Kir2 inward rectification-controlled precise and dynamic balances between Kir2 and HCN currents initiate pacemaking activity.

Spontaneous rhythmic action potential or pacemaking activity of pacemaker cells controls rhythmic signaling such as heartbeat. The mechanism underlying the origin of pacemaking activity is not well understood. In this study, we created human embryonic kidney (HEK) 293 cells that show pacemaking activity through heterologous expression of strong inward rectifier K+ subfamily 2 isoform 1 (Kir2.1) channels, hyperpolarization-activated cyclic nucleotide-gated isoform 2 (HCN2) nonselective cation channels, and voltage-gated Na+ subfamily 1 isoform 5 or Ca2+ subfamily 3 isoform 1 (Nav1.5 or Cav3.1) channels. A range of relative levels of Kir2.1 and HCN2 currents dynamically counterbalance, generating spontaneous rhythmic oscillation of resting membrane potential between -64 and -34 mV and determining oscillation rates. Each oscillation cycle begins with an autodepolarization phase, which slowly proceeds to the threshold potential that activates Nav1.5 or Cav3.1 channels and triggers action potential, causing engineered HEK293 cells to exhibit pacemaking activity at a rate of ≤67 beats/min. Engineered HEK293 cells with Kir2.1 and either HCN3 or HCN4 also show the oscillation. Engineered HEK293 cells expressing HCN2 and other Kir2 channels, which lack Kir2.1-like complete inward rectification, do not show the oscillation. Therefore, Kir2.1-like inward rectification-controlled precise and dynamic balances between Kir2 and HCN currents initiate spontaneous rhythmic action potential and form an origin of pacemaking activity; Kir2 and HCN channels play essential roles in pacemaking activity.-Chen, K., Zuo, D., Wang, S.-Y. Chen, H. Kir2 inward rectification-controlled precise and dynamic balances between Kir2 and HCN currents initiate pacemaking activity.

Single rat muscle Na+ channel mutation confers batrachotoxin autoresistance found in poison-dart frog Phyllobates terribilis.

Poison-dart Phyllobates terribilis frogs sequester lethal amounts of steroidal alkaloid batrachotoxin (BTX) in their skin as a defense mechanism against predators. BTX targets voltage-gated Na+ channels and enables them to open persistently. How BTX autoresistance arises in such frogs remains a mystery. The BTX receptor has been delineated along the Na+ channel inner cavity, which is formed jointly by four S6 transmembrane segments from domains D1 to D4. Within the P. terribilis muscle Na+ channel, five amino acid (AA) substitutions have been identified at D1/S6 and D4/S6. We therefore investigated the role of these naturally occurring substitutions in BTX autoresistance by introducing them into rat Nav1.4 muscle Na+ channel, both individually and in combination. Our results showed that combination mutants containing an N1584T substitution all conferred a complete BTX-resistant phenotype when expressed in mammalian HEK293t cells. The single N1584T mutant also retained its functional integrity and became exceptionally resistant to 5 µM BTX, aside from a small residual BTX effect. Single and combination mutants with the other four S6 residues (S429A, I433V, A445D, and V1583I) all remained highly BTX sensitive. These findings, along with diverse BTX phenotypes of N1584K/A/D/T mutant channels, led us to conclude that the conserved N1584 residue is indispensable for BTX actions, probably functioning as an integral part of the BTX receptor. Thus, complete BTX autoresistance found in P. terribilis muscle Na+ channels could emerge primarily from a single AA substitution (asparagine→threonine) via a single nucleotide mutation (AAC→ACC).

R-Duloxetine and N-Methyl Duloxetine as Novel Analgesics Against Experimental Postincisional Pain.

