Biochemical properties and subcellular distribution of an N-type calcium channel alpha 1 subunit

Spatial distribution of omega-agatoxin IVA binding sites in mouse brain slices

A peptide toxin derived from funnel-web spider venom, omega-agatoxin IVA, blocks voltage-sensitive calcium channels. Many pharmacological and electrophysiological studies have shown that these channels are widely distributed in both the central nervous system (CNS) and neuromuscular junctions. However, a direct morphological demonstration of the binding sites of this toxin is still lacking. To identify which cells have the binding sites, a biologically active, biotin-conjugated omega-agatoxin IVA was applied to mouse cerebellar and hippocampal slices. Confocal microscopy revealed that omega-agatoxin IVA binding sites were distributed on the somata of Purkinje cells, cerebellar granule cells and interneurons, as well as on the dendrites of Purkinje cells. In the hippocampus, the binding sites were localized on the somata of pyramidal cells of the CA1-CA4 region and on the somata of granule cells in the dentate gyrus. A sequential competitive reaction confirmed the specificity of the binding in the cerebellum and CA1 pyramidal cells, and also suggested a difference in the binding affinity between CA1 and CA3 pyramidal cells. Since a high concentration of omega-agatoxin IVA (2 microM) was needed for the present study, the omega-agatoxin IVA binding sites presented in this study may represent "P-type" and "Q-type" calcium channels.

Involvement of P-type calcium channels in high potassium-elicited release of neurotransmitters from rat brain slices

Several types of voltage-dependent calcium channels appear to occur in neurons, although coupling of the particular subtype of calcium channels to the release of neurotransmitter has not been clearly understood. We have examined the effects of subtype-specific inhibitors of the calcium channels on depolarization-induced release of endogenous neurotransmitters from brain slices. High potassium-induced release of glutamate and aspartate from hippocampal and striatal slices was almost completely inhibited by a P-type channel blocker, omega-agatoxin IVA. omega-Agatoxin IVA also completely inhibited the release of serotonin from the hippocampal slices with almost the same potency as in the case of glutamate, whereas the potency in blocking the release of serotonin and dopamine from striatal slices was lower than that from the hippocampal slices. Another calcium channel blocker, omega-agatoxin TK, that was recently found to block P-type channels with very similar selectivity and potency to omega-agatoxin IVA, also inhibited the release of amino acid transmitters and monoamines, though its potency was lower than that of omega-agatoxin IVA. An N-type channel blocker, omega-conotoxin GVIA, partially inhibited the neurotransmitter release, but an L-type channel blocker, nifedipine was ineffective. We propose that the activation of P-type calcium channels makes a major contribution to depolarization-elicited neurotransmitter release in the CNS and that multiple P-type channels sensitive to omega-agatoxin IVA and omega-agatoxin TK modulate the neurotransmitter release.

L-type calcium channels mediate dynorphin neuropeptide release from dendrites but not axons of hippocampal granule cells

Granule cells in the guinea pig dentate gyrus release kappa opioid neuropeptides, dynorphins, from dendrites as well as from axon terminals. We have found that both L- and N-type calcium channel antagonists inhibited dendritic dynorphin release. In contrast, N-type but not L-type calcium channel antagonists inhibited axonal dynorphin release. Neither L- nor N-type channel antagonists directly altered the effects of kappa opioid receptor activation. By inhibiting dynorphin release, L-type channel antagonists also facilitated the induction of long-term potentiation of the perforant path-granule cell synapse. These studies establish that a single cell type can release a transmitter from two different cellular domains and provide new distinction between axonal and dendritic transmitter release mechanisms.

Dendritic calcium transients evoked by single back-propagating action potentials in rat neocortical pyramidal neurons

