Selective block of Ca2+-dependent K+ current in crayfish neuromuscular system and chromaffin cells by sea anemone Bunodosoma cangicum venom

The effects of the nematocyst venom of the sea anemone Bunodosoma cangicum on depolarization-activated currents were studied in opener crayfish muscle fibers and in cultured bovine chromaffin cells. The venom selectively and reversibly blocked the Ca²⁺ -dependent K⁺ current (I_K(Ca)) present in crayfish muscle in a dose-dependent manner without affecting voltage-gated Ca²⁺ or K⁺ currents. Furthermore, the venom also reduced I_K(Ca) in chromaffin cells, without modifying voltage-gated Na⁺, Ca²⁺, or K⁺ currents. Synaptic transmission in crayfish muscle was also affected by the venom. Repetitive excitatory and inhibitory postsynaptic currents (each associated with a presynaptic action potential) were evoked by each nerve stimulus, suggesting that presynaptic I_K(Ca) may control the electrical activity of excitatory and inhibitory presynaptic fibers. We conclude that B. cangicum venom includes a toxin that selectively and reversibly blocks Ca²⁺ -dependent K⁺ currents in crayfish muscle and in bovine chromaffin cells, and modifies excitatory and inhibitory synaptic transmission, probably abolishing a similar conductance at the presynaptic fibers. © 1995 Wiley-Liss, Inc.     

Sodium and calcium mechanisms of rhythmic bursting in excitatory neural networks of the pre‐Bötzinger complex: a computational modelling study

The neural mechanisms generating rhythmic bursting activity in the mammalian brainstem, particularly in the pre‐Bötzinger complex (pre‐BötC), which is involved in respiratory rhythm generation, and in the spinal cord (e.g. locomotor rhythmic activity) that persist after blockade of synaptic inhibition remain poorly understood. Experimental studies in rodent medullary slices containing the pre‐BötC identified two mechanisms that could potentially contribute to the generation of rhythmic bursting: one based on the persistent Na⁺ current (I_NaP), and the other involving the voltage‐gated Ca²⁺ current (I_Ca) and the Ca²⁺‐activated nonspecific cation current (I_CAN), activated by intracellular Ca²⁺ accumulated from extracellular and intracellular sources. However, the involvement and relative roles of these mechanisms in rhythmic bursting are still under debate. In this theoretical/modelling study, we investigated Na⁺‐dependent and Ca²⁺‐dependent bursting generated in single cells and heterogeneous populations of synaptically interconnected excitatory neurons with I_NaP and I_Ca randomly distributed within populations. We analysed the possible roles of network connections, ionotropic and metabotropic synaptic mechanisms, intracellular Ca²⁺ release, and the Na⁺/K⁺ pump in rhythmic bursting generated under different conditions. We show that a heterogeneous population of excitatory neurons can operate in different oscillatory regimes with bursting dependent on I_NaP and/or I_CAN, or independent of both. We demonstrate that the operating bursting mechanism may depend on neuronal excitation, synaptic interactions within the network, and the relative expression of particular ionic currents. The existence of multiple oscillatory regimes and their state dependence demonstrated in our models may explain different rhythmic activities observed in the pre‐BötC and other brainstem/spinal cord circuits under different experimental conditions.     

INa and IKir are reduced in Type 1 hypokalemic and thyrotoxic periodic paralysis

We evaluated voltage‐gated Na⁺ (I_Na) and inward rectifier K⁺ (I_Kir) currents and Na⁺ conductance (G_Na) in patients with Type 1 hypokalemic (HOPP) and thyrotoxic periodic paralysis (TPP). We studied intercostal muscle fibers from five subjects with HOPP and one with TPP. TPP was studied when the patient was thyrotoxic (T‐toxic) and euthyroid. We measured: (1) I_Kir, (2) action potential thresholds, (3) I_Na, (4) G_Na, (5) intracellular [Ca²⁺], and (6) histochemical fiber type. HOPP fibers had lower I_Na, G_Na, and I_Kir and increased action potential thresholds. Paralytic attack frequency correlated with the action potential threshold, G_Na and I_Na, but not with I_Kir. G_Na, I_Na, and [Ca²⁺] varied with fiber type. HOPP fibers had increased [Ca²⁺]. The subject with TPP had values for G_Na, I_Na, action potential threshold, I_Kir, and [Ca²⁺] that were similar to HOPP when T‐toxic and to controls when euthyroid. HOPP T‐toxic TPP fibers had altered G_Na, I_Na, and I_Kir associated with elevation in [Ca²⁺]. Muscle Nerve, 2010     

