Models of the structure and gating mechanisms of the pore domain of the NaChBac ion channel

The NaChBac prokaryotic sodium channel appears to be a descendent of an evolutionary link between voltage-gated K_V and Ca_V channels. Like K_V channels, four identical six-transmembrane subunits comprise the NaChBac channel, but its selectivity filter possesses a signature sequence of eukaryotic Ca_V channels. We developed structural models of the NaChBac channel in closed and open conformations, using K⁺-channel crystal structures as initial templates. Our models were also consistent with numerous experimental results and modeling criteria. This study concerns the pore domain. The major differences between our models and K⁺ crystal structures involve the latter portion of the selectivity filter and the bend region in S6 of the open conformation. These NaChBac models may serve as a stepping stone between K⁺ channels of known structure and Na_V, Ca_V, and TRP channels of unknown structure.     

Analysis of the selectivity filter of the voltage-gated sodium channel NavRh

NaChBac is a bacterial voltage-gated sodium (Na_v) channel that shows sequence similarity to voltage-gated calcium channels. To understand the ion-permeation mechanism of Na_v channels, we combined molecular dynamics simulation, structural biology and electrophysiological approaches to investigate the recently determined structure of Na_vRh, a marine bacterial NaChBac ortholog. Two Na⁺ binding sites are identified in the selectivity filter (SF) in our simulations: The extracellular Na⁺ ion first approaches site 1 constituted by the side groups of Ser181 and Glu183, and then spontaneously arrives at the energetically more favorable site 2 formed by the carbonyl oxygens of Leu179 and Thr178. In contrast, Ca²⁺ ions are prone to being trapped by Glu183 at site 1, which then blocks the entrance of both Na⁺ and Ca²⁺ to the vestibule of the SF. In addition, Na⁺ permeates through the selective filter in an asymmetrical manner, a feature that resembles that of the mammalian Na_v orthologs. The study reported here provides insights into the mechanism of ion selectivity on Na⁺ over Ca²⁺ in mammalian Na_v channels.     

Single channel measurements demonstrate the voltage dependence of permeation through N-type and L-type CaV channels

The delivery of Ca²⁺ into cells by Ca_V channels provides the trigger for many cellular actions, such as cardiac muscle contraction and neurotransmitter release. Thus, a full understanding of Ca²⁺ permeation through these channels is critical. Using whole-cell voltage-clamp recordings, we recently demonstrated that voltage modulates the apparent affinity of N-type (Ca_V2.2) channels for permeating Ca²⁺ and Ba²⁺ ions. While we took many steps to ensure the high fidelity of our recordings, problems can occur when Ca_V currents become large and fast, or when currents run down. Thus, we use here single channel recordings to further test the hypothesis that permeating ions interact with N-type channels in a voltage-dependent manner. We also examined L-type (Ca_V1.2) channels to determine if these channels also exhibit voltage-dependent permeation. Like our whole-cell data, we find that voltage modulates N-channel affinity for Ba²⁺ at voltages > 0 mV, but has little or no effect at voltages < 0 mV. Furthermore, we demonstrate that permeation through L-channel is also modulated by voltage. Thus, voltage-dependence may be a common feature of divalent cation permeation through Ca_V1 and Ca_V2 channels (i.e. high-voltage activated Ca_V channels). The voltage dependence of Ca_V1 channel permeation is likely a mechanism mediating sustained Ca²⁺ influx during the plateau phase of the cardiac action potential.     

Probing ion binding in the selectivity filter of the Cav1.1 channel with molecular dynamics

Ca_v1.1 is the voltage-gated calcium channel essential for the contraction of skeletal muscles upon membrane potential changes. Structural determination of the Ca_v1.1 channel opens the avenue toward understanding of the structure-function relationship of voltage-gated calcium channels. Here, we show that there exist two Ca²⁺-binding sites, termed S1 and S2, within the selectivity filter of Ca_v1.1 through extensive molecular dynamics simulations on various initial ion arrangement configurations. The formation of both binding sites is associated with the four Glu residues (Glu292/614/1014/1323) that constitute the so-called EEEE locus. At the S1 site near the extracellular side, the Ca²⁺ ion is coordinated with the negatively charged carboxylic groups of these Glu residues and of the Asp615 residue either in a direct way or via an intermediate water molecule. At the S2 site, Ca²⁺ binding shows two distinct states: an upper state involving two out of the four Glu residues in the EEEE locus and a lower state involving only one Glu residue. In addition, there exist two recruitment sites for Ca²⁺ above the entrance of the filter. These findings promote the understanding of mechanism for ion permeation and selectivity in calcium channels.     

