Xiong W , Li RA , Tian Y , Tomaselli GF .

R01 HL052768-10 NHLBI NIH HHS , R01 HL50411 NHLBI NIH HHS , R01 HL050411 NHLBI NIH HHS

           BRUGADA SYNDROME 1; BRGDA1

	Figure 1. . Schematic depiction of the Na channel α subunit. It consists of four domains, each of which has six transmembrane segments. The S4 segments represent at least part of the voltage sensor. The segments between S5 and S6 (P-segments) line the outer pore. The outer ring of negative charge (E403, E758, D1241, and D1532) is illustrated in filled circles. The open circles represent the putative selectivity filter residues (D400, E755, K1237, and A1529). The domain III-IV linker underlies fast inactivation. The 13 double cysteine mutants studied are shown below the schematic. E403C, E758C, and D1241C (enclosed in the boxes) were paired with other cysteine mutants in different domains of the outer pore.
	Figure 2. . Evidence for disulfide bonding of residues in the outer ring of charge. (A) Representative traces show that current through E403C+E758C mutant Na channels increased more than twofold in magnitude in the presence of 1mM DTT. (B) The current-voltage relationship shows a similar increase in peak current amplitude of the double mutant by exposure to DTT over the entire voltage range (P < 0.01, n = 8). Peak currents measured at each voltage step were normalized to the maximum current observed in each cell, averaged and plotted as a function of voltage. (C) A plot of the time course of the decrease in peak current amplitude upon exposure to 100 μM Cu(phe)3. The effects of Cu(phe)3 were not reversed during washout. The inset shows currents recorded at time (a) and (b). (D) A plot of the peak Na current amplitude during application of Cu(phe)3, washout, and subsequent treatment with 1 mM DTT.
	Figure 3. . Rate-dependent modification by Cu(phe)3 in paired mutant channels. (A) Rate-dependent modification by Cu(phe)3 of E403C+E758C mutant channels. Increasing stimulation frequency (from 0.033 Hz to 1 Hz) enhanced the rate of current reduction of E403C+E758C, suggesting rate-dependent modification of Cu(phe)3 in E403C+E758C mutant channels. The inset shows representative currents at 2 min (a) and 12.5 min at stimulation frequencies of 1 Hz (b) and 0.033 Hz (c) after the application of Cu(phe)3. (B) In contrast, current reduction was rapid and not dependent on stimulation frequency in the E403C+W1239C mutant channels. (C) Plots of the rates of reduction in peak current amplitude at different stimulation frequencies in the presence of Cu(phe)3 (n = 2–7). Single exponential fits of the form y = Ae(−t/τ) to plots like those shown in A and B were used to determine the time constants, τ. A is the amplitude. The top panel shows the time constants of current decay of mutant channels that were significantly increased at slower stimulation frequencies. The bottom panel is a plot of the time constants of double mutant channels that did not exhibit stimulation frequency dependent rates of modification. (*P < 0.05, **P < 0.01).
	Figure 4. . Slow inactivation prevented the modification of E403C+ E758C, but not E403C+W1531C mutant channels by Cu(phe)3. (A). Slow inactivation was induced by holding the cells at −20 mV for 15 min with brief repolarizations to −100 mV for 10 ms to elicit currents after recovery from fast inactivation. The mean data shows that channels entered slow-inactivated states at approximately the same rate regardless the presence (filled circles) or absence (open circles) of Cu(phe)3. (B) Upon washout, Na currents nearly completely recovered from slow inactivation induced by the voltage protocol used in A independent of prior exposure to Cu(phe)3 (P > 0.05, n = 6). The inset shows representative currents before (a) and 60 s after initiation of recovery (b) with (filled circle) or without (open circle) prior exposure to Cu(phe)3. (C) A complementary voltage protocol was employed to induce slow inactivation before application of Cu(phe)3. Channels were held at −20 mV and pulsed for 50 ms to 0 mV at 1 Hz for 30 min. After 15 min of pulsing, Cu(phe)3 (100 μM) was applied for 15 min before washout. The oocytes were voltage clamped at −20 mV during the 4 min washout, then they were stimulated at 1 Hz from a holding potential of −100 to −20 mV to elicit Na currents. The Na currents completely recovered from slow inactivation compared with control (P > 0.05) (B). (D) After washout of Cu(phe)3, Na currents in E403C+W1531C mutant channels did not significantly recover from slow inactivation induced by the voltage protocol used in A (P < 0.05, n = 3). E403C+W1239C mutant channels were also subjected to modification by Cu(phe)3 and recovered incompletely (P < 0.05, n = 3).
	Figure 5. . A bar plot of the percent recovery from slow inactivation elicited by the voltage protocol in Fig. 4 A. The percent recoveries of E403C+E758C, E403C+K1240C, E403C+D1241C, and E403C+D1532C channels were not significantly changed in the presence of Cu(phe)3 (P > 0.05, n = 3–6). Significant Cu(phe)3-induced modification of the other paired mutants occurred during induction of slow inactivation (P < 0.05, n = 3–4).
	Figure 6. . A schematic model showing how gating influences the rate and extent of disulfide bond formation of double mutants in the external pore of the Na channel. In the case of E403C+E758C, enhanced rates of current reduction with higher stimulation frequencies suggest that the activated or fast inactivated states are modified more readily than the rested state. In contrast, double mutant channels such as E403C+W1531C (Fig. 3 C) are rapidly modified at both slow and fast stimulation rates, suggesting that the rested state may be accessible to modification by Cu(phe)3. Slow inactivation protects E403C+E758C channels (and E403C+D1241C and E403C+D1532C in the outer ring of charge) but not E403C+W1531C from Cu(phe)3-induced modification. The results are consistent with a change in the conformation of the outer ring of charge during slow inactivation of Na channels.

