Important Role of Asparagines in Coupling the Pore and Votage-Sensor Domain in Voltage-Gated Sodium Channels.

Voltage-gated sodium (NaV) channels contain an α-subunit incorporating the channel's pore and gating machinery composed of four homologous domains (DI-DIV), with a pore domain formed by the S5 and S6 segments and a voltage-sensor domain formed by the S1-S4 segments. During a membrane depolarization movement, the S4s in the voltage-sensor domains exert downstream effects on the S6 segments to control ionic conductance through the pore domain. We used lidocaine, a local anesthetic and antiarrhythmic drug, to probe the role of conserved Asn residues in the S6s of DIII and DIV in NaV1.

The sodium channel as a target for local anesthetic drugs.

Na channels are the source of excitatory currents for the nervous system and muscle. They are the target for a class of drugs called local anesthetics (LA), which have been used for local and regional anesthesia and for excitatory problems such as epilepsy and cardiac arrhythmia. These drugs are prototypes for new analgesic drugs.

A molecular model of the inner pore of the Ca channel in its open state.

Structure of the Ca channel open pore is unlikely to be the same as that of the K channel because Ca channels do not contain the hinge residues Gly or Pro. The Ca channel does not have a wide entry into the inner pore, as is found in K channels. First we sought to simulate the open state of the Ca channel by modeling forced opening of the KcsA channel using a procedure of restrained minimization with distance constraints at the level of the α-helical bundle, corresponding to segments Thr-107-Val-115.

A molecular switch between the outer and the inner vestibules of the voltage-gated Na+ channel.

Voltage-gated ion channels are transmembrane proteins that undergo complex conformational changes during their gating transitions. Both functional and structural data from K(+) channels suggest that extracellular and intracellular parts of the pore communicate with each other via a trajectory of interacting amino acids. No crystal structures are available for voltage-gated Na(+) channels, but functional data suggest a similar intramolecular communication involving the inner and outer vestibules.

Sodium channel molecular conformations and antiarrhythmic drug affinity.

Class I cardiac antiarrhythmic drugs, for example, lidocaine, mexiletine, flecainide, quinidine, and procainamide, continue to play an important role in the therapy for cardiac arrhythmias because of the presence of use-dependent block. Lidocaine, as well as related drugs such as mepivacaine, bupivacaine, and cocaine, also belong to the class of medications referred to as local anesthetics. In this review, we will consider lidocaine as the prototypical antiarrhythmic drug because it continues to be widely used both as an antiarrhythmic drug (first used as an antiarrhythmic drug in 1950) as well as a local anesthetic agent.

Molecular model of anticonvulsant drug binding to the voltage-gated sodium channel inner pore.

The tricyclic anticonvulsant drugs phenytoin, carbamazepine, and lamotrigine block neuronal voltage-gated Na(+) channels, and their binding sites to domain IV-S6 in the channel's inner pore overlap with those of local anesthetic drugs. These anticonvulsants are neutral, in contrast to the mostly positively charged local anesthetics, but their open/inactivated-state blocking affinities are similar. Using a model of the open pore of the Na(+) channel that we developed by homology with the crystal structures of potassium channels, we have docked these three anticonvulsants with residues identified by mutagenesis as important for their binding energy.

The tetrodotoxin binding site is within the outer vestibule of the sodium channel.

Tetrodotoxin and saxitoxin are small, compact asymmetrical marine toxins that block voltage-gated Na channels with high affinity and specificity. They enter the channel pore's outer vestibule and bind to multiple residues that control permeation. Radiolabeled toxins were key contributors to channel protein purification and subsequent cloning.

Using lidocaine and benzocaine to link sodium channel molecular conformations to state-dependent antiarrhythmic drug affinity.

Rationale: Lidocaine and other antiarrhythmic drugs bind in the inner pore of voltage-gated Na channels and affect gating use-dependently. A phenylalanine in domain IV, S6 (Phe1759 in Na(V)1.5), modeled to face the inner pore just below the selectivity filter, is critical in use-dependent drug block.

Toxin-resistant sodium channels: parallel adaptive evolution across a complete gene family.

Approximately 75% of vertebrate proteins belong to protein families encoded by multiple evolutionarily related genes, a pattern that emerged as a result of gene and genome duplications over the course of vertebrate evolution. In families of genes with similar or related functions, adaptation to a strong selective agent should involve multiple adaptive changes across the entire gene family. However, we know of no evolutionary studies that have explicitly addressed this point.

Speeding the recovery from ultraslow inactivation of voltage-gated Na+ channels by metal ion binding to the selectivity filter: a foot-on-the-door?

Slow inactivated states in voltage-gated ion channels can be modulated by binding molecules both to the outside and to the inside of the pore. Thus, external K(+) inhibits C-type inactivation in Shaker K(+) channels by a "foot-in-the-door" mechanism. Here, we explore the modulation of a very long-lived inactivated state, ultraslow inactivation (I(US)), by ligand binding to the outer vestibule in voltage-gated Na(+) channels.