Synaptic vesicle glycoprotein 2A modulates vesicular release and calcium channel function at peripheral sympathetic synapses

Synaptic vesicle glycoprotein (SV)2A is a transmembrane protein found in secretory vesicles and is critical for Ca²⁺‐dependent exocytosis in central neurons, although its mechanism of action remains uncertain. Previous studies have proposed, variously, a role of SV2 in the maintenance and formation of the readily releasable pool (RRP) or in the regulation of Ca²⁺ responsiveness of primed vesicles. Such previous studies have typically used genetic approaches to ablate SV2 levels; here, we used a strategy involving small interference RNA (siRNA) injection to knockdown solely presynaptic SV2A levels in rat superior cervical ganglion (SCG) neuron synapses. Moreover, we investigated the effects of SV2A knockdown on voltage‐dependent Ca²⁺ channel (VDCC) function in SCG neurons. Thus, we extended the studies of SV2A mechanisms by investigating the effects on vesicular transmitter release and VDCC function in peripheral sympathetic neurons. We first demonstrated an siRNA‐mediated SV2A knockdown. We showed that this SV2A knockdown markedly affected presynaptic function, causing an attenuated RRP size, increased paired‐pulse depression and delayed RRP recovery after stimulus‐dependent depletion. We further demonstrated that the SV2A–siRNA‐mediated effects on vesicular release were accompanied by a reduction in VDCC current density in isolated SCG neurons. Together, our data showed that SV2A is required for correct transmitter release at sympathetic neurons. Mechanistically, we demonstrated that presynaptic SV2A: (i) acted to direct normal synaptic transmission by maintaining RRP size, (ii) had a facilitatory role in recovery from synaptic depression, and that (iii) SV2A deficits were associated with aberrant Ca²⁺ current density, which may contribute to the secretory phenotype in sympathetic peripheral neurons.     

Synthetic ω-conotoxin: a potent calcium channel blocking neurotoxin

The Ca²⁺ channel blocking action of synthetic ω-conotoxin (ωCTX) was studied on isolated frog dorsal root ganglion neurons using a ‘concentration clamp’ technique which enabled internal perfusion and rapid external solution change. At 100 nM, ωCTX showed a time-dependent depression of Ca²⁺ current (I_Ca). At higher concentrations, ωCTX exhibited a dose-dependent depression of I_Ca amplitude without changing the current-voltage relationship. Increases in external Ca²⁺ concentration partly overcame the inhibitory action of ωCTX on the I_Ca amplitude. At 10 μM ωCTX totally blocked I_Ca without effect on the Na⁺ current. It was likely that ωCTX had high selectivity for the Ca²⁺ channel.     

Different mechanisms of Ca2+ regulation that influence synaptic transmission: Comparison between crayfish and Drosophila neuromuscular junctions

