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Original Article

State-Dependent Inactivation of the 1g T-Type Calcium Channel

^a From the Department of Physiology and Biophysics, Case Western Reserve University, Cleveland, Ohio 44106
^b Department of Physiology, Loyola University Medical Center, Maywood, Illinois 60153
Department of Physiology and Biophysics, Case Western Reserve University, Cleveland, OH 44106.Fax: 216-368-3952;

swj{at}po.cwru.edu

	ABSTRACT

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We have examined the kinetics of whole-cell T-current in HEK 293 cells stably expressing the 1G channel, with symmetrical Na⁺_i and Na⁺_o and 2 mM Ca²⁺_o. After brief strong depolarization to activate the channels (2 ms at +60 mV; holding potential –100 mV), currents relaxed exponentially at all voltages. The time constant of the relaxation was exponentially voltage dependent from –120 to –70 mV , but . This suggests a mixture of voltage-dependent deactivation (dominating at very negative voltages) and nearly voltage-independent inactivation. Inactivation measured by test pulses following that protocol was consistent with open-state inactivation. During depolarizations lasting 100–300 ms, inactivation was strong but incomplete (98%). Inactivation was also produced by long, weak depolarizations , which could not be explained by voltage-independent inactivation exclusively from the open state. Recovery from inactivation was exponential and fast , but weakly voltage dependent. Recovery was similar after 60-ms steps to –20 mV or 600-ms steps to –70 mV, suggesting rapid equilibration of open- and closed-state inactivation. There was little current at –100 mV during recovery from inactivation, consistent with 8% of the channels recovering through the open state. The results are well described by a kinetic model where inactivation is allosterically coupled to the movement of the first three voltage sensors to activate. One consequence of state-dependent inactivation is that 1G channels continue to inactivate after repolarization, primarily from the open state, which leads to cumulative inactivation during repetitive pulses.

Key Words: T-channel • cumulative inactivation • recovery from inactivation

	Introduction

Top ABSTRACT Introduction Materials and Methods results Discussion REFERENCES

 
Voltage-dependent Ca²⁺ channels provide a pathway for rapid influx of Ca²⁺ into cells, which plays a crucial role in both electrical and metabolic signaling. Electrophysiological studies have identified two primary channel types, high voltage-activated (HVA)¹ and low voltage-activated (LVA, or T-type) channels (Bean 1989). Beginning in 1987, the cloning of several HVA channels allowed detailed study of their properties (Catterall 1996), but the molecular basis of T-channels proved more elusive. The recent cloning of 1G, which exhibits the key functional properties of T-channels when expressed in Xenopus oocytes (Perez-Reyes et al. 1998), was an important step toward understanding the biology of T-channels.

T-Channels have been distinguished from HVA channels by a set of biophysical properties, including a more negative voltage range for both activation and inactivation, rapid and nearly complete inactivation, and relatively slow channel closing upon repolarization (deactivation) (Carbone and Lux 1984; Armstrong and Matteson 1985; Fox et al. 1987). T-channels also have a lower single channel conductance in isotonic Ba²⁺, and differ from most HVA channels in selectivity among divalent cations for permeation and block (Bean 1985; Nilius et al. 1985; Nowycky et al. 1985; Narahashi et al. 1987). The kinetic properties of T-channels suggest a key role in regulating electrical activity in the critical voltage region near threshold. For example, T-channels are involved in generation of bursts of action potentials in thalamic neurons (Huguenard 1996).

Significant heterogeneity has been observed in the kinetics of T-channel gating, particularly inactivation rates and the voltage dependence of steady state inactivation (Huguenard 1996). This may be partially explained by use of different experimental conditions, notably the nonphysiological ionic conditions often required to isolate T-current from currents through other ion channels. However, T-currents can genuinely differ in kinetics and pharmacology among cell types (Chen and Hess 1990; Huguenard and Prince 1992; Todorovic and Lingle 1998). This may reflect the emerging molecular diversity among T-channels, with three clones (1G, 1H, and 1I) known to date (Perez-Reyes et al. 1998; Cribbs et al. 1998; Lee et al. 1999).

Cloned T-channels have putative S4 transmembrane regions, suggesting that the mechanism of voltage-dependent activation is essentially the same as in other members of the extended family of K⁺, Na⁺, and Ca²⁺ channels. However, little is known about the mechanism of inactivation in T-channels, or its relationship to the various fast and slow voltage-dependent inactivation processes known for other channels. T-channel inactivation has been described either by models based on Hodgkin and Huxley 1952b that assume intrinsically voltage-dependent inactivation (Wang et al. 1991; Huguenard and McCormick 1992), or by state-dependent inactivation (Chen and Hess 1990).

The goal of this study was to characterize the gating of T-channels using whole-cell recording from HEK 293 cells stably expressing the 1G clone, with emphasis on the kinetics of inactivation. In this system, it was possible to characterize T-currents over a wide voltage range, under nearly normal ionic conditions (notably, 2 mM Ca²⁺ as the charge carrier). We found that 1G channels inactivate primarily from the open state, although inactivation at hyperpolarized voltages involves "partially activated" closed states, and the main pathway for recovery from inactivation bypasses the open state. The currents show strong cumulative inactivation in response to repetitive depolarizations, consistent with continued inactivation from the open state even after repolarization.

	Materials and Methods

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Cell Culture
Generation of the stable HEK 293 cell line expressing rat 1G (sequence data available from EMBL/GenBank/DDBJ under accession no. AF027984) has been described previously (Lee et al. 1999). Cells were cultured in MEM supplemented with 10% fetal bovine serum and 600 µg/ml G418, at 37°C in 95% O₂, 5% CO₂. Cell culture media and reagents were from GIBCO BRL. The cells were passaged every 3–4 d. Before recording, cells were harvested from the culture dish by trypsinization, washed with MEM, and stored in the supplemented medium. Cells were used for patch clamp recording 1–4 d after trypsinization.

