Electrical excitability of taste cells. Mechanisms and possible physiological significance

Neuronal, muscle and some endocrine cells are electrically excitable. While in muscle and endocrine cells AP stimulates and synchronizes intracellular processes, neurons employ action potentials (APs) to govern discontinuous synapses located distantly. Meanwhile, such axonless sensory cells as photoreceptors and hair cells exemplify afferent output, which is not driven by APs; instead, gradual receptor potentials elicited by sensory stimuli control the release of afferent neurotransmitter glutamate. Mammalian taste cells of the type II and type III are electrically excitable and respond to stimulation by firing APs. Since taste cells also have no axons, physiological significance of the electrical excitability for taste transduction and encoding sensory information is unclear. Perhaps, AP facilitates transmitter release, ATP in type II cells and 5-HT in type III cells, although via different mechanisms. The ATP release is mediated by connexin hemichannels, does not require a Ca²⁺ trigger, and largely gated by membrane voltage. 5-HT secretion is driven by intracellular Ca²⁺ and involves VG Ca²⁺ channels. Here, we discuss ionic mechanisms of excitability of taste cells and speculate on a likely role of APs in mediating their afferent output.     

Membrane excitability expressed in human neuroblastoma cell hybrids

The voltage-sensitive Na+ channel is responsible for the action potential of membrane electrical excitability in neuronal tissue. Three methods were used to demonstrate the presence of neurotoxin-responsive Na+ channels in two hybrid cell lines resulting from the fusion of excitable human neuroblastoma cells with mouse fibroblasts. Only one of the two electrically active hybrid cell lines maintained the sensitivity of the neuroblastoma parent to tetrodotoxin (TTX). The other hybrid, although electrically active, was not responsive to TTX or scorpion venom. Comparisons of the patterns of expression of membrane excitability and of chromosome complements in these human neuroblastoma cell hybrids suggest that the phenotype of membrane excitability is composed of genetically distinct elements.     

Evidence for functional sodium and calcium ion channels in the membrane of cultured cardiomyocytes of the adult rat

Characteristics are reported for electrical activity of adult rat cardiomyocytes in long-term primary culture. Cells in vitro for 12 to 28 days have mean membrane potential of -53 mV, are electrically excitable, and some are spontaneously contractile. The action potential of these cells has a slow rate of depolarization and is abolished by methoxyverapamil (D-600) but not by tetrodotoxin (TTX). When cells are hyperpolarized by passage of an inward current, spontaneous action potentials cease and action potentials evoked by depolarizing pulses are then TTX sensitive. Fetal bovine serum is a constituent of the culture medium. Its temporary removal causes spontaneous contractility to cease but the cells remain electrically excitable.     

Mathematical models for excitable systems in biology and medicine.

The excitable systems play a very important role in Biology and Medicine. Phenomena such as the transmission of impulses between neurons, the cardiac arrhythmia, the aggregation of amoebas, the appearance of organized structures in the cortex of egg cells, all derive from the activity of excitable media. In the first part of this work a general definition of excitable system is given; we then analyze some cases of excitability, distinguishing between electrical and chemical excitability and comparing experimental observations with simulations carried out by appropriate mathematical models. Such models are almost always formulated by partial differential equations of "reaction-diffusion" type and they have the characteristic to describe propagations of electrical waves (neurons, pacemaker cardiac cells, pancreatic b-cells) or chemical and mechanical waves (propagation of Ca++ waves or mechanical waves in the endoplasmic reticulum). The aim is to put in evidence that the biological systems can show not only excitability of electrical type, but also excitability of chemical nature, which can be observed in the first steps of development of egg cells or, for example, in the formation of pigments in vertebrate skin or in clam shells.     

Studies of excitable membrane formed on the surface of protoplasmic drops isolated from Nitella II. Tension at the surface of protoplasmic drops

A protoplasmic drop isolated from an internodal cell of Nitella became electrically excitable in a solution containing 0.5 mM NaCl, 0.5 mM KNO₃, 1mM Ca(NO₃)₂ and 2mM Mg(NO₃)₂. A thermodynamic property of the excitable membrane was characterized in terms of tension at the surface of the protoplasmic drop. This was determined by the compression method and/or by the sessile-drop method. The surface tension of the membrane was obtained as a function of the composition of the salts in the external solution, and the time during the formative period of the excitable surface membrane. The results are summarized as follows:

1. 1. The surface of the protoplasmic drop increased with time starting from 0.003 dyne/cm and approached a steady value of about 0.1 dyne/cm within 1 h after the drop was placed in the test solution described above. The membrane became electrically excitable when the surface tension attained the steady value.

