Endfeet of retinal glial cells have higher densities of ion channels that mediate K+ buffering

A major function of glial cells in the central nervous system is to buffer the extracellular potassium concentration, [K+]o. A local rise in [K+]o causes potassium ions to enter glial cells, which have membranes that are highly permeable to K+; potassium then leaves the glial cells at other locations where [K+]o has not risen. We report here the first study of the individual ion channels mediating potassium buffering by glial cells. The patch-clamp technique was employed to record single channel currents in Müller cells, the radial glia of the vertebrate retina. Those cells have 94% of their potassium conductance in an endfoot apposed to the vitreous humour, causing K+ released from active retinal neurones to be buffered preferentially to the vitreous. Recordings from patches of endfoot and cell body membrane show that a single type of inward-rectifying K+ channel mediates potassium buffering at both cell locations. The non-uniform density of K+ conductance is due to a non-uniform distribution of one type of K+ channel, rather than to the cell expressing high conductance channels at the endfoot and low conductance channels elsewhere on the cell.     

Myelin-associated glycoprotein in human retina

The human retina is unmyelinated, but structural similarities have been noted between Müller cells, the main glial cell type of retina, and oligodendrocytes, the myelin-forming cells of the central nervous system. We now show that antibodies against myelin-associated glycoprotein, a minor component of central and peripheral myelin so far found only in myelin and myelin-forming cells, also stain Müller cells. Immunoblot analysis of retinal proteins indicates that the antigen detected is myelin associated glycoprotein. These results suggest a closer relationship between Müller cells and oligodendrocytes than previously suspected and raise questions about the functional role of myelin-associated glycoprotein.     

Regional specialization of retinal glial cell membrane

Neural activity generates increases in extracellular K+ concentration, [K+]0, which must be regulated in order to maintain normal brain function. Glial cells are thought to play an important part in this regulation through the process of K+ spatial buffering: K+-mediated current flow through glial cells redistributes extracellular K+ following localized [K+]0 increases. As is the case in other glia, the retinal Müller cell is permeable almost exclusively to K+ . Recent experiments have suggested that this K+ conductance may not be distributed uniformly over the cell surface. In the present study, two novel techniques have been used to assess the Müller cell K+ conductance distribution. The results demonstrate that 94% of all membrane conductance lies in the endfoot process of the cell. This strikingly asymmetric distribution has important consequences for theories concerning K+ buffering and should help to explain the generation of the electroretinogram.     

Functional analysis of an archaebacterial voltage-dependent K+ channel

All living organisms use ion channels to regulate the transport of ions across cellular membranes. Certain ion channels are classed as voltage-dependent because they have a voltage-sensing structure that induces their pores to open in response to changes in the cell membrane voltage. Until recently, the voltage-dependent K+, Ca2+ and Na+ channels were regarded as a unique development of eukaryotic cells, adapted to accomplish specialized electrical signalling, as exemplified in neurons. Here we present the functional characterization of a voltage-dependent K+ (K(V)) channel from a hyperthermophilic archaebacterium from an oceanic thermal vent. This channel possesses all the functional attributes of classical neuronal K(V) channels. The conservation of function reflects structural conservation in the voltage sensor as revealed by specific, high-affinity interactions with tarantula venom toxins, which evolved to inhibit eukaryotic K(V) channels.     

Facilitation of voltage-gated ion channels in frog neuroglia by nerve impulses

The functions of glial cells in the nervous system are not well defined, with the exception of myelin production by oligodendrocytes, uptake of amino-acid synaptic transmitters, and a contribution to extracellular potassium homeostasis. Neuroglia have receptors for neurotransmitters which may be involved in neuron-glia interactions. Recent studies have demonstrated voltage-gated ion channels in glial membranes. In a study of the optic nerve of the frog, small areas of the surface were examined with the loose patch-clamp method, and voltage-gated Na+ and K+ channels, presumably located in the membranes of the astrocytes forming the glia limitans, were identified. We now report that nerve impulses in the axons of the frog optic nerve transiently alter the properties of the voltage-dependent membrane channels of the surface glial cells (astrocytes), a demonstration of a new form of neuron-glia interaction.     

