State-Dependent Block of Na+ Channels by Articaine Via the Local Anesthetic Receptor

Background Opioids induce analgesia mainly by inhibiting synaptic transmission via G protein-coupled opioid receptors. In addition to analgesia, buprenorphine induces a pronounced antihyperalgesia and is an effective adjuvant to local anesthetics. These properties only partially apply to other opioids, and thus targets other than opioid receptors are likely to be employed. Here we asked if buprenorphine inhibits voltage-gated Na(+) channels. Methods Na(+) currents were examined by whole cell patch clamp recordings on different recombinant Na(+) channel α-subunits. The effect of buprenorphine on unmyelinated mouse C-fibers was examined with the skin-nerve preparation. Data are presented as mean ± SEM. Results Buprenorphine induced a concentration-dependent tonic (IC(50) 33 ± 2 μM) and use-dependent block of endogenous Na(+) channels in ND7/23 cells. This block was state-dependent and displayed slow on and off characteristics. The effect of buprenorphine was reduced on local anesthetic insensitive Nav1.4-mutant constructs and was more pronounced on the inactivation-deficient Nav1.4-WCW mutant. Neuronal (Nav1.3, Nav1.7, and Nav1.8), cardiac (Nav1.5), and skeletal muscle (Nav1.4) α-subunits displayed small differences in tonic block, but similar degrees of use-dependent block. According to our patch clamp data, buprenorphine blocked electrically evoked action potentials in C-fiber nerve terminals. Buprenorphine was more potent than other opioids, including morphine (IC(50) 378 ± 20 μM), fentanyl (IC(50) 95 ± 5 μM), sufentanil (IC(50) 111 ± 6 μM), remifenatil (IC(50) 612 ± 17 μM), and tramadol (IC(50) 194 ± 9 μM). Conclusions Buprenorphine is a potent local anesthetic and blocks voltage-gated Na(+) channels via the local anesthetic binding site. This property is likely to be relevant when buprenorphine is used for pain treatment and for local anesthesia.

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A common local anesthetic receptor for benzocaine and etidocaine in voltage-gated μ1 Na + channels

Pflügers Archiv - European Journal of Physiology ◽

10.1007/s004240050515 ◽

1997 ◽

Vol 435 (2) ◽

pp. 293-302 ◽

Cited By ~ 51

Author(s):

G. K. Wang ◽

C. Quan ◽

S.-Y. Wang

Keyword(s):

Local Anesthetic ◽

Na Channels ◽

Voltage Gated

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State-dependent Block of Wild-type and Inactivation-deficient Na+ Channels by Flecainide

The Journal of General Physiology ◽

10.1085/jgp.200308857 ◽

2003 ◽

Vol 122 (3) ◽

pp. 365-374 ◽

Cited By ~ 34

Author(s):

Ging Kuo Wang ◽

Corinna Russell ◽

Sho-Ya Wang

Keyword(s):

Time Constant ◽

Open Channel ◽

Inhibitory Concentration ◽

Antiarrhythmic Agent ◽

Na Channels ◽

Fast Inactivation ◽

Wild Type ◽

Open Channel Block ◽

State Dependent ◽

Na Currents

The antiarrhythmic agent flecainide appears beneficial for painful congenital myotonia and LQT-3/ΔKPQ syndrome. Both diseases manifest small but persistent late Na+ currents in skeletal or cardiac myocytes. Flecainide may therefore block late Na+ currents for its efficacy. To investigate this possibility, we characterized state-dependent block of flecainide in wild-type and inactivation-deficient rNav1.4 muscle Na+ channels (L435W/L437C/A438W) expressed with β1 subunits in Hek293t cells. The flecainide-resting block at −140 mV was weak for wild-type Na+ channels, with an estimated 50% inhibitory concentration (IC50) of 365 μM when the cell was not stimulated for 1,000 s. At 100 μM flecainide, brief monitoring pulses of +30 mV applied at frequencies as low as 1 per 60 s, however, produced an ∼70% use-dependent block of peak Na+ currents. Recovery from this use-dependent block followed an exponential function, with a time constant over 225 s at −140 mV. Inactivated wild-type Na+ channels interacted with flecainide also slowly at −50 mV, with a time constant of 7.9 s. In contrast, flecainide blocked the open state of inactivation-deficient Na+ channels potently as revealed by its rapid time-dependent block of late Na+ currents. The IC50 for flecainide open-channel block at +30 mV was 0.61 μM, right within the therapeutic plasma concentration range; on-rate and off-rate constants were 14.9 μM−1s−1 and 12.2 s−1, respectively. Upon repolarization to −140 mV, flecainide block of inactivation-deficient Na+ channels recovered, with a time constant of 11.2 s, which was ∼20-fold faster than that of wild-type counterparts. We conclude that flecainide directly blocks persistent late Na+ currents with a high affinity. The fast-inactivation gate, probably via its S6 docking site, may further stabilize the flecainide-receptor complex in wild-type Na+ channels.

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Block of Human Heart hH1 Sodium Channels by the Enantiomers of Bupivacaine

Anesthesiology ◽

10.1097/00000542-200010000-00026 ◽

2000 ◽

Vol 93 (4) ◽

pp. 1022-1033 ◽

Cited By ~ 48

Author(s):

Carla Nau ◽

Sho-Ya Wang ◽

Gary R. Strichartz ◽

Ging Kuo Wang

Keyword(s):

Human Heart ◽

Point Mutations ◽

Cell Voltage ◽

Site Directed Mutagenesis ◽

Na Channel ◽

Amino Acid Residues ◽

Na Channels ◽

State Dependent ◽

Positively Charged

Background S(-)-bupivacaine reportedly exhibits lower cardiotoxicity but similar local anesthetic potency compared with R(+)-bupivacaine. The bupivacaine binding site in human heart (hH1) Na+ channels has not been studied to date. The authors investigated the interaction of bupivacaine enantiomers with hH1 Na+ channels, assessed the contribution of putatively relevant residues to binding, and compared the intrinsic affinities to another isoform, the rat skeletal muscle (mu1) Na+ channel. Methods Human heart and mu1 Na+ channel alpha subunits were transiently expressed in HEK293t cells and investigated during whole cell voltage-clamp conditions. Using site-directed mutagenesis, the authors created point mutations at positions hH1-F1760, hH1-N1765, hH1-Y1767, and hH1-N406 by introducing the positively charged lysine (K) or the negatively charged aspartic acid (D) and studied their influence on state-dependent block by bupivacaine enantiomers. Results Inactivated hH1 Na+ channels displayed a weak stereoselectivity with a stereopotency ratio (+/-) of 1.5. In mutations hH1-F1760K and hH1-N1765K, bupivacaine affinity of inactivated channels was reduced by approximately 20- to 40-fold, in mutation hH1-N406K by approximately sevenfold, and in mutations hH1-Y1767K and hH1-Y1767D by approximately twofold to threefold. Changes in recovery of inactivated mutant channels from block paralleled those of inactivated channel affinity. Inactivated hH1 Na+ channels exhibited a slightly higher intrinsic affinity than mu1 Na+ channels. Conclusions Differences in bupivacaine stereoselectivity and intrinsic affinity between hH1 and mu1 Na+ channels are small and most likely of minor clinical relevance. Amino acid residues in positions hH1-F1760, hH1-N1765, and hH1-N406 may contribute to binding of bupivacaine enantiomers in hH1 Na+ channels, whereas the role of hH1-Y1767 remains unclear.

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Local Anesthetic Block of Batrachotoxin-Resistant Muscle Na+ Channels

Molecular Pharmacology ◽

10.1124/mol.54.2.389 ◽

1998 ◽

Vol 54 (2) ◽

pp. 389-396 ◽

Cited By ~ 27

Author(s):

Ging Kuo Wang ◽

Catherine Quan ◽

Sho-Ya Wang

Keyword(s):

Local Anesthetic ◽

Na Channels

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Local Anesthetics Disrupt Energetic Coupling between the Voltage-sensing Segments of a Sodium Channel

The Journal of General Physiology ◽

10.1085/jgp.200810103 ◽

2008 ◽

Vol 133 (1) ◽

pp. 1-15 ◽

Cited By ~ 48

Author(s):

Yukiko Muroi ◽

Baron Chanda

Keyword(s):

Sodium Channel ◽

Local Anesthetic ◽

Local Anesthetics ◽

Quantitative Description ◽

Single Mutation ◽

Voltage Sensing ◽

State Behavior ◽

Fluorescence Measurements ◽

State Dependent ◽

Domain Iii

Local anesthetics block sodium channels in a state-dependent fashion, binding with higher affinity to open and/or inactivated states. Gating current measurements show that local anesthetics immobilize a fraction of the gating charge, suggesting that the movement of voltage sensors is modified when a local anesthetic binds to the pore of the sodium channel. Here, using voltage clamp fluorescence measurements, we provide a quantitative description of the effect of local anesthetics on the steady-state behavior of the voltage-sensing segments of a sodium channel. Lidocaine and QX-314 shifted the midpoints of the fluorescence–voltage (F-V) curves of S4 domain III in the hyperpolarizing direction by 57 and 65 mV, respectively. A single mutation in the S6 of domain IV (F1579A), a site critical for local anesthetic block, abolished the effect of QX-314 on the voltage sensor of domain III. Both local anesthetics modestly shifted the F-V relationships of S4 domain IV toward hyperpolarized potentials. In contrast, the F-V curve of the S4 domain I was shifted by 11 mV in the depolarizing direction upon QX-314 binding. These antagonistic effects of the local anesthetic indicate that the drug modifies the coupling between the voltage-sensing domains of the sodium channel. Our findings suggest a novel role of local anesthetics in modulating the gating apparatus of the sodium channel.

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Inhibition of Nav1.7 and Nav1.4 Sodium Channels by Trifluoperazine Involves the Local Anesthetic Receptor

Journal of Neurophysiology ◽

10.1152/jn.00354.2006 ◽

2006 ◽

Vol 96 (4) ◽

pp. 1848-1859 ◽

Cited By ~ 13

Author(s):

Patrick L. Sheets ◽

Peter Gerner ◽

Chi-Fei Wang ◽

Sho-Ya Wang ◽

Ging Kuo Wang ◽

...

Keyword(s):

Sodium Channels ◽

Local Anesthetic ◽

Receptor Site ◽

Inhibitory Peptide ◽

Sensory Blockade ◽

Voltage Gated Sodium Channels ◽

State Dependent ◽

Steady State Inactivation ◽

Channel Interactions

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 Nav1.7 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 μM TFP induce major decreases in Nav1.7 and Nav1.4 current amplitudes and that 2 μM TFP causes hyperpolarizing shifts in the steady-state inactivation of Nav1.7 and Nav1.4. 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 Nav1.7 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.

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