Pharmacological characterization of the serotonin-sensitive potassium channel of Aplysia sensory neurons

The effects of a variety of K+ channel blockers on current flow through single serotonin-sensitive K+ channels (the S channels) of Aplysia sensory neurons were studied using the patch-clamp technique. Tetraethylammonium (TEA), 4-aminopyridine (4-AP), and Co2+ and Ba2+ were first applied to the external membrane surface using cell-free outside-out patches. At concentrations up to 10 mM, these agents had little or no effect on single S-channel currents. At higher concentrations, external TEA acted as a fast open-channel blocker, reducing the single-channel current amplitude according to a simple one-to-one binding scheme with an apparent Kd of 90 mM. Blockage by external TEA is voltage independent. Internal TEA also acts as an open-channel blocker, with an apparent Kd of approximately 40 mM and a relatively weak voltage dependence, corresponding to an apparent electrical distance to the internal TEA-binding site of 0.1. Both internal and external TEA block the open channel selectively, with an affinity that is 10-100-fold greater than the affinity for the closed channel. Internal Ba2+ acts as a slow channel blocker, producing long closures of the channel, and binding with an apparent Kd of approximately 25-30 microM. These results show that single S-channel currents share a similar pharmacological profile with the macroscopic S current previously characterized with voltage clamp. On the basis of these results, a structural model for S-channel opening is proposed.     

Fractal analysis of a voltage-dependent potassium channel from cultured mouse hippocampal neurons.

The kinetics of ion channels have been widely modeled as a Markov process. In these models it is assumed that the channel protein has a small number of discrete conformational states and the kinetic rate constants connecting these states are constant. In the alternative fractal model the spontaneous fluctuations of the channel protein at many different time scales are represented by a kinetic rate constant k = At1-D, where A is the kinetic setpoint and D the fractal dimension. Single-channel currents were recorded at 146 mM external K+ from an inwardly rectifying, 120 pS, K+ selective, voltage-sensitive channel in cultured mouse hippocampal neurons. The kinetics of these channels were found to be statistically self-similar at different time scales as predicted by the fractal model. The fractal dimensions were approximately 2 for the closed times and approximately 1 for the open times and did not depend on voltage. For both the open and closed times the logarithm of the kinetic setpoint was found to be proportional to the applied voltage, which indicates that the gating of this channel involves the net inward movement of approximately one negative charge when this channel opens. Thus, the open and closed times and the voltage dependence of the gating of this channel are well described by the fractal model.     

Temperature dependence of drug blockade of a calcium-dependent potassium channel in cultured hippocampal neurons.

The temperature dependence of drug blockade of a calcium-dependent potassium channel K(Ca) has been studied in cultured CA1 hippocampal neurons. Channel openings from a 70-pS K+ channel were recorded when inside-out patches were exposed to a bath solution containing 140 mM K+ and 0.2 mM Ca2+. The mean open times of channel events were not significantly altered when the bath temperature was lowered from 24 degrees to 14 degrees C (Q10 = 1.2). Introduction of the drug RP-62719 into the bath solution (at 5 microM) resulted in the mean open time of the K(Ca) channel to be diminished by 85% (at 24 degrees C) with no change in the amplitudes of the unitary currents. Over the same temperature range of 24 degrees to 14 degrees C, in the presence of RP-62719, the mean open times were significantly prolonged (Q10 = 2.2). A simple open channel block scheme was used to determine the temperature dependence of the onward- (blocking) and off- (unblocking) rate constants. Thermodynamic analysis, using transition rate theory, showed that the blocking rate constant was associated with a large increase in entropy. The relatively high temperature dependence for channel blockade is not consistent with a rate-limiting process established by simple diffusion of the agent to a channel blocking site. Channel block may involve conformational changes in the channel protein as a consequence of hydrophobic interactions between drug and channel sites.     

Synapse formation and mRNA localization in cultured Aplysia neurons

mRNA localization and regulated translation provide a means of spatially restricting gene expression within neurons during axon guidance and long-term synaptic plasticity. Here we show that synapse formation specifically alters the localization of the mRNA encoding sensorin, a peptide neurotransmitter with neurotrophin-like properties. In isolated Aplysia sensory neurons, which do not form chemical synapses, sensorin mRNA is diffusely distributed throughout distal neurites. Upon contact with a target motor neuron, sensorin mRNA rapidly concentrates at synapses. This redistribution only occurs in the presence of a target motor neuron and parallels the distribution of sensorin protein. Reduction of sensorin mRNA, but not protein, with dsRNA inhibits synapse formation. Our results indicate that synapse formation can alter mRNA localization within individual neurons. They further suggest that translation of a specific localized mRNA, encoding the neuropeptide sensorin, is required for synapse formation between sensory and motor neurons.     

GABA-induced potassium channels in cultured neurons

When gamma-aminobutyric acid (GABA) or baclofen were applied to cultured rat hippocampal neurons, single-channel potassium currents appeared after a delay of 30 s or more in patches of membrane on the cell surface isolated from the agonists by the recording pipette. The appearance of currents in patches not exposed to agonist, the delay in their appearance and the suppression of currents in cells pre-incubated with pertussis toxin indicate the involvement of an intracellular second messenger system. The channels were associated with a GABAB receptor rather than a GABAA receptor as they were blocked by baclofen, a GABAB antagonist, but were not affected by bicuculline, a GABAA antagonist. A feature of the single channel currents was their variable amplitude: they had a maximum conductance of ca. 70 pS and displayed many lower conductance states that were integral multiples of 5-6 pS. In several cells exposed to GABA or baclofen, first small currents and then progressively larger currents appeared: current amplitude was a multiple of an elementary current. It is suggested that binding of GABA to GABAB receptors activates a second messenger system causing opening of oligomeric potassium channels.     

A discrete type of potassium channel conductance in snail neurons

The results of further investigations on a single potential dependent K+ channel are described. It was shown that ionic selectivity of the channel for monovalent ions is too high: Li+, Na+, and Cs+ are practically impermeant ions. Permeability of the channel for Rb+ is approximately 10 times less, and for Tl+ it is 2 times more than permeability for K+. Besides, it was found that open K+ channel has 16 multiple conductance levels.     

Fast inactivating potassium current in cultured hippocampal neurons

Using a voltage-clamp whole-cell technique, we studied transmembrane currents in hippocampal neurons after their long-lasting cultivation. Based on the activational characteristics and data on pharmacological sensitivity, we isolated and described an A-type voltage-activated fast inactivating potassium current (FIPC). This transient FIPC was activated at −50… −40 mV and was rather sensitive to 4-aminopyridine (4-AP). Extracellular application of 5 mM 4-AP decreased the FIPC amplitude by 75%, while application of 10 mM tetraethylammonium evoked no significant changes in it. Kinetics of FIPC activation could be described by one exponent in the fourth degree. With variations of the membrane potential from −40 to 30 mV, the activation time constant varied from 2.8 to 1.5 msec. Inactivation kinetics was described by one exponent with the time constant varying from 37 msec at −45 mV to 18 msec at 40 mV. Stationary activation and inactivation curves could be described by Boltzmann's equation; a half value of the level of stationary inactivation was reached at −80 mV, while stationary activation was attained at −25 mV. Kinetics of deinactivation (from stationary inactivation) was monoexponential with the time constant of 41 msec. It is supposed that FIPC through the membrane of hippocampal neurons is provided by the type Kv4.2 potassium channels.     

Repetitive firing triggers clustering of Kv2.1 potassium channels in Aplysia neurons

The Kv2.1 gene encodes a highly conserved delayed rectifier potassium channel that is widely expressed in neurons of the central nervous system. In the bag cell neurons of Aplysia, Kv2.1 channels contribute to the repolarization of action potentials during a prolonged afterdischarge that triggers a series of reproductive behaviors. Partial inactivation of Aplysia Kv2.1 during repetitive firing produces frequency-dependent broadening of action potentials during the afterdischarge. We have now found that, as in mammalian neurons, Kv2.1 channels in bag cell neurons are localized to ring-like clusters in the plasma membrane of the soma and proximal dendrites. Either elevation of cyclic AMP levels or direct electrical stimulation of afterdischarge rapidly enhanced formation of these clusters on the somata of these neurons. In contrast, injection of a 13-amino acid peptide corresponding to a region in the C terminus that is required for clustering of Kv2.1 channels produced disassociation of the clusters, resulting in a more uniform distribution over the somata. Voltage clamp recordings demonstrated that peptide-induced dissociation of the Kv2.1 clusters is associated with an increase in the amplitude of delayed rectifier current and a shift of activation toward more negative potentials. In current clamp recording, injection of the unclustering peptide reduced the width of action potentials and reduced frequency-dependent broadening of action potentials. Our results suggest that rapid redistribution of Kv2.1 channels occurs during physiological changes in neuronal excitability.     

Concanavalin A induces endoreduplication in cultured mammalian cells.

Concanavalin A (Con A) induced endoreduplication in an established cell line, Don, of the Chinese hamster. The inducibility of Con A was inhibited by α-methyl-D-mannoside. When a secondary culture of kidney cells (CHK), which showed the contact-inhibition of growth, was used, there was an increase in spontaneous endoreduplication. CHK cells or some of them were more sensitive to Con A than Don cells, in which few spontaneous endoreduplications were observed. Mitotic shake-off after Con A treatment led to the higher ratio of endoreduplicated cells to normal mitoses, suggesting that endoreduplicating cells do not “round-up” and probably do not condense chromosomes through the cell cycle until M is reached.     

Zinc modulates a-type potassium currents and neuronal excitability in snail neurons

Summary 1. Zinc-induced actions were studied on the A-current and neuronal activity in identified and unidentified nerve cells of the snail,Helix pomatia L., under voltage and current clamp conditions.2. Extracellularly applied Zn²⁺ attenuated the peak amplitude of the A-current in a potential- and dose-dependent way (K _i=1.8 mM at –30 mV,n _H=0.6).3. Attenuation of the A-currents was initiated as Zn²⁺ shifted the potential dependence of both activation and inactivation of the currents toward more positive potential values.4. Zinc concomitantly prolonged the time to peak and decay time constant of the A-currents (K _d=1.7 mM,n _H=1.4) as well.5. Zn²⁺ decreased the resting membrane potential and the spike amplitude and increased the action potential duration and the input resistance of the cells in current clamp experiments.6. A complex action of zinc increased the neuronal excitability, indicating spontaneous and synaptically evoked spike discharges.7. Common and specific zinc binding sites are supposed on vertebrate and invertebrate A-type potassium channel proteins, where binding Zn²⁺ can modulate the gating properties and kinetics of the fast outward potassium currents.     

Phosphoproteins associated with the regulation of a specific potassium channel in the identified Aplysia neuron R15

The neurotransmitter serotonin (5HT) activates a specific K+ conductance in the identified Aplysia neuron R15. This response to 5HT has been shown previously to be mediated by cAMP and cAMP-dependent protein phosphorylation. We have measured protein phosphorylation within neuron R15 in vivo, following the intracellular injection of [gamma-32P]ATP, and have demonstrated that 5HT modulates the phosphorylation of a number of proteins in R15. The present study was undertaken to determine which of these phosphoproteins are closely associated with, and may be responsible for, the K+ conductance increase. Treatment of neuron R15 with a cAMP analog produces some but not all of the 5HT-induced phosphoprotein changes, indicating that some are not cAMP-dependent and thus can be dissociated from the cAMP-dependent K+ conductance increase. Similar results are obtained by intracellular injection of the adenylate cyclase inhibitor guanosine 5'-O-(2-thiodiphosphate), which completely blocks the 5HT-evoked K+ conductance increase but fails to block some of the 5HT-induced phosphorylation changes. Examination of the phosphoprotein pattern at short times after 5HT application has demonstrated that some of the phosphoprotein changes, but not others, are closely associated in time with the appearance of the physiological response. These and other pharmacological and kinetic experiments have allowed the identification of two phosphoproteins, of Mr = 29,000 and 70,000, which cannot be dissociated from the 5HT-induced K+ conductance increase whatever the experimental manipulation. Thus, one or both of these phosphoproteins may be involved in the regulation of the 5HT-sensitive K+ channel in neuron R15.     

Coupled potassium channels induced by arachidonic acid in cultured neurons

Exposure of the inside surface of patches of membrane excised from cultured rat hippocampal neurons to arachidonic acid (10-100 microM) caused the appearance of potassium currents of variable amplitude similar to those activated by GABA or baclofen in cell-attached patches. The amplitude of single-channel currents increased with time after exposure to 20 or 50 microM arachidonic acid and also increased when arachidonic acid concentration was increased from 20 to 50 or 100 microM. Current-amplitude probability histograms had peaks at integral multiples of an 'elementary' current. It is proposed that arachidonic acid or its metabolites cause synchronous opening and closing of coupled conducting units (co-channels) in cell membranes.     

Clustering of extrasynaptic GABA(A) receptors modulates tonic inhibition in cultured hippocampal neurons

Tonic inhibition plays a crucial role in regulating neuronal excitability because it sets the threshold for action potential generation and integrates excitatory signals. Tonic currents are known to be largely mediated by extrasynaptic gamma-aminobutyric acid type A (GABA(A)) receptors that are persistently activated by submicromolar concentrations of ambient GABA. We recently reported that, in cultured hippocampal neurons, the clustering of synaptic GABA(A) receptors significantly affects synaptic transmission. In this work, we demonstrated that the clustering of extrasynaptic GABA(A) receptors modulated tonic inhibition. Depolymerization of the cytoskeleton with nocodazole promoted the disassembly of extrasynaptic clusters of delta and gamma(2) subunit-containing GABA(A) receptors. This effect was associated with a reduction in the amplitude of tonic currents and diminished shunting inhibition. Moreover, diffuse GABA(A) receptors were less sensitive to the GAT-1 inhibitor NO-711 and to flurazepam. Quantitative analysis of GABA-evoked currents after prolonged exposure to submicromolar concentrations of GABA and model simulations suggest that clustering affects the gating properties of extrasynaptic GABA(A) receptors. In particular, a larger occupancy of the singly and doubly bound desensitized states can account for the modulation of tonic inhibition recorded after nocodazole treatment. Moreover, comparison of tonic currents recorded during spontaneous activity and those elicited by exogenously applied low agonist concentrations allows estimation of the concentration of ambient GABA. In conclusion, receptor clustering appears to be an additional regulating factor for tonic inhibition.     

Single channel recordings from calcium-activated potassium channels in cultured rat muscle

Single channel recordings from cultured rat skeletal muscle have revealed a large conductance (230 pS) channel with a high selectivity for K⁺ over Na⁺. In excised patches of membrane, the probability of channel opening is sensitive to micromolar concentrations of calcium ions at the intracellular surface of the patch. Channel openings appear grouped together into bursts whose duration increases with Ca²⁺ and membrane depolarization. Statistical analysis of the individual open times during each burst showed that there are two distinct open states of similar conductance but dissimilar average lifetimes. These channels might contribute to a macroscopic calcium-activated potassium conductance in rat skeletal muscle and other preparations.     

Calcium concentration threshold and translocation kinetics of EGFP-DOC2B expressed in cultured Aplysia neurons

The double C2 domain protein family (DOC2) is characterized by two calcium-binding domains (C2). Upon binding to calcium, the affinity of the protein to phospholipids is significantly increased, leading to translocation of the protein from the cytosol to the plasma membrane. These properties, and the binding domain of DOC2B to Munc13, suggested that DOC2B could play a role in augmentation and potentiation of synaptic release. Nevertheless, the level of the free intracellular calcium concentration ([Ca(2+)](i)) which triggers its translocation under in vivo conditions, is not known. Using cultured Aplysia neurons that express rat EGFP-DOC2B, we found that the [Ca(2+)](i) increment necessary to induce EGFP-DOC2B translocation is approximately 200 nM in the bulk of the cytoplasm. The rate of EGFP-DOC2B recruitment to the plasma membrane is slower than the [Ca(2+)](i) elevation rate, while the detachment of EGFP-DOC2B from it is faster than the calcium removal. The extent of EGFP-DOC2B translocation to the plasma membrane reflects local submembrane [Ca(2+)](i). Our observations are consistent with the view that DOC2B can participate in the regulation of neurotransmitter release. It should be noted that EGFP-DOC2B could be used as a tool to map sub-membrane calcium dynamics under physiological conditions.     

Think globally, act locally: local translation and synapse formation in cultured Aplysia neurons

Synapse formation is initiated by cell-cell contact between appropriate pre- and postsynaptic cells and is followed by recruitment of protein complexes in both pre- and postsynaptic compartments. In this issue of Neuron, Lyles et al. show that in cultured Aplysia neurons, clustering of an mRNA at nascent synapses is not only induced by the recognition between synaptic partners, but is also required for further synaptic development and maintenance.     

急性分离缰核神经细胞膜上外向整流钾通道的电生理特性

钾电流参与静息电位的形成及动作电位的复极过程 ,许多神经递质通过调节Ｋ 通道的活动而影响细胞膜的兴奋性。缰核 (Ｈｂ)是连接边缘前脑至脑干背侧通路的驿站 ,参与机体活动的调节。Ｈｂ内也存在多种神经递质 ,而这些递质对Ｋ 通道活动的影响知之甚少。且关于Ｈｂ神经细胞膜上Ｋ 通道的研究主要运用分子生物学的方法 ,电生理研究较少。本实验用膜片钳的方法探讨了Ｈｂ神经细胞膜上最常见的一种Ｋ 通道的电生理特性 ,为探讨Ｈｂ内神经递质的作用机制提供基础。1　材料和方法(1 )Ｈｂ神经细胞的急性分离　将 1 0～ 2 0ｄ的ＳＤ乳鼠断头取脑 ,…