The electrophysiology of gap junctions and gap junction channels and their mathematical modelling

In most tissues of vertebrates, gap junctions control the exchange of ions and small molecules between adjacent cells, thus co-ordinating the cellular activities. The application of the dual voltage-clamp method to cell pair preparations enables one to elucidate the electrical properties of gap junctions and gap junction channels. The conductive and kinetic data obtained at the multichannel and single channel level led to a generalised concept for the operation of gap junction channels. Based on the biological data gained in this way, a mathematical model has been developed. This model is versatile and allows to simulate the electrophysiological behaviour of different types of vertebrate gap junctions.     

Cell coupling in the retina: patterns and purpose

Gap junction channels (electrical synapses) are a major component of the central nervous system mediating both electrical and metabolic coupling between neurons and glia. Their roles are as diverse as the cell types in which they are expressed and only some of these are reviewed here. In the adult the plastic nature of the gap junction channel allows for changes in the writing of the retinal circuitry that optimize visual processing to suit ambient lighting conditions. Gap junctional communication has been proposed to play a key role in embryonic development in general and in particular during the development of the retina where its roles may include control of neurogenesis, cell specification, synaptogenesis, and the synchronization of the spontaneous electrical activity required for the sharpening of central visual projections. Here we review gap junctional coupling within the retina and present data correlating gap junction expression with development events in the chick retina.     

Comparison of the function of the tight junctions of endothelial cells and epithelial cells in regulating the movement of electrolytes and macromolecules across the cell monolayer

In cell culture, both endothelial and epithelial cell monolayers have been found to generate structurally similar tight junctional complexes, as assessed by thin complexes of the two cell types are, at least in part, responsible for the very different permeability characteristics of native endothelial and epithelial cell monolayers. The purpose of this work was to compare cultured endothelial and epithelial cells with respect to the function of their tight junctional complexes in regulating the movement of macromolecules and ions across the cell monolayers, and define functional parameters to characterize the tight junctional complexes. Bovine aorta endothelial cells and T84 colonic carcinoma epithelial cells were cultured on a microporous membrane support. The permeability coefficients of inulin, albumin, and insulin were determined with the cell monolayers and compared with the permeability coefficients obtained with 3T3-C2 fibroblasts, a cell line that does not generate tight junctions. Electrical resistance measurements across the monolayer-filter systems were also compared. The permeability coefficient of albumin across the endothelial cell monolayer compared favorably with other reported values. Likewise, the electrical resistance across the T84 cell monolayer was in good agreement with published values. Utilizing permeability coefficients for macromolecules as an index of tight junction function, we found that a distinction between a lack of tight junctions (fibroblasts), the presence of endothelial tight junctions, and the presence of epithelial tight junctions was readily made. However, when utilizing electrical resistance as an index of tight junction function, identical measurements were obtained with fibroblasts and endothelial cells. This indicates that more than one index of tight junction function is necessary to characterize the junctional complexes. Although structurally similar, epithelial cell and endothelial cell tight junctions perform very different functions, and, from our data, we conclude that the demonstration of tight junctional structures by electron microscopy is not relevant to the functional nature of the junction: structure does not imply function. A minimal assessment of tight junction function should rely on both the determination of the electrical resistance across the cell monolayer, and the determination of the permeability coefficients of selected macromolecules.     

Detrusor smooth muscle cells of the guinea-pig are functionally coupled via gap junctions in situ and in cell culture

Intercellular communication between smooth muscle cells is crucial for contractile behaviour in normal and pathologically altered urinary bladder. Since the study of coupling is difficult in situ, we established cell cultures of bladder smooth muscle cells to analyse coupling mechanisms. Microinjection of Lucifer yellow demonstrated syncytia composed of only a few to several dozen cells. Electron-microscopic examination of freeze-fracture specimens and ultrathin sections revealed that the dye-coupling was based on typical gap junction formation between the cultured smooth muscle cells. Furthermore, we were able to demonstrate gap junctions within the tissue fragments from which the primary cultures were grown. By Western blotting, we found connexin-43-positive protein bands both in native tissue probes from the guinea-pig urinary bladder and in smooth muscle cell cultures. Extracellular electrical stimulation of single cells evoked calcium transients, as visualized by fura-2 ratiofluorimetry. Calcium waves propagated throughout the syncytia with a declining amplitude, showing that the calcium signal was not regenerative. Therefore, the calcium signal was probably transmitted by a diffusible factor. These findings correlated well with the dye-coupling that we found between detrusor smooth muscle cells in situ. The use of smooth muscle cell cultures therefore seems to be a feasible approach for studying coupling behaviour in vitro.     