A brief historical background on synaptic transmission in relation to Ca²⁺ dynamics and short‐term facilitation is described. This study focuses on the mechanisms responsible for the regulation of intracellular calcium concentration ([Ca²⁺]_i) in high output terminals of larval Drosophila compared to a low‐output terminal of the crayfish neuromuscular junction (NMJ). Three processes; plasmalemmal Na⁺/Ca²⁺ exchanger [NCX], Ca²⁺‐ATPase (PMCA), and sarcoplasmic/endoplasmic Ca²⁺‐ATPase (SERCA) are important in regulating the [Ca²⁺]_i are examined. When the NCX is compromised by reduced [Na⁺]_o, no consistent effect occurred; but a NCX blocker KB‐R7943 decreased the excitatory postsynaptic potential (EPSP) amplitudes. Compromising the PMCA with pH 8.8 resulted in an increase in EPSP amplitude but treatment with a PMCA specific inhibitor carboxyeosin produced opposite results. Thapsigargin exposure to block the SERCA generally decreases EPSP amplitude. Compromising the activity of the above Ca²⁺ regulating proteins had no substantial effects on short‐term depression. The Kum^170TS strain (with dysfunctional SERCA), showed a decrease in EPSP amplitudes including the first EPSP within the train. Synaptic transmission is altered by reducing the function of the above three [Ca²⁺]_i regulators; but they are not consistent among different species as expected. Results in crayfish NMJ were more consistent with expected results as compared to the Drosophila NMJ. It is predicated that different mechanisms are used for regulating the [Ca²⁺]_i in high and low output synaptic terminals. Synapse 63:1100–1121, 2009. © 2009 Wiley‐Liss, Inc.     

Ca-Antagonistic action of bevantolol on hypothalamic neurons in vitro: its comparison with those of other β-adrenoceptor antagonists, a local anesthetic and a Ca-antagonist

The Ca²⁺-antagonistic action of bevantolol, aβ₁-adrenoceptor antagonist, on high- and low-voltage activated Ca²⁺ currents (HVA- and LVA-I_Ca) was examined on neurons dissociated from rat brain. Bevantolol (10⁻⁶ to 10⁻⁴ M) inhibited concentration-dependently bothI_Ca. The IC₅₀ value of bevantolol for LVA-I_Ca was 4 × 10⁻⁵ M, while bevantolol at 10⁻⁴ M inhibited HVA-I_Ca by 28.5 ± 7.7%. The potency of bevantolol in inhibiting bothI_Ca was greater than those of propranolol, labetalol and lidocaine, while the inhibitory action of bevantolol on voltage-activated Na⁺ current was weakest among them. Bevantolol may possess Ca²⁺-antagonistic action that is independent from local anesthetic action.     

Effects of hypertonia on voltage-gated ion currents in freshly isolated hippocampal neurons, and on synaptic currents in neurons in hippocampal slices

We studied the effects of hypertonia on voltage-gated currents of freshly isolated hippocampal CA1 neurons, using open pipette whole-cell as well as gramicidin-perforated patch-clamp recording. Extracellular osmolarity (π_o) was raised by adding mannitol (50 or 100 mmol/l) to the bathing solution. Hypertonia depressed voltage-gated sodium, potassium and calcium currents in all trials. The threshold activation voltage of the currents did not change during hypertonic depression, but maximal activation of Ca²⁺ current shifted to a more negative potential, suggesting stronger depression of high- compared to low-voltage activated currents. During 30 min high π_o treatment (recorded with open pipette), the depression reached maximum in 10–15 min of exposure. The depression of the computed transient component of the K⁺ current recorded by open pipette was statistically not significant. Following hypertonic treatment recovery of the I_Na, the sustained I_K and sustained I_Ca were incomplete compared to control cells maintained in normal solution for an equal length of time. In hippocampal tissue slices hypertonia (+25, +50 and +100 mmol/l fructose) reversibly depressed excitatory postsynaptic currents (EPSCs). We conclude that the shutdown of membrane ion currents by elevated π_o is not selective, but the degree of the suppression varies among current types. Raising π_o in human patients, possibly combined with mild artificial acidosis, may be useful in the prevention and treatment of acute crises associated with excessive excitation or depolarization of neurons.     