1. Dendrites of rat neocortical layer V pyramidal neurons were loaded with the Ca2+ indicator dye Calcium Green-1 (CG-1) or fluo-3, and the mechanisms which govern action potential (AP)-evoked transient changes in dendritic cytosolic Ca2+ concentration ([Ca2+]i) were examined. APs were initiated either by synaptic stimulation or by depolarizing the soma or dendrite by current injection, and changes in fluorescence of the indicator dye were measured in the proximal 170 microns of the apical dendrite. 2. Simultaneous two-pipette recordings of APs from the soma and apical dendrite, and dendritic fluorescence imaging indicated that a single AP propagating from the soma into the apical dendrite evokes a rapid transient increase in fluorescence indicating a transient increase in [Ca2+]i. At 35-37 degrees C the decay time constant of the fluorescence transient following an AP was around 80 ms. 3. Voltage-activated Ca2+ channels (VACCs) of several subtypes mediated the AP-evoked fluorescence transient in the proximal (100-170 microns) apical dendrite. The AP-evoked fluorescence transient resulted from Ca2+ entry through L-type (nifedipine sensitive; 25%), N-type (omega-conotoxin GVIA sensitive; 28%) and P-type (omega-agatoxin IVA sensitive; 10%) Ca2+ channels and through Ca2+ channels (R-type) not sensitive to L-, N- and P-type Ca2+ channel blockers (cadmium ion sensitive; 37%). 4. The decay time course of the dendritic fluorescence transient was prolonged by the blockers of endoplasmic reticulum (ER) Ca(2+)-ATPase, cyclopiazonic acid and thapsigargin, suggesting that uptake of Ca2+ into the ER in dendrites governs clearance of dendritic Ca2+. 5. The decay time course of the fluorescence transient was slightly prolonged by benzamil, a blocker of plasma membrane Na(+)-Ca2+ exchange and by calmidazolium, a blocker of the calmodulin-dependent plasma membrane Ca(2+)-ATPase, suggesting that these pathways are less important for dendrite Ca2+ clearance following a single AP. Neither the mitochondrial uncoupler carbonyl cyanide p-(trifluoromethoxy)phenylhydrazone (FCCP) nor the blocker of Ca2+ uptake into mitochondria, Ruthenium Red, had any measurable effect on the decay time course of the fluorescence transient. 6. Dendritic fluorescence transients measured during trains of dendritic APs began to summate at impulse frequencies of 5 APs s-1. At higher frequencies APs caused a concerted and maintained elevation of dendritic fluorescence during the train.(ABSTRACT TRUNCATED AT 400 WORDS)

Different calcium channels are coupled to potassium channels with distinct physiological roles in vagal neurons

Whole-cell and sharp microelectrode recordings were obtained from neurons of rat dorsal motor nucleus of the vagus (DMV) in transverse slices of the rat medulla maintained in vitro. Calcium currents were studied with sodium currents blocked with tetrodotoxin, potassium currents blocked by perfusing the cell with caesium as the main cation and using barium as the charge carrier. From a holding potential of -60 mV, inward currents activated at potentials positive of -50 mV and peaked around 0 mV. Voltage clamping the neuron at more hyperpolarised potentials did not reveal any low-threshold inward current. The inward current was effectively blocked by cadmium (100 microM) and nicked (1 mM), suggesting that it is carried by voltage-dependent calcium channels. The inward current could be separated into three pharmacologically distinct components: 40% of the whole cell current was omega-conotoxin sensitive; 20% of the current was nifedipine sensitive; and the rest was blocked by high concentrations of cadmium and nickel. This remaining current cannot be due to P-type calcium channels as omega-agatoxin had no effect on the inward current. Nifedipine had no significant effect on the action potential. Application of omega-conotoxin reduced the calcium component of the action potential and significantly reduced the potassium current underlying the afterhyperpolarization. Application of charybdotoxin slowed action potential repolarization. When N-type calcium channels were blocked with omega-conotoxin, charybdotoxin was still effective in slowing repolarization. In contrast, charybdotoxin was ineffective ineffective when calcium influx was blocked with the non-specific calcium channel blocker cadmium.(ABSTRACT TRUNCATED AT 250 WORDS)

Calcium signaling in neurons: molecular mechanisms and cellular consequences

Neuronal activity can lead to marked increases in the concentration of cytosolic calcium, which then functions as a second messenger that mediates a wide range of cellular responses. Calcium binds to calmodulin and stimulates the activity of a variety of enzymes, including calcium-calmodulin kinases and calcium-sensitive adenylate cyclases. These enzymes transduce the calcium signal and effect short-term biological responses, such as the modification of synaptic proteins and long-lasting neuronal responses that require changes in gene expression. Recent studies of calcium signal-transduction mechanisms have revealed that, depending on the route of entry into a neuron, calcium differentially affects processes that are central to the development and plasticity of the nervous system, including activity-dependent cell survival, modulation of synaptic strength, and calcium-mediated cell death.