Voltage control of Ca2+ permeation through N-type calcium (CaV2.2) channels

Voltage-gated calcium (Ca_V) channels deliver Ca²⁺ to trigger cellular functions ranging from cardiac muscle contraction to neurotransmitter release. The mechanism by which these channels select for Ca²⁺ over other cations is thought to involve multiple Ca²⁺-binding sites within the pore. Although the Ca²⁺ affinity and cation preference of these sites have been extensively investigated, the effect of voltage on these sites has not received the same attention. We used a neuronal preparation enriched for N-type calcium (Ca_V2.2) channels to investigate the effect of voltage on Ca²⁺ flux. We found that the EC₅₀ for Ca²⁺ permeation increases from 13 mM at 0 mV to 240 mM at 60 mV, indicating that, during permeation, Ca²⁺ ions sense the electric field. These data were nicely reproduced using a three-binding-site step model. Using roscovitine to slow Ca_V2.2 channel deactivation, we extended these measurements to voltages <0 mV. Permeation was minimally affected at these hyperpolarized voltages, as was predicted by the model. As an independent test of voltage effects on permeation, we examined the Ca²⁺-Ba²⁺ anomalous mole fraction (MF) effect, which was both concentration and voltage dependent. However, the Ca²⁺-Ba²⁺ anomalous MF data could not be reproduced unless we added a fourth site to our model. Thus, Ca²⁺ permeation through Ca_V2.2 channels may require at least four Ca²⁺-binding sites. Finally, our results suggest that the high affinity of Ca²⁺ for the channel helps to enhance Ca²⁺ influx at depolarized voltages relative to other ions (e.g., Ba²⁺ or Na⁺), whereas the absence of voltage effects at negative potentials prevents Ca²⁺ from becoming a channel blocker. Both effects are needed to maximize Ca²⁺ influx over the voltages spanned by action potentials.     

Conserved biophysical features of the CaV2 presynaptic Ca2+ channel homologue from the early-diverging animal Trichoplax adhaerens

The dominant role of Ca_V2 voltage-gated calcium channels for driving neurotransmitter release is broadly conserved. Given the overlapping functional properties of Ca_V2 and Ca_V1 channels, and less so Ca_V3 channels, it is unclear why there have not been major shifts toward dependence on other Ca_V channels for synaptic transmission. Here, we provide a structural and functional profile of the Ca_V2 channel cloned from the early-diverging animal Trichoplax adhaerens, which lacks a nervous system but possesses single gene homologues for Ca_V1–Ca_V3 channels. Remarkably, the highly divergent channel possesses similar features as human Ca_V2.1 and other Ca_V2 channels, including high voltage–activated currents that are larger in external Ba²⁺ than in Ca²⁺; voltage-dependent kinetics of activation, inactivation, and deactivation; and bimodal recovery from inactivation. Altogether, the functional profile of Trichoplax Ca_V2 suggests that the core features of presynaptic Ca_V2 channels were established early during animal evolution, after Ca_V1 and Ca_V2 channels emerged via proposed gene duplication from an ancestral Ca_V1/2 type channel. The Trichoplax channel was relatively insensitive to mammalian Ca_V2 channel blockers ω-agatoxin-IVA and ω-conotoxin-GVIA and to metal cation blockers Cd²⁺ and Ni²⁺. Also absent was the capacity for voltage-dependent G-protein inhibition by co-expressed Trichoplax Gβγ subunits, which nevertheless inhibited the human Ca_V2.1 channel, suggesting that this modulatory capacity evolved via changes in channel sequence/structure, and not G proteins. Last, the Trichoplax channel was immunolocalized in cells that express an endomorphin-like peptide implicated in cell signaling and locomotive behavior and other likely secretory cells, suggesting contributions to regulated exocytosis.     

Single channel measurements demonstrate the voltage dependence of permeation through N-type and L-type CaV channels

The delivery of Ca²⁺ into cells by Ca_V channels provides the trigger for many cellular actions, such as cardiac muscle contraction and neurotransmitter release. Thus, a full understanding of Ca²⁺ permeation through these channels is critical. Using whole-cell voltage-clamp recordings, we recently demonstrated that voltage modulates the apparent affinity of N-type (Ca_V2.2) channels for permeating Ca²⁺ and Ba²⁺ ions. While we took many steps to ensure the high fidelity of our recordings, problems can occur when Ca_V currents become large and fast, or when currents run down. Thus, we use here single channel recordings to further test the hypothesis that permeating ions interact with N-type channels in a voltage-dependent manner. We also examined L-type (Ca_V1.2) channels to determine if these channels also exhibit voltage-dependent permeation. Like our whole-cell data, we find that voltage modulates N-channel affinity for Ba²⁺ at voltages > 0 mV, but has little or no effect at voltages < 0 mV. Furthermore, we demonstrate that permeation through L-channel is also modulated by voltage. Thus, voltage-dependence may be a common feature of divalent cation permeation through Ca_V1 and Ca_V2 channels (i.e. high-voltage activated Ca_V channels). The voltage dependence of Ca_V1 channel permeation is likely a mechanism mediating sustained Ca²⁺ influx during the plateau phase of the cardiac action potential.     

Simulations of calcium channel block by trivalent cations: Gd competes with permeant ions for the selectivity filter

Current through L-type calcium channels (Ca_V1.2 or dihydropyridine receptor) can be blocked by micromolar concentrations of trivalent cations like the lanthanide gadolinium (Gd³⁺). It has been proposed that trivalent block is due to ions competing for a binding site in both the open and closed configuration, but possibly with different trivalent affinities. Here, we corroborate this general view of trivalent block by computing conductance of a model L-type calcium channel. The model qualitatively reproduces the Gd³⁺ concentration dependence and the effect that substantially more Gd³⁺ is required to produce similar block in the presence of Sr²⁺ (compared to Ba²⁺) and even more in the presence of Ca²⁺. Trivalent block is explained in this model by cations binding in the selectivity filter with the charge/space competition mechanism. This is the same mechanism that in the model channel governs other selectivity properties. Specifically, selectivity is determined by the combination of ions that most effectively screen the negative glutamates of the protein while finding space in the midst of the closely packed carboxylate groups of the glutamate residues.     

Molecular basis of ion permeability in a voltage‐gated sodium channel

Voltage‐gated sodium channels are essential for electrical signalling across cell membranes. They exhibit strong selectivities for sodium ions over other cations, enabling the finely tuned cascade of events associated with action potentials. This paper describes the ion permeability characteristics and the crystal structure of a prokaryotic sodium channel, showing for the first time the detailed locations of sodium ions in the selectivity filter of a sodium channel. Electrostatic calculations based on the structure are consistent with the relative cation permeability ratios (Na⁺ ≈ Li⁺ ≫ K⁺, Ca²⁺, Mg²⁺) measured for these channels. In an E178D selectivity filter mutant constructed to have altered ion selectivities, the sodium ion binding site nearest the extracellular side is missing. Unlike potassium ions in potassium channels, the sodium ions in these channels appear to be hydrated and are associated with side chains of the selectivity filter residues, rather than polypeptide backbones.     

Structural implications of weak Ca2+ block in Drosophila cyclic nucleotide–gated channels