Molecular targets for antiepileptic drug development

This review considers how recent advances in the physiology of ion channels and other potential molecular targets, in conjunction with new information on the genetics of idiopathic epilepsies, can be applied to the search for improved antiepileptic drugs (AEDs). Marketed AEDs predominantly target voltage-gated cation channels (the α subunits of voltage-gated Na⁺ channels and also T-type voltage-gated Ca²⁺ channels) or influence GABA-mediated inhibition. Recently, α2-δ voltage-gated Ca²⁺ channel subunits and the SV2A synaptic vesicle protein have been recognized as likely targets. Genetic studies of familial idiopathic epilepsies have identified numerous genes associated with diverse epilepsy syndromes, including genes encoding Na⁺ channels and GABA_A receptors, which are known AED targets. A strategy based on genes associated with epilepsy in animal models and humans suggests other potential AED targets, including various voltage-gated Ca²⁺ channel subunits and auxiliary proteins, A- or M-type voltage-gated K⁺ channels, and ionotropic glutamate receptors. Recent progress in ion channel research brought about by molecular cloning of the channel subunit proteins and studies in epilepsy models suggest additional targets, including G-protein-coupled receptors, such as GABA_B and metabotropic glutamate receptors; hyperpolarization-activated cyclic nucleotide-gated cation (HCN) channel subunits, responsible for hyperpolarization-activated currentI _h; connexins, which make up gap junctions; and neurotransmitter transporters, particularly plasma membrane and vesicular transporters for GABA and glutamate. New information from the structural characterization of ion channels, along with better understanding of ion channel function, may allow for more selective targeting. For example, Na⁺ channels underlying persistent Na⁺ currents or GABA_A receptor isoforms responsible for tonic (extrasynaptic) currents represent attractive targets. The growing understanding of the pathophysiology of epilepsy and the structural and functional characterization of the molecular targets provide many opportunities to create improved epilepsy therapies.     

The voltage‐dependent conductances of rat neocortical layer I neurons

Whole cell patch-clamp techniques were used to study voltage-dependent sodium (Na⁺), calcium (Ca²⁺), and potassium (K⁺) conductances in acutely isolated neurons from cortical layer I of adult rats. Layer I cells were identified by means of γ-aminobutyric acid (GABA) immunocytochemistry. Positive stainings for the Ca²⁺-binding protein calretinin in a subset of cells, indicated the presence of Cajal–Retzius (C-R) cells. All investigated cells displayed a rather homogeneous profile of voltage-dependent membrane currents. A fast Na⁺ current activated at about −45 mV, was half-maximal steady-state inactivated at −66.6 mV, and recovery from inactivation followed a two-exponential process (τ₁ = 8.4 ms and τ₂ = 858.8 ms). Na⁺ currents declined rapidly with two voltage-dependent time constants, reaching baseline current after some tens of milliseconds. In a subset of cells (< 50%) a constant current level of < 65 pA remained at the end of a 90 ms step. A transient outward current (I_fast) activated ≈–40 mV, declined rapidly with a voltage-insensitive time constant (τ≈ 350 ms) and was relatively insensitive to tetraethylammonium (TEA, 20 mm ). I_fast was separated into two components based on their sensitivity to 4-aminopyridine (4-AP): one was blocked by low concentrations (40 μm ) and a second by high concentrations (6 mm ). After elimination of I_fast by a conditioning prepulse (50 ms to −50 mV), a slow K⁺ current (I_KV) could be studied in isolation. I_KV was only moderately affected by 4-AP (6 mm ), while TEA (20 mm ) blocked most (> 80%) of the current. I_KV activated at about −40 mV, declined monoexponentially in a voltage-dependent manner (τ≈ 850 ms at −30 mV), and revealed an incomplete steady-state inactivation. In addition to I_fast and I_KV, indications of a Ca²⁺-dependent outward current component were found. When Na⁺ currents, I_fast, and I_KV were blocked by tetrodotoxin (TTX, 1 μm ), 4-AP (6 mm ) and TEA (20 mm ) an inward current carried by Ca²⁺ was found. Ca²⁺ currents activated at depolarized potentials at about −30 mV, were completely blocked by 50 μm cadmium (Cd²⁺), were sensitive to verapamil (≈ 40% block by 10 μm ), and were not affected by nickel (50 μm ). During current clamp recordings, isolated layer I neurons displayed fast spiking behaviour with short action potentials (≈ 2 ms, measured at half maximal amplitude) of relative small amplitude (≈ 83 mV, measured from the action potential threshold).     

