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Slow inactivation does not affect movement of the fast inactivation gate in voltage-gated Na+ channels.
Vedantham V
,
Cannon SC
.
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Voltage-gated Na+ channels exhibit two forms of inactivation, one form (fast inactivation) takes effect on the order of milliseconds and the other (slow inactivation) on the order of seconds to minutes. While previous studies have suggested that fast and slow inactivation are structurally independent gating processes, little is known about the relationship between the two. In this study, we probed this relationship by examining the effects of slow inactivation on a conformational marker for fast inactivation, the accessibility of a site on the Na+ channel III-IV linker that is believed to form a part of the fast inactivation particle. When cysteine was substituted for phenylalanine at position 1304 in the rat skeletal muscle sodium channel (microl), application of [2-(trimethylammonium)ethyl]methanethiosulfonate (MTS-ET) to the cytoplasmic face of inside-out patches from Xenopus oocytes injected with F1304C RNA dramatically disrupted fast inactivation and displayed voltage-dependent reaction kinetics that closely paralleled the steady state availability (hinfinity) curve. Based on this observation, the accessibility of cys1304 was used as a conformational marker to probe the position of the fast inactivation gate during the development of and the recovery from slow inactivation. We found that burial of cys1304 is not altered by the onset of slow inactivation, and that recovery of accessibility of cys1304 is not slowed after long (2-10 s) depolarizations. These results suggest that (a) fast and slow inactivation are structurally distinct processes that are not tightly coupled, (b) fast and slow inactivation are not mutually exclusive processes (i.e., sodium channels may be fast- and slow-inactivated simultaneously), and (c) after long depolarizations, recovery from fast inactivation precedes recovery from slow inactivation.
Figure 2. MTS-ET disrupts fast inactivation of F1304C. (A) Selected current traces evoked by depolarization to â20 mV from â120 mV after successive 50-ms exposures to 4 μM MTS-ET are superimposed over a final trace measured after an additional 4 s of exposure (average of two individual records) and a control trace measured before any MTS-ET exposure (average of 10 individual records). MTS-ET application to the cytoplasmic face was accomplished by computer-controlled rapid solution switching (see materials and methods) from bath solution into 4 μM MTS-ET-containing bath solution. In this case, the peak current increased from â129 pA before exposure to â208 pA after the modification reached completion, and the persistent current (measured as the average current between 40 and 42 ms divided by the peak current) increased from 6.1% before exposure to 65.5% after the modification reached completion. (B) After each experiment, the kinetics of solution exchange was evaluated by switching the patch into a solution containing a sodium concentration equal to the pipette solution. The switching was timed to occur for 20 ms at the beginning of a depolarization to 0 from â120 mV. For this patch, there was a 7.4-ms delay from the time of the switching command before the current began to decay, and a monoexponential fit to the current decay gave a time constant for solution exchange of 1.7 ms. (C) The value of the fractional persistent current after each exposure is plotted against the cumulative exposure time. The curve was fit with a monoexponential approaching unity that had nonzero pedestal (solid line): F = (1 â Fo)(1 â exp[âtexp/Ïmod]) + Fo, where Ïmod is the reciprocal of the reaction rate and was 0.279 s (corresponding to a rate of 0.895 μmolâ1 sâ1), and Fo is the value of the fractional persistent current before modification (0.059).
Figure 3. Doseâresponse curve. Reaction rates for MTS-ET modification of F1304C are shown as a function of MTS-ET concentration used. All exposures were carried out at â120 mV and were either 50 (1 μM, n = 3; 2 μM, n = 6; and 4 μM, n = 10) or 25 (8 μM, n = 5) ms in duration. Rates were determined as described in Fig. 2. The doseâresponse curve was fit to an unweighted linear regression constrained to pass through the origin, giving a slope of 1.03 μmolâ1 sâ1.