Synaptic activation of voltage-gated channels in the dendrites of hippocampal pyramidal neurons

Activation of dendritic voltage-gated ion channels by local synaptic input was tested by simultaneous dendrite-attached patch-clamp recordings and whole-cell somatic voltage recordings made from CA1 pyramidal neurons in hippocampal slices. Schaffer collateral stimulation elicited subthreshold excitatory postsynaptic potentials (EPSPs) that opened voltage-gated sodium and calcium channels in the apical dendrites. The EPSP-activated sodium channels opened near the peak of the EPSP, whereas low voltage-activated calcium channels opened near the EPSP peak and during the decay phase. Dendritic high voltage-activated channels required somatic action potential generation or suprathreshold synaptic trains for activation. Dendritic voltage-gated channels are, therefore, likely to participate in dendritic integration of synaptic events.

Measurements of exocytosis from single presynaptic nerve terminals reveal heterogeneous inhibition by Ca(2+)-channel blockers

The effect of various Ca(2+)-channel blockers on exocytosis has been studied at the level of single presynaptic terminals in rat hippocampal cell cultures. The fluorescence change of the styryl dye FM 1-43 has been used as a measure of exocytosis during electrical stimulation. omega-Conotoxin GVIA (2-10 microM) completely inhibited exocytosis in approximately 45% of the boutons in the field of view, while in approximately 55% exocytosis was inhibited incompletely (by 38%). This heterogeneity in response of presynaptic boutons was not seen with isradipine (5 microM) or omega-agatoxin IVA (80 nM), which inhibited exocytosis by 23% and 17%, respectively. However, it was observed with a combination of all three blockers. Pre- and postsynaptic events could be separated in single synapses by measuring FM1-43 release and NMDA-induced changes in the intracellular Ca2+ concentration independently.

Modulation of calcium currents by a D1 dopaminergic protein kinase/phosphatase cascade in rat neostriatal neurons

In rat neostriatal neurons, D1 dopamine receptors regulate the activity of cyclic AMP-dependent protein kinase (PKA) and protein phosphatase 1 (PP1). The influence of these signaling elements on high voltage-activated (HVA) calcium currents was studied using whole-cell voltage-clamp techniques. The application of D1 agonists or cyclic AMP analogs reversibly reduced N- and P-type Ca2+ currents. Inhibition of PKA antagonized this modulation, as did inhibition of PP1, suggesting that the D1 effect was mediated by a PKA enhancement of PP1 activity directed toward Ca2+ channels. In a subset of neurons, D1 receptor-mediated activation of PKA enhanced L-type currents. The differential regulation of HVA currents by the D1 pathway helps to explain the diversity of effects this pathway has on synaptic integration and plasticity in medium spiny neurons.

Expression of nerve growth factor, p75, and trk in the somatosensory and motor cortices of mature rats: evidence for local trophic support circuits

Neurotrophins such as nerve growth factor (NGF) are critical for the maintenance of CNS neurons. We determined the expression of NGF and the neurotrophin receptors p75 and trk in the somatosensory and motor cortices of mature rats with immunohistochemical techniques. Sections of mature rat cortex were processed immunohistochemically with primary antibodies directed against NGF, p75, or trk. The distribution of immunoreactive elements was examined, and stereological techniques were used to determine the density and size of immunoreactive cell bodies. Some sections processed for trk immunoreactivity were examined with an electron microscope. From the size and morphology of the labeled cells, it appeared that only neurons in the gray matter were NGF-positive. NGF was detected in one-third of the neurons in layers II-III, V, and VI of both somatosensory cortex and motor cortex; however, fewer than 1 in 12 of the layer IV neurons was NGF-positive. With the notable exception of layer V, few cell bodies (2-10% of the total population) were p75- or trk-immunoreactive. Layer Vb was replete with receptor-positive cell bodies; more than one-third of the layer Vb neurons were p75- or trk-positive. All labeled cells appeared to be pyramidal neurons. The distribution of p75 labeling with the two anti-p75 antibodies was indistinguishable. In addition, the neuropil in the supragranular laminae was p75- or trk-positive. Electron microscopy showed that trk immunoreactivity was also expressed by dendrites. Only rarely were immunoreactive axons detected. In summary, NGF is expressed by cortical neurons throughout cortex, and neurotrophin receptors are widely produced by postsynaptic targets. Thus, NGF appears to participate in an intracortical autoregulatory system. The strong expression of neurotrophin receptors by pyramidal neurons in layer Vb (the origin of brainstem and spinal cord projections) suggests that the neurotrophins are especially critical for the regulation of corticofugal projection systems.

