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Volume 16, Number 16,
Issue of August 15, 1996
pp. 4983-4993
Copyright ©1996 Society for Neuroscience
The  1E Calcium Channel Exhibits Permeation
Properties Similar to Low-Voltage-Activated Calcium Channels
Emmanuel Bourinet1,
Gerald W. Zamponi1,
Anthony Stea1,
Tuck W. Soong1,
Bertram A. Lewis2,
Lisa P. Jones2,
David T. Yue2, and
Terry P. Snutch1
1 Biotechnology Laboratory, University of British
Columbia, Vancouver, British Columbia, Canada V6T 1Z3, and
2 Department of Biomedical Engineering, Johns Hopkins
University School of Medicine, Baltimore, Maryland 21205
 ABSTRACT
- INTRODUCTION
- MATERIALS AND METHODS
- RESULTS
- DISCUSSION
- FOOTNOTES
- REFERENCES
ABSTRACT 
The physiological and pharmacological properties of the
 1E calcium (Ca) channel subtype do not exactly
match any of the established categories described for native neuronal
Ca currents. Many of the key diagnostic features used to assign cloned
Ca channels to their native counterparts, however, are dependent on a
number of factors, including cellular environment,  subunit
coexpression, and modulation by second messengers and G-proteins. Here,
by examining the intrinsic pore characteristics of a family of
transiently expressed neuronal Ca channels, we demonstrate that the
permeation properties of 1E closely resemble
those described for a subset of low-threshold Ca channels. The
1A (P-/Q-type), 1B
(N-type), and 1C (L-type) high-threshold Ca
channels all exhibit larger whole-cell currents with barium (Ba) as the
charge carrier as compared with Ca or strontium (Sr). In contrast,
macroscopic 1E currents are largest in Sr,
followed by Ca and then Ba. The unique permeation properties of
1E are maintained at the single-channel level,
are independent of the nature of the expression system, and are not
affected by coexpression of 2 and subunits. Overall, the permeation characteristics of
1E are distinct from those described for
R-type currents and share some similarities with native low-threshold
Ca channels.
Key words:
calcium channel;
permeation;
barium;
strontium;
transient
expression;
conductance;
pore properties
INTRODUCTION
Calcium (Ca) influx through voltage-dependent Ca
channels mediates a wide range of neurophysiological functions,
including gene expression, neurotransmitter release, and firing
patterns (Tsien et al., 1988 ). On the basis of their
electrophysiological and pharmacological properties, Ca channels have
been classified into T-, L-, N-, P-, and Q-types (for review, see Stea
et al., 1995b). T-type channels transiently activate at relatively
negative membrane potentials, whereas the other channel types first
activate at more positive potentials and display diverse kinetic
characteristics. The high threshold channels can also be distinguished
pharmacologically: L-type channels are sensitive to dihydropyridine
agonists and antagonists, N-type channels are blocked by  -conotoxin
GVIA, and P-type channels are sensitive to nanomolar concentrations of
-agatoxin IVA. Q-type channels are sensitive to both -conotoxin
MVII-C and -agatoxin IVA and may be related structurally to P-type
channels (Stea et al., 1994; Dunlap et al., 1995). To date, there are
no known specific blockers of native low voltage-activated
channels.
In addition to their differential kinetic and pharmacological profiles,
the major types of Ca channels display distinct permeation
characteristics (Bean, 1985; Nilius et al., 1986; Carbone and Lux,
1987; Fox et al., 1987; Akaike et al., 1989; Takahashi et al., 1991).
Of particular note, the relative permeabilities for Ca, barium (Ba),
and strontium (Sr) are dependent on the Ca channel subtype. In general,
Ba permeates high voltage-activated Ca channels more effectively than
Ca does, whereas low voltage-activated (T-type) Ca channels are
permeated by Ca as well as or better than by Ba (Hille, 1992). Most
neurons express multiple subtypes of Ca channels, however, making it
difficult to determine the exact permeation properties of individual
subtypes of neuronal Ca channels. Furthermore, to date, there has been
no side-by-side comparison of the permeation characteristics of the
major Ca channel subtypes under identical experimental conditions.