Electrophysiology
Currents were recorded using conventional whole-cell patch clamp recording, with an Axopatch 200A amplifier and the Clampex program of pClamp v. 6.0.3 (Axon Instruments). The extracellular solution was 140 mM NaCl, 2 mM CaCl₂, 1 mM MgCl₂, and 10 mM HEPES, adjusted to pH 7.2 with NaOH. The intracellular solution contained 140 mM NaCl, 11 mM EGTA, 2 mM CaCl₂, 4 mM MgATP, 1 mM MgCl₂, and 10 mM HEPES, pH 7.2 with NaOH. The pipets filled with intracellular solution had resistances of 2–4 M. The series resistance in the whole-cell configuration (measured from optimal compensation of capacity transients with the amplifier circuitry) was 5.7 ± 0.3 M, with cell capacitance of 15.3 ± 0.5 pF . Series resistance compensation was nominally 80–90%. All experiments were performed at room temperature (20°C).

The holding potential was –100 mV. Currents were recorded on two channels, with on-line leak subtraction using the P/–4 method on one channel, and raw data during depolarizations on the other, to assess the holding current and cell stability. When this is done, Clampex v. 6 incorrectly sets the current to zero at the end of each leak-subtracted record, so all protocols included a significant period of time at the holding potential at the beginning of each record, and the current during that first holding level was set to zero when the leak-subtracted data were analyzed (using Analyze Adjust Baseline for Epoch A in Clampfit).

Data Analysis
Most data analysis used Clampfit v. 6. Exponential fits to data records used the Simplex or Mixed methods of Clampfit. Other curve fitting was done with the Solver function of Microsoft Excel v. 5 or Excel 97. Unless noted otherwise, values are mean ± SEM. For figures showing averaged data, error bars (±SEM) are shown when larger than the symbols.

Since the currents recorded could be >1 nA, data were examined closely for signs of series resistance error. Clamp speed was assessed by the rise time of tail currents, and steady state accuracy by the effect of partial inactivation on the time course of tail currents. For cells used for kinetic analysis of tail currents (e.g., Fig. 3), the 10–90% rise time was 0.15–0.35 ms after 10-kHz analogue filtering. Prepulses that caused 70% inactivation (using the protocol illustrated in the inset to Fig. 11) affected the time constant for deactivation at –100 mV by 15%. Since the measured time constants changed 37% per 10 mV near –100 mV (see Fig. 5), this suggests 5 mV error.

View larger version (15K): [in this window] [in a new window] [Download PPT slide]   Figure 3 Instantaneous current–voltage relations for 1G channels. (A) Sample current records, with 5 kHz Gaussian filtering, from cell e8612. The initial step to +60 mV lasted 2 ms. Records are shown for repolarizations in 20-mV increments. 2-ms test pulses to +60 mV were given at the end of the protocol, 20-ms after repolarization to –100 mV, to assess inactivation (not shown; see Fig. 11 below). (B) Instantaneous current–voltage relations, measured from the protocol of A, averaged from eight cells. Currents were measured at the peak of the tail current in each cell, which varied from 0.3 to 0.5 ms in these cells.

View larger version (20K): [in this window] [in a new window] [Download PPT slide]   Figure 11 Predicted open-state inactivation. The voltage protocol is shown in the inset. The steps to +60 mV lasted 2 ms each, the variable steps were 40 ms, and the interval at –100 mV was 20 ms. Measured inactivation is from the currents during the two steps to +60 mV (1.0 – I+60,post/I+60,pre). Predicted inactivation was calculated from , including the PO,r values from all three voltage levels before the final test pulse to +60 mV.

View larger version (13K): [in this window] [in a new window] [Download PPT slide]   Figure 5 Time course of inactivation and deactivation. (A) Time constants are from single exponential fits, from two protocols. The diamonds are for currents recorded during direct depolarizations (the protocol of Fig. 1), with the fit beginning well after the point of peak inward current, and ending at 60 or 120 ms. The squares are for currents recorded after repolarization from +60 mV (the protocol of Fig. 3), fitted from 0.4–0.6 ms after repolarization to the end of the 40-ms steps. Data are from the same eight cells as Fig. 3 B. (B) Deactivation kinetics at strongly hyperpolarized voltages. Voltage steps were in 15-mV increments, from –90 to –150 mV. The records are from cell a8o29, with 5 kHz Gaussian filtering. The inset shows the time constants, which changed e-fold for 32.8 ± 0.4 mV .

	results

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General Characteristics of Macroscopic Currents
Currents with the properties expected of T-type calcium currents were recorded from HEK 293 cells stably expressing 1G cDNA. Depolarizations in 10-mV increments from a holding potential of –100 mV elicited transient inward and outward currents (Fig. 1 A). Currents showed voltage-dependent macroscopic activation and inactivation, with faster kinetics at more depolarized voltages. At intermediate voltages, the currents "cross over" as typically observed for Na⁺ currents and T-currents (Randall and Tsien 1997; Perez-Reyes et al. 1998). The current–voltage (I–V) relationship, measured at the time of peak current during each record, is shown in Fig. 1 B. Detectable current was first observed near –70 mV, with peak inward current near –40 mV.

View larger version (18K): [in this window] [in a new window] [Download PPT slide]   Figure 1 Current–voltage relations for 1G channels. (A) Sample current records, with 5 kHz Gaussian filtering, from cell e8612. (B) Current–voltage relations averaged from 12 cells, measured at the point of peak current at each voltage.