An anti-peptide antibody specific for the class A calcium channel alpha 1 subunit labels mammalian neuromuscular junction

We have generated an anti-peptide antibody specific for the class A calcium channel alpha 1 subunit from rat brain. In immunoblots of the calcium channel complex partially purified from rat brain membranes, the antibody specifically recognized two doublets, one of apparent M(r) 210,000 and M(r) 180,000 and another of apparent M(r) 160,000 and M(r) 130,000. Immunofluorescent staining of sections of rat diaphragm showed that this antibody specifically recognizes antigens that are highly concentrated at neuromuscular synapses. Using this antibody, we also examined the distribution of the class A alpha 1 subunit in sagittal sections of rat cerebellum by immunoperoxidase staining. Specific immunoreactivity was localized in the granule cell layer, possibly to the cerebellar glomeruli, the unique structures in cerebellum where mossy fibers synapse with granule cell dendrites. Purkinje cell neurons were not stained specifically. These results indicate that the class A calcium channel alpha 1 subunit is highly concentrated at mammalian neuromuscular junction and has a restricted localization in cerebellum that does not include Purkinje cell soma or dendrites.

Identification of a syntaxin-binding site on N-type calcium channels

Immunochemical studies have suggested a tight association of syntaxin with N-type calcium channels. Syntaxin specifically interacts with the fusion proteins containing the cytoplasmic loop (LII-III) between homologous repeats II and III of the alpha 1 subunit of the class B N-type calcium channel (alpha 1B) from rat brain, but not with those of the class A Q-type (alpha 1A) or the class S L-type (alpha 1S) calcium channels. This interaction is mediated by an 87 amino acid sequence (773-859) containing two overlapping predicted helix-loop-helix domains. The 87 amino acid peptide can specifically block binding of native N-type calcium channels to syntaxin, indicating that this binding site is required for stable interaction of these two proteins. Interaction takes place with the C-terminal one-third of syntaxin (residues 181-288), which is thought to be anchored in the presynaptic plasma membrane. Our results suggest a direct interaction between the cytoplasmic domains of these two presynaptic membrane proteins that could have an important role in the targeting and docking of synaptic vesicles near N-type calcium channels, enabling tight structural and functional association of calcium entry sites and neurotransmitter release sites.

Structural determinants of the blockade of N-type calcium channels by a peptide neurotoxin

Neurotoxins that selectively block Na+, K+ or Ca2+ channels have provided valuable information about the functional diversity of the voltage-gated channel superfamily. For Ca2+ channels, a variety of toxins have been found to block individual channel types. The best-known example is omega-conotoxin-GVIA, a member of a large family of peptide toxins derived from venomous cone snails, which potently and selectively blocks N-type Ca2+ channels, allowing their purification, cellular localization, and the elucidation of their roles in Ca2+ entry, neurotransmitter release and neuronal migration. In contrast to Na+ and K+ channels, little is known about the molecular features that underlie Ca(2+)-channel susceptibility to toxin block; it is also unknown whether block occurs by direct physical occlusion or an action on channel gating. Here we describe structural determinants of N-type Ca2+ channel's interaction with omega-conotoxin-GVIA. When chimaeras combining individual motifs from the N-type channel and from a channel insensitive to omega-conotoxin-GVIA were expressed in Xenopus oocytes, each of the four motifs appeared to contribute to interaction with the toxin. The most dramatic effects on toxin interactions were seen at a single cluster of residues in the large putative extracellular loop between IIIS5 and IIIH5, consistent with a direct pore-blocking mechanism. These results provide a starting point for delineating the architecture of the outer vestibule of the Ca2+ channel.