BACKGROUND: Antidepressant S-duloxetine alleviates intractable pain associated with diabetic peripheral neuropathy and fibromyalgia. It also reduces both acute and persistent pain in various animal models. This study addresses whether the enantiomer, R-duloxetine, and the homolog, N-methyl duloxetine, could act as analgesics and whether they block neuronal Na⁺ channels. METHODS: The rat incision plus extension model on the dorsothoracic skin was applied to evoke postoperative mechanoallodynia and hyperalgesia, measured for 5 days postoperatively by local responses to von Frey filaments. R-Duloxetine and N-methyl duloxetine were administered systemically (intraperitoneal) or locally (subcutaneous [SC]) 1 hour before the surgery. The block of Na currents in rat neuronal GH3 cells was determined under the whole-cell configuration. RESULTS: Ipsilateral SC injections (2 mg/0.4 mL) of R-duloxetine and N-methyl duloxetine reduced both postoperative allodynia and hyperalgesia by approximately 89% to 99% in the area under the curve of skin responses next to incision over 5 days. Systemic intraperitoneal injections at a higher dosage (10 mg) had smaller analgesic effects (reduced by approximately 53%-69%), whereas contralateral SC injections (10 mg) were ineffective. Both R-duloxetine and N-methyl duloxetine blocked neuronal Na⁺ currents, with a higher affinity for the inactivated than the resting states. In addition, both drugs elicited significant use-dependent block of Na currents when stimulated at 5 Hz. CONCLUSIONS: R-Duloxetine and N-methyl duloxetine are highly effective against postoperative pain using the skin incision model, and they elicit both tonic and use-dependent block of neuronal Na⁺ channels. Our results suggest that R-duloxetine and N-methyl duloxetine are applicable as novel analgesics.

Block of human cardiac sodium channels by lacosamide: evidence for slow drug binding along the activation pathway.

Lacosamide is an anticonvulsant hypothesized to enhance slow inactivation of neuronal Na(+) channels for its therapeutic action. Cardiac Na(+) channels display less and incomplete slow inactivation, but their sensitivity toward lacosamide remains unknown. We therefore investigated the action of lacosamide in human cardiac Nav1.5 and Nav1.5-CW inactivation-deficient Na(+) channels. Lacosamide showed little effect on hNav1.5 Na(+) currents at 300 µM when cells were held at -140 mV. With 30-second conditioning pulses from -90 to -50 mV; however, hNav1.5 Na(+) channels became sensitive to lacosamide with IC50 (50% inhibitory concentration) around 70-80 µM. Higher IC50 values were found at -110 and -30 mV. The development of lacosamide block at -70 mV was slow in wild-type Na(+) channels (τ; 8.04 ± 0.39 seconds, n = 8). This time constant was significantly accelerated in hNav1.5-CW inactivation-deficient counterparts. The recovery from lacosamide block at -70 mV for 10 seconds was relatively rapid in wild-type Na(+) channels (τ; 639 ± 90 milliseconds, n = 8). This recovery was accelerated further in hNav1.5-CW counterparts. Unexpectedly, lacosamide elicited a time-dependent block of persistent hNav1.5-CW Na(+) currents with an IC50 of 242 ± 19 µM (n = 5). Furthermore, both hNav1.5-CW/F1760K mutant and batrachotoxin-activated hNav1.5 Na(+) channels became completely lacosamide resistant, indicating that the lacosamide receptor overlaps receptors for local anesthetics and batrachotoxin. Our results together suggest that lacosamide targets the intermediate preopen and open states of hNav1.5 Na(+) channels. Lacosamide may thus track closely the conformational changes at the hNav1.5-F1760 region along the activation pathway.

Persistent human cardiac Na+ currents in stably transfected mammalian cells: Robust expression and distinct open-channel selectivity among Class 1 antiarrhythmics.

Miniature persistent late Na(+) currents in cardiomyocytes have been linked to arrhythmias and sudden death. The goals of this study are to establish a stable cell line expressing robust persistent cardiac Na(+) currents and to test Class 1 antiarrhythmic drugs for selective action against resting and open states. After transient transfection of an inactivation-deficient human cardiac Na(+) channel clone (hNav1.5-CW with L409C/A410W double mutations), transfected mammalian HEK293 cells were treated with 1 mg/ml G-418. Individual G-418-resistant colonies were isolated using glass cylinders. One colony with high expression of persistent Na(+) currents was subjected to a second colony selection. Cells from this colony remained stable in expressing robust peak Na(+) currents of 996 ± 173 pA/pF at +50 mV (n = 20). Persistent late Na(+) currents in these cells were clearly visible during a 4-second depolarizing pulse albeit decayed slowly. This slow decay is likely due to slow inactivation of Na(+) channels and could be largely eliminated by 5 µM batrachotoxin. Peak cardiac hNav1.5-CW Na(+) currents were blocked by tetrodotoxin with an IC(50) value of 2.27 ± 0.08 µM (n = 6). At clinic relevant concentrations, Class 1 antiarrhythmics are much more selective in blocking persistent late Na(+) currents than their peak counterparts, with a selectivity ratio ranging from 80.6 (flecainide) to 3 (disopyramide). We conclude that (1) Class 1 antiarrhythmics differ widely in their resting- vs. open-channel selectivity, and (2) stably transfected HEK293 cells expressing large persistent hNav1.5-CW Na(+) currents are suitable for studying as well as screening potent open-channel blockers.