View larger version (17K): [in this window] [in a new window] [Download PPT slide]   Figure 2 Envelope test for isolation of 1G currents. Depolarizations of variable duration were given to +60 mV (above) or –20 mV (below). The records shown lasted 2, 5, 10, 20, 50, and 100 ms. The peak amplitudes of the tail currents after repolarization for those records (and for steps lasting 0.2, 0.5, and 1 ms) were scaled to match the currents during depolarization, and are shown as open squares superimposed on the records. Cell a8612, 3 kHz Gaussian filtering.

Division of the I–V curve (Fig. 1 B) by the instantaneous I–V curve (Fig. 3 B) was used to evaluate the voltage dependence of activation of 1G channels (Fig. 4 A). That ratio (P_O,r) should be proportional to the number of channels open at the time of peak current at each voltage. Compared with the usual procedure of measuring tail current amplitudes after depolarizations of fixed duration, this method has the advantage of measuring activation at the maximal value for each voltage. The data at 0 mV were fitted to a single Boltzmann function, with half-maximal activation at –48 mV. The data deviate from that function at positive voltages, in part because the current ratios become discontinuous at the reversal potential, but the measured activation was consistently 20% greater near +60 mV than near 0 mV. For a rapidly inactivating channel, some channels will inactivate before the point of peak inward current, and the extent of that "hidden" inactivation may vary with voltage. Therefore, the activation curve (Fig. 4 A) should be considered an empirical measurement, which may not fully describe the true voltage dependence of the microscopic activation process.

View larger version (12K): [in this window] [in a new window] [Download PPT slide]   Figure 4 Activation of 1G channels. (A) Activation curve, from current ratios: the peak current recorded during depolarization directly to the indicated voltage (the protocol of Fig. 1), divided by the instantaneous current recorded after repolarization from a 2-ms step to +60 mV (the protocol of Fig. 3). Data are not shown for voltages near the reversal potential. . The smooth curve is a fit to a Boltzmann functions: mV, e-fold for 9.4 mV, amplitude 0.80. (B) Time to peak, for the protocol of Fig. 1, .

Voltage Dependence of Inactivation and Deactivation
Macroscopic inactivation was measured by single exponential fits to the time course of current decay using the protocol of Fig. 1 (filled symbols, Fig. 5 A). Inactivation was relatively slow at more negative voltages (–60 to –40 mV), but varied little with voltage between –30 and +70 mV. One explanation is that the microscopic inactivation process is voltage independent, as proposed for Na⁺ channels (Armstrong and Bezanilla 1977), but macroscopic inactivation is voltage dependent because of kinetic coupling to the activation process, especially at relatively negative voltages where activation is incomplete. To test that idea, time constants were also measured for the relaxations from the protocol of Fig. 3 (open symbols, Fig. 5 A). The decay of current in that case reflects a combination of channel closing (deactivation) and inactivation. From –120 to –70 mV, where channels would be expected to deactivate, the time constants varied exponentially with voltage . At more depolarized voltages, the time constants varied little , and were comparable to the time constants for macroscopic inactivation. These results are consistent with voltage-dependent channel closing, dominating at extreme negative voltages, but nearly voltage-independent inactivation. There was actually a slight increase in the time constant for inactivation with depolarization (20% from –20 to +60 mV; Fig. 5 A).

The rate of T-channel deactivation reaches a voltage-independent limiting rate at extreme negative voltages in some studies (Chen and Hess 1990) but not others (Herrington and Lingle 1992; Todorovic and Lingle 1998). To test this for 1G, we examined tail currents at voltages as negative as –150 mV. The time constants showed no detectable deviation from exponential voltage dependence (Fig. 5 B).

Inactivation and Recovery at Negative Voltages
Substantial inactivation was observed at voltages as negative as –80 mV (Fig. 6 A). Pulses to –120 mV had little effect, implying that there is little resting fast inactivation at our holding potential of –100 mV. At –80 mV, inactivation proceeded with , and was 70 ± 5% complete . Inactivation was nearly complete at –70 mV .

View larger version (14K): [in this window] [in a new window] [Download PPT slide]   Figure 6 Time course of inactivation and recovery. (A) Effect of prepulses of variable voltage and duration on the current evoked by a test pulse to –20 mV. The currents were normalized to that observed during a test pulse given alone (with no prepulse). The smooth curves are exponential functions, with time constants of 202 ms at –80 mV, and 210 ms at –70 mV. (B) The time course of recovery from inactivation, after 60-ms pulses to –20 mV. The values are the current during the test pulse to –20 mV, divided by the current at the corresponding time in the 60-ms prepulse. Time constants for recovery were 86 ms at –120 mV, 74 ms at –100 mV, and 175 ms at –80 mV. (C) The protocol for recovery from inactivation. Records (analogue filtering at 1 kHz) are shown for recovery at the holding potential of –100 mV, with recovery intervals of 8, 20, 40, 80, and 200 ms. All data in this figure are from cell a8612.

View larger version (19K): [in this window] [in a new window] [Download PPT slide]   Figure 7 Voltage dependence of steady state inactivation. Steps lasting 1 s to the indicated voltages were followed by 5-ms test pulses to –20 mV. The protocol was run either with no preceding depolarization (for inactivation) or immediately after a 60-ms step to –20 mV (for recovery). For the recovery protocol, the values are the ratio of current in the test pulse to the current during the 60-ms prepulse, measured at comparable times. For the inactivation protocol, currents were normalized to the value at –100 mV (i.e., with no prepulse). Test pulses (with no prepulse) were given before and after the rest of the protocol, to control for rundown or accumulation of inactivation. The smooth curves are fits to a Boltzmann relation, with (inactivation) and (recovery). Cell a8n02, 1 kHz analogue antialias filtering.