Involvement of N- and non-N-type calcium channels in synaptic transmission at corticostriatal synapses

Calcium channels participate in the events linking axon terminal depolarization to neurotransmitter secretion. We wished to evaluate the role of N-type and non-N-type calcium channels in glutamatergic transmission at corticostriatal synapses, since this is a well defined excitatory synapse. In addition, these synapses are subject to a variety of forms of presynaptic modulation, some of which may involve alterations in calcium channel function. Application of the selective N-type channel blocker omega-conotoxin GVIA produced an irreversible depression of excitatory synaptic transmission in rat neostriatal slices shown by a decrease of approximately 50% in the amplitude of the synaptically driven population spike during field potential recording and a similar decrease in the amplitude of excitatory postsynaptic potentials during whole-cell recording. The component of transmission which was resistant to omega-conotoxin GVIA was blocked by omega-conotoxin MVIIC. omega-Agatoxin IVA had little effect on transmission. Activation of a presynaptic metabotropic glutamate receptor depressed transmission to a similar extent before and after omega-conotoxin GVIA treatment. Likewise, protein kinase C-activating phorbol esters potentiated transmission to the same extent before and after omega-conotoxin GVIA treatment. N-type calcium channels appear to be crucial for a component of excitation-secretion coupling at corticostriatal synapses. A component of transmission involves non-N-, non-L-type high-voltage-activated calcium channels. The effects of presynaptic metabotropic receptors and protein kinase C activation cannot be accounted for solely by alterations in the N-type channel function.

Neuroanatomical distribution of receptors for a novel voltage-sensitive calcium-channel antagonist, SNX-230 (omega-conopeptide MVIIC)

Neuronal voltage-sensitive calcium channels (VSCCs) are a diverse family of proteins that regulate entry of Ca2+ into neurons. Selective antagonists of VSCCs have proven to be powerful pharmacological tools for identifying and characterizing these channels. A new VSCC antagonist, SNX-230 (also known as omega-conopeptide MVIIC), binds with high affinity to receptors in rat brain and blocks one or more high-threshold VSCCs that are neither L- nor N-type. We have defined the neuroanatomical distribution of the high-affinity non-L, non-N VSCC receptors for SNX-230 using [125I]SNX-230 bound to rat brain sections and compared it with that of [125I]SNX-111, a reversible blocker of N-type VSCCs. Highest densities of binding for both ligands were seen in areas rich in synaptic connections, such as the oriens, radiatum and molecular layers of the hippocampus. In general, the density of [125I]SNX-230-binding was higher in cerebellum compared with that in forebrain. In contrast, this general distribution of density was reversed for [125I]SNX-111. In the glomeruli of the olfactory bulb, binding of [125I]SNX-230 was undetectable compared with the high density of [125I]SNX-111-binding. Differential localization of the two ligands was also seen in cervical spinal cord. The clearly different localization of [125I]SNX-230 compared with that of [125I]SNX-111 in the olfactory bulb and spinal cord suggested that the binding sites for [125I]SNX-230 in other brain regions, while co-localized macroscopically, are also distinct from those for [125I]SNX-111. This was confirmed when addition of saturating concentrations of SNX-111 did not affect the distribution pattern of [125I]SNX-230-binding.(ABSTRACT TRUNCATED AT 250 WORDS)

Isoflurane inhibits calcium currents in neocortical neurons

We used voltage-clamp techniques to assess the effects of isoflurane anaesthesia in slices of sensorimotor cortex of guinea pigs and neonatal rats. Isoflurane (0.5-4%) depressed inward Ca(2+)-currents evoked by depolarizing commands from -50 mV. With additional blockade of K(+)-currents by internal Cs+, an early component of the sustained inward currents was a high voltage-activated current whereas the delayed component was an unclamped Ca(2+)-current; this was consistent with a simple compartmental model. Isoflurane decreased the magnitude of the high voltage-activated current.