Block of neuronal Na+ channels by antidepressant duloxetine in a state-dependent manner.

BACKGROUND: Duloxetine is a mixed serotonin-norepinephrine reuptake inhibitor used for major depressive disorder. Duloxetine is also beneficial for patients with diabetic peripheral neuropathy and with fibromyalgia, but how it works remains unclear. METHODS: We used the whole cell, patch clamp technique to test whether duloxetine interacts with the neuronal Nav1.7 Na+ channel as a potential target. Resting and inactivated Nav1.7 Na+ channel block by duloxetine were measured by conventional pulse protocols in transfected human embryonic kidney cells. The open-channel block was determined directly using inactivation-deficient mutant Nav1.7 Na+ channels. RESULTS: The 50% inhibitory concentration (IC50) of duloxetine for the resting and inactivated wild-type hNav1.7 Na+ channel were 22.1+/-0.4 and 1.79+/-0.10 microM, respectively (mean+/-SE, n=5). The IC50 for the open Na+ channel was 0.25+/-0.02 microM (n=5), as determined by the block of persistent late Nav1.7 Na+ currents. Similar open-channel block by duloxetine was found in the muscle Nav1.4 isoform (IC50=0.51+/-0.05 microM; n=5). Block by duloxetine appeared via the conserved local anesthetic receptor as determined by site-directed mutagenesis. Finally, duloxetine elicited strong use-dependent block of neuronal transient Nav1.7 Na+ currents during repetitive stimulations. CONCLUSIONS: Duloxetine blocks persistent late Nav1.7 Na+ currents preferentially, which may in part account for its analgesic action.

State-dependent block of Na+ channels by articaine via the local anesthetic receptor.

Articaine is widely used as a local anesthetic (LA) in dentistry, but little is known regarding its blocking actions on Na+ channels. We therefore examined the state-dependent block of articaine first in rat skeletal muscle rNav1.4 Na+ channels expressed in Hek293t cells. Articaine exhibited a weak block of resting rNav1.4 Na+ channels at -140 mV with a 50% inhibitory concentration (IC(50)) of 378 +/- 26 microM (n = 5). The affinity was higher for inactivated Na+ channels measured at -70 mV with an IC50 value of 40.6 +/- 2.7 microM (n = 5). The open-channel block by articaine was measured using inactivation-deficient rNav1.4 Na+ channels with an IC50 value of 15.8 +/- 1.5 microM (n = 5). Receptor mapping demonstrated that articaine interacted strongly with a D4S6 phenylalanine residue, which is known to form a part of the LA receptor. Thus the block of rNav1.4 Na+ channels by articaine is via the conserved LA receptor in a highly state-dependent manner, with a ranking order of open (23.9x) > inactivated (9.3x) > resting (1x) state. Finally, the open-channel block by articaine was likewise measured in inactivation-deficient hNav1.7 and rNav1.8 Na+ channels, with IC(50) values of 8.8 +/- 0.1 and 22.0 +/- 0.5 microM, respectively (n = 5), indicating that the high-affinity open-channel block by articaine is indeed preserved in neuronal Na+ channel isoforms.

Use of bulleyaconitine A as an adjuvant for prolonged cutaneous analgesia in the rat.