Completeness of Inactivation
The inactivation curve could be described well by a single Boltzmann relation, assuming that channels inactivate fully at depolarized voltages (Fig. 7). The currents recorded during depolarizations do decay to near zero, but small currents are consistently observed at the end of the pulse (Fig. 1 A). This was observed even after depolarizations lasting 120 ms (Fig. 8 A). If the inactivated state is fully absorbing, only 0.0003 of the channels should remain open after 120 ms , but the peak tail current amplitudes correspond to P_O,r 0.02 over a wide voltage range (–60 to +70 mV). The tail currents were small and noisy, so the measured current amplitudes show considerable variability, but residual channel activation was clearly detectable.

View larger version (16K): [in this window] [in a new window] [Download PPT slide]   Figure 8 Test for window current. (A) Incomplete inactivation after 120-ms depolarizations. Tail currents at –100 mV were fitted to a single exponential (plus a constant) beginning 0.6–0.8 ms after repolarization from the voltages indicated (protocol of Fig. 1, except voltage steps lasted 120 ms). PO,r was calculated by dividing the initial tail current amplitude (sum of the exponentially decaying component, plus the constant) by the instantaneous current at –100 mV after a 2-ms depolarization to +60 mV (the protocol of Fig. 3). Each symbol is a different cell , and the line is drawn through the mean values. (B) Incomplete inactivation for 300-ms depolarizations to –20 mV. The records are the averaged currents from four depolarizations, in each of five cells. The inset shows the current at the end of the step and the tail current, at a 10x higher amplification. 1 kHz Gaussian filter.

Another possible source of incomplete inactivation is a "window current" produced by overlap of the steady state activation and inactivation curves. Roughly speaking, that current should be maximal halfway between the midpoint voltages of the two curves (approximately –70 mV for 1G). Tail currents after 600-ms pulses to –70 mV were very small , corresponding to a P_O,r of 0.003, suggesting little steady state activation at –70 mV.

As noted above, single exponential fits to tail currents from the protocol of Fig. 8 B yielded an apparently nondeactivating component of 10 ± 2 pA, which corresponds to P_O,r = 0.002. One possible interpretation is that the slow component is a "resurgent current," reflecting channels recovering from inactivation by passing through the open state (Raman and Bean 1997).

For comparison, we calculated the resurgent current expected if all of the channels must recover through the open state. We used a three-state scheme: C O I, assuming that channel closing is irreversible at –100 mV. The inactivation (k_I) and recovery (k_–I) rates can be estimated from the limiting time constants for inactivation and recovery : . From the tail current time constant at –100 mV , the channel closing rate . From the analytic solution to the general three-state model (Gutnick et al. 1989), those values predict a reopening current with peak , starting from the initial condition . Thus, the observed P_O,r of 0.002 is consistent with 8% of the channels recovering through the open state. Since the slow component of the tail current could be explained in other ways (e.g., a small amount of slow deactivation), this value should be considered an upper limit for the fraction of channels that recover through the open state.

Another argument that inactivation and activation are not strictly coupled is that a C ... C O I scheme predicts much less complete inactivation than observed. If the rate constants for inactivation and recovery are truly voltage independent with the values estimated above, at steady state (at depolarized voltages where the C O reaction favors the open state). This is additional evidence that recovery from inactivation cannot occur primarily through the open state; i.e., the limiting rate for recovery from inactivation is considerably faster than the rate constant for the O I reaction.

Closed-state Inactivation
Fig. 7 demonstrates that there is considerable inactivation at quite negative voltages, below the range where channel activation is detectable (see Fig. 1 B and Fig. 4). This observation suggests that channels can inactivate directly from closed states. However, it is possible that open-state inactivation could slowly accumulate even if P_O is low, perhaps undetectably low. To examine this quantitatively, we calculated the amount of inactivation expected if channels can inactivate only from the open state. That can be done in a model-independent manner, if we make two assumptions: (a) the microscopic rate constant for inactivation k_I (O I) is the reciprocal of the nearly voltage-independent time constant measured at more than –30 mV, and (b) recovery from inactivation can be neglected (i.e., inactivation is absorbing). We do not mean to imply that these assumptions are true, but they allow simple calculation of the amount of inactivation expected to be produced by a voltage protocol, and deviations from the "predicted" inactivation are likely to be informative.

The predicted inactivation was calculated as follows: first, after measuring the instantaneous I–V relation for a cell (Fig. 3 B), currents are converted to relative P_O values (P_O,r), by dividing the observed current by the instantaneous current at the same voltage. This gives P_O,r as a function of time (relative to that at +60 mV). The expected open-state inactivation is then calculated by integrating . That is calculated as the point-by-point sum

(1)

during the protocol. Note that this calculation does not make any assumptions about the kinetic scheme for channel activation; i.e., it is independent of number and arrangement of closed states. Similar analyses have been done by Bean 1981 for Na⁺ channels, and Herrington and Lingle 1992 for T-channels of GH₃ cells.

At –70 mV, where channel opening was clearly detectable, the observed inactivation was approximately twice the predicted value (Fig. 9 A). The difference was larger at –80 mV (Fig. 9 B), where inward currents were visible in one or two of the four cells analyzed. If recovery from inactivation were considered, the predicted inactivation would be reduced further, increasing the discrepancy. We conclude that there is excess inactivation that cannot be accounted for by inactivation from the open state, presumably indicating inactivation directly from closed states.

View larger version (19K): [in this window] [in a new window] [Download PPT slide]   Figure 9 Test for closed-state inactivation. Voltage steps to –70 mV (A) or –80 mV (B) for the indicated duration were immediately followed by 5-ms test pulses to –20 mV. Inactivation measured from the test pulses (diamonds) is compared with the expected open-state inactivation (squares) calculated from the integrated current during the step to –70 mV (). (A), (B).