The expression of cloned Ca channels in exogenous systems has allowed
the study of individual Ca channel subtypes in isolation. Five distinct
Ca channel 1 subunit genes are expressed in
the mammalian CNS (1A,
1B, 1C,
1D, and 1E).
Functional expression and immunoprecipitation studies have demonstrated
that 1C and 1D encode
dihydropyridine-sensitive L-type channels (Williams et al., 1992a; Hell
et al., 1993; Tomlinson et al., 1993), whereas
1B encodes an -conotoxin-sensitive N-type
channel (Dubel et al., 1992; Williams et al., 1992b; Fujita et al.,
1993; Stea et al., 1993). The 1A channel
displays properties similar to P- and Q-type currents (Mori et al.,
1991, Sather et al., 1993; Stea et al., 1994), whereas
1E does not fit exactly into any of the Ca
channel subtypes described in native cells. Although
1E channels differ from T-type channels
expressed in endocrine and cardiac cells, they display several
properties consistent with a subset of mid- to low-threshold Ca
channels expressed in the brain, including relatively more negative
potentials for half-activation and inactivation and a high sensitivity
to blockade by nickel (Soong et al., 1993). On the basis of these
properties, together with cellular and subcellular distribution, Soong
and coworkers (1993) have suggested that 1E
constitutes a novel member of the heterogeneous family of low
voltage-activated Ca channels, although this notion is controversial
(Ellinor et al., 1993; Zhang et al., 1993; Williams et al., 1994).
In this study, we show that consistent with native P-/Q-, N-, and
L-type channels, peak whole-cell currents recorded from
1A, 1B, and
1C were consistently smaller with Ca or Sr as
the carrier ion compared with Ba. A similar behavior was observed at
the single-channel level. In contrast, Ca or Sr substitution for Ba
resulted in consistently larger peak whole-cell currents for
1E. At the single-channel level, Ba, Ca, and
Sr permeated 1E equally, suggesting that this
channel exhibits pronounced differences in its inner pore properties
compared with the other Ca channel subtypes. Overall, the permeation
properties observed with 1E resemble those
described for T-type Ca channels and support the notion that
1E constitutes a novel member of a diverse
family of low voltage-activated Ca channels.
MATERIALS AND METHODS
Isolation of Xenopus oocytes and nuclear
injection of cloned Ca channel subunits. Stage V and VI oocytes
were surgically removed from anesthetized adult Xenopus
laevis and treated for 2-3 hr with 2 mg/ml collagenase (Type 1A;
Sigma, St. Louis, MO) in a Ca-free medium. After a recovery period of
3-10 hr, nuclear injection was performed using 10 nl of a 1:1:1 mix of
cDNAs encoding rat brain Ca channel 1,
2, and subunits inserted into the pMT2
expression vector (2.5 ng of each cDNA). The cDNA constructs carrying
the 1A, 1B,
1C, 1E,
2, and 1b have been
described previously (Soong et al., 1993; Tomlinson et al., 1993;
Bourinet et al., 1994; Stea et al., 1994, 1995a). Before
electrophysiological recording, oocytes were incubated at 19°C under
gentle shaking on a rotating platform for 3-5 d in standard oocyte
saline [(in mM): 100 NaCl, 2 KCl, 1.8 CaCl2, 1 MgCl2, 5 HEPES, at
pH 7.5] containing 2.5 mM sodium pyruvate and 10 µg/ml gentamycin sulfate.
