The duration of the response was 4.9 ± 2.12 s; its latency was 10.4 ± 1.1 ms. Activation of the Mauthner axon played a decisive role in this phenomenon as indicated by the following: (1) recordings from the axon cap of the Mauthner cell demonstrated that the response was evoked if the Mauthner axon was antidromically activated and (2) a response that was similar to that produced by spinal cord stimulation, was elicited by intracellular stimulation of either Mauthner cell. Stimulation of the eighth nerve could also increase the discharge rate of the electric organ. The effect was greater if a Mauthner cell action potential was elicited. The findings described in the present report, indicate the existence of a functional connection between the Mauthner cell and the electromotor system in Gymnotus carapo. This connection may function to enhance the electrolocative sampling of the environment during Mauthner-cell mediated behaviors. This is a novel function for the Mauthner cell.Abbreviations EHP extrinsic hyperpolarizing potential - EOD electric organ discharge - M-AIR Mauthner initiated abrupt increase in rate - M-cell Mauthner cell - M-axon Mauthner axon - PM pacemaker nucleus - PM-cell pacemaker cell - PPn prepacemaker nucleus - SPPn sublemniscal prepacemaker nucleus