View larger version (15K): [in this window] [in a new window] [Download PPT slide]   Figure 10 Recovery from closed-state inactivation. In this cell, a 600-ms step to –70 mV produced a small inward current , but a subsequent 10-ms test pulse to –20 mV demonstrated 40% inactivation (compared with 8% predicted open-state inactivation). The main figure shows the time course of recovery from inactivation at –100 mV, fitted to an exponential function with . Currents were measured during the steps to –20 mV, and were normalized to the current recorded during test pulses to –20 mV (with no prepulse to –70 mV) given after the protocol. The inset shows records for recovery intervals of 25, 50, 100, 250, 500, and 1,000 ms (cell d8o28, 500 Hz Gaussian filter). In this cell, the peak PO,r and the amount of inactivation at –70 mV were both less than typically observed (compare with Fig. 6, Fig. 7, and Fig. 9).

Most of the inactivation observed at –120 to –100 mV in Fig. 11 can be attributed to the predicted open-state inactivation produced during the initial 2-ms step to +60 mV . But the amount of inactivation increases with depolarization from –90 to –60 mV, and that extra inactivation can be quantitatively explained by inactivation from the open state during the tail current. That is, a fraction of channels inactivate after repolarization, rather than closing. This behavior is expected from inactivation that is state but not voltage dependent, as channels have a "choice" of pathways for leaving the open state (C ... C O I). In contrast, with a model where inactivation and recovery are intrinsically voltage dependent, channels would begin to recover from inactivation immediately upon repolarization.

Cumulative Inactivation
State-dependent inactivation is often associated with cumulative inactivation, a phenomenon where repetitive pulses produce significant inactivation, even when little or no inactivation is visible during each depolarization (Neher and Lux 1971; Aldrich 1981). We do observe strong cumulative inactivation for brief trains of pulses for 1G, either using square voltage steps (Fig. 12 A) or action potential–like depolarizations (Fig. 12 B).

View larger version (14K): [in this window] [in a new window] [Download PPT slide]   Figure 12 Cumulative inactivation. (A) The upper panel is two superimposed current records, a single 50-ms depolarization to –20 mV, and four steps to –20 mV for 5 ms each, separated by 10-ms intervals at –100 mV. The lower panel is the predicted open-state inactivation for the four-pulse protocol. Cell a8612, 2 kHz Gaussian filter. (B) Inactivation during a train of four action potential–like depolarizations. Cell e8612, 5 kHz Gaussian filter. The voltage command (shown below) was simulated from the Hodgkin-Huxley (1952b) model for the squid axon, modified to allow spontaneous 50-Hz repetitive firing by shifting the voltage dependence of the "m" gate by 2 mV to more negative voltages. The action potentials were scaled to an initial voltage of –100 mV, with an overshoot of +39 mV. The dashed lines are at 0 and –100 mV.

Another sign of state-dependent inactivation is "nonmonotonic recovery from inactivation" (Neher and Lux 1971; Marom and Levitan 1994). For pairs of brief depolarizations, channels continue to inactivate during the initial part of the interpulse interval, before recovery from inactivation begins, producing a U-shaped time course for the current measured during the second pulse (Fig. 13). However, apparent nonmonotonic recovery can be observed for interpulse intervals that are not long enough to fully close the channel, if that leads to more channel activation during the second pulse (Gillespie and Meves 1980). That is, a larger test pulse current could result from greater channel activation, rather than less inactivation, for very brief intervals. To exclude this possibility, we delivered a third pulse, after allowing 20 ms for complete channel closing. Currents during the third pulse also showed a U-shaped time dependence (Fig. 13), although inactivation during the 20-ms tail current (and at early times during the third pulse) made the U shape less dramatic. Since nonmonotonic recovery would not occur at all if inactivation were strictly voltage dependent, this is good evidence for state-dependent inactivation.

View larger version (14K): [in this window] [in a new window] [Download PPT slide]   Figure 13 Nonmonotonic recovery from inactivation. Three pulses were given (each 5 ms to –20 mV), with a variable interval (1–300 ms) between the first two pulses (P1 and P2), and 20 ms between P2 and P3. (A) Sample records for P1–P2 intervals of 1 and 10 ms. Note that the 1-ms interval at –100 mV is not long enough for many channels to close. The P2 current is clearly larger for the 1-ms interval, and the P3 current is slightly larger (easiest to see in the tail current amplitudes following P3, see dashed lines). Cell a8702, 3 kHz Gaussian filter. (B) The time course of recovery from inactivation, averaged from seven cells. Note the log time scale. The decrease in P2 amplitude from 1 to 10 ms could reflect either continued inactivation during the tail current, or residual activation remaining from P1 (see A). But the 20-ms P2–P3 interval is long enough for channels to fully deactivate, so the decrease in P3 amplitude from 1 to 10 ms indicates a genuinely nonmonotonic time course for recovery from inactivation.

We considered a model where inactivation is coupled allosterically to voltage sensor activation (Fig. 14 A), which has proven successful for describing inactivation for several voltage-dependent channels (Kuo and Bean 1994; Klemic et al. 1998; Patil et al. 1998). The model involves sequential activation of four voltage sensors (presumably the S4 regions), followed by a distinct channel opening step with less voltage dependence. This can describe the observed delay before channel opening, but voltage-independent channel opening (k_O) limits the voltage dependence of the time to peak. Channel closing (k_–O) must have significant voltage dependence, however, to produce the observed exponential voltage dependence of deactivation (Fig. 5 A). Inactivation is allowed from any of the closed or open states, as in the Hodgkin and Huxley 1952b Na⁺ channel model, but channel activation favors inactivation (and slows recovery). The rate constants for inactivation and recovery are state dependent, but do not depend directly on voltage.