2. 2. Increase of concentration of either Na⁺ or K⁺ in the solution induced a sudden decrease of the surface tension, which followed a suppression of the excitability. The critical concentration of Na⁺ or K⁺ was about 10 mM.

3. 3. The surface tension remained constant at about 0.1 dyne/cm in a Ca²⁺ concentration ranging between about 0.1 and 10 mM. At this concentration the drop was excitable. Below and above this range of Ca²⁺ concentration, the surface tension changed sharply with concentration, and the excitability disappeared. At about 0.1 mM Ca²⁺ concentration a discrete variation of the surface tension was observed.

4. 4. The surface tension of the drop stayed constant at 0.1 dyne/cm in the range between 1 and 10 mM of Mg²⁺ concentration. Above and below this range of Mg²⁺ concentration, the surface tension increased sharply with the variation of Mg²⁺ concentration.

These results indicate that the protoplasmic drop retains its excitability in a limited range of salt composition in the external solution. This implies that the excitable membrane of the drop must be very labile in its structure against external perturbations such as electrical stimulus and/or slight variation of salt composition in the solution.     

Excitable properties of insect neurones in culture: A developmental study

The passive and excitable electrical properties of cockroach neurones growing in vitro have been investigated using intracellular recording techniques. The resting membrane potentials of the neurones are similar to those of their in vivo counterparts but the input resistances and membrane capacitive properties are more typical of embryonic insect neurones. During the first 12 days of growth in vitro the neurones exhibit delayed rectification in response to the injection of depolarising current steps. After this period “all or none” action potentials can be evoked by depolarising pulses in approximately half of the neurones tested. These spikes are abolised by 1 μM tetrodotoxin but are unaffected by 5 mM Co²⁺. Spontaneous excitatory activity develops in approx 25% of the neurones after 3 weeks in culture.     

Graded and All-or-None Electrogenesis in Arthropod Muscle : I. The effects of alkali-earth cations on the neuromuscular system of Romalea microptera

Graded electrically excited responsiveness of Romalea muscle fibers is converted to all-or-none activity by Ba⁺⁺, Sr⁺⁺, or Ca⁺⁺, the two former being much the more effective in this action. The change occurs with as little as 7 to 10 per cent of Na⁺ substituted by Ba⁺⁺. The spikes now produced have overshoots and may be extremely prolonged, lasting many seconds. During the spike the membrane resistance is lower than in the resting fiber, but the resting resistance and time constant are considerably increased by the alkali-earth ions. The excitability is also increased, spikes arising neurogenically from spontaneous repetitive discharges in the axon as well as myogenically from spontaneous activity in the muscle fibers. Repetitive responses frequently occur on intracellular stimulation with a brief pulse. The data indicate that the alkali-earth ions exert a complex of effects on the different action components of electrically excitable membrane. They may be described in terms of the ionic theory as follows: The resting K⁺ conductance is diminished. The sodium inactivation process is also diminished, and sodium activation may be increased. Together these changes can act to convert graded responsiveness to the all-or-none variety. The alkali-earth ions can also to some degree carry inward positive charge during activity, since spikes are produced when Na⁺ is fully replaced with the divalent ions.     

Contribution of BKCa-Channel Activity in Human Cardiac Fibroblasts to Electrical Coupling of Cardiomyocytes-Fibroblasts

Cardiac fibroblasts are involved in the maintenance of myocardial tissue structure. However, little is known about ion currents in human cardiac fibroblasts. It has been recently reported that cardiac fibroblasts can interact electrically with cardiomyocytes through gap junctions. Ca²⁺-activated K⁺ currents (I _K[Ca]) of cultured human cardiac fibroblasts were characterized in this study. In whole-cell configuration, depolarizing pulses evoked I _K(Ca) in an outward rectification in these cells, the amplitude of which was suppressed by paxilline (1 μM) or iberiotoxin (200 nM). A large-conductance, Ca²⁺-activated K⁺ (BK_Ca) channel with single-channel conductance of 162 ± 8 pS was also observed in human cardiac fibroblasts. Western blot analysis revealed the presence of α-subunit of BK_Ca channels. The dynamic Luo-Rudy model was applied to predict cell behavior during direct electrical coupling of cardiomyocytes and cardiac fibroblasts. In the simulation, electrically coupled cardiac fibroblasts also exhibited action potential; however, they were electrically inert with no gap-junctional coupling. The simulation predicts that changes in gap junction coupling conductance can influence the configuration of cardiac action potential and cardiomyocyte excitability. I _k(Ca) can be elicited by simulated action potential waveforms of cardiac fibroblasts when they are electrically coupled to cardiomyocytes. This study demonstrates that a BK_Ca channel is functionally expressed in human cardiac fibroblasts. The activity of these BK_Ca channels present in human cardiac fibroblasts may contribute to the functional activities of heart cells through transfer of electrical signals between these two cell types.     