BACKGROUND: Bulleyaconitine A (BLA) is an analgesic and antiinflammatory drug isolated from Aconitum plants. BLA has several potential targets, including voltage-gated Na+ channels. We tested whether BLA elicited long-lasting cutaneous analgesia, when co-injected with lidocaine and epinephrine, as a model for prolonged infiltration anesthesia. METHODS: The local anesthetic properties of BLA were assessed by the patch-clamp technique in HEK293t cells expressing Nav1.7 and Nav1.8 neuronal Na+ channels, both crucial for nociception. Drug solutions (0.6 mL) were injected subcutaneously via rat shaved dorsal skin. Inhibition of the cutaneous trunci muscle reflex was evaluated by pinpricks. Skin cross-sections were stained with hematoxylin and eosin or with antibodies against PGP9.5. RESULTS: BLA at 10 microM interacted minimally with resting or inactivated Nav1.7 and Nav1.8 Na+ channels when infrequently stimulated to +50 mV for 3 ms. However, when stimulated at 2 Hz for 1000 pulses, their peak Na+ currents were >90% reduced by BLA. This use-dependent inhibition was not significantly reversed after 15-min washing. Complete nociceptive blockade after injection of lidocaine (0.5%)/epinephrine (1:200,000) lasted for approximately 1 h in rats; full recovery occurred after approximately 6 h. Co-injection of 0.125 mM BLA with lidocaine/epinephrine increased the duration of complete nociceptive blockade to 24 h. Full recovery occurred after approximately 6 days. Skin histology including peripheral nerve fibers appeared unaffected by BLA. CONCLUSIONS: BLA inhibits Nav1.7 and Nav1.8 Na+ currents in a use-dependent manner. Co-injection of BLA at

Block of persistent late Na+ currents by antidepressant sertraline and paroxetine.

Antidepressants, such as traditional tricyclic antidepressants (TCAs), are the first-line treatment for various pain syndromes. Available evidence indicates that TCAs may target Na+ channels for their analgesic action. In this report, we examined the effects of contemporary antidepressants sertraline and paroxetine on (1) neuronal Na+ channels expressed in GH3 cells and (2) muscle rNav1.4 Na+ channels heterologously expressed in Hek293t cells. Our results showed that both antidepressants blocked Na+ channels in a highly state-dependent manner. The 50% inhibitory concentrations (IC50) for sertraline and paroxetine ranged approximately 18-28 microM: for resting block and approximately 2-8 microM: for inactivated block of neuronal and rNav1.4 Na+ channels. Surprisingly, the IC50 values for both drugs were about 0.6-0.7 microM: for the open channel block of persistent late Na+ currents generated through inactivation-deficient rNav1.4 mutant Na+ channels. For comparison, the open channel block in neuronal hNav1.7 counterparts yielded IC50 values around 0.3-0.4 microM: for both drugs. Receptor mapping using fast inactivation-deficient rNav1.4-F1579A/K mutants with reduced affinities toward local anesthetics (LAs) and TCAs indicated that the F1579 residue is not involved in the binding of sertraline and paroxetine. Thus, sertraline and paroxetine are potent open channel blockers that target persistent late Na+ currents preferentially, but their block is not mediated via the phenylalanine residue at the known LA/TCA receptor site.

State- and use-dependent block of muscle Nav1.4 and neuronal Nav1.7 voltage-gated Na+ channel isoforms by ranolazine.

Ranolazine is an antianginal agent that targets a number of ion channels in the heart, including cardiac voltage-gated Na(+) channels. However, ranolazine block of muscle and neuronal Na(+) channel isoforms has not been examined. We compared the state- and use-dependent ranolazine block of Na(+) currents carried by muscle Nav1.4, cardiac Nav1.5, and neuronal Nav1.7 isoforms expressed in human embryonic kidney 293T cells. Resting and inactivated block of Na(+) channels by ranolazine were generally weak, with a 50% inhibitory concentration (IC(50)) >/= 60 microM. Use-dependent block of Na(+) channel isoforms by ranolazine during repetitive pulses (+50 mV/10 ms at 5 Hz) was strong at 100 microM, up to 77% peak current reduction for Nav1.4, 67% for Nav1.5, and 83% for Nav1.7. In addition, we found conspicuous time-dependent block of inactivation-deficient Nav1.4, Nav1.5, and Nav1.7 Na(+) currents by ranolazine with estimated IC(50) values of 2.4, 6.2, and 1.7 microM, respectively. On- and off-rates of ranolazine were 8.2 microM(-1) s(-1) and 22 s(-1), respectively, for Nav1.4 open channels and 7.1 microM(-1) s(-1) and 14 s(-1), respectively, for Nav1.7 counterparts. A F1579K mutation at the local anesthetic receptor of inactivation-deficient Nav1.4 Na(+) channels reduced the potency of ranolazine approximately 17-fold. We conclude that: 1) both muscle and neuronal Na(+) channels are as sensitive to ranolazine block as their cardiac counterparts; 2) at its therapeutic plasma concentrations, ranolazine interacts predominantly with the open but not resting or inactivated Na(+) channels; and 3) ranolazine block of open Na(+) channels is via the conserved local anesthetic receptor albeit with a relatively slow on-rate.