View larger version (26K): [in this window] [in a new window] [Download PPT slide]   Figure 14 A kinetic scheme for gating of 1G T-channels. It differs from Kuo and Bean 1994 and Klemic et al. 1998 in assuming that the rates for inactivation and recovery are the same for the rightmost three states (C3, C4, and O). The model includes six rate constants at 0 mV, for voltage sensor movement , channel opening/closing , and inactivation . Three of the rate constants (kV, k–V, and k–O) depend exponentially on voltage, changing e-fold for 25, –18, and –34 mV depolarization (respectively). Inactivation is allosterically coupled to movement of the first three voltage sensors, with factors for inactivation rate constants and for recovery. (B) Records of PO,r versus time, from –70 to –20 mV, calculated by dividing currents (recorded by the protocol of Fig. 1 A) by the peak tail current amplitude at each voltage (protocol of Fig. 3). Cell a8612, 3 kHz Gaussian filter. (C) Simulated PO versus time records. The scale bars apply to both B and C.

The crossover exhibited by the simulations suggested that the model underestimated the rate of inactivation at more negative voltages, which presumably must occur from closed states. We thus modified the scheme, so that activation of only the first three voltage sensors affects the inactivation rate. That is, the last voltage sensor to move (C₃–C₄) has no further effect on the inactivation rate, and the open channel inactivates at the same rate as closed channels in C₃ and C₄. This is arbitrary, but there is precedent for differential coupling of voltage sensors to inactivation of Na⁺ channels (Mitrovic et al. 1998). Faster inactivation from the intermediate closed state C₃ significantly reduced the sustained current at negative voltages, and reduced the crossover (Fig. 14 C). Allowing only the first two voltage sensors to affect the inactivation rate eliminated crossover of P_O records, but degraded the quality of the fit in other ways, notably weakening the voltage dependence of steady state inactivation.

The scheme of Fig. 14 A can accurately describe many aspects of the experimental data (Fig. 15). Current records cross over at negative voltages (Fig. 15 A) and activate in the appropriate voltage range (Fig. 15B and Fig. C). The sum of two Boltzmann distributions was required for accurate description of the simulated activation curve (Fig. 15 C; compare with Fig. 4 A). The voltage dependence of the time to peak (Fig. 15 D) resembled the experimental data (Fig. 4 B), approaching 1 ms at strongly positive voltages. Tail currents from the protocol of Fig. 3 A decayed nearly monoexponentially (Fig. 15E and Fig. F), although the model does not describe the small increase in time constant at positive voltages (Fig. 5 A). The model reproduces cumulative inactivation (Fig. 15 G), with considerable inactivation occurring during tail currents. Nonmonotonic recovery from inactivation occurs after brief (5-ms) steps, although this is barely visible in the P3/P1 ratio (Fig. 15 H).

View larger version (22K): [in this window] [in a new window] [Download PPT slide]   Figure 15 Simulation of 1G T-currents. Parameters are given in the legend to Fig. 14. Currents were calculated assuming a reversal potential of +25 mV, with a linear open-channel I–V. (A) Currents during 60-ms depolarizations from –100 mV to voltages from –90 to +70 mV, as in Fig. 1 A. Peak current–voltage relations (B), the peak probability that the channel is open (C), and the time to peak (D) from the protocol of A (compare with Fig. 1 B and Fig. 4A and Fig. B, respectively). The smooth curve in C is the sum of two Boltzmann functions: . (E) Currents from the protocol of Fig. 3, recorded in 20-mV increments from –120 to +60 mV, after 2-ms depolarizations to +60 mV. (F) Time constants for inactivation (triangles) from A, and for inactivation plus deactivation (squares) from E, shown as in Fig. 5 A. Time constants changed e-fold for 26 mV from –70 to –120 mV. (G) Currents during a train of 5-ms depolarizations from –100 to –20 mV, given at 15-ms intervals, superimposed on the current during a 50-ms depolarization to –20 mV. The lower panel shows the summed probability of being in an inactivated state, in response to the four depolarizations shown above. Compare with Fig. 12. Note that net inactivation occurs during the tail current after the first two steps, despite some recovery from inactivation (more apparent after the last two steps). (H) Nonmonotonic recovery from inactivation, using the protocol of Fig. 13.

The model also produced appropriate steady state inactivation, including its steep voltage dependence . Inactivation near the V_1/2 was predominantly from closed states. Recovery from inactivation was weakly voltage dependent (Table ). There was no obvious resurgent current during recovery from inactivation, but the tail current (primarily reflecting deactivation of the small steady state current) was 20% slower than after brief depolarizations, reflecting some channels recovering from inactivation through the open state (simulations not shown).

	Discussion

Top ABSTRACT Introduction Materials and Methods results Discussion REFERENCES

 
Functional expression of the 1G clone in HEK 293 cells produced currents with the essential kinetic properties of T-type calcium currents. Specifically, the voltage dependence of activation (V_1/2 –50 mV) is clearly in the LVA range, and inactivation (V_1/2 –80 mV) also occurs at more negative voltages than for most HVA channels. Inactivation is not only rapid ( 15 ms at –40 mV and above), but also nearly complete. 1G deactivates 10-fold slower than HVA channels . Similar properties have been observed for 1G expressed in Xenopus oocytes (Perez-Reyes et al. 1998), but use of a mammalian cell line allowed control of the intracellular medium, so that currents could be studied in nearly physiological conditions. The kinetic analysis in this study depended on the ability to isolate 1G currents over a wide voltage range, without detectable contamination from other currents, as shown by the envelope test (Fig. 2) and the absence of ionic currents at the observed reversal potential (Fig. 3 A).

State Dependence of Inactivation
The main goal of this study was to characterize the kinetics of inactivation in 1G channels. We conclude that inactivation is state dependent, with little intrinsic voltage dependence. For brief strong depolarizations, inactivation occurs primarily from the open state, but long weak depolarizations produce inactivation from partially activated closed states. We will next discuss the evidence for these conclusions.