Differential contributions of Ca2+‐activated K+ channels and Na+/K+‐ATPases to the generation of the slow afterhyperpolarization in CA1 pyramidal cells

In many types of CNS neurons, repetitive spiking produces a slow afterhyperpolarization (sAHP), providing sustained, intrinsically generated negative feedback to neuronal excitation. Changes in the sAHP have been implicated in learning behaviors, in cognitive decline in aging, and in epileptogenesis. Despite its importance in brain function, the mechanisms generating the sAHP are still controversial. Here we have addressed the roles of M‐type K⁺ current (I_M), Ca²⁺‐gated K⁺ currents (I_Ca(K)'s) and Na⁺/K⁺‐ATPases (NKAs) current to sAHP generation in adult rat CA1 pyramidal cells maintained at near‐physiological temperature (35 °C). No evidence for I_M contribution to the sAHP was found in these neurons. Both I_Ca(K)'s and NKA current contributed to sAHP generation, the latter being the predominant generator of the sAHP, particularly when evoked with short trains of spikes. Of the different NKA isoenzymes, α₁‐NKA played the key role, endowing the sAHP a steep voltage‐dependence. Thus normal and pathological changes in α₁‐NKA expression or function may affect cognitive processes by modulating the inhibitory efficacy of the sAHP.     

Effects of myasthenia gravis patients' sera with different autoantibodies on slow K+ current at mouse motor nerve terminals

Abstract

The antibodies against pre-synaptic membrane receptor (PsmR) and acetylcholine receptor (AChR) in serum samples of myasthenia gravis (MG) patients and healthy donors were tested by enzyme-linked immunosorbent assays (ELISA). The serum samples of eight MG patients with different autoantibodies and those of six healthy donors without these two kinds of autoantibodies were collected to investigate their effects on the peri-neurially recorded membrane currents at mouse motor nerve terminals. After inhibition of both fast and Ca²⁺-dependent K⁺ currents by tetra-ethylammonium (TEA), a positive wave was revealed, which was a balance of the slow K⁺(I_K,s) and Ca²⁺ currents (I_Ca). Application of anti-PsmR antibody negative MG sera and healthy donor sera, whether anti-AChR antibody positive or negative, did not affect the positive wave. However, the positive wave shifted to prolonged Ca²⁺-plateau when adding two of four anti-PsmR antibody positive serum samples from MG patients, indicating an inhibition of I_K,s by anti-PsmR antibody positive sera. Meanwhile, all serum samples derived from either patients or healthy donors did not affect I_Na.     

Functional Ca2+ and Na+ channels on mouse Schwann cells cultured in serum‐free medium: regulation by a diffusible factor from neurons and by cAMP

Regulation of expression of functional voltage-gated ion channels for inward currents was studied in Schwann cells in organotypic cultures of dorsal root ganglia from E19 mouse embryos maintained in serum-free medium. Of the Schwann cells that did not contact axons, 46.5% expressed T-type Ca²⁺ conductances (I_CaT). Two days or more after excision of the ganglia, and consequent disappearance of neurites, I_CaT were detectable in only 10.9% of the cells, and the marker 04 disappeared. On Schwann cells deprived of neurons, T- (but not L-) type Ca²⁺ conductances were re-induced by weakly hydrolysable analogues of cAMP, and by forskolin (an activator of adenylyl cyclase) after long-term treatment (4 days). With CPT cAMP (0.1–2 mm ), 8Br cAMP, db cAMP or forskolin (0.01 or 0.1 mm ), the proportion of cells with I_CaT was not significantly different from the proportion in the cultures with neurons. These agents also induced expression in some cells of tetrodotoxin-resistant Na⁺ currents, which were rarely induced by neurons, but 04 was not re-induced by cAMP analogue treatments that re-induced I_CaT. Inward currents (Ba²⁺ or Na⁺) were partly restored (P < 0.05) on Schwann cells cultured for 6–7 days beneath a filter bearing cultured neurons. In contrast, addition of neuron-conditioned medium was ineffective. The results suggest that neurons activate, via diffusible and degradable factors, a subset of Schwann cell cAMP pathways leading to expression of I_CaT, and activate additional non-cAMP pathways that lead to expression of 04.     