Calcium permeability and the concomitant calcium block of monovalent ion current (“Ca²⁺ block”) are properties of cyclic nucleotide–gated (CNG) channel fundamental to visual and olfactory signal transduction. Although most CNG channels bear a conserved glutamate residue crucial for Ca²⁺ block, the degree of block displayed by different CNG channels varies greatly. For instance, the Drosophila melanogaster CNG channel shows only weak Ca²⁺ block despite the presence of this glutamate. We previously constructed a series of chimeric channels in which we replaced the selectivity filter of the bacterial nonselective cation channel NaK with a set of CNG channel filter sequences and determined that the resulting NaK2CNG chimeras displayed the ion selectivity and Ca²⁺ block properties of the parent CNG channels. Here, we used the same strategy to determine the structural basis of the weak Ca²⁺ block observed in the Drosophila CNG channel. The selectivity filter of the Drosophila CNG channel is similar to that of most other CNG channels except that it has a threonine at residue 318 instead of a proline. We constructed a NaK chimera, which we called NaK2CNG-Dm, which contained the Drosophila selectivity filter sequence. The high resolution structure of NaK2CNG-Dm revealed a filter structure different from those of NaK and all other previously investigated NaK2CNG chimeric channels. Consistent with this structural difference, functional studies of the NaK2CNG-Dm chimeric channel demonstrated a loss of Ca²⁺ block compared with other NaK2CNG chimeras. Moreover, mutating the corresponding threonine (T318) to proline in Drosophila CNG channels increased Ca²⁺ block by 16 times. These results imply that a simple replacement of a threonine for a proline in Drosophila CNG channels has likely given rise to a distinct selectivity filter conformation that results in weak Ca²⁺ block.     

Seeing the Forest through the Trees: towards a Unified View on Physiological Calcium Regulation of Voltage-Gated Sodium Channels

Voltage-gated sodium channels (Na_Vs) underlie the upstroke of the action potential in the excitable tissues of nerve and muscle. After opening, Na_Vs rapidly undergo inactivation, a crucial process through which sodium conductance is negatively regulated. Disruption of inactivation by inherited mutations is an established cause of lethal cardiac arrhythmia, epilepsy, or painful syndromes. Intracellular calcium ions (Ca²⁺) modulate sodium channel inactivation, and multiple players have been suggested in this process, including the cytoplasmic Na_V C-terminal region including two EF-hands and an IQ motif, the Na_V domain III-IV linker, and calmodulin. Calmodulin can bind to the IQ domain in both Ca²⁺-bound and Ca²⁺-free conditions, but only to the DIII-IV linker in a Ca²⁺-loaded state. The mechanism of Ca²⁺ regulation, and its composite effect(s) on channel gating, has been shrouded in much controversy owing to numerous apparent experimental inconsistencies. Herein, we attempt to summarize these disparate data and propose a novel, to our knowledge, physiological mechanism whereby calcium ions promote sodium current facilitation due to Ca²⁺ memory at high-action-potential frequencies where Ca²⁺ levels may accumulate. The available data suggest that this phenomenon may be disrupted in diseases where cytoplasmic calcium ion levels are chronically high and where targeted phosphorylation may decouple the Ca²⁺ regulatory machinery. Many Na_V disease mutations associated with electrical dysfunction are located in the Ca²⁺-sensing machinery and misregulation of Ca²⁺-dependent channel modulation is likely to contribute to disease phenotypes.     

CaV3.1 channel pore pseudo-symmetry revealed by selectivity filter mutations in its domains I/II

There is growing evidence indicating that the pore structure of voltage-gated ion channels (VGICs) influences gating besides their conductance. Regarding low voltage-activated (LVA) Ca²⁺ channels, it has been demonstrated that substitutions of the pore aspartate (D) by a glutamate (D-to-E substitution) in domains III and IV alter channel gating properties such as a positive shift in the channel activation voltage dependence. In the present report, we evaluated the effects of E-to-D substitution in domains I and II on the Ca_V3.1 channel gating properties. Our results indicate that substitutions in these two domains differentially modify the gating properties of Ca_V3.1 channels. The channel with a single mutation in domain I (DEDD) presented slower activation and faster inactivation kinetics and a slower recovery from inactivation, as compared with the WT channel. In contrast, the single mutant in domain II (EDDD) presented a small but significant negative shift of activation voltage dependence with faster activation and slower inactivation kinetics. Finally, the double mutant channel (DDDD) presented somehow intermediate properties with respect to the two single mutants but with fastest deactivation kinetics. Overall, our results indicate that single amino acid modification of the selectivity filter of LVA Ca²⁺ channels in distinct domains differentially influence their gating properties, supporting a pore pseudo-symmetry.     