The macroscopic inactivation and recovery processes reach essentially voltage-independent time constants at extreme voltages, above –50 mV for inactivation and below –90 mV for recovery (Fig. 5 and Fig. 7). This can be described by intrinsically voltage-dependent inactivation, if rate constants depend nonexponentially on voltage, as for β_h in the original Hodgkin and Huxley 1952b model, but a voltage-independent rate-limiting step is a more attractive explanation. Furthermore, open-state inactivation at a voltage-independent rate can account for the inactivation observed for brief depolarizations and the subsequent tail currents (Fig. 11). Most notably, there was more inactivation during tail currents at –80 to –60 mV than at more negative voltages, as predicted by open-state inactivation, since channels deactivate slowly in that range. The observation of nonmonotonic recovery from inactivation (Fig. 13) confirms that inactivation can continue to occur after repolarization, as expected for state-dependent but not voltage-dependent inactivation.

Although open-state inactivation can account for the effects of brief depolarization (Fig. 11), inactivation also occurred slowly during depolarizations to –90 mV (Fig. 7), where no channel opening was detectable. At –70 or –80 mV, the amount of observed inactivation considerably exceeded that predicted by voltage-independent open-state inactivation (Fig. 9). Unless the rate for open-state inactivation increases more than twofold at these hyperpolarized voltages, which is unlikely, inactivation must also occur from closed states. The simplest explanation for the inactivation observed below –60 mV is that activation of voltage sensors favors inactivation, even if the channel does not open (Fig. 14 A). For 1G, inactivation is faster from the open state than from some of the intermediate closed states, since macroscopic inactivation slowed below –40 mV, and a maintained depolarization produced more inactivation than repetitive pulses (Fig. 13 A).

Open- and closed-state inactivation of 1G appear to be closely linked processes, since recovery from inactivation is similar after procedures that favor open-state inactivation (60-ms pulses to –20 mV) or closed-state inactivation (600-ms pulses to –70 mV). The absence of a significant inward current during recovery from inactivation (Fig. 8) demonstrates that the primary pathway for recovery from inactivation is via closed states.

It is possible that what we describe as open-state inactivation actually occurs from a closed state that is in rapid, voltage-independent equilibrium with the open state (Marom and Levitan 1994). Since this can be difficult to distinguish from inactivation directly from the open state, even with single channel data, we retain the expression "open-state inactivation" to emphasize that this form of inactivation is closely coupled kinetically to channel opening. Although our model assumes that inactivation occurs at the same rate from certain closed states (C₃ and C₄) as from the open state, open-state inactivation is the predominant pathway except at the most negative voltages, mainly because the C₄ O equilibrium is strongly to the right for the parameters used, so occupancy of C₃ and C₄ is generally low.

Although our model describes well many qualitative and quantitative features of the experimental data, it should be considered preliminary. The model parameters were found by trial and error, rather than rigorous parameter estimation procedures based on quantitative error minimization. We have not systematically tested alternative models. Our data do not include information from single-channel or gating current experiments, which have proven important for modeling gating of other channels. We believe it is useful to present this model at this time, as a possible basis for future studies on the gating of both cloned and native T-channels.

Comparison with Native T-currents
1G is likely to underlie native T-currents in some but not all cells. Notably, it is highly expressed in the thalamus (Perez-Reyes et al. 1998). Two other 1 subunits (1H and 1I) produce T-currents in expression systems (Cribbs et al. 1998; Perez-Reyes et al. 1998; Lee et al. 1999), and the existence of additional 1 genes cannot be excluded. Other sources of diversity in channel properties, including accessory subunits and posttranslational modifications, remain to be fully explored for T-channels. It has been suggested that ₁ subunits normally associated with HVA channels can produce T-like activity under some conditions (Soong et al. 1993; Meir and Dolphin 1998), but the cloning of three indisputable T-channels makes this possibility less attractive as a general explanation for native T-currents (Randall and Tsien 1997; Bean and McDonough 1998; Lambert et al. 1998; Nakashima et al. 1998).

Kinetic and pharmacological diversity among T-channels is well established (Huguenard 1996). One feature with possible implications for mechanisms of channel gating is the voltage dependence at extreme voltages, which could reveal voltage-independent limiting rates (Chen and Hess 1990). We found clear evidence for voltage independence of the inactivation process (above –50 mV) and recovery (below –90 mV). This agrees well with some studies (Chen and Hess 1990; Herrington and Lingle 1992), although a limiting voltage-independent rate for recovery is not always clear (Huguenard and McCormick 1992). In contrast, channel deactivation remained strongly voltage dependent even at –150 mV (Herrington and Lingle 1992; Todorovic and Lingle 1998; but see Chen and Hess 1990). We have not examined activation kinetics closely in this study, but channel opening became quite rapid at depolarized voltages, with time to peak 1.4 ± 0.1 ms at +60 mV .

Our data for 1G are consistent with single exponential kinetics both for development of inactivation and for recovery, on a time scale up to 1 s. This is consistent with most previous work on native T-channels, although some studies have reported multiexponential kinetics (Bossu and Feltz 1986; Herrington and Lingle 1992). A preliminary report suggests that 1G may also exhibit a second inactivation process, on a longer time scale (Martin et al. 1998).

Comparison with Inactivation in Other Voltage-dependent Channels
There are some similarities among inactivation processes for different voltage-dependent channels. Fast inactivation of Na⁺ channels and N-type inactivation of K⁺ channels reach a limiting rate at positive voltages. At intermediate voltages, macroscopic inactivation is voltage dependent due to kinetic coupling to the activation process, which is relatively slow at such voltages. Inactivation is strong but not necessarily 100% complete. Inactivation of 1G channels shares these properties.