The mechanism of the actions of oxaliplatin on ion currents and action potentials in differentiated NG108-15 neuronal cells

Oxaliplatin (OXAL) is a platinum-based chemotherapeutic agent which is effective against advanced or metastatic gastrointestinal cancer. However, the mechanisms responsible for the development of the neuropathy induced by this agent remain unclear. In this study, we attempted to evaluate the possible effects of OXAL on ion currents and action potentials (APs) in NG108-15 cells differentiated with dibutyryl cyclic-AMP. Application of OXAL decreased the peak amplitude of voltage-gated Na⁺ current (I_Na) with no change in the overall current–voltage relations of the currents. This agent also produced a concentration-dependent slowing of I_Na inactivation. A further application of ranolazine reversed OXAL-induced slowing of I_Na inactivation. Unlike ranolazine or riluzole, OXAL had no effect on persistent I_Na elicited by long ramp pulses. OXAL (100 μM) also had little or no effect on the peak amplitude of L-type Ca²⁺ currents in NG108-15 cells, while it suppressed delayed-rectifier K⁺ current. In current-clamp recordings, OXAL alone reduced the amplitude of APs; however, it did not alter the duration of APs. However, after application of tefluthrin, OXAL did increase the duration of APs. Moreover, OXAL decreased the peak amplitude of I_Na with a concomitant reduction of current inactivation in HEK293T cells expressing SCN5A. The effects of OXAL on ion currents presented here may contribute to its neurotoxic actions in vivo.     

Presynaptic pH and vesicle fusion in Drosophila larvae neurones

Both intracellular pH (pH_i) and synaptic cleft pH change during neuronal activity yet little is known about how these pH shifts might affect synaptic transmission by influencing vesicle fusion. To address this we imaged pH‐ and Ca²⁺‐sensitive fluorescent indicators (HPTS, Oregon green) in boutons at neuromuscular junctions. Electrical stimulation of motor nerves evoked presynaptic Ca²⁺_i rises and pH_i falls (～0.1 pH units) followed by recovery of both Ca²⁺_i and pH_i. The plasma‐membrane calcium ATPase (PMCA) inhibitor, 5(6)‐carboxyeosin diacetate, slowed both the calcium recovery and the acidification. To investigate a possible calcium‐independent role for the pH_i shifts in modulating vesicle fusion we recorded post‐synaptic miniature end‐plate potential (mEPP) and current (mEPC) frequency in Ca²⁺‐free solution. Acidification by propionate superfusion, NH₄⁺ withdrawal, or the inhibition of acid extrusion on the Na⁺/H⁺ exchanger (NHE) induced a rise in miniature frequency. Furthermore, the inhibition of acid extrusion enhanced the rise induced by propionate addition and NH₄⁺ removal. In the presence of NH₄⁺, 10 out of 23 cells showed, after a delay, one or more rises in miniature frequency. These findings suggest that Ca²⁺‐dependent pH_i shifts, caused by the PMCA and regulated by NHE, may stimulate vesicle release. Furthermore, in the presence of membrane permeant buffers, exocytosed acid or its equivalents may enhance release through positive feedback. This hitherto neglected pH signalling, and the potential feedback role of vesicular acid, could explain some important neuronal excitability changes associated with altered pH and its buffering. Synapse 67:729–740, 2013 . © 2013 Wiley Periodicals, Inc.     

Arachidonic acid potently inhibits both postsynaptic-type Kv4.2 and presynaptic-type Kv1.4 IA potassium channels

Arachidonic acid (AA) is a free fatty acid membrane‐permeable second messenger that is liberated from cell membranes via receptor‐ and Ca²⁺‐dependent events. We have shown previously that extremely low [AA]_i (1 pm ) inhibits the postsynaptic voltage‐gated K⁺ current (I_A) in hippocampal neurons. This inhibition is blocked by some antioxidants. The somatodendritic I_A is mediated by Kv4.2 gene products, whereas presynaptic I_A is mediated by Kv1.4 channel subunits. To address the interaction of AA with these α‐subunits we studied the modulation of A‐currents in human embryonic kidney 293 cells transfected with either Kv1.4 or Kv4.2 rat cDNA, using whole‐cell voltage‐clamp recording. For both currents 1 pm [AA]_i inhibited the conductance by > 50%. In addition, AA shifted the voltage dependence of inactivation by ?9 (Kv1.4) and +6 mV (Kv4.2), respectively. Intracellular co‐application of Trolox C (10 μm ), an antioxidant vitamin E derivative, only slowed the effects of AA on amplitude. Notably, Trolox C shifted the voltage dependence of activation of Kv1.4‐mediated I_A by ?32 mV. Extracellular Trolox for > 15 min inhibited the AA effects on I_A amplitudes as well as the effect of intracellular Trolox on the voltage dependence of activation of Kv1.4‐mediated I_A. Extracellular Trolox further shifted the voltage dependence of activation for Kv4.2 by +33 mV. In conclusion, the inhibition of maximal amplitude of Kv4.2 channels by AA can explain the inhibition of somatodendritic I_A in hippocampal neurons, whereas the negative shift in the voltage dependence of inactivation apparently depends on other neuronal channel subunits. Both AA and Trolox potently modulate Kv1.4 and Kv4.2 channel α‐subunits, thereby presumably tuning presynaptic transmitter release and postsynaptic somatodendritic excitability in synaptic transmission and plasticity.     

Familial hemiplegic migraine

Familial hemiplegic migraine (FHM) is a rare and genetically heterogeneous autosomal dominant subtype of migraine with aura. Mutations in the genes CACNA1A and SCNA1A, encoding the pore-forming α₁ subunits of the neuronal voltage-gated Ca²⁺ channels Ca_v2.1 and Na⁺ channels Na_v1.1, are responsible for FHM1 and FHM3, respectively, whereas mutations in ATP1A2, encoding the α₂ subunit of the Na⁺, K⁺ adenosinetriphosphatase (ATPase), are responsible for FHM2. This review discusses the functional studies of two FHM1 knockin mice and of several FHM mutants in heterologous expression systems (12 FHM1, 8 FHM2, and 1 FHM3). These studies show the following: (1) FHM1 mutations produce gain-of-function of the Ca_v2.1 channel and, as a consequence, increased Ca_v2.1-dependent neurotransmitter release from cortical neurons and facilitation of in vivo induction and propagation of cortical spreading depression (CSD: the phenomenon underlying migraine aura); (2) FHM2 mutations produce loss-of-function of the α₂ Na⁺,K⁺-ATPase; and (3) the FHM3 mutation accelerates recovery from fast inactivation of Na_v1.5 (and presumably Na_v1.1) channels. These findings are consistent with the hypothesis that FHM mutations share the ability of rendering the brain more susceptible to CSD by causing either excessive synaptic glutamate release (FHM1) or decreased removal of K⁺ and glutamate from the synaptic cleft (FHM2) or excessive extracellular K⁺ (FHM3). The FHM data support a key role of CSD in migraine pathogenesis and point to cortical hyperexcitability as the basis for vulnerability to CSD and to migraine attacks. Hence, they support novel therapeutic strategics that consider CSD and cortical hyperexcitability as key targets for preventive migraine treatment.     