Figure 4. Voltage dependence of F1304C accessibility. (A) The protocol for measuring the accessibility of site 1304 as a function of voltage is shown. 200-ms prepulses were used at each voltage, followed by 50 ms of exposure to 4 μM MTS-ET, and an additional 100 ms at the prepulse voltage to prevent unwanted exposure after repolarization. The time between the prepulse and the test pulse ranged from 3.5 to 18 s, according to the necessary recovery time at â100 mV after 350 ms at the prepulse voltage. Degree of modification was assessed with a 45-ms test pulse to â20 mV. (B) Reaction rates were determined as described in Fig. 2 and are plotted against the voltage at which the exposure occurred (average of n = 6 per voltage; all points at least n = 3). The curve was fit to a Boltzmann (solid line) with a nonzero pedestal: R(V) = (Rmax â Rmin)/{1 + exp [(V - V1/2)/k]} + Rmin, where Rmax is the maximum rate (0.932 μmolâ1 sâ1), Rmin is the minimum rate (0.208 μmolâ1 sâ1), V1/2 is the voltage at half-maximal rate (â85.1 mV), and k is the slope factor (6.4). For comparison, the measured hâ⢠curve for F1304C (dotted line) is superimposed scaled to Rmax and Rmin (V1/2 = â81.6 ± 1.3 mV and k = 5.5 ± 0.5).
Figure 5. Recovery from inactivation. The two-pulse protocol (top) was used to assess recovery from inactivation in F1304C in response to varying length conditioning pulses. The time axis is displayed logarithmically because recovery rates vary over several orders of magnitude. Symbols indicate means ± SEM (n = 5â7 for each curve). Using this data, experimental protocols (diagrammed in Fig. 6 A) were designed to measure the accessibility of cys1304 when channels are slow inactivated. The shaded area indicates the duration of MTS-ET exposure during the protocol shown in Fig. 6 A (bottom).
Figure 6. Accessibility of site 1304 recovers rapidly for fast- and slow-inactivated channels. (A) Two protocols were used to measure accessibility of site 1304 in response to variable length conditioning pulses to 0 mV from a holding potential of â120 mV. In the experiment shown on top, the MTS-ET exposure was placed near the end of the conditioning pulse to verify that site 1304 remains buried during long depolarizations and to determine how quickly it becomes buried for short depolarizations. Depolarization was maintained throughout the exposure and shortly after. (Tpre = 0.007, 0.2, 2.0, or 10.0 s; MTS-ET exposure was 20 or 50 ms; [MTS-ET] = 4 or 8 μM; n = 3 for all). In the bottom protocol, the exposure was placed 5 ms after repolarization: 4 μM, 50 ms (average n = 5 per Tcond, except Tcond = 10 s) or 8 μM, 20 ms (average n = 8 per Tcond, all points at least n = 4). The total time between the end of the conditioning pulse and the beginning of the exposure includes a short delay due to lag of the switching apparatus, which we measured as described above (Fig. 2) to be 7.1 ± 0.1 ms, giving a preexposure recovery time of 12.1 ± 0.1 ms. Therefore, for the 20-ms case, exposure occurred from 12.1 to 32.1 ms after repolarization (depicted as the shaded area in the graph in Fig. 5). For both protocols, enough time after the conditioning pulse was allowed for complete recovery (from 5 s for Tcond = 0.02 s to 45 s for Tcond = 10 s) before the 45-ms test pulse was administered. (B) Reaction rates were determined as described above (Fig. 2) for the two protocols described in A. Dotted lines indicate Rmax (0.932 μmolâ1 sâ1) and Rmin (0.208 μmolâ1 sâ1). The reaction rates for the first protocol, in which the exposures occurred during the conditioning pulse (â) were slow, consistent with site 1304 burial. For the experiments in which the exposure occurred shortly after the end of the conditioning pulse (â¢), the measured rate was consistent with nearly complete accessibility (experiments without any conditioning pulse are shown for comparison as Tcond = 0). This result suggests that the fast inactivation gate recovers rapidly despite the fact that >90% of the channels remain slow inactivated.
Adelman,
The effects of external potassium and long duration voltage conditioning on the amplitude of sodium currents in the giant axon of the squid, Loligo pealei.