One striking difference from Na⁺ channels is that recovery from inactivation shows little voltage dependence for T-current (Table ; Chen and Hess 1990). This suggests a voltage-independent rate-limiting step for recovery, consistent with the view that the microscopic inactivation and recovery rates are both independent of voltage. In one study, recovery became voltage independent for Na⁺ channels, but only below –160 mV (Kuo and Bean 1994). Further work will be necessary to determine whether these differences are merely quantitative, or reflect qualitatively different inactivation mechanisms.

Inactivation of 1G was strong but incomplete, with 98–99% inactivation over a wide voltage range. There is considerable variability in the extent of inactivation of Na⁺ channels, 70–97% in the squid giant axon (Vandenberg and Bezanilla 1991) but 99.9% in mammalian skeletal muscle (Cannon and Corey 1993). In squid axon, the extent of inactivation decreases with strong depolarization (Chandler and Meves 1970), which may be true to a lesser extent for 1G (Fig. 8). This effect is not clearly associated with a slower macroscopic inactivation rate in squid axon (Chandler and Meves 1970), but an 20% decrease in the inactivation rate was detectable above +50 mV for 1G (Fig. 5 A). The decreased inactivation with strong depolarization was voltage dependent in squid axon (Bezanilla and Armstrong 1977), but effects of permeant ions on gating should also be considered for T-channels (Carbone and Lux 1987; Shuba et al. 1991), since in our ionic conditions the primary charge carriers are Ca²⁺ for inward currents and Na⁺ for outward currents.

Fast inactivation of Na⁺ and K⁺ channels is believed to occur primarily but not exclusively from open states (Bean 1981; Aldrich and Stevens 1983; Hoshi et al. 1990), as we find here for 1G. This contrasts with slower inactivation processes of some K⁺ (Aldrich 1981; Klemic et al. 1998, Klemic et al. 1999) and HVA Ca²⁺ channels (Patil et al. 1998), where inactivation from closed states appears to be the predominant pathway even at positive voltages.

Possible Physiological Implications
One of the clearest functional roles of native T-channels is generation of the low threshold spike that underlies bursts of action potentials in (e.g.) thalamic relay neurons (Huguenard 1996). In those cells, T-channels are inactivated at the normal resting potential (near –60 mV). But inactivation can be rapidly removed by hyperpolarizations, such as inhibitory postsynaptic potentials (IPSPs). This allows rebound activation of T-channels and a low threshold spike, terminated in part by T-channel inactivation. The properties of 1G currents are fully consistent with such a scheme.

1G exhibited a sustained current, with 1–2% of the channels remaining open at all voltages above –70 mV (Fig. 8). Our kinetic model accounts for that current with a finite, voltage-independent rate of recovery from inactivation. This differs from the "window current" predicted from an overlap between the activation and inactivation curves, which has a bell-shaped P_O versus voltage relation (if inactivation is complete at positive voltages, as often assumed), peaking near the foot of the activation curve (Williams et al. 1997). But in either case, there would be a steady state T-current at voltages near the resting potential, which could have interesting consequences for neuronal integration and calcium homeostasis (Williams et al. 1997; Bean and McDonough 1998). We are not aware of direct evidence for such a current from previous voltage clamp studies of T-current, although current clamp studies on thalamic neurons do suggest existence of a window current (Williams et al. 1997). Our results could overestimate the steady state T-current if additional slow inactivation processes exist, but the time scale we have examined (up to 1 s) is sufficient to predict that there should be significant T-channel activity during hyperpolarized intervals during a burst of action potentials.

It is not possible to extrapolate directly from results in an expression system to the situation in vivo, but several kinetic properties of 1G could have important physiological consequences. Activation is quite rapid at positive voltages, so any 1G channels not already activated in a low threshold spike might be activated significantly by a single Na⁺-dependent action potential. After repolarization, slow deactivation will keep the channels open for a few milliseconds, producing maintained Ca²⁺ entry (as noted by Huguenard 1996). In addition, a significant fraction of channels will inactivate (rather than deactivate) after repolarization. This contributes to the strong cumulative inactivation observed for 1G during action potential–like depolarizations (Fig. 13).

The cumulative inactivation critically depends on the state dependence of inactivation, combined with the characteristic slow deactivation of T-channels. Previous models for thalamic T-currents resemble the original Hodgkin and Huxley 1952b model for Na⁺ current, with inactivation depending on voltage but not on the state of activation of the channel. Some degree of cumulative inactivation does occur with Hodgkin-Huxley models, as some channels inactivate without opening in response to brief depolarizations, but recovery from inactivation begins immediately upon repolarization. Correspondingly, the models of Wang et al. 1991 and Huguenard and McCormick 1992 for thalamic T-current produce much less cumulative inactivation than observed here (simulations not shown). It is sometimes assumed that Hodgkin-Huxley models are valid as operational descriptions of macroscopic ionic currents, even if they are not mechanistically correct. However, state-dependent inactivation can produce effects that are not describable by such models, notably in response to repetitive depolarizations (Klemic et al. 1998; Patil et al. 1998). Future studies will be necessary to determine whether T-channels natively expressed in neurons also exhibit strong cumulative inactivation during a burst of action potentials, and to explore the consequences for the role of T-channels in neuronal excitability.

	ACKNOWLEDGMENTS

 
We thank Drs. Leanne L. Cribbs and Toni Schneider for preparation of the 1G cell line, and Dr. Christopher J. Lingle for helpful comments on a draft of this paper.

This work was supported in part by National Institutes of Health grant NS24471 to S.W. Jones and HL58728 to E. Perez-Reyes, and by a Howard Hughes Medical Institute grant to Case Western Reserve University School of Medicine.

Submitted: 3 March 1999
Revised: 19 May 1999
Accepted: 28 May 1999

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