Autorhythmicity and entrainment in excitable membranes

Low calcium increases the excitability of neurones and can induce autorhythmicity in excitable cells. Numerical solutions of the Hodgkin-Huxley membrane equations, and numerical evaluations of the small-signal impedance and admittance are used to illustrate the increase in resonance produced by low [Ca²⁺]₀. The resonant frequency may be located either by the peak of the amplitude of the impedance, or by the frequency at which the phase angle is zero for 1:1 entrained action potentials. Autorhythmicity is produced by any mechanism which increases the resonant peak of the amplitude of the membrane impedance.     

Electrical properties of motoneurons in the spinal cord of rat embryos

Electrical properties of immature motoneurons were studied in vitro using isolated segments of spinal cords of rat embryos aged 14-21 days of gestation. Stable resting potentials and evoked synaptic potentials were recorded for more than 9 hr, indicating that motoneurons remain viable for many hours. Motoneurons are electrically excitable at 14 days of gestation and from the onset of excitability the action potentials are Na+-dependent but slow rising long-duration Ca2+-dependent action potentials can be evoked if K+ conductance is reduced. Thus, during embryonic development the regenerative potential inward current is Na+-and Ca2+-dependent. During motoneurons' differentiation there are some changes in their electrical properties: resting membrane potential increases, input resistance decreases, input capacitance increases, threshold for action potential decreases, and maximum rate of rise of action potential increases. Afferent motoneuron contacts are formed at 16-18 days of gestation when excitatory synaptic potentials can first be evoked in response to dorsal root stimulation. The changes in input capacitance and threshold for action potential occur at the onset of functional afferent motoneuron contacts, but it is not known whether these changes are autonomous or are influenced by the newly formed sensory inputs.     

Preparation of neuronal cultures from midgastrula stage Drosophila embryos

This video illustrates the procedure for making primary neuronal cultures from midgastrula stage Drosophila embryos. The methods for collecting embryos and their dechorionation using bleach are demonstrated. Using a glass pipet attached to a mouth suction tube, we illustrate the removal of all cells from single embryos. The method for dispersing cells from each embryo into a small (5 l) drop of medium on an uncoated glass coverslip is demonstrated. A view through the microscope at 1 hour after plating illustrates the preferred cell density. Most of the cells that survive when grown in defined medium are neuroblasts that divide one or more times in culture before extending neuritic processes by 12-24 hours. A view through the microscope illustrates the level of neurite outgrowth and branching expected in a healthy culture at 2 days in vitro. The cultures are grown in a simple bicarbonate based defined medium, in a 5% CO(2) incubator at 22-24 degrees C. Neuritic processes continue to elaborate over the first week in culture and when they make contact with neurites from neighboring cells they often form functional synaptic connections. Neurons in these cultures express voltage-gated sodium, calcium, and potassium channels and are electrically excitable. This culture system is useful for studying molecular genetic and environmental factors that regulate neuronal differentiation, excitability, and synapse formation/function.     

Expression and properties of acetylcholine receptors in several clones of mouse neuroblastoma X L cell somatic hybrids

Three clones of somatic cell hybrids between neuroblastoma and L cells, NL-1F, NL-308 and NL-309 (3), have been studied for their electrical excitability and chemosensitivity to acetylcholine (Ach) applied by iontophoresis. Parental and hybrid lines were all treated and tested in media containing mM db-cAMP. The percentage of excitable N X L hybrid cells was as high or higher than that of their neuroblastoma parents. The percentage of cells sensitive to Ach was several-fold higher for the three N X L clones than for the neuroblastoma or L cell parents. While the neuroblastoma parents gave only depolarizing cholinergic responses, the N X L hybrid cells displayed slow hyperpolarizing (H) responses which resembled the H-cholinergic response obtained from L cells. The H-response of the N X L hybrids has properties which indicate the involvement of a muscarinic receptor. A correlation between expression of muscarinic receptors and excitability to electrical current (i.e., action potential ionophores), not found in the neuroblastoma parents, was present in the hybrids. However, a few N X L hybrid cells expressed muscarinic receptors independently from electrical excitability, as is the case for the L cell parent. The three N X L clones are discussed as potentially useful models to study interaction of Ach with muscarinic receptors.     