K+-Dependent Selectivity and External Ca2+ Block of Shab K+ Channels

Potassium channels allow the selective flux of K⁺ excluding the smaller, and more abundant in the extracellular solution, Na⁺ ions. Here we show that Shab is a typical K⁺ channel that excludes Na⁺ under bi-ionic, Na_o/K_i or Na_o/Rb_i, conditions. However, when internal K⁺ is replaced by Cs⁺ (Na_o/Cs_i), stable inward Na⁺ and outward Cs⁺ currents are observed. These currents show that Shab selectivity is not accounted for by protein structural elements alone, as implicit in the snug-fit model of selectivity. Additionally, here we report the block of Shab channels by external Ca²⁺ ions, and compare the effect that internal K⁺ replacement exerts on both Ca²⁺ and TEA block. Our observations indicate that Ca²⁺ blocks the channels at a site located near the external TEA binding site, and that this pore region changes conformation under conditions that allow Na⁺ permeation. In contrast, the latter ion conditions do not significantly affect the binding of quinidine to the pore central cavity. Based on our observations and the structural information derived from the NaK bacterial channel, we hypothesize that Ca²⁺ is probably coordinated by main chain carbonyls of the pore´s first K⁺-binding site.     

Phospholemman Modulates the Gating of Cardiac L-Type Calcium Channels

Ca²⁺ entry through L-type calcium channels (Ca_V1.2) is critical in shaping the cardiac action potential and initiating cardiac contraction. Modulation of Ca_V1.2 channel gating directly affects myocyte excitability and cardiac function. We have found that phospholemman (PLM), a member of the FXYD family and regulator of cardiac ion transport, coimmunoprecipitates with Ca_V1.2 channels from guinea pig myocytes, which suggests PLM is an endogenous modulator. Cotransfection of PLM in HEK293 cells slowed Ca_V1.2 current activation at voltages near the threshold for activation, slowed deactivation after long and strong depolarizing steps, enhanced the rate and magnitude of voltage-dependent inactivation (VDI), and slowed recovery from inactivation. However, Ca²⁺-dependent inactivation was not affected. Consistent with slower channel closing, PLM significantly increased Ca²⁺ influx via Ca_V1.2 channels during the repolarization phase of a human cardiac action potential waveform. Our results support PLM as an endogenous regulator of Ca_V1.2 channel gating. The enhanced VDI induced by PLM may help protect the heart under conditions such as ischemia or tachycardia where the channels are depolarized for prolonged periods of time and could induce Ca²⁺ overload. The time and voltage-dependent slowed deactivation could represent a gating shift that helps maintain Ca²⁺ influx during the cardiac action potential waveform plateau phase.     

Antagonism of 4-substituted 1,4-dihydropyridine-3,5-dicarboxylates toward voltage-dependent L-type Ca2+ channels CaV1.3 and CaV1.2

L-type Ca²⁺ channels in mammalian brain neurons have either a Ca_V1.2 or Ca_V1.3 pore-forming subunit. Recently, it was shown that Ca_V1.3 Ca²⁺ channels underlie autonomous pacemaking in adult dopaminergic neurons in the substantia nigra pars compacta, and this reliance renders them sensitive to toxins used to create animal models of Parkinson’s disease. Antagonism of these channels with the dihydropyridine antihypertensive drug isradipine diminishes the reliance on Ca²⁺ and the sensitivity of these neurons to toxins, pointing to a potential neuroprotective strategy. However, for neuroprotection without an antihypertensive side effect, selective Ca_V1.3 channel antagonists are required. In an attempt to identify potent and selective antagonists of Ca_V1.3 channels, 124 dihydropyridines (4-substituted-1,4-dihydropyridine-3,5-dicarboxylic diesters) were synthesized. The antagonism of heterologously expressed Ca_V1.2 and Ca_V1.3 channels was then tested using electrophysiological approaches and the FLIPR Calcium 4 assay. Despite the large diversity in substitution on the dihydropyridine scaffold, the most Ca_V1.3 selectivity was only about twofold. These results support a highly similar dihydropyridine binding site at both Ca_V1.2 and Ca_V1.3 channels and suggests that other classes of compounds need to be identified for Ca_V1.3 selectivity.     