Bulleyaconitine A isolated from aconitum plant displays long-acting local anesthetic properties in vitro and in vivo.

BACKGROUND: Bulleyaconitine A (BLA) is an active ingredient of Aconitum bulleyanum plants. BLA has been approved for the treatment of chronic pain and rheumatoid arthritis in China, but its underlying mechanism remains unclear. METHODS: The authors examined (1) the effects of BLA on neuronal voltage-gated Na channels in vitro under the whole cell patch clamp configuration and (2) the sensory and motor functions of rat sciatic nerve after single BLA injections in vivo. RESULTS: BLA at 10 microm did not affect neuronal Na currents in clonal GH3 cells when stimulated infrequently to +50 mV. When stimulated at 2 Hz for 1,000 pulses (+50 mV for 4 ms), BLA reduced the peak Na currents by more than 90%. This use-dependent reduction of Na currents by BLA reversed little after washing. Single injections of BLA (0.2 ml at 0.375 mm) into the rat sciatic notch not only blocked sensory and motor functions of the sciatic nerve but also induced hyperexcitability, followed by sedation, arrhythmia, and respiratory distress. When BLA at 0.375 mm was coinjected with 2% lidocaine (approximately 80 mm) or epinephrine (1:100,000) to reduce drug absorption by the bloodstream, the sensory and motor functions of the sciatic nerve remained fully blocked for approximately 4 h and regressed completely after approximately 7 h, with minimal systemic effects. CONCLUSIONS: BLA reduces neuronal Na currents strongly at +50 mV in a use-dependent manner. When coinjected with lidocaine or epinephrine, BLA elicits prolonged block of both motor and sensory functions in rats with minimal adverse effects.

Serine-401 as a batrachotoxin- and local anesthetic-sensing residue in the human cardiac Na+ channel.

Sequence alignment of four S6 segments in the human cardiac Na+ channel suggests that serine-401 (hNav1.5-S401) at D1S6 along with asparagine-927 (N927) at D2S6, serine-1458 (S1458) at D3S6, and phenylalanine-1760 (F1760) at D4S6 may jointly form a pore-facing S(401)N(927)S(1458)F(1760) ring. Importantly, this pore-facing structure is adjacent to the putative gating-hinge (G(400)G(926)G(1457)S(1759)) and close to the selectivity filter. Within this SNSF ring, only S401 has not yet been identified as a batrachotoxin (BTX) sensing residue. We therefore created S401 mutants with 12 substitutions (S401C,W,P,A,K,F,R,E,L,N,D,G) and assayed their BTX sensitivity. All S401 mutants expressed Na+ currents but often with altered gating characteristics. Ten mutants were found sensitive to 5 muM BTX, which eliminated Na+ channel fast inactivation after repetitive pulses. However, S401K and S401R became BTX resistant. In addition, the block of open and inactivated hNav1.5-S401K Na+ channels by local anesthetic bupivacaine was reduced by approximately 8-10-fold, but not the block of resting Na+ channels. Qualitatively, these ligand-sensing phenotypes of hNav1.5-S401K channels resemble those of S1458K and F1760K channels reported earlier. Together, our results support that residue hNav1.5-S401 at D1S6 is facing the inner cavity and is in close proximity to the receptor sites for BTX and for local anesthetics.

Preferential block of inactivation-deficient Na+ currents by capsaicin reveals a non-TRPV1 receptor within the Na+ channel.