NMDA-receptor activation increases cytoplasmic calcium concentration in cultured spinal cord neurones

Excitatory amino acids act via receptor subtypes in the mammalian central nervous system (CNS). The receptor selectively activated by N-methyl-D-aspartic acid (NMDA) has been best characterized using voltage-clamp and single-channel recording; the results suggest that NMDA receptors gate channels that are permeable to Na+, K+ and other monovalent cations. Various experiments suggest that Ca2+ flux is also associated with the activation of excitatory amino-acid receptors on vertebrate neurones. Whether Ca2+ enters through voltage-dependent Ca2+ channels or through excitatory amino-acid-activated channels of one or more subtype is unclear. Mg2+ can be used to distinguish NMDA-receptor-activated channels from voltage-dependent Ca2+ channels, because at micromolar concentrations Mg2+ has little effect on voltage-dependent Ca2+ channels while it enters and blocks NMDA receptor channels. Marked differences in the potency of other divalent cations acting as Ca2+ channel blockers compared with their action as NMDA antagonists also distinguish the NMDA channel from voltage-sensitive Ca2+ channels. However, we now directly demonstrate that excitatory amino acids acting at NMDA receptors on spinal cord neurones increase the intracellular Ca2+ activity, measured using the indicator dye arsenazo III, and that this is the result of Ca2+ influx through NMDA receptor channels. Kainic acid (KA), which acts at another subtype of excitatory amino-acid receptor, was much less effective in triggering increases in intracellular free Ca2+.     

X-ray structure of a voltage-dependent K+ channel

Voltage-dependent K+ channels are members of the family of voltage-dependent cation (K+, Na+ and Ca2+) channels that open and allow ion conduction in response to changes in cell membrane voltage. This form of gating underlies the generation of nerve and muscle action potentials, among other processes. Here we present the structure of KvAP, a voltage-dependent K+ channel from Aeropyrum pernix. We have determined a crystal structure of the full-length channel at a resolution of 3.2 A, and of the isolated voltage-sensor domain at 1.9 A, both in complex with monoclonal Fab fragments. The channel contains a central ion-conduction pore surrounded by voltage sensors, which form what we call 'voltage-sensor paddles'-hydrophobic, cationic, helix-turn-helix structures on the channel's outer perimeter. Flexible hinges suggest that the voltage-sensor paddles move in response to membrane voltage changes, carrying their positive charge across the membrane.     

Monoclonal antibodies which recognize different cell types in the rat retina

Seven monoclonal antibodies have been produced against a membrane preparation from adult rat retina. Three antibodies reacted with particular regions of rat photoreceptor cell surfaces: RET-P1 labelled the cell bodies, outer and inner segments (rods but not cones), RET-P2 labelled only outer segments and RET-P3 labelled only the cell bodies. Three antibodies reacted with glial cells; RET-G2 and RET-G3 were specific for Müller cells, RET-G1 also labelled glia elsewhere in brain. The seventh antibody (RET-N1) reacted with many types of neuronal cells.     

Novel mechanism of voltage-dependent gating in L-type calcium channels

Activation of voltage-dependent calcium channels by membrane depolarization triggers a variety of key cellular responses, such as contraction in heart and smooth muscle and exocytotic secretion in endocrine and nerve cells. Modulation of calcium channel gating is believed to be the mechanism by which several neurotransmitters, hormones and therapeutic agents mediate their effects on cell function. Here we describe a novel type of voltage-dependent equilibrium between different gating patterns of dihydropyridine-sensitive (L-type) cardiac Ca2+ channels. Strong depolarizations drive the channel from its normal gating pattern into a mode of gating characterized by long openings and high open probability. The rate constants for conversions between gating modes, estimated from single channel recordings, are much slower than normal channel opening and closing rates, but the equilibrium between modes is almost as steeply voltage-dependent as channel activation and deactivation at more negative potentials. This new mechanism of voltage-dependent gating can explain previous reports of activity-dependent Ca2+ channel potentiation in cardiac and other cells and forms a potent mechanism by which Ca2+ uptake into cells could be regulated.     