Ion channel clustering enhances weak electric field detection by neutrophils: apparent roles of SKF96365-sensitive cation channels and myeloperoxidase trafficking in cellular responses

We have tested Galvanovskis and Sandblom’s prediction that ion channel clustering enhances weak electric field detection by cells as well as how the elicited signals couple to metabolic alterations. Electric field application was timed to coincide with certain known intracellular chemical oscillators (phase-matched conditions). Polarized, but not spherical, neutrophils labeled with anti-K_v1.3, FL-DHP, and anti-TRP1, but not anti-T-type Ca²⁺ channels, displayed clusters at the lamellipodium. Resonance energy transfer experiments showed that these channel pairs were in close proximity. Dose-field sensitivity studies of channel blockers suggested that K⁺ and Ca²⁺ channels participate in field detection, as judged by enhanced oscillatory NAD(P)H amplitudes. Further studies suggested that K⁺ channel blockers act by reducing the neutrophil’s membrane potential. Mibefradil and SKF93635, which block T-type Ca²⁺ channels and SOCs, respectively, affected field detection at appropriate doses. Microfluorometry and high-speed imaging of indo-1-labeled neutrophils was used to examine Ca²⁺ signaling. Electric fields enhanced Ca²⁺ spike amplitude and triggered formation of a second traveling Ca²⁺ wave. Mibefradil blocked Ca²⁺ spikes and waves. Although 10 μM SKF96365 mimicked mibefradil, 7 μM SKF96365 specifically inhibited electric field-induced Ca²⁺ signals, suggesting that one SKF96365-senstive site is influenced by electric fields. Although cells remained morphologically polarized, ion channel clusters at the lamellipodium and electric field sensitivity were inhibited by methyl-β-cyclodextrin. As a result of phase-matched electric field application in the presence of ion channel clusters, myeloperoxidase (MPO) was found to traffic to the cell surface. As MPO participates in high amplitude metabolic oscillations, this suggests a link between the signaling apparatus and metabolic changes. Furthermore, electric field effects could be blocked by MPO inhibition or removal while certain electric field effects were mimicked by the addition of MPO to untreated cells. Therefore, channel clustering plays an important role in electric field detection and downstream responses of morphologically polarized neutrophils. In addition to providing new mechanistic insights concerning electric field interactions with cells, our work suggests novel methods to remotely manipulate physiological pathways.     

K+ Block Is the Mechanism of Functional Asymmetry in Bacterial Nav Channels

Crystal structures of several bacterial Na_v channels have been recently published and molecular dynamics simulations of ion permeation through these channels are consistent with many electrophysiological properties of eukaryotic channels. Bacterial Na_v channels have been characterized as functionally asymmetric, and the mechanism of this asymmetry has not been clearly understood. To address this question, we combined non-equilibrium simulation data with two-dimensional equilibrium unperturbed landscapes generated by umbrella sampling and Weighted Histogram Analysis Methods for multiple ions traversing the selectivity filter of bacterial Na_vAb channel. This approach provided new insight into the mechanism of selective ion permeation in bacterial Na_v channels. The non-equilibrium simulations indicate that two or three extracellular K⁺ ions can block the entrance to the selectivity filter of Na_vAb in the presence of applied forces in the inward direction, but not in the outward direction. The block state occurs in an unstable local minimum of the equilibrium unperturbed free-energy landscape of two K⁺ ions that can be ‘locked’ in place by modest applied forces. In contrast to K⁺, three Na⁺ ions move favorably through the selectivity filter together as a unit in a loose “knock-on” mechanism of permeation in both inward and outward directions, and there is no similar local minimum in the two-dimensional free-energy landscape of two Na⁺ ions for a block state. The useful work predicted by the non-equilibrium simulations that is required to break the K⁺ block is equivalent to large applied potentials experimentally measured for two bacterial Na_v channels to induce inward currents of K⁺ ions. These results illustrate how inclusion of non-equilibrium factors in the simulations can provide detailed information about mechanisms of ion selectivity that is missing from mechanisms derived from either crystal structures or equilibrium unperturbed free-energy landscapes.     