Capsaicin elicits burning pain via the activation of the vanilloid receptor (TRPV1). Intriguingly, several reports showed that capsaicin also inhibits Na+ currents but the mechanisms remain unclear. To explore this non-TRPV1 action we applied capsaicin to HEK293 cells stably expressing inactivation-deficient rat skeletal muscle Na+ mutant channels (rNav1.4-WCW). Capsaicin elicited a conspicuous time-dependent block of inactivation-deficient Na+ currents. The 50% inhibitory concentration (IC50) of capsaicin for open Na+ channels at +30 mV was measured 6.8+/-0.6 microM (n=5), a value that is 10-30 times lower than those for resting (218 microM) and inactivated (74 microM) wild-type Na+ channels. On-rate and off-rate constants for capsaicin open-channel block at +30 mV were estimated to be 6.37 microM(-1) s(-1) and 34.4 s(-1), respectively, with a calculated dissociation constant (KD) of 5.4 microM. Capsaicin at 30 microM produced approximately 70% additional use-dependent block of remaining rNav1.4-WCW Na+ currents during repetitive pulses at 1 Hz. Site-directed mutagenesis showed that the local anesthetic receptor was not responsible for the capsaicin block of the inactivation-deficient Na+ channel. Interestingly, capsaicin elicited little time-dependent block of batrachotoxin-modified rNav1.4-WCW Na+ currents, indicating that batrachotoxin prevents capsaicin binding. Finally, neuronal open Na+ channels endogenously expressed in GH3 cells were as sensitive to capsaicin block as rNav1.4 counterparts. We conclude that capsaicin preferentially blocks persistent late Na+ currents, probably via a receptor that overlaps the batrachotoxin receptor but not the local anesthetic receptor. Drugs that target such a non-TRPV1 receptor could be beneficial for patients with neuropathic pain.

Irreversible block of cardiac mutant Na+ channels by batrachotoxin.

Batrachotoxin (BTX) not only keeps the voltage-gated Na(+) channel open persistently but also reduces its single-channel conductance. Although a BTX receptor has been delimited within the inner cavity of Na(+) channels, how Na(+) ions flow through the BTX-bound permeation pathway remains unclear. In this report we tested a hypothesis that Na(+) ions traverse a narrow gap between bound BTX and residue N927 at D2S6 of cardiac hNa(v)1.5 Na(+) channels. We found that BTX at 5 microM indeed elicited a strong block of hNa(v)1.5-N927K currents (approximately 70%) after 1000 repetitive pulses (+50 mV/20 ms at 2 Hz) without any effects on Na(+) channel gating. Once occurred, this unique use-dependent block of hNa(v)1.5-N927K Na(+) channels recovered little at holding potential (-140 mV), demonstrating that BTX block is irreversible under our experimental conditions. Such an irreversible effect likewise developed in fast inactivation-deficient hNa(v)1.5-N927K Na(+) channels albeit with a faster on-rate; approximately 90% of peak Na(+) currents were abolished by BTX after 200 repetitive pulses (+50 mV/20 ms). This use-dependent block of fast inactivation-deficient hNa(v)1.5-N927K Na(+) channels by BTX was duration dependent. The longer the pulse duration the larger the block developed. Among N927K/W/R/H/D/S/Q/G/E substitutions in fast inactivation-deficient hNa(v)1.5 Na(+) channels, only N927K/R Na(+) currents were highly sensitive to BTX block. We conclude that (a) BTX binds within the inner cavity and partly occludes the permeation pathway and (b) residue hNa(v)1.5-N927 is critical for ion permeation between bound BTX and D2S6, probably because the side-chain of N927 helps coordinate permeating Na(+) ions.

Inhibition of Nav1.7 and Nav1.4 sodium channels by trifluoperazine involves the local anesthetic receptor.

The calmodulin (CaM) inhibitor trifluoperazine (TFP) can produce analgesia when given intrathecally to rats; however, the mechanism is not known. We asked whether TFP could modulate the Na(v)1.7 sodium channel, which is highly expressed in the peripheral nervous system and plays an important role in nociception. We show that 500 nM and 2 muM TFP induce major decreases in Na(v)1.7 and Na(v)1.4 current amplitudes and that 2 muM TFP causes hyperpolarizing shifts in the steady-state inactivation of Na(v)1.7 and Na(v)1.4. CaM can bind to the C-termini of voltage-gated sodium channels and modulate their functional properties; therefore we investigated if TFP modulation of sodium channels was due to CaM inhibition. However, the TFP inhibition was not replicated by whole cell dialysis of a calmodulin inhibitory peptide, indicating that major effects of TFP do not involve a disruption of CaM-channel interactions. Rather, our data show that TFP inhibition is state dependent and that the majority of the TFP inhibition depends on specific amino-acid residues in the local anesthetic receptor site in sodium channels. TFP was also effective in vivo in causing motor and sensory blockade after subfascial injection to the rat sciatic nerve. The state-dependent block of Na(v)1.7 channels with nanomolar concentrations of TFP raises the possibility that TFP, or TFP analogues, might be useful for regional anesthesia and pain management and could be more potent than traditional local anesthetics.