Retinal astrocytes are immigrants from the optic nerve

The retina in most mammals contains two types of macroglial cells--Müller cells, which span the entire thickness of the retina, and astrocytes, which are mainly confined to the nerve fibre layer. Whereas Müller cells are diffusely distributed in all vertebrate retinae, the presence and distribution of retinal astrocytes correlate with the presence and distribution of retinal blood vessels: retinae that are avascular contain no astrocytes; those that are diffusely vascularized contain diffusely distributed astrocytes; and those that are vascularized in a restricted region contain astrocytes only in the vascularized region. This striking correlation between vascularization and the presence of astrocytes led Stone and Dreher to postulate that retinal astrocytes are immigrants that enter the retina with its vasculature, although others have suggested that they derive from Müller cells. Here we provide strong evidence that astrocytes in the diffusely vascularized rat retina are immigrants from the optic nerve.     

Neuropeptide modulation of single calcium and potassium channels detected with a new patch clamp configuration

Calcium channel activity is crucial for secretion and synaptic transmission, but it has been difficult to study Ca2+ channel modulation because survival and regulation of some of these channels require cytoplasmic constituents that are lost with the formation of cell-free patches. Here we report a new patch clamp configuration in which activity and regulation of channels are maintained after removal from cells. A pipette containing the pore-forming agent nystatin is sealed onto a cell and withdrawn to form an enclosed vesicle. The resulting perforated vesicle, formed from pituitary tumour cells, contains Ca2+ and K+ channels. Ca2(+)-activated K+ channels in the vesicle are activated by cyclic AMP analogues, and by a neuropeptide (thyrotropin-releasing hormone) that stimulates phosphatidylinositol turnover and inositol trisphosphate-gated Ca2+ release from intracellular organelles. Thus, the perforated vesicle retains signal transduction systems necessary for ion channel modulation. Functional dihydropyridine-sensitive Ca2+ channels (L-type) are maintained in the vesicle, and their gating is inhibited by thyrotropin-releasing hormone. Hence, this new patch clamp configuration has allowed a direct detection of the single-channel basis of transmitter-induced inhibition of L-type Ca2+ channels. The modulation of Ca2(+)-channel gating may be an important mechanism for regulating hormone secretion from pituitary cells.     

A common progenitor for neurons and glia persists in rat retina late in development

Retrovirus-mediated gene transfer was used to mark cell lineages in vivo in the postnatal rat retina. Labelled clones contained up to three different cell types: three types of neurons or two types of neurons and a Müller glial cell. This indicates that a single retinal progenitor can generate remarkably diverse cell types near the end of development.     

Quantification of Ca2+-activated K+ channels under hormonal control in pig pancreas acinar cells

Ca2+- and voltage-activated K+ channels are found in many electrically excitable cells and have an important role in regulating electrical activity. Recently, the large K+ channel has been found in the baso-lateral plasma membranes of salivary gland acinar cells, where it may be important in the regulation of salt transport. Using patch-clamp methods to record single-channel currents from excised fragments of baso-lateral acinar cell membranes in combination with current recordings from isolated single acinar cells and two- and three-cell clusters, we have now for the first time characterized the K+ channels quantitatively. In pig pancreatic acini there are 25-60 K+ channels per cell with a maximal single channel conductance of about 200 pS. We have quantified the relationship between internal ionized Ca2+ concentration [( Ca2+]i) membrane potential and open-state probability (p) of the K+ channel. By comparing curves obtained from excised patches relating membrane potential to p, at different levels of [Ca2+]i, with similar curves obtained from intact cells, [Ca2+]i in resting acinar cells was found to be between 10(-8) and 10(-7) M. In microelectrode experiments acetylcholine (ACh), gastrin-cholecystokinin (CCK) as well as bombesin peptides evoked Ca2+-dependent opening of the K+ conductance pathway, resulting in membrane hyperpolarization. The large K+ channel, which is under strict dual control by internal Ca2+ and voltage, may provide a crucial link between hormone-evoked increase in internal Ca2+ concentration and the resulting NaCl-rich fluid secretion.     

Mechanism of ion permeation through calcium channels

Calcium channels carry out vital functions in a wide variety of excitable cells but they also face special challenges. In the medium outside the channel, Ca2+ ions are vastly outnumbered by other ions. Thus, the calcium channel must be extremely selective if it is to allow Ca2+ influx rather than a general cation influx. In fact, calcium channels show a much greater selectivity for Ca2+ than sodium channels do for Na+ despite the high flux that open Ca channels can support. Relatively little is known about the mechanism of ion permeation through Ca channels. Earlier models assumed ion independence or single-ion occupancy. Here we present evidence for a novel hypothesis of ion movement through Ca channels, based on measurements of Ca channel activity at the level of single cells or single channels. Our results indicate that under physiological conditions, the channel is occupied almost continually by one or more Ca2+ ions which, by electrostatic repulsion, guard the channel against permeation by other ions. On the other hand, repulsion between Ca2+ ions allows high throughput rates and tends to prevent saturation with calcium.     

Mediation of cell volume regulation by Ca2+ influx through stretch-activated channels

Animal cells initially swell in hypotonic media by osmotic water equilibration, but their volume is subsequently regulated by a net loss of KCl and amino acids with concomitant loss of cell water. Mechanisms for regulating cell volume are important in allowing cells to adapt to variations in external tonicity and metabolic load. In red cells the KCl loss is mediated by electroneutral ion transport mechanisms. In contrast, conductive K+ and Cl- transport pathways are activated during regulatory volume decrease in several cell types including epithelia. The activation seems to be mediated by internal Ca2+, but the detailed mechanism is not known. In a leaky epithelium, the choroid plexus epithelium, we have found a cation-selective, Ca2+-permeable channel which opens with membrane stretch. The epithelium also contains a high density of the large (approximately 200 pS) type of Ca2+- voltage-activated K+ channel. Both channels are normally closed. I propose that in hypotonic media, the stretching of the cell membrane produced by the initial swelling causes influx of Ca2+ through the stretch-activated channels, which activates the neighbouring large K+ channels to produce increased K+ outflux with associated loss of cell water.     

A functional correlate for the dihydropyridine binding site in rat brain

Calcium channels, controlling the influx of extracellular Ca2+ and hence neurotransmitter release, exist in the brain. However, drugs classed as calcium antagonists and which inhibit Ca2+ entry through voltage-activated Ca2+ channels in heart and smooth muscle, seem not to affect any aspect of neuronal function in the brain at pharmacologically relevant concentrations. Yet the dihydropyridine calcium antagonists (for example, nitrendipine) bind stereospecifically with high affinity to a recognition site on brain-cell membranes thought to represent the Ca2+ channel and consequently, the physiological relevance of these sites has been questioned. However, activation of voltage-dependent Ca2+ channels can increase cytoplasmic Ca2+ and neurotransmitter release in neuronal tissue. We show here that Bay K8644, a dihydropyridine Ca2+-channel activator, can augment K+-stimulated release of serotonin from rat frontal cortex slices and that these effects can be antagonized by low concentrations of calcium antagonists. As 3H-dihydropyridine binding to cortical membrane preparations resembles the binding in heart and smooth muscle where there are good functional correlates we conclude that the dihydropyridine binding sites in the brain represent functional Ca2+ channels that can be unmasked under certain circumstances.     