A novel network of multipolar bursting interneurons generates theta frequency oscillations in neocortex

GABAergic interneurons can phase the output of principal cells, giving rise to oscillatory activity in different frequency bands. Here we describe a new subtype of GABAergic interneuron, the multipolar bursting (MB) cell in the mouse neocortex. MB cells are parvalbumin positive but differ from fast-spiking multipolar (FS) cells in their morphological, neurochemical, and physiological properties. MB cells are reciprocally connected with layer 2/3 pyramidal cells and are coupled with each other by chemical and electrical synapses. MB cells innervate FS cells but not vice versa. MB to MB cell as well as MB to pyramidal cell synapses exhibit paired-pulse facilitation. Carbachol selectively induced synchronized theta frequency oscillations in MB cells. Synchrony required both gap junction coupling and GABAergic chemical transmission, but not excitatory glutamatergic input. Hence, MB cells form a distinct inhibitory network, which upon cholinergic drive can generate rhythmic and synchronous theta frequency activity, providing temporal coordination of pyramidal cell output.     

Motility of the oviduct and uterus of the cow during the oestrous cycle.

Recordings of electrical activity of the oviduct and uterus were obtained during three oestrous cycles in cows fitted with an extra-cellular multi-electrode assembly. The stages of the cycle were identified by the appearance of the cervico-vaginal secretions and changes in the peripheral plasma level of progesterone were determined by radioimmunoassay. A gradual transition from local non-propagating electrical activity to propagating electrical activity with increase in the duration of contractions and then of their amplitude occurred 48 hr before the onset of oestrus. The transition coincided with a rapid decrease in progesterone level from 5 to 10 ng/ml to less than 0-1 to 0-4 ng/ml. This phenomenon was recorded from all uterine electrode sites, but was most marked at the uterotubal junction. Two days before oestrus, trains of potentials and bursts of activity became progressively grouped, apparently randomly, into prolonged phases in the distal portion of the oviduct and over the entire myometrium. During oestrus, the phases of activity became synchronized at these sites and both their amplitude and frequency reached a maximum. The strength but not the frequency of the phases diminished progressively 3 days after oestrus, followed by relative inactivity. The last remaining zone of activity was the uterotubal junction. During oestrus, the activities of the oviduct and the uterus were modified by oxytocin and adrenaline, the effect of the former being more marked on the uterus and that of the latter on the oviduct.     

Interrelations of the emotionally positive and negative areas of the brain in the edible snail

Fine wire electrodes were surgically implanted in two regions of a snail's brain (Helix aspersa). To receive electrical stimulation of the brain, the tethered snail was required to displace the end of a rod. Self-stimulation delivered to the parietal ganglion resulted in nonrepetition of the operant response, whereas self-stimulation delivered to the mesocerebrum resulted in an increase in response frequency. In neurophysiological experiments it was found that extracellular stimulation of mesocerebrum inhibits spontaneous activity of serotonergic cells modulating avoidance reactions, and decreases synaptic input of a command cell for avoidance behaviour. These findings make possible intracellular investigations of the mechanisms of positive and negative reinforcement.     

Occluding Junctions in MDCK Cells: Modulation of Transepithelial Permeability by the Cytoskeleton

In MDCK cell monolayers the opening and resealing of occluding junctions can be induced by removal and restoration of calcium to the external medium. The overall changes in permeability of the occluding junctions in the monolayer can be monitored by the drop and recovery of the total transepithelial electrical resistance. We have investigated the effects of cytochalasin B (CB) on this process. When CB is added to sealed monolayers there is a gradual drop in the electrical resistance across the monolayer. This drop is accompanied by a slow disorganization of the microfilament pattern of these cells, including a disturbance of a ring of cortical microfilaments that is normally associated with the junctions. Cells in open monolayers treated with CB will not reseal and have an altered filament distribution. These cells do not have a continuous cortical ring. We have used a voltage scanning technique that uses a microelectrode to measure the resistance at selected points along the junction which surrounds a single cell. In untreated, closed monolayers, the junction is heterogeneous with alternating points of high and low conductance. In closed monolayers treated with CB, although there are low conductance points, we have observed an increased frequency of high conductance points that correlates with the change in the overall conductance. The frequency of high conductance points along the junction and the overall conductance both increase with time of exposure to CB. In an effort to understand the molecular basis for the permeability changes induced by EGTA and CB, we have looked for differences in the protein components of the cell membranes of open, closed, and CB-treated MDCK monolayers. This was done by radioiodinating the surface membrane proteins under control and experimental conditions that bring about permeability changes. No significant differences in the labeled protein patterns were found under these conditions. These results suggest that the permeability changes involve only a structural rearrangement of membrane components. In addition we have observed that about 36% of the surface label remains bound to the insoluble cytoskeletons obtained from cells in control and experimental conditions that alter the permeability of the tight junctions. The iodinated proteins attached to the CS include polypeptides with M_r of ≥ 120K daltons as well as peptides with M_r = 56K, 50K, 36K, and 18K daltons.     

On the generation of potential differences across the membranes of ellipsoidal cells in an alternating electrical field

Summary Particles with a nonconducting membrane, oriented in an alternating electrical field, will show the behaviour of electrical dipoles. Across the membranes there will be generated alternating electrical potential differences, which may be calculated for confocal ellipsoidal cells by solving Laplace's equation. We have evaluated a formula valid generally for single confocal ellipsoidal cells under physiological conditions, the cells being placed with one of their semi-axes parallel to an external electrical field. The values of the generated potential difference, considered at the position of their maximum values, are dependent on the shape and size of the cells, on their orientation to the electrical field and on the frequency and strength of the field. The relaxation frequency depends also on cell shape, size and orientation, but furthermore on the membrane properties and on the conductivities inside and outside the cells. For simple cases like spheres and cylinders perpendicular to the electrical field, our formula will correspond to known expressions. Values for the generated potential differences, form-factors and relaxation frequencies are given for different types of spheroids and at different orientations. Of some practical importance are long prolate spheroids with their long semi-axes parallel to the external field, because only small field strengths are necessary in order to generate large potential differences which may evoke action potentialse.g. in muscle or nerve cells. The significance of this mechanism concerning the determination of protection and safeguard standards for the exposure to low-frequency electrical fields is discussed.Dedicated to Prof. Dr. Dr. h. c. mult. B. Rajewsky on the occasion of his 80th birthday.     

Effect of FCCP on tight junction permeability and cellular distribution of ZO-1 protein in epithelial (MDCK) cells

The effect of the uncoupler of oxidative phosphorylation, FCCP (carbonylcyanide p-trifluoromethoxyphenylhydrazone), on the tight junction of Madin-Darby canine kidney cells was examined. FCCP induced an abrupt decrease in the transepithelial electrical resistance of the confluent monolayers over a period of 20 s. When FCCP was withdrawn from the incubation medium, the monolayer resistance recovered to close to the original level in less than 2 h. Staining of the tight junction-associated protein ZO-1 showed that the changes in transepithelial electrical resistance were accompanied by a diffusing of the protein away from cell peripheries and a reconcentration to the tight junction areas following resistance recovery. Intracellular pH was decreased by FCCP on a similar time-scale with no obvious changes in ATP levels over this time-course. These data suggest that the uncoupler FCCP has a profound effect on tight junction permeability and cellular distribution of the tight junction protein ZO-1 in the epithelial cells and that it probably acts by breaking down proton gradients and altering intracellular pH.     

Limitations of the dual voltage clamp method in assaying conductance and kinetics of gap junction channels.

The electrical properties of gap junctions in cell pairs are usually studied by means of the dual voltage clamp method. The voltage across the junctional channels, however, cannot be controlled adequately due to an artificial resistance and a natural resistance, both connected in series with the gap junction. The access resistances to the cell interior of the recording pipettes make up the artificial resistance. The natural resistance consists of the cytoplasmic access resistances to the tightly packed gap junction channels in both cells. A mathematical model was constructed to calculate the actual voltage across each gap junction channel. The stochastic open-close kinetics of the individual channels were incorporated into this model. It is concluded that even in the ideal case of complete compensation of pipette series resistance, the number of channels comprised in the gap junction may be largely underestimated. Furthermore, normalized steady-state junctional conductance may be largely overestimated, so that transjunctional voltage dependence is easily masked. The model is used to discuss conclusions drawn from dual voltage clamp experiments and offers alternative explanations for various experimental observations.     

Measuring electric impedance of organs--methodologic principles]

Ischemia causes changes in organ tissue (e.g. during operation or transplantation) which may finally lead to irreversible injury, so that the organ can no longer be resuscitated. To the extent that these changes affect the electrical properties of the tissue they are manifested in the impedance spectrum. As an example, the course of impedance of a HTK-protected porcine liver is presented in the frequency range of 0.1 Hz to 10 MHz, which includes two dispersion--alpha- and beta-dispersion. Using a suitable electrical equivalent circuit analogue to the structure of the liver, the behavior of the alpha- and beta-dispersion is explained on the basis of gap junction closure and narrowing of the extracellular space due to cell swelling.     

Gap junctional communication and compaction during preimplantation stages of mouse development

The ability of gap junction antibodies to block dye transfer and electrical coupling was examined in the compacted 8-cell mouse zygote. In control zygotes, Lucifer yellow injected into 1 cell transferred to the rest of the embryo. When antibodies raised against the major protein extracted from gap junctions were co-injected with Lucifer yellow, dye transfer failed in 86% of the zygotes tested and electrical coupling was almost completely inhibited. Subsequently, the antibody-containing cells were extruded. When the antibodies were injected into 1 cell at the 2-cell stage, 82% of the zygotes divided normally to the 8-cell stage. Cells containing gap junction antibodies were uncompacted, but continued to divide. We conclude that these antibodies inhibit gap junctional communication in the early mouse zygote and that communication through gap junctions may be involved in the maintenance of compaction.     

A Synthetic Peptide Corresponding to the Extracellular Domain of Occludin Perturbs the Tight Junction Permeability Barrier

Occludin, the putative tight junction integral membrane protein, is an attractive candidate for a protein that forms the actual sealing element of the tight junction. To study the role of occludin in the formation of the tight junction seal, synthetic peptides (OCC1 and OCC2) corresponding to the two putative extracellular domains of occludin were assayed for their ability to alter tight junctions in Xenopus kidney epithelial cell line A6. Transepithelial electrical resistance and paracellular tracer flux measurements indicated that the second extracellular domain peptide (OCC2) reversibly disrupted the transepithelial permeability barrier at concentrations of < 5 μM. Despite the increased paracellular permeability, there were no changes in gross epithelial cell morphology as determined by scanning EM. The OCC2 peptide decreased the amount of occludin present at the tight junction, as assessed by indirect immunofluorescence, as well as decreased total cellular content of occludin, as assessed by Western blot analysis. Pulse-labeling and metabolic chase analysis suggested that this decrease in occludin level could be attributed to an increase in turnover of cellular occludin rather than a decrease in occludin synthesis. The effect on occludin was specific because other tight junction components, ZO-1, ZO-2, cingulin, and the adherens junction protein E-cadherin, were unaltered by OCC2 treatment. Therefore, the peptide corresponding to the second extracellular domain of occludin perturbs the tight junction permeability barrier in a very specific manner. The correlation between a decrease in occludin levels and the perturbation of the tight junction permeability barrier provides evidence for a role of occludin in the formation of the tight junction seal.     

Comparative studies of the aggressive behaviour of two gymnotid electric fish (Gymnotus carapo and Hypopomus artedi).

Electrical and motor behaviour was studied during aggressive interactions in two species of electric fish (Gymnotus carapo and Hypopomus artedi). Paired comparison methods were used to obtain the data, and analysis of the results was undertaken at three different levels: (1) The repertoire of behaviour (motor and electrical); (2) The changes in relative frequency of components with increasing exposure to conspecifics; (3) Sequential analysis of patterns of behaviour occuring both within and between individuals. The results of the three analyses showed: (1) A great similarity in repertoire although a much higher rate of interaction for Gymnotus. The relative importance of the "off" and "burst" signals was reversed for the two species. A prolonged orientation component in Hypopomus was found to be related to the occurrence of discharge synchrony. (2) Habituation of intense components in favour of electrical signalling in both species. (3) Important differences in both the length and structure of sequences.     

The Croonian Lecture 2000. Nicotinic acetylcholine receptor and the structural basis of fast synaptic transmission

Communication in the nervous system takes place at chemical and electrical synapses, where neurotransmitter-gated ion channels, such as the nicotinic acetylcholine (ACh) receptor, and gap junction channels control propagation of electrical signals from one cell to the next. Newly developed electron crystallographic methods have revealed the structures of these channels trapped in open as well as closed states, suggesting how they work. The ACh receptor has large vestibules extending from the membrane which shape the ACh-binding pockets and facilitate selective transport of cations across a narrow membrane-spanning pore. When ACh enters the pockets it triggers a concerted conformational change that opens the pore by destabilizing a gate in the middle of the membrane made by a ring of pore-lining alpha-helical segmets. The alternative 'open' configuration of pore-lining segments reshapes the lumen and creates new surfaces, allowing the ions to pass through. The gap junction channel uses a similar structural mechanism, involving coordinated rearrangements of alpha-helical segments in the plane of the membrane, to open its pore.     

Microtubule Integrity Is Necessary for the Epithelial Barrier Function of Cultured Thyroid Cell Monolayers

Vectorial transport in the thyroid epithelium requires an efficient barrier against passive paracellular flux, a role which is principally performed by the tight junction (zonula occludens). There is increasing evidence that tight junction integrity is determined by integral and peripheral membrane proteins which interact with the cell cytoskeleton. Although the contribution of the actin cytoskeleton to tight junction physiology has been intensively studied, less is known about possible interactions with microtubules. In the present study we used electrophysiological and immunohistochemical approaches to investigate the contribution of microtubules to the paracellular barrier in cultured thyroid cell monolayers which displayed a high transepithelial electrical resistance (6000-9000 ohm · cm²). Colchicine (1 μM) caused a progressive fall in electrical resistance to <10% of baseline after 6 h and depolarization of the transepithelial electrical potential difference consistent with a significant increase in paracellular permeability. The effect of colchicine on TER was not affected by agents which inhibit the major apical conductances of thyroid cells but was reversed upon removal of the drug. Immunofluorescent staining for tubulin combined with confocal laser scanning microscopy demonstrated that thyroid cells possessed a dense microtubule network extending throughout the cytoplasm which was destroyed by colchicine. Colchicine also produced changes in the localization of the tight junction-associated protein, ZO-1: its normally continuous junctional distribution was disrupted by striking discontinuities and the appearance of many fine strands which extended into the cytoplasm. A similar disruption in E-cadherin staining was also observed, but colchicine did not affect the distribution of vinculin associated with adherens junctions nor the integrity of the perijunctional actin ring. We conclude that microtubules are necessary for the functional and structural integrity of tight junctions in this electrically tight, transporting epithelium.     

Co-culture of two MDCK strains with distinct junctional protein expression: a model for intercellular junction rearrangement and cell sorting

Distinct epithelial MDCK cell strains displaying extremes in transepithelial electrical resistance (paracellular permeability) have been established in co-culture and the subsequent cellular behaviour and formation of junctional complexes investigated. After high-density seeding, MDCK strain I and II cells in co-culture are initially randomly distributed but subsequently sort themselves out in a time-dependent manner to form separate homotypic aggregates. The final pattern of cell arrangement of homotypic aggregates depends on the relative seeding proportion of each cell type. Immunostaining of established marker proteins for junctional complexes has revealed that MDCK I and II cells differ in the degree of expression of the zonula-adherens-associated protein, E-cadherin, their cytoskeletal architecture and the junctional distribution of a desmosomal protein, and by showing subtle differences in tight junction staining for the zona-occludens-associated proteins, ZO-1 and occludin. The distinct pattern of junctional protein expression is maintained when the two MDCK strains are co-cultured; however, morphologically atypical intercellular junctions between heterotypic cells at the boundary of homotypic cell aggregates have been observed. It has been suggested that cell sorting, a phenomenon yet to be completely understood, is involved in important morphogenetic processes. We propose that co-culture of strains of the well-characterised MDCK cell line may be a novel but well-defined cell system for studying epithelial cell rearrangement and sorting in intact epithelial sheets.     

Signalling to and from tight junctions

Tight junctions have long been regarded as simple barriers that separate compartments of different compositions, but recent research indicates that different types of signalling proteins and transduction pathways are associated with these junctions. They receive and convert signals from the cell interior to regulate junction assembly and function, and transmit signals to the cell interior to modulate gene expression and cell behaviour.