Electrophysiological recording. For oocytes, macroscopic
currents were recorded using the two-electrode voltage-clamp technique
with either a GeneClamp 500 amplifier or an Axoclamp 2A amplifier (Axon
Instruments, Burlingame, CA). Acquisition and data analysis were
performed using pCLAMP (v6.0) software (Axon Instruments). Leak
currents and capacitive transients were subtracted using a P/5
procedure. Oocytes were placed in a 150 µl recording chamber and
superfused continuously with a solution containing (in
mM): either 5 Ba(OH)2, 5 Ca(OH)2, or 5 Sr(OH)2, 60 TEA-OH, 25 NaOH, 2 CsOH, 5 HEPES (titrated to pH 7.3 with methane
sulfonic acid). KCl-Agar bridges were used as ground electrodes to
minimize any junction potential attributable to the change in ionic
composition of the bath solution. Pipettes of typical resistance
ranging from 0.5 to 1.5 M were filled with 2.8 M CsCl, 0.2 M CsOH, 10 mM HEPES, and 10 mM
BAPTA-free acid. To record Ca channel activity accurately, the
endogenous oocyte Ca-activated Cl current was suppressed by injection
of 10-30 nl of a solution containing 100 mM
BAPTA-free acid and 10 mM HEPES (pH titrated to
7.2 with CsOH) using a third pipette connected to an electric
microinjector. The estimated final intraoocyte BAPTA concentration was
2-5 mM. An effective exchange of the chamber
solution was achieved within 1-2 sec, as judged by superperfusion of a
solution containing 100 µM Cd and by monitoring
the development of block. For each oocyte, solutions were switched from
Ba to Ca to Sr and then again to Ba to eliminate possible errors
arising from rundown during the time course of the experiment.
For concentration-conductance experiments, a different set of
solutions was used because the hydroxide salts of Ca, Ba, and Sr are
not soluble at physiological pH at concentrations greater than ~50
mM. In these cases we used 40 mM BaCl2 or 40 mM CaCl2, 2 mM CsCl, 36 mM TEA, 0.4 mM niflumic acid, 20 µM
5-nitro-2-(3-phenylpropylamino) benzoic acid (NPPB), 5 mM HEPES, pH 7.6. In lower ionic strength
solutions, sucrose was substituted for Ca or Ba; in 100 mM solutions, TEA and CsCl were omitted. In these
experiments current-voltage (I-V) curves were
acquired using a ramp stimulation from  100 to 100 mV (dV/dt = 1 mV/msec). This protocol permitted the acquisition of a complete
I-V relation in 2 sec and allowed the study of a
range of different ionic conditions on the same oocyte. There were no
detectable differences between I-V curves
recorded using either the more typical increased steps to various
potentials or the ramp protocol.
Macroscopic currents in HEK 293 cells were obtained by the whole-cell
patch-clamp technique using an Axopatch 200A amplifier. The internal
solution contained (in mM): 140 N-methyl-D-glucamine
(NMG)-MeSO3, 5 EGTA, 1 MgCl2, 4 MgATP, and 10 HEPES, pH 7.3, adjusted
with NMG. The external solution contained (in
mM): 130 NMG-aspartate, 1 MgCl2, 10 glucose, 10 4-aminopyridine, 10 HEPES,
and 10 BaCl2 or CaCl2, pH
7.3, adjusted with NMG.
Single-channel recordings were performed on oocytes in the
cell-attached mode using a Gene Clamp 500 amplifier. The sampling
frequency for acquisition was 5-10 kHz, and records were filtered at 1 kHz. After a short incubation (1-3 min) in a hyperosmotic medium to
shrink the cell membrane, the vitelline envelope was removed manually
from the oocyte. The membrane potential was reduced essentially to zero
by placing the oocytes in a high potassium solution (100 mM KCl, 10 mM EGTA, 2 mM MgCl2, and 10 mM HEPES, pH 7.3, with NaOH). Sylgard-coated
pipettes with resistances between 15 and 25 m were filled with a
solution containing either 100 mM
BaCl2, 100 mM
CaCl2, or 100 mM
SrCl2, and 10 mM HEPES, pH
7.5, with NaOH. For recordings of 1C, 5 mM Bay K8644 was included in the pipette.
Transient expression in HEK cells. HEK 293 cells were
transiently transfected as described previously (Dhallan et al., 1990),
using 10 µg each of 1E and
2a cDNAs subcloned into the vector pGW1H
(British Biotechnology, Abingdon, UK).
