S.-Y. Wang scite author profile

Slow inactivation occurs in voltage-gated Na+ channels when the membrane is depolarized for several seconds, whereas fast inactivation takes place rapidly within a few milliseconds. Unlike fast inactivation, the molecular entity that governs the slow inactivation of Na+ channels has not been as well defined. Some regions of Na+ channels, such as mu1-W402C and mu1-T698M, have been reported to affect slow inactivation. A mutation in segment I-S6 of mu1 Na+ channels, N434A, shifts the voltage dependence of activation and fast inactivation toward the depolarizing direction. The mutant Na+ current at +50 mV is diminished by 60-80% during repetitive stimulation at 5 Hz, resulting in a profound use-dependent phenomenon. This mutant phenotype is due to the enhancement of slow inactivation, which develops faster than that of wild-type channels (tau = 0.46 +/- 0.01 s versus 2.11 +/- 0.10 s at +30 mV, n = 9). An oxidant, chloramine-T, abolishes fast inactivation and yet greatly accelerates slow inactivation in both mutant and wild-type channels (tau = 0.21 +/- 0.02 s and 0.67 +/- 0.05 s, respectively, n = 6). These findings together demonstrate that N434 of mu1 Na+ channels is also critical for slow inactivation. We propose that this slow form of Na+ channel inactivation is analogous to the "C-type" inactivation in Shaker K+ channels.

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Differences in steady-state inactivation between Na channel isoforms affect local anesthetic binding affinity

Wright

Wang

Kallen

et al. 1997

Biophysical Journal

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Cocaine and lidocaine are local anesthetics (LAs) that block Na currents in excitable tissues. Cocaine is also a cardiotoxic agent and can induce cardiac arrhythmia and ventricular fibrillation. Lidocaine is commonly used as a postinfarction antiarrhythmic agent. These LAs exert clinically relevant effects at concentrations that do not obviously affect the normal function of either nerve or skeletal muscle. We compared the cocaine and lidocaine affinities of human cardiac (hH1) and rat skeletal (mu 1) muscle Na channels that were transiently expressed in HEK 293t cells. The affinities of resting mu 1 and hH1 channels were similar for cocaine (269 and 235 microM, respectively) and for lidocaine (491 and 440 microM, respectively). In addition, the affinities of inactivated mu 1 and hH1 channels were also similar for cocaine (12 and 10 microM, respectively) and for lidocaine (19 and 12 microM, respectively). In contrast to previous studies, our results indicate that the greater sensitivity of cardiac tissue to cocaine or lidocaine is not due to a higher affinity of the LA receptor in cardiac Na channels, but that at physiological resting potentials (-100 to -90 mV), a greater percentage of hH1 channels than mu 1 channels are in the inactivated (i.e., high-affinity) state.

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S.-Y. Wang

A mutation in segment I-S6 alters slow inactivation of sodium channels

Differences in steady-state inactivation between Na channel isoforms affect local anesthetic binding affinity

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