Alekov, Enhanced inactivation and acceleration of activation of the sodium channel associated with epilepsy in man. 2001, Pubmed

Alekov, Enhanced inactivation and acceleration of activation of the sodium channel associated with epilepsy in man. 2001, Pubmed
Armstrong, Sodium channels and gating currents. 1981, Pubmed
Balser, External pore residue mediates slow inactivation in mu 1 rat skeletal muscle sodium channels. 1996, Pubmed , Xenbase
Baukrowitz, Modulation of K+ current by frequency and external [K+]: a tale of two inactivation mechanisms. 1995, Pubmed
Bell, Effects of phospholipid surface charge on ion conduction in the K+ channel of sarcoplasmic reticulum. 1984, Pubmed
Bendahhou, Impairment of slow inactivation as a common mechanism for periodic paralysis in DIIS4-S5. 2002, Pubmed
Bendahhou, Activation and inactivation of the voltage-gated sodium channel: role of segment S5 revealed by a novel hyperkalaemic periodic paralysis mutation. 1999, Pubmed
Bénitah, Adjacent pore-lining residues within sodium channels identified by paired cysteine mutagenesis. 1996, Pubmed , Xenbase
Bénitah, Molecular motions within the pore of voltage-dependent sodium channels. 1997, Pubmed , Xenbase
Bénitah, Molecular dynamics of the sodium channel pore vary with gating: interactions between P-segment motions and inactivation. 1999, Pubmed , Xenbase
Careaga, Thermal motions of surface alpha-helices in the D-galactose chemosensory receptor. Detection by disulfide trapping. 1992, Pubmed
Cha, Voltage sensors in domains III and IV, but not I and II, are immobilized by Na+ channel fast inactivation. 1999, Pubmed , Xenbase
Chiamvimonvat, Depth asymmetries of the pore-lining segments of the Na+ channel revealed by cysteine mutagenesis. 1996, Pubmed , Xenbase
Choi, Tetraethylammonium blockade distinguishes two inactivation mechanisms in voltage-activated K+ channels. 1991, Pubmed
Cummins, Impaired slow inactivation in mutant sodium channels. 1996, Pubmed
Featherstone, Interaction between fast and slow inactivation in Skm1 sodium channels. 1996, Pubmed , Xenbase
Fleidervish, Slow inactivation of Na+ current and slow cumulative spike adaptation in mouse and guinea-pig neocortical neurones in slices. 1996, Pubmed
Green, Batrachotoxin-modified sodium channels in planar lipid bilayers. Ion permeation and block. 1987, Pubmed
Hayward, Slow inactivation differs among mutant Na channels associated with myotonia and periodic paralysis. 1997, Pubmed
Hayward, Defective slow inactivation of sodium channels contributes to familial periodic paralysis. 1999, Pubmed
Heinemann, Calcium channel characteristics conferred on the sodium channel by single mutations. 1992, Pubmed , Xenbase
Hilber, Interaction between fast and ultra-slow inactivation in the voltage-gated sodium channel. Does the inactivation gate stabilize the channel structure? 2002, Pubmed , Xenbase
Hilber, The selectivity filter of the voltage-gated sodium channel is involved in channel activation. 2001, Pubmed , Xenbase
Hirschberg, Transfer of twelve charges is needed to open skeletal muscle Na+ channels. 1995, Pubmed , Xenbase
Hoshi, Two types of inactivation in Shaker K+ channels: effects of alterations in the carboxy-terminal region. 1991, Pubmed , Xenbase
Hoshi, Biophysical and molecular mechanisms of Shaker potassium channel inactivation. 1990, Pubmed , Xenbase
Isom, Primary structure and functional expression of the beta 1 subunit of the rat brain sodium channel. 1992, Pubmed , Xenbase
Jiang, X-ray structure of a voltage-dependent K+ channel. 2003, Pubmed
Kambouris, Mechanistic link between lidocaine block and inactivation probed by outer pore mutations in the rat micro1 skeletal muscle sodium channel. 1998, Pubmed , Xenbase