Charge at the lidocaine binding site residue Phe-1759 affects permeation in human cardiac voltage-gated sodium channels.

Our homology molecular model of the open/inactivated state of the Na(+) channel pore predicts, based on extensive mutagenesis data, that the local anaesthetic lidocaine docks eccentrically below the selectivity filter, such that physical occlusion is incomplete. Electrostatic field calculations suggest that the drug's positively charged amine produces an electrostatic barrier to permeation. To test the effect of charge at this pore level on permeation in hNa(V)1.

Selectivity filter residues contribute unequally to pore stabilization in voltage-gated sodium channels.

Mutations in the putative selectivity filter region of the voltage-gated Na+ channel, the so-called DEKA-motif, not only affect selectivity but also alter the channel's gating properties, suggesting functional coupling between permeation and gating. We have previously reported that charge-altering mutations at position 1237 in the P-loop of domain III (position K of the DEKA-motif in the adult rat skeletal muscle Na+ channel, rNa(v)1.4) dramatically enhanced entry to an inactivated state from which the channels recovered with a very slow time constant on the order of approximately 100 s (Todt, H.

Molecular modeling of local anesthetic drug binding by voltage-gated sodium channels.

Voltage-gated sodium (Na+) channels are targets for local anesthetic (LA) drugs that bind in the inner pore of the channel with affinities related to the channel gating states. Our core model of the sodium channel (P loops and S5 and S6 segments from each of the four domains) was closed because it was developed using coordinates from the KcsA channel crystallographic structure. We developed a model of the activated, open channel based on the structure of the open MthK channel, which was characterized by bends at the S6 glycine or serine residues.

Accessibility of mid-segment domain IV S6 residues of the voltage-gated Na+ channel to methanethiosulfonate reagents.

The inner pore of the voltage-gated Na+ channel is predicted by the structure of bacterial potassium channels to be lined with the four S6 alpha-helical segments. Our previously published model of the closed pore based on the KcsA structure, and our new model of the open pore based on the MthK structure predict which residues in the mid-portion of S6 face the pore. We produced cysteine mutants of the mid-portion of domain IV-S6 (Ile-1575-Leu-1591) in NaV 1.

Lidocaine: a foot in the door of the inner vestibule prevents ultra-slow inactivation of a voltage-gated sodium channel.

After opening, Na(+) channels may enter several kinetically distinct inactivated states. Whereas fast inactivation occurs by occlusion of the inner channel pore by the fast inactivation gate, the mechanistic basis of slower inactivated states is much less clear. We have recently suggested that the inner pore of the voltage-gated Na(+) channel may be involved in the process of ultra-slow inactivation (I(US)).

Molecular modeling of interactions of dihydropyridines and phenylalkylamines with the inner pore of the L-type Ca2+ channel.

Domains IIIS5, IIIS6, and IVS6 transmembrane segments of L-type Ca(2+) channels participate in dihydropyridine (DHP) and phenylalkylamine (PAA) binding. The inner pore structure of the Ca(v)1.2 channel was reconstructed from coordinates of the transmembrane alpha-helices of the KcsA channel.

Interaction between fast and ultra-slow inactivation in the voltage-gated sodium channel. Does the inactivation gate stabilize the channel structure?

Recently, we reported that mutation A1529D in the domain (D) IV P-loop of the rat skeletal muscle Na(+) channel mu(1) (DIV-A1529D) enhanced entry to an inactivated state from which the channels recovered with an abnormally slow time constant on the order of approximately 100 s. Transition to this "ultra-slow" inactivated state (USI) was substantially reduced by binding to the outer pore of a mutant mu-conotoxin GIIIA. This indicated that USI reflected a structural rearrangement of the outer channel vestibule and that binding to the pore of a peptide could stabilize the pore structure (Hilber, K.

Cardiac sodium and calcium channels: a history of excitatory currents.

The entire concept of ion channels as molecular machines to gate ion traffic across the membrane has only recently been generally recognized, even though ion channels are found in almost all cells. Na+ and Ca2+ channels are the basis of excitability, and in the heart they generate the rhythm, coordinating and controlling cardiac contraction. Dysfunction of ion channels results in arrhythmias that underlie 20-25% of deaths in the developed world, and some arrhythmias result directly from gene defects in ion channels.

Do defects in ion channel glycosylation set the stage for lethal cardiac arrhythmias?

Many ion channels are modified by the addition of carbohydrate residues. Fozzard and Kyle discuss evidence that sialic acid residues on glycosylated cardiac sodium and potassium channels may be important for preventing early after-depolarizations that can result in cardiac arrhythmias.

Electrostatic and steric contributions to block of the skeletal muscle sodium channel by mu-conotoxin.

Pore-blocking toxins are valuable probes of ion channels that underlie electrical signaling. To be effective inhibitors, they must show high affinity and specificity and prevent ion conduction. The 22-residue sea snail peptide, mu-conotoxin GIIIA, blocks the skeletal muscle sodium channel completely.