Apamin Boosting of Synaptic Potentials in CaV2.3 R-Type Ca2+ Channel Null Mice

SK2- and K_V4.2-containing K⁺ channels modulate evoked synaptic potentials in CA1 pyramidal neurons. Each is coupled to a distinct Ca²⁺ source that provides Ca²⁺-dependent feedback regulation to limit AMPA receptor (AMPAR)- and NMDA receptor (NMDAR)-mediated postsynaptic depolarization. SK2-containing channels are activated by Ca²⁺ entry through NMDARs, whereas K_V4.2-containing channel availability is increased by Ca²⁺ entry through SNX-482 (SNX) sensitive Ca_V2.3 R-type Ca²⁺ channels. Recent studies have challenged the functional coupling between NMDARs and SK2-containing channels, suggesting that synaptic SK2-containing channels are instead activated by Ca²⁺ entry through R-type Ca²⁺ channels. Furthermore, SNX has been implicated to have off target affects, which would challenge the proposed coupling between R-type Ca²⁺ channels and K_V4.2-containing K⁺ channels. To reconcile these conflicting results, we evaluated the effect of SK channel blocker apamin and R-type Ca²⁺ channel blocker SNX on evoked excitatory postsynaptic potentials (EPSPs) in CA1 pyramidal neurons from Ca_V2.3 null mice. The results show that in the absence of Ca_V2.3 channels, apamin application still boosted EPSPs. The boosting effect of Ca_V2.3 channel blockers on EPSPs observed in neurons from wild type mice was not observed in neurons from Ca_V2.3 null mice. These data are consistent with a model in which SK2-containing channels are functionally coupled to NMDARs and K_V4.2-containing channels to Ca_V2.3 channels to provide negative feedback regulation of EPSPs in the spines of CA1 pyramidal neurons.     

Mechanism of tetrodotoxin block and resistance in sodium channels

Tetrodotoxin (TTX) has been used for many decades to characterize the structure and function of biological ion channels. Yet, the precise mechanism by which TTX blocks voltage-gated sodium (Na_V) channels is not fully understood. Here molecular dynamics simulations are used to elucidate how TTX blocks mammalian voltage-gated sodium (Nav) channels and why it fails to be effective for the bacterial sodium channel, Na_VAb. We find that, in Na_VAb, a sodium ion competes with TTX for the binding site at the extracellular end of the filter, thus reducing the blocking efficacy of TTX. Using a model of the skeletal muscle channel, Na_V1.4, we show that the conduction properties of the channel observed experimentally are faithfully reproduced. We find that TTX occludes the entrance of Na_V1.4 by forming a network of hydrogen-bonds at the outer lumen of the selectivity filter. The guanidine group of TTX adopts a lateral orientation, rather than pointing into the filter as proposed previously. The acidic residues just above the selectivity filter are important in stabilizing the hydrogen-bond network between TTX and Na_V1.4. The effect of two single mutations of a critical tyrosine residue in the filter of Na_V1.4 on TTX binding observed experimentally is reproduced using computational mutagenesis.     

Functional Expression of T-Type Ca2+ Channels in Spinal Motoneurons of the Adult Turtle

Voltage-gated Ca²⁺ (Ca_V) channels are transmembrane proteins comprising three subfamilies named Ca_V1, Ca_V2 and Ca_V3. The Ca_V3 channel subfamily groups the low-voltage activated Ca²⁺ channels (LVA or T-type) a significant role in regulating neuronal excitability. Ca_V3 channel activity may lead to the generation of complex patterns of action potential firing such as the postinhibitory rebound (PIR). In the adult spinal cord, these channels have been found in dorsal horn interneurons where they control physiological events near the resting potential and participate in determining excitability. In motoneurons, Ca_V3 channels have been found during development, but their functional expression has not yet been reported in adult animals. Here, we show evidence for the presence of Ca_V3 channel-mediated PIR in motoneurons of the adult turtle spinal cord. Our results indicate that Ni²⁺ and NNC55-0396, two antagonists of Ca_V3 channel activity, inhibited PIR in the adult turtle spinal cord. Molecular biology and biochemical assays revealed the expression of the Ca_V3.1 channel isotype and its localization in motoneurons. Together, these results provide evidence for the expression of Ca_V3.1 channels in the spinal cord of adult animals and show also that these channels may contribute to determine the excitability of motoneurons.