Kontis, Sodium channel inactivation is altered by substitution of voltage sensor positive charges. 1997, Pubmed , Xenbase
Kontis, Sodium channel activation gating is affected by substitutions of voltage sensor positive charges in all four domains. 1997, Pubmed , Xenbase
Krieg, Functional messenger RNAs are produced by SP6 in vitro transcription of cloned cDNAs. 1984, Pubmed , Xenbase
Kunkel, Rapid and efficient site-specific mutagenesis without phenotypic selection. 1985, Pubmed
Liu, Dynamic rearrangement of the outer mouth of a K+ channel during gating. 1996, Pubmed
López-Barneo, Effects of external cations and mutations in the pore region on C-type inactivation of Shaker potassium channels. 1993, Pubmed , Xenbase
Mitrovic, Role of domain 4 in sodium channel slow inactivation. 2000, Pubmed
Nuss, Coupling between fast and slow inactivation revealed by analysis of a point mutation (F1304Q) in mu 1 rat skeletal muscle sodium channels. 1996, Pubmed , Xenbase
Ong, A structural rearrangement in the sodium channel pore linked to slow inactivation and use dependence. 2000, Pubmed
Pardo, Extracellular K+ specifically modulates a rat brain K+ channel. 1992, Pubmed , Xenbase
Patton, Amino acid residues required for fast Na(+)-channel inactivation: charge neutralizations and deletions in the III-IV linker. 1992, Pubmed
Pérez-García, Structure of the sodium channel pore revealed by serial cysteine mutagenesis. 1996, Pubmed , Xenbase
Richmond, Slow inactivation in human cardiac sodium channels. 1998, Pubmed , Xenbase
Ruff, Slow sodium channel inactivation in mammalian muscle: a possible role in regulating excitability. 1988, Pubmed
Simoncini, Slow sodium channel inactivation in rat fast-twitch muscle. 1987, Pubmed
Spampanato, Functional effects of two voltage-gated sodium channel mutations that cause generalized epilepsy with febrile seizures plus type 2. 2001, Pubmed , Xenbase
Struyk, Slow inactivation does not block the aqueous accessibility to the outer pore of voltage-gated Na channels. 2002, Pubmed , Xenbase
Stühmer, Structural parts involved in activation and inactivation of the sodium channel. 1989, Pubmed , Xenbase
Todt, Ultra-slow inactivation in mu1 Na+ channels is produced by a structural rearrangement of the outer vestibule. 1999, Pubmed , Xenbase
Tomaselli, A mutation in the pore of the sodium channel alters gating. 1995, Pubmed , Xenbase
Townsend, Effect of alkali metal cations on slow inactivation of cardiac Na+ channels. 1997, Pubmed , Xenbase
Trimmer, Primary structure and functional expression of a mammalian skeletal muscle sodium channel. 1989, Pubmed , Xenbase
Tsushima, Altered ionic selectivity of the sodium channel revealed by cysteine mutations within the pore. 1997, Pubmed , Xenbase
Vassilev, Inhibition of inactivation of single sodium channels by a site-directed antibody. 1989, Pubmed
Veldkamp, Two distinct congenital arrhythmias evoked by a multidysfunctional Na(+) channel. 2000, Pubmed
Vilin, A single residue differentiates between human cardiac and skeletal muscle Na+ channel slow inactivation. 2001, Pubmed , Xenbase
Wang, A mutation in segment I-S6 alters slow inactivation of sodium channels. 1997, Pubmed
West, A cluster of hydrophobic amino acid residues required for fast Na(+)-channel inactivation. 1992, Pubmed , Xenbase
Yang, Molecular basis of charge movement in voltage-gated sodium channels. 1996, Pubmed
Yang, Evidence for voltage-dependent S4 movement in sodium channels. 1995, Pubmed
Zhang, A negatively charged residue in the outer mouth of rat sodium channel determines the gating kinetics of the channel. 2003, Pubmed