Electrically excitable normal rat kidney fibroblasts: A new model system for cell-semiconductor hybrids

In testing various designs of cell-semiconductor hybrids, the choice of a suitable type of electrically excitable cell is crucial. Here normal rat kidney (NRK) fibroblasts are presented as a cell line, easily maintained in culture, that may substitute for heart or nerve cells in many experiments. Like heart muscle cells, NRK fibroblasts form electrically coupled confluent cell layers, in which propagating action potentials are spontaneously generated. These, however, are not associated with mechanical disturbances. Here we compare heart muscle cells and NRK fibroblasts with respect to action potential waveform, morphology, and substrate adhesion profile, using the whole-cell variant of the patch-clamp technique, atomic force microscopy (AFM), and reflection interference contrast microscopy (RICM), respectively. Our results clearly demonstrate that NRK fibroblasts should provide a highly suitable test system for investigating the signal transfer between electrically excitable cells and extracellular detectors, available at a minimum cost and effort for the experimenters.     

Electrical properties of the dendrite in an insect mechanoreceptor: Effects of antidromic or direct electrical stimulation

A study of the negative phase of the spikes recorded extra cellularly from insect mechanoreceptor has been performed in order to characterize some electrical properties of the dendrite which contains the transducing part of the sensory neuron. These properties have been investigated in mechanoreceptors of the metathoracic leg of the locust Schistocerca gregaria by firing antidromic action potentials both at rest and during mechanical or electrical stimulation. The amplitude of the negative phase of the spike appears to be correlated with the polarization of the dendritic membrane, although when bursts of action potentials are applied, the relation is more complex, including a depressive influence of a given spike on the following spike. The receptor potential and the antidromic dendritic spikes both originate in the same region of the dendrite but they involve different ionic processes. Our results indicate that the dendrite is electrically excitable. The spike which originates in the dendrite has an initial negative phase with a small superimposed positive component. A spike of this shape is never observed under natural stimulation. It is proposed that the negative phase of the antidromic impulse provides a suitable means for studying the variations in electrical polarization of the dendrite which cannot be recorded directly.     

A network model for biofilm development in Escherichia coli K-12

Proteins in any solution with a pH value that differs from their isoelectric point exert both an electric Donnan effect (DE) and colloid osmotic pressure. While the former alters the distribution of ions, the latter forces water diffusion. In cells with highly Cl^--permeable membranes, the resting potential is more dependent on the cytoplasmic pH value, which alters the Donnan effect of cell proteins, than on the current action of Na/K pumps. Any weak (positive or negative) electric disturbances of their resting potential are quickly corrected by chloride shifts. In many excitable cells, the spreading of action potentials is mediated through fast, voltage-gated sodium channels. Tissue cells share similar concentrations of cytoplasmic proteins and almost the same exposure to the interstitial fluid (IF) chloride concentration. The consequence is that similar intra- and extra-cellular chloride concentrations make these cells share the same Nernst value for Cl^-. Further extrapolation indicates that cells with the same chloride Nernst value and high chloride permeability should have similar resting membrane potentials, more negative than -80 mV. Fast sodium channels require potassium levels >20 times higher inside the cell than around it, while the concentration of Cl^- ions needs to be >20 times higher outside the cell. When osmotic forces, electroneutrality and other ions are all taken into account, the overall osmolarity needs to be near 280 to 300 mosm/L to reach the required resting potential in excitable cells. High plasma protein concentrations keep the IF chloride concentration stable, which is important in keeping the resting membrane potential similar in all chloride-permeable cells. Probable consequences of this concept for neuron excitability, erythrocyte membrane permeability and several features of circulation design are briefly discussed.     

MEMBRANE POTENTIAL DEPENDENT BINDING OF SCORPION TOXIN TO THE ACTION POTENTIAL SODIUM IONOPHORE. STUDIES WITH A 3-(4-HYDROXY 3-[125I] IODOPHENYL) PROPIONYL DERIVATIVE