1969, Pubmed
Adelman,
The effects of external potassium and long duration voltage conditioning on the amplitude of sodium currents in the giant axon of the squid, Loligo pealei.
1969,
Pubmed
Almers,
Slow changes in currents through sodium channels in frog muscle membrane.
1983,
Pubmed
Armstrong,
Inactivation of the sodium channel. II. Gating current experiments.
1977,
Pubmed
Baukrowitz,
Modulation of K+ current by frequency and external [K+]: a tale of two inactivation mechanisms.
1995,
Pubmed
Bezanilla,
Distribution and kinetics of membrane dielectric polarization. 1. Long-term inactivation of gating currents.
1982,
Pubmed
Cannon,
Slow inactivation of sodium channels: more than just a laboratory curiosity.
1996,
Pubmed
Chen,
Modulation of Na+ channel inactivation by the beta 1 subunit: a deletion analysis.
1995,
Pubmed
,
Xenbase
Cummins,
Impaired slow inactivation in mutant sodium channels.
1996,
Pubmed
Featherstone,
Interaction between fast and slow inactivation in Skm1 sodium channels.
1996,
Pubmed
,
Xenbase
Gonoi,
Gating of Na channels. Inactivation modifiers discriminate among models.
1987,
Pubmed
Hayward,
Slow inactivation differs among mutant Na channels associated with myotonia and periodic paralysis.
1997,
Pubmed
Hayward,
Inactivation defects caused by myotonia-associated mutations in the sodium channel III-IV linker.
1996,
Pubmed
HODGKIN,
The dual effect of membrane potential on sodium conductance in the giant axon of Loligo.
1952,
Pubmed
HODGKIN,
A quantitative description of membrane current and its application to conduction and excitation in nerve.
1952,
Pubmed
Kellenberger,
Movement of the Na+ channel inactivation gate during inactivation.
1996,
Pubmed
,
Xenbase
Kellenberger,
Molecular analysis of the putative inactivation particle in the inactivation gate of brain type IIA Na+ channels.
1997,
Pubmed
Kuo,
Na+ channels must deactivate to recover from inactivation.
1994,
Pubmed
Larsson,
Transmembrane movement of the shaker K+ channel S4.
1996,
Pubmed
,
Xenbase
Liman,
Subunit stoichiometry of a mammalian K+ channel determined by construction of multimeric cDNAs.
1992,
Pubmed
,
Xenbase
Liu,
Dynamic rearrangement of the outer mouth of a K+ channel during gating.
1996,
Pubmed
McClatchey,
The cloning and expression of a sodium channel beta 1-subunit cDNA from human brain.
1993,
Pubmed
,
Xenbase
Meves,
Slow recovery of sodium current and 'gating current' from inactivation.
1977,
Pubmed
NARASHASHI,
RESTORATION OF ACTION POTENTIAL BY ANODAL POLARIZATION IN LOBSTER GIANT AXONS.
1964,
Pubmed
Quandt,
Burst kinetics of sodium channels which lack fast inactivation in mouse neuroblastoma cells.
1987,
Pubmed
Rojas,
Sodium conductance activation without inactivation in pronase-perfused axons.
1971,
Pubmed
Ruben,
Steady-state availability of sodium channels. Interactions between activation and slow inactivation.
1992,
Pubmed
Rudy,
Slow inactivation of the sodium conductance in squid giant axons. Pronase resistance.
1978,
Pubmed
Simoncini,
Slow sodium channel inactivation in rat fast-twitch muscle.
1987,
Pubmed
Stühmer,
Structural parts involved in activation and inactivation of the sodium channel.
1989,
Pubmed
,
Xenbase
Townsend,
Effect of alkali metal cations on slow inactivation of cardiac Na+ channels.
1997,
Pubmed
,
Xenbase
Vassilev,
Identification of an intracellular peptide segment involved in sodium channel inactivation.
1988,
Pubmed
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,
Evidence for voltage-dependent S4 movement in sodium channels.
1995,
Pubmed
Yang,
Molecular basis of charge movement in voltage-gated sodium channels.
1996,
Pubmed