Effect of charybdotoxin and leiurotoxon I on potassium currents in bullfrog sympathetic ganglion and hippocampal neurons

The effects of charybdotoxin and leiurotoxin I were examined on several classes of K⁺ currents in bullfrog sympathetic ganglion and hippocampal CA1 pyramidal neurons. Highly purified preparations of charybdotoxin selectively blocked a large voltage- and Ca²⁺-dependent K⁺ current (I_c) responsible for action potential repolarization (IC₅₀ = 6 nM) while leiurotoxin I selectively blocked a small Ca²⁺-dependent K⁺ conductance (I_AHP) responsible for the slow afterhyperpolarization following an action potential (IC₅₀ = 7.5 nM) in bullfrog sympathetic ganglion neurons. Neither of the toxins had a significant effects on other K⁺ currents (M-current [I_M], A-current [I_A] and the delayed rectifier [I_KD] present in these cells. Leiurotoxin I at a concentration of 20 nM had no detectable effect on currents in hippocampal CA1 pyramidal neurons. This lack of effect on I_AHP in central neurons suggests that the channels underlying slow AHPs in those neurons are pharmacologically distinct from analogous channels in peripheral neurons.     

Activation of ryanodine receptors is required for PKA‐mediated downregulation of A‐type K+ channels in rat hippocampal neurons

A‐type K⁺ channels (I_A channels) contribute to learning and memory mechanisms by regulating neuronal excitabilities in the CNS, and their expression level is targeted by Ca²⁺ influx via synaptic NMDA receptors (NMDARs) during long‐term potentiation (LTP). However, it is not clear how local synaptic Ca²⁺ changes induce I_A downregulation throughout the neuron, extending from the active synapse to the soma. In this study, we tested if two major receptors of endoplasmic reticulum (ER), ryanodine (RyRs), and IP₃ (IP₃R) receptors, are involved in Ca²⁺‐mediated I_A downregulation in cultured hippocampal neurons of rats. The downregulation of I_A channels was induced by doubling the Ca²⁺ concentration in culture media (3.6 mM for 24 hrs) or treating with glycine (200 μM for 3 min) to induce chemical LTP (cLTP), and the changes in I_A peaks were measured electrophysiologically by a whole‐cell patch. We confirmed that Ca²⁺ or glycine treatment significantly reduced I_A peaks and that their effects were abolished by blocking NMDARs or voltage‐dependent Ca²⁺ channels (VDCCs). In this cellular processing, blocking RyRs (by ryanodine, 10 μM) but not IP₃Rs (by 2APB, 100 μM) completely abolished I_A downregulation, and the LTP observed in hippocampal slices was more diminished by ryanodine rather than 2APB. Furthermore, blocking RyRs also reduced Ca²⁺‐mediated PKA activation, indicating that sequential signaling cascades, including the ER and PKA, are involved in regulating I_A downregulation. These results strongly suggest a possibility that RyR contribution and mediated I_A downregulation are required to regulate membrane excitability as well as synaptic plasticity in CA3‐CA1 connections of the hippocampus. © 2017 Wiley Periodicals, Inc.     

Dendritic mechanisms controlling the threshold and timing requirement of synaptic plasticity

Active conductances located and operating on neuronal dendrites are expected to regulate synaptic integration and plasticity. We investigate how Kv4.2‐mediated A‐type K⁺ channels and Ca²⁺‐activated K⁺ channels are involved in the induction process of Hebbian‐type plasticity that requires correlated pre‐ and postsynaptic activities. In CA1 pyramidal neurons, robust long‐term potentiation (LTP) induced by a theta burst pairing protocol usually occurred within a narrow window during which incoming synaptic potentials coincided with postsynaptic depolarization. Elimination of dendritic A‐type K⁺ currents in Kv4.2^?/? mice, however, resulted in an expanded time window, making the induction of synaptic potentiation less dependent on the temporal relation of pre‐ and postsynaptic activity. For the other type of synaptic plasticity, long‐term depression, the threshold was significantly increased in Kv4.2^?/? mice. This shift in depression threshold was restored to normal when the appropriate amount of internal free calcium was chelated during induction. In concert with A‐type channels, Ca²⁺‐activated K⁺ channels also exerted a sliding effect on synaptic plasticity. Blocking these channels in Kv4.2^?/? mice resulted in an even larger potentiation while by contrast, the depression threshold was shifted further. In conclusion, dendritic A‐type and Ca²⁺‐activated K⁺ channels dually regulate the timing‐dependence and thresholds of synaptic plasticity in an additive way. © 2010 Wiley‐Liss, Inc.