Abstract— A polypeptide toxin purified 80-fold from the venom of the scorpion Leiurus quinquestriatus enhances activation of the action potential Na⁺ ionophore by the alkaloid neurotoxins veratridine, batrachotoxin and aconitine in electrically excitable neuroblastoma cells. The purified toxin can be labelled with [¹²⁵I] by reaction with N-succinimidyl 3-(4-hydroxy 3-[¹²⁵I] iodophenyl) propionate. The [¹²⁵I] labelled toxin obtained from carboxymethyl Sephadex ion exchange chromatography appears homogeneous by gel electrophoresis and isoelectric focusing. The [¹²⁵I] labelled toxin binds to a single class of saturable binding sites and also activates the action potential Na⁺ ionophore in electrically excitable neuroblastoma cells showing identical concentration dependence for both the binding and the activation effects. The labelled toxin does not show any saturable binding or activation of the action potential Na⁺ ionophore in variant neuroblastoma clones that specifically lack the action potential Na⁺ ionophore. The results indicate that scorpion toxin binds specifically to the action potential Na⁺ ionophore. The binding sites have a mean equilibrium dissociation constant of 3 IIH, a mean binding capacity of 46fmol toxin per mg cell protein and a mean density of 24 sites per μm² of cell surface membrane. A single action potential Na⁺ ionophore transports 1 × 10⁸ ions per min and has a conductance of 3 psiemens at physiologic ion concentrations. Depolarization of cells by elevated K⁺ concentration inhibits the saturable binding. Depolarization of cells by incubation in high Na⁺ medium (130mm -Na⁺, 5mm -K⁺) with gramicidin A or batrachotoxin also inhibits the saturable toxin binding. These results suggest that scorpion toxin binds specifically to a regulatory component (gate) of the Na⁺ ionophore. whose conformation is dependent on membrane potential.     

Induced pacemaker activity on toad skin

The electrical transients produced on the isolated abdominal skin obtained from Bufo arenarum Hensel, under the influence of inward current pulses of constant intensity have been studied. When both faces of the skin are bathed with Ringer''s solution, short pulses of inward current give rise to transient variations of the potential difference between both faces of the skin with "all-or-nothing" characteristics (action potentials, AP). When the outer face is bathed with a modified Ringer solution with low sodium content (2.4 mM), the transients are longer and they are only evident when the pulse is several hundred milliseconds long. With even longer pulses (several seconds) a repetitive activity can be elicited, with the electrical characteristics of a "pacemaker" activity. In all these "excitability" phenomena Na⁺ may be replaced by Li⁺ in the outer solution. The logarithm of the duration of AP''s is inversely related to the logarithm of the increase in concentration of Na⁺ or Li⁺ in the solution bathing the external face of the skin. The duration of AP''s is increased when the Ca⁺⁺ concentration in the outer solution is raised. This effect is more evident with low sodium concentration on the outside. The evolution of the slope conductance during repetitive activity has been determined. The site and mechanisms of the "excitable" behavior of the skin and the induced repetitive activity are discussed. Under the experimental conditions employed the behavior of the skin is compared with that of normally excitable plasma membranes.     

Excitability and chemosensitivity properties of a somatic cell hybrid between mouse neuroblastoma and sympathetic ganglion cells

A somatic cell hybrid line, NX-31, formed by fusion of mouse neuroblastoma and mouse sympathetic ganglion cells has been studied for its electrophysiologic properties and its chemosensitivity to iontophoretically applied acetylcholine (ACh). The cell lines (parent and hybrid) were treated and studied in media containing mM dibutyryl cyclic AMP (db-cAMP) in order to obtain them in a maximally differentiated state. The hybrid cell line was electrically excitable and its excitability characteristics were found to be closer to those of its putative neuronal parent than were those of its neuroblastoma parent. In particular, increases were observed in the percentage of cells giving action potentials when electrically stimulated at their resting membrane potentials, in the maximal rate of rise (dV/dt) of the elicited spikes, and in the percentage of cells displaying repetitive-firing ability. Fifty percent of the hybrid cells were sensitive to ACh. Two types of depolarizing responses were evoked—an early, rapidly developing response and, less frequently, a late, slowly developing response. The first type of depolarization appears to be mediated by a nicotinic cholinergic receptor while the latter type does not. Neuroblastoma cells may exhibit only the early, rapid response; sympathetic neurons show depolarizations corresponding to both types of responses. These findings suggest that the phenotypes expressed by NX-31 hybrid cells more closely resemble those of sympathetic neurons than do those of their neuroblastoma parents. The possibility is raised of further exploiting the strategy of hybridizing a dividing cell line with other types of neurons to obtain new neuronal cell lines.     

Ionic channel density of excitable membranes can act as a bifurcation parameter

As the maximal K⁺-conductance (or K⁺-channel density) of the Hodgkin-Huxley equations is reduced, the stable resting membrane potential bifurcates at a subcritical Hopf bifurcation into small amplitude unstable oscillations. These small amplitude solutions jump to large amplitude periodic solutions that correspond to a repetitive discharge of action potentials. Thus the specific channel density can act as a bifurcation parameter, and can control the excitability and autorhythmicity of excitable membranes.