Data analysis and curve fitting. Macroscopic
I-V relations were fitted using the
equation:
where I is the current at the potential V,
G is the maximum slope conductance, and
Erev, V0.5, and
K are the reversal potential, the potential of half
activation, and the slope factor of the activation curve, respectively.
Single-channel conductances were obtained from linear regression
through open single-channel I-V relationships.
Unless stated otherwise, error bars represent SE.
Materials. Drugs were purchased from Sigma, except for BayK
8644 and NPPB, which were purchased from RBI (Natick, MA), and for
Sr(OH)2, which was a kind gift from Dr.
Joël Nargeot.
RESULTS
1E channels exhibit permeation properties distinct
from other Ca channel subtypes
Figure 1 illustrates the whole-cell properties of
four major rat brain Ca channel subtypes, 1A,
1B, 1C, and
1E (coexpressed with
2 and 1b subunits),
using Ba, Sr, or Ca as the charge carriers. For each channel type,
switching the external solution from Ba to Sr to Ca induced a
depolarizing shift of the I-V relation toward
more depolarized potentials. Furthermore, at least for
1C, the steepness of the activation curve
appeared reduced, consistent with that observed for native L-type Ca
channels (Byerly et al., 1985). Of particular note, both the peak
currents and the maximum slope conductances were differentially
affected among various neuronal Ca channel subtypes. Although the peak
currents of 1A, 1B,
and 1C were all significantly larger in Ba
than in Sr or Ca (IBa > ISr > ICa),
1E showed larger currents in Sr compared with
Ca or Ba (ISr > ICa > IBa).
Although switching the type of permeant ion also appeared to result in
changes in the reversal potential, producing a more positive reversal
potential with Ca as the charge carrier compared with Sr and Ba
(Erev,Ca > Erev,Sr > Erev,Ba), we did not attempt to estimate
permeability ratios from the measured reversal potential values,
because the intracellular divalent cation concentration could not be
controlled precisely.
Fig. 1.
Comparison of macroscopic currents carried by 5 mM Ba, Ca, or Sr. Current traces obtained at the
peak of the I-V relations for
1A, 1B,
1C, and 1E
(coexpressed with 2 and
1b) are presented with their respective
I-V relations. I-V
relations were fitted as described in Materials and Methods. Note that
Ba produces the largest currents through 1A,
1B, and 1C, but the
smallest currents through 1E channels. Also
note the pronounced Ca-dependent inactivation for
1C.
[View Larger Version of this Image (33K GIF file)]
If changes in reversal potential and half-activation potential differed
in their absolute magnitudes, the peak current ratios would be a poor
indication of the true conductance ratio. To circumvent this issue, we
used the slope of the I-V relation on the
plateau of the activation curve (i.e., the maximum slope conductance,
G) as an indication of the ability of the carrier ion to
permeate the channel. As shown in Figure 2a,
Ca and Sr produced a larger conductance compared to Ba for
1E, whereas the order was reversed for the
other channel isoforms (for 1A,
1B, and 1C:
GBa > GSr > GCa). A comparison with the peak ratios
(Fig. 2b) revealed a similar profile, consistent with the
observation that the shifts in reversal potential and the shifts in
half-activation voltage that occur when switching from Ba to Ca (or Sr)
were of similar magnitude.
Fig. 2.
Summary of the conductance properties of the
different channels. Apparent maximum slope conductances obtained from
fits to individual I-V relations are compared in
a. Values are presented in the form of conductance ratios
(Gion/GBa).
b, The peak current values from the same experiments,
normalized to those seen in Ba
(Imax(ion)/Imax(Ba)).
Note the different permeation profile of the
1E channel. Error bars are SE based on 5-14
determinations.