Time-dependent block and resurgent tail currents induced by mouse beta4(154-167) peptide in cardiac Na+ channels.

Resurgent tail Na(+) currents were first discovered in cerebellar Purkinje neurons. A recent study showed that a 14-mer fragment of a mouse beta4 subunit, beta4(154-167), acts as an intracellular open-channel blocker and elicits resurgent currents in Purkinje neurons (Grieco, T.M., J.D. Malhotra, C. Chen, L.L. Isom, and I.M. Raman. 2005. Neuron. 45:233-244). To explore these phenotypes in vitro, we characterized beta4(154-167) actions in inactivation-deficient cardiac hNav1.5 Na(+) channels expressed in human embryonic kidney 293t cells. Intracellular beta4(154-167) from 25-250 microM elicited a conspicuous time-dependent block of inactivation-deficient Na(+) currents at 50 mV in a concentration-dependent manner. On and off rates for beta4(154-167) binding were estimated at 10.1 microM(-1)s(-1) and 49.1 s(-1), respectively. Upon repolarization, large tail currents emerged with a slight delay at -140 mV, probably as a result of the rapid unblocking of beta4(154-167). Near the activation threshold (approximately -70 mV), resurgent tail currents were robust and long lasting. Likewise, beta4(154-167) induces resurgent currents in wild-type hNav1.5 Na(+) channels, although to a lesser extent. The inactivation peptide acetyl-KIFMK-amide not only restored the fast inactivation phenotype in hNav1.5 inactivation-deficient Na(+) channels but also elicited robust resurgent currents. When modified by batrachotoxin (BTX), wild-type hNav1.5 Na(+) channels opened persistently but became resistant to beta4(154-167) and acetyl-KIFMK-amide block. Finally, a lysine substitution of a phenylalanine residue at D4S6, F1760, which forms a part of receptors for local anesthetics and BTX, rendered cardiac Na(+) channels resistant to beta4(154-167). Together, our in vitro studies identify a putative S6-binding site for beta4(154-167) within the inner cavity of hNav1.5 Na(+) channels. Such an S6 receptor readily explains (1) why beta4(154-167) gains access to its receptor as an open-channel blocker, (2), why bound beta4(154-167) briefly prevents the activation gate from closing by a "foot-in-the-door" mechanism during deactivation, (3) why BTX inhibits beta4(154-167) binding by physical exclusion, and (4) why a lysine substitution of residue F1760 eliminates beta4(154-167) binding.

Potent block of inactivation-deficient Na+ channels by n-3 polyunsaturated fatty acids.

A voltage-gated, small, persistent Na(+) current (I(Na)) has been shown in mammalian cardiomyocytes. Hypoxia potentiates the persistent I(Na) that may cause arrhythmias. In the present study, we investigated the effects of n-3 polyunsaturated fatty acids (PUFAs) on I(Na) in HEK-293t cells transfected with an inactivation-deficient mutant (L409C/A410W) of the alpha-subunit (hH1(alpha)) of human cardiac Na(+) channels (hNav1.5) plus beta(1)-subunits. Extracellular application of 5 microM eicosapentaenoic acid (EPA; C20:5n-3) significantly inhibited I(Na). The late portion of I(Na) (I(Na late), measured near the end of each pulse) was almost completely suppressed. I(Na) returned to the pretreated level after washout of EPA. The inhibitory effect of EPA on I(Na) was concentration dependent, with IC(50) values of 4.0 +/- 0.4 microM for I(Na) peak (I(Na peak)) and 0.9 +/- 0.1 microM for I(Na late). EPA shifted the steady-state inactivation of I(Na peak) by -19 mV in the hyperpolarizing direction. EPA accelerated the process of resting inactivation of the mutant channel and delayed the recovery of the mutated Na(+) channel from resting inactivation. Other polyunsaturated fatty acids, docosahexaenoic acid, linolenic acid, arachidonic acid, and linoleic acid, all at 5 microM concentration, also significantly inhibited I(Na). In contrast, the monounsaturated fatty acid oleic acid or the saturated fatty acids stearic acid and palmitic acid at 5 microM concentration had no effect on I(Na). Our data demonstrate that the double mutations at the 409 and 410 sites in the D1-S6 region of hH1(alpha) induce inactivation-deficient I(Na) and that n-3 PUFAs inhibit mutant I(Na).