Voltage and Ca2+-activated K+ channel in baso-lateral acinar cell membranes of mammalian salivary glands

Nervous or hormonal stimulation of many exocrine glands evokes release of cellular K+ (ref. 1), as originally demonstrated in mammalian salivary glands2,3, and is associated with a marked increase in membrane conductance1,4,5. We now demonstrate directly, by using the patch-clamp technique6, the existence of a K+ channel with a large conductance localized in the baso-lateral plasma membranes of mouse and rat salivary gland acinar cells. The K+ channel has a conductance of approximately 250 pS in the presence of high K+ solutions on both sides of the membrane. Although mammalian exocrine glands are believed not to possess voltage-activated channels1,7, the probability of opening the salivary gland K+ channel was increased by membrane depolarization. The frequency of channel opening, particularly at higher membrane potentials, was increased markedly by elevating the internal ionized Ca2+ concentration, as previously shown for high-conductance K+ channels from cells of neural origin8-10. The Ca2+ and voltage-activated K+ channel explains the marked cellular K+ release that is characteristically observed when salivary glands are stimulated to secrete.     

Voltage-dependent ATP-sensitive potassium channels of skeletal muscle membrane

It has been known for some years that skeletal muscle develops a high potassium permeability in conditions that produce rigor, where ATP concentrations are low and intracellular Ca2+ is high. It has seemed natural to attribute this high permeability to K channels that are opened by internal Ca2+, especially as the presence of such channels has been demonstrated in myotubes and in the transverse tubular membrane system of adult skeletal muscle. However, as we show here, the surface membrane of frog muscle contains potassium channels that open at low internal concentrations of ATP (less than 2 mM). ATP induces closing of these channels without being split, apparently holding the channels in one of a number of closed states. The channels have at least two open states whose dwell times are voltage-dependent. Surprisingly, we find that these may be the most common K channels of the surface membrane of skeletal muscle.     

Stereospecific binding of a disordered peptide segment mediates BK channel inactivation

A number of functionally important actions of proteins are mediated by short, intrinsically disordered peptide segments, but the molecular interactions that allow disordered domains to mediate their effects remain a topic of active investigation. Many K+ channel proteins, after initial channel opening, show a time-dependent reduction in current flux, termed 'inactivation', which involves movement of mobile cytosolic peptide segments (approximately 20-30 residues) into a position that physically occludes ion permeation. Peptide segments that produce inactivation show little amino-acid identity and tolerate appreciable mutational substitutions without disrupting the inactivation process. Solution nuclear magnetic resonance of several isolated inactivation domains reveals substantial conformational heterogeneity with only minimal tendency to ordered structures. Channel inactivation mechanisms may therefore help us to decipher how intrinsically disordered regions mediate functional effects. Whereas many aspects of inactivation of voltage-dependent K+ channels (Kv) can be described by a simple one-step occlusion mechanism, inactivation of the voltage-dependent large-conductance Ca2+-gated K+ (BK) channel mediated by peptide segments of auxiliary β-subunits involves two distinguishable kinetic steps. Here we show that two-step inactivation mediated by an intrinsically disordered BK β-subunit peptide involves a stereospecific binding interaction that precedes blockade. In contrast, blocking mediated by a Shaker Kv inactivation peptide is consistent with direct, simple occlusion by a hydrophobic segment without substantial steric requirement. The results indicate that two distinct types of molecular interaction between disordered peptide segments and their binding sites produce qualitatively similar functions.     

Evidence for the formation of heteromultimeric potassium channels in Xenopus oocytes

Potassium channels show a wide range of functional diversity. Nerve cells typically express a number of K+ channels that differ in their kinetics, single-channel conductance, pharmacology, and sensitivity to voltage and second messengers. The cloning of the Shaker gene in Drosophila, and of related genes, has revealed that the encoded K+ channel polypeptides resemble one of the four internally homologous domains of the alpha-subunits of Na+ channels and Ca2+ channels, indicating that K+ channels may form by the co-assembly of several polypeptides. In this report we provide evidence that the Shaker A-type K+ channels expressed in Xenopus oocytes contain several Shaker polypeptides, that heteromultimeric channels may form through assembly of different channel polypeptides, that the kinetics or pharmacology of some heteromultimeric channels differ from those of homomultimeric channels, and that channel polypeptides from the fruit fly can co-assemble with homologous polypeptides from the rat. We suggest that heteromultimer formation may increase K+ channel diversity beyond even the level expected from the large number of K+ channel genes and alternative splicing products.