Ca2+ accumulations in dendrites of neocortical pyramidal neurons: an apical band and evidence for two functional compartments

Apical dendrites constitute a prominent feature of the microcircuitry in the neocortex, yet their function is poorly understood. Using fura-2 imaging of layer 5 pyramidal neurons from slices of rat somatosensory cortex, we have investigated the Ca2+ influx into dendrites under intracellular, antidromic, synaptic, and receptor-agonist stimulation. We find three spatial patterns of Ca2+ accumulations: an apical band in the apical dendrite approximately 500 microns from the soma, an accumulation restricted to the basal dendrites, soma, and proximal apical dendrite, and a combination of both of these. We show that the apical band can be activated antidromically and synaptically and that, under blocked Na+ and K+ conductances, it generates Ca2+ spikes. Thus, the apical band may serve as a dendritic trigger zone for regenerative Ca2+ spikes or as a current amplifier for distal synaptic events. Our results suggest that the distal apical dendrite should be considered a separate functional compartment from the rest of the cell.

Dendritic calcium dynamics

Further characterization of the biochemical components that contribute to calcium handling, together with advances in optical imaging of ion concentration, are providing quantitative information on the dynamics of calcium in the dendrites of neurons in tissue culture, brain slices and in vivo. It has recently been demonstrated that strong spatial gradients and transient calcium elevations result from the geometry and membrane properties of dendrites. These studies are adding to our understanding of calcium's role in synaptic plasticity and in shaping the electrophysiological properties of neurons.

Solutions for transients in arbitrarily branching cables: IV. Nonuniform electrical parameters

Solutions for transients in arbitrarily branching passive cable neurone models with a soma are extended to models with nonuniform electrical parameters and multiple dendritic shunts. The response to an injected current can again be represented as an infinite series of exponentially decaying components with system time constants obtained from the roots of a recursive transcendental equation. The reciprocity relations and global parameter dependencies are the same as for uniform models. Infinitely many "raw" electro-morphological models map onto a given "core" electrotonic model; local as well as global raw parameter trade-offs are now possible. The solutions are illustrated by means of biologically relevant examples: (i) the effects of nonuniform electrical parameters in a two-cylinder + soma cortical pyramidal cell model, (ii) the errors that can occur when uniformity is incorrectly assumed in a single cylinder model, (iii) nonsumming interactions between cells and electrodes that can dramatically increase the duration of the effective capacitative electrode artefact, and (iv) shunting inhibition and double impalements in a hippocampal CA1 pyramidal cell "cartoon" representation. These solutions should complement compartmental modelling techniques.

Antipeptide antibodies against a Torpedo cysteine-string protein

An antipeptide antiserum was raised against the C-terminal undecapeptide of a Torpedo cysteine-string protein (csp), a putative subunit or modulator of presynaptic calcium channels. This antiserum was shown to identify selectively the 27-kDa in vitro translation product of the csp cRNA both by immunoprecipitation and on immunoblots. When affinity-purified anti-csp antibodies were used to probe immunoblots of membrane proteins from Torpedo electric organ or liver, specific immunoreactivity was detected only in electric organ. This immunoreactivity was associated principally with a single protein species of about 34 kDa. These results indicate that csp immunoreactivity is detectably expressed in electroplax, a heavily innervated tissue, but not in liver, which should have an appreciably lower abundance of presynaptic calcium channel proteins. Moreover, the increased relative molecular mass of csp in electric organ (compared with in vitro translated material) implies that csp is posttranslationally modified. Finally, immunoblot analysis of either intact, alkali-treated, or solubilized membrane fractions of electric organ reveals that csp is predominantly a membrane protein.

Molecular cloning of a murine N-type calcium channel alpha 1 subunit. Evidence for isoforms, brain distribution, and chromosomal localization

A cDNA encoding a N-type Ca2+ channel has been cloned from the murine neuroblastoma cell line N1A103. The open reading frame encodes a protein of 2,289 amino acids (257 kDa). Analysis of different clones provided evidence for the existence of distinct isoforms of N-type channels. High levels of mRNA were found in the pyramidal cell layers CA1, CA2 and CA3 of the hippocampus, in the dentate gyrus, in the cortex layers 2 and 4, in the subiculum and the habenula. The N-type Ca2+ channel gene has been localized on the chromosome 2, band A.

Potentiating and depressant effects of metabotropic glutamate receptor agonists on high-voltage-activated calcium currents in cultured retinal ganglion neurons from postnatal mice

This study was aimed at clarifying the role of metabotropic glutamate receptors (mGluRs) in the regulation of intracellular Ca2+ concentration ([Ca2+]i in postnatal mouse retinal ganglion neurons (RGNs). RGNs were maintained for 1-2 weeks in vitro by adding brain-derived neurotrophic factor (BDNF) and basic fibroblast growth factor (bFGF) to the culture medium. In order to select these cells for electrophysiological measurements, RGNs were vitally labelled with an antibody against Thy-1.2. Voltage-activated Ca2+ currents [ICa(V)] were recorded with patch electrodes in the whole-cell configuration. It was found that racemic +/--1-amino-cyclopentane-trans-1,3-dicarboxylic acid (t-ACPD) or its active enantiomer 1S,3R-ACPD rapidly and reversibly either enhanced or depressed ICa(V). Quisqualate (QA), L-2-amino-4-phosphonobutyrate (L-AP4) and the endogenous transmitter glutamate induced similar effects when ionotropic glutamate receptors were blocked with D-2-amino-5-phosphonovalerate (D-APV) and 6,7-dinitroquinoxaline-2,3-dione (DNQX). omega-Conotoxin GVIA (omega-CgTx GVIA), but not nifedipine prevented modulation of ICa(V) by mGluR agonists. The depression of ICa(V) by t-ACPD was irreversible when cells were dialysed with guanosine-5'-O-(3-thiotriphosphate) (GTP[gamma-S]). Ratio measurements of fura-2 fluorescence in Thy-1+ cells showed that neither t-ACPD, QA nor L-AP4 affected [Ca2+]i by liberation of Ca2+ from intracellular stores. Our results suggest that cultured RGNs express mGluRs. These receptors cannot induce Ca2+ release from intracellular stores but regulate [Ca2+]i by a fast and reversible, G-protein-mediated action on a subpopulation of voltage-activated Ca2+ channels.

Analytical solutions to the multicylinder somatic shunt cable model for passive neurones with differing dendritic electrical parameters

The multicylinder somatic shunt cable model for passive neurones with differing time constants in each cylinder is considered in this paper. The solution to the model with general inputs is developed, and the parameteric dependence of the voltage response is investigated. The method of analysis is straightforward and follows that laid out in Evans et al. (1992, 1994): (i) The dimensional problem is stated with general boundary and initial conditions. (ii) The model is fully non-dimensionalised, and a dimensionless parameter family which uniquely governs the behaviour of the dimensionless voltage response is obtained. (iii) The fundamental unit impulse problem is solved, and the solutions to problems involving general inputs are written in terms of the unit impulse solution. (iv) The large and small time behaviour of the unit impulse solution is examined. (v) The parametric dependence of the unit impulse upon the dimensionless parameter family is explored for two limits of practical interest. A simple expression for the principle relationship between the dimensionless parameter family is derived and provides insight into the interaction between soma and cylinders. A well-posed method for the solution of the dimensional inverse problem is presented.

Prominent location of a K+ channel containing the alpha subunit Kv 1.2 in the basket cell nerve terminals of rat cerebellum

A panel of monoclonal antibodies specific for a family of voltage-dependent, fast-activating K+ channels, raised against alpha-dendrotoxin acceptors purified from bovine brain, were used to probe the distribution of these important proteins in rat cerebellum. All the antibodies reacted with their antigens in the folial white matter, the granular cell layer and the basket cell nerve termini within the Purkinje cell layer. However, a very intense staining pattern was exhibited by only one monoclonal that reacts exclusively with Kv 1.2 alpha subunit, the predominant isoform present in alpha-dendrotoxin sensitive K+ channels. Double-labelling procedures with neuronal and glial markers were used to verify this discrete antibody staining of the basket cell terminals that synapse with the base of Purkinje cell bodies in a readily recognizable and characteristic fashion. This is the first direct demonstration, using a monoclonal antibody, of a presynaptic location for a voltage-activated K+ channel; its discrete distribution in the basket cell pinceau suggests that it could control release of the inhibitory transmitter GABA and, thereby, influence excitability of Purkinje cells in the cerebellum.

Identification and differential subcellular localization of the neuronal class C and class D L-type calcium channel alpha 1 subunits

To identify and localize the protein products of genes encoding distinct L-type calcium channels in central neurons, anti-peptide antibodies specific for the class C and class D alpha 1 subunits were produced. Anti-CNC1 directed against class C immunoprecipitated 75% of the L-type channels solubilized from rat cerebral cortex and hippocampus. Anti-CND1 directed against class D immunoprecipitated only 20% of the L-type calcium channels. Immunoblotting revealed two size forms of the class C L-type alpha 1 subunit, LC1 and LC2, and two size forms of the class D L-type alpha 1 subunit, LD1 and LD2. The larger isoforms had apparent molecular masses of approximately 200-210 kD while the smaller isoforms were 180-190 kD, as estimated from electrophoresis in gels polymerized from 5% acrylamide. Immunocytochemical studies using CNC1 and CND1 antibodies revealed that the alpha 1 subunits of both L-type calcium channel subtypes are localized mainly in neuronal cell bodies and proximal dendrites. Relatively dense labeling was observed at the base of major dendrites in many neurons. Staining in more distal dendritic regions was faint or undetectable with CND1, while a more significant level of staining of distal dendrites was observed with CNC1, particularly in the dentate gyrus and the CA2 and CA3 areas of the hippocampus. Class C calcium channels were concentrated in clusters, while class D calcium channels were generally distributed in the cell surface membrane of cell bodies and proximal dendrites. Our results demonstrate multiple size forms and differential localization of two subtypes of L-type calcium channels in the cell bodies and proximal dendrites of central neurons. The differential localization and multiple size forms may allow these two channel subtypes to participate in distinct aspects of electrical signal integration and intracellular calcium signaling in neuronal cell bodies. The preferential localization of these calcium channels in cell bodies and proximal dendrites implies their involvement in regulation of calcium-dependent functions occurring in those cellular compartments such as protein phosphorylation, enzyme activity, and gene expression.

The calcium channel coupled to the exocytosis of L-glutamate from cerebellar granule cells is inhibited by the spider toxin, Aga-GI

The increase in cytosolic calcium, [Ca2+]c, evoked with 50 mM KCl in cerebellar granule cells consists of four components; (1) a rapidly inactivating transient or spike; (2) a nifedipine-sensitive non-inactivating plateau; (3) an Aga-GI (spider toxin) sensitive non-inactivating plateau; (4) a residual non-inactivating plateau insensitive to nifedipine and Aga-GI. None of these components is blocked by synthetic arginine polyamine toxin, spermine, (+)-MK-801 hydrogen maleate, D(-)-2-amino-5-phosphonopentanoic acid or omega-conotoxin-GVIA. The proposed P-type channel antagonist, omega-agatoxin-IVA, has a limited but non-significant effect on the elevated plateau [CA2+]c.L-type Ca2+ channels are located primarily on the soma whereas the component of the plateau which is blocked specifically by Aga-GI is localized primarily on the cell neurites. The latter component is coupled to the exocytosis of endogenous glutamate evoked with 50 mM KCl.

A beta-subunit normalizes the electrophysiological properties of a cloned N-type Ca2+ channel alpha 1-subunit

The electrophysiological and pharmacological properties of a cloned rat brain N-type Ca2+ channel were determined by transient expression in Xenopus oocytes. Expression of the class B Ca2+ channel alpha 1 subunit, rbB-I, resulted in a high voltage-threshold current that activated slowly and showed little inactivation over 800 msec. Characteristic of N-type currents, the rbB-I current was completely blocked by omega-conotoxin GVIA and was insensitive to nifedipine and Bay K8644. The modulatory effects on the rbB-I current by cloned rat brain Ca2+ channel alpha 2 and beta 1b subunits were also examined. Coexpression of rbB-I with the beta 1b subunit caused significant changes in the properties of the rbB-I current making it more similar to N-type currents in neurons. These included: (1) an increase in the whole-cell current, (2) an increased rate of activation, (3) a shift of the voltage-dependence of inactivation to hyperpolarized potentials and (4) a pronounced inactivation of the current over 800 msec. Coexpression with the rat brain alpha 2 subunit had no significant effect on the rbB-I current alone but appeared to potentiate the rbB-I+beta 1b whole cell current. The results show that coexpression with the brain beta 1b subunit normalizes the rbB-I N-type current, and suggests the possibility that differences in subunit composition may contribute to the heterogeneous properties described for N-type channels in neurons.