How batrachotoxin modifies the sodium channel permeation pathway: computer modeling and site-directed mutagenesis.

A structural model of the rNav1.4 Na+ channel with batrachotoxin (BTX) bound within the inner cavity suggested that the BTX pyrrole moiety is located between a lysine residue at the DEKA selectivity filter (Lys1237) and an adjacent phenylalanine residue (Phe1236). We tested this pyrrole-binding model by site-directed mutagenesis of Phe1236 at D3/P-loop with 11 amino acids. Mutants F1236D and F1236E expressed poorly, whereas nine other mutants either expressed robust Na+ currents, like the wild-type (F1236Y/Q/K), or somewhat reduced current (F1236G/A/C/N/W/R). Gating properties were altered modestly in most mutant channels, with F1236G displaying the greatest shift in activation and steady-state fast inactivation (-10.1 and -7.5 mV, respectively). Mutants F1236K and F1236R were severely resistant to BTX after 1000 repetitive pulses (+50 mV/20 ms at 2 Hz), whereas seven other mutants were sensitive but with reduced magnitudes compared with the wild type. It is noteworthy that rNav1.4-F1236K mutant Na+ channels remained highly sensitive to block by the local anesthetic bupivacaine, unlike several other BTX-resistant mutant channels. Our data thus support a model in which BTX, when bound within the inner cavity, interacts with the D3/P-loop directly. Such a direct interaction provides clues on how BTX alters the Na+ channel selectivity and conductance.

Tryptophan substitution of a putative D4S6 gating hinge alters slow inactivation in cardiac sodium channels.

Voltage-gated Na(+) channels display rapid activation gating (opening) as well as fast and slow inactivation gating (closing) during depolarization. We substituted residue S1759 (serine), a putative D4S6 gating hinge of human cardiac hNav1.5 Na(+) channels with A (alanine), D (aspartate), K (lysine), L (leucine), P (proline), and W (tryptophan). Significant shifts in gating parameters for activation and steady-state fast inactivation were observed in A-, D-, K-, and W-substituted mutant Na(+) channels. No gating shifts occurred in the L-substituted mutant, whereas the P-substituted mutant did not yield sufficient Na(+) currents. Wild-type, A-, D-, and L-substituted mutant Na(+) channels showed little or no slow inactivation with a 10-s conditioning pulse ranging from -180 to 0 mV. Unexpectedly, W- and K-substituted mutant Na(+) channels displayed profound maximal slow inactivation around -100 mV ( approximately 85% and approximately 70%, respectively). However, slow inactivation was progressively reversed in magnitude from -70 to 0 mV. This regression was minimized in inactivation-deficient hNav1.5-S1759W/L409C/A410W Na(+) channels, indicating that the intracellular fast-inactivation gate caused such a reversal. Our data suggest that the hNav1.5-S1759 residue plays a critical role in slow inactivation. Possible mechanisms for S1759 involvement in slow inactivation and for antagonism between fast and slow inactivation are discussed.

Block of inactivation-deficient cardiac Na(+) channels by acetyl-KIFMK-amide.

The Na(+) channel alpha-subunit contains an IFM motif that is critical for the fast inactivation process. In this study, we sought to determine whether an IFM-containing peptide, acetyl-KIFMK-amide, blocks open cardiac Na(+) channels via the inner cavity. Intracellular acetyl-KIFMK-amide at 2mM elicited a rapid time-dependent block (tau=0.24 ms) of inactivation-deficient human heart Na(+) channels (hNav1.5-L409C/A410W) at +50 mV. In addition, a peptide-induced tail current appeared conspicuously upon repolarization, suggesting that the activation gate cannot close until acetyl-KIFMK-amide is cleared from the open pore. Repetitive pulses (+50 mV for 20 ms at 1Hz) produced a substantial use-dependent block of both peak and tail currents by approximately 65%. A F1760K mutation (hNav1.5-L409C/A410W/F1760K) abolished the use-dependent block by acetyl-KIFMK-amide and hindered the time-dependent block. Competition experiments showed that acetyl-KIFMK-amide antagonized bupivacaine binding. These results are consistent with a model that two acetyl-KIFMK-amide receptors exist in proximity within the Na(+) channel inner cavity.