[View Larger Version of this Image (27K GIF file)]
Ca channel permeation characteristics are determined by the
1 subunit
The coexpression of ancillary Ca channel subunits modulates
several biophysical properties of cloned Ca channel
1 subunits (for review, see Stea et al.,
1995b). To determine whether 2 and subunits affected permeation, we examined the conductance profiles of
1A and 1E alone (both
of these channel types result in high levels of expression in oocytes
in the absence of ancillary subunits) (Soong et al., 1993; Stea et al.,
1994). Figure 3 shows that no significant differences in
the response to switching the type of permeant ion were observed when
2 and subunits were omitted. All of the
changes induced by the Ba-Ca-Sr substitutions described in Figures 1
and 2 were maintained, including the unique profile of the
1E channel. Taken together, these data suggest
that the basic permeation properties are intrinsic to the
1 subunit and are not significantly affected
by coexpression with 2 or subunits.
Furthermore, the permeation differences between
1E and the other channel types is indicated to
be an inherent property of the 1E protein.
Fig. 3.
Comparison of macroscopic Ba, Ca, and Sr currents
through 1A and 1E in
the absence of ancillary subunits. a, Peak current traces
with their respective current-voltage relationships as described in
Figure 1 ( , Ba;  , Ca;  , Sr). b, Comparison of the
maximum slope conductance ratios
(Gion/GBa)
and peak current ratios
(Imax(ion)/Imax(Ba))
in the presence and absence of 2 and
1b subunits. Note that the ancillary subunits
do not significantly affect the permeation properties of the channels.
Error bars are SE on 5-12 determinations.
[View Larger Version of this Image (34K GIF file)]
Dependence of the different 1 channels on
[Ba2+]o and
[Ca2+]o
To characterize further the permeation characteristics of the Ca
channel isoforms, we recorded concentration-conductance relations for
the four Ca channel subtypes in both Ba and Ca (Fig. 4).
Increasing the external concentration of either cation progressively
increased the whole-cell conductance. The conductance subsequently
leveled off at higher concentrations and was consistent with the
existence of one or more saturable binding sites for both Ca and Ba
within the pore. In Figure 4, the data obtained in Ba and Ca are scaled
and superimposed, revealing that the binding sites along the permeation
pathway become similarly saturated with either Ba or Ca as the carrier
ion for each of the channel subtypes. A pronounced difference, however,
becomes apparent on comparison of 1C with the
other channel subtypes. The concentration-conductance relation rose
more steeply for 1C and saturated at a lower
concentration (Fig. 4), suggesting that the divalent binding sites in
the pore of 1C exhibit a higher affinity for
permeating ions relative to the other channel types. Because the
saturation for 1E channels was similar to that
for 1A and 1B, a
difference in affinity for a putative divalent binding site as the
reason for the permeation differences in Ba and Ca can be excluded.
Fig. 4.
Concentration-conductance relations obtained for
the four 1 subunits coexpressed with
1b and 2. The data
were normalized to 1 at an ion concentration of 2 mM and superimposed. Note that the conductance
depends similarly on both Ba and Ca concentration for each of the Ca
channel subtypes. The 1C channels seem to
differ from the other subtypes in that the current saturates at lower
concentrations. The data were obtained from fits to macroscopic
I-V relations. Error bars indicate SE; the
solid lines are a smooth approximation of the Ba data based
on the Hill equation.
[View Larger Version of this Image (26K GIF file)]
Unitary current as a function of the permeant ion
The maximum slope conductance G is a
product of the single-channel conductance (g), the number of
channels (n) and their open probability (Po). To
determine whether the dependence of the whole-cell conductance was
attributable to a change in g, we examined the
single-channel conductances of the four Ca channel subtypes in both Ba
and Ca (and Sr in the case of 1E). Figure
5 shows that the single-channel conductances of
1C, 1A, and
1B all were reduced notably when Ca replaced
Ba. In contrast, the single-channel conductance of
1E was similar in Ba, Ca, or Sr. The two
most extreme cases are illustrated in Figure 5b, with a
side-by-side comparison of the unitary conductance-voltage relations
for 1E and 1C and
single-channel records at a test potential of 0 mV. Consistent with the
whole-cell data, the single-channel amplitude of currents carried by
1C channels was about half of that seen with
Ba. For 1E, the unitary currents were nearly
identical with either Ba, Ca, or Sr. These data indicate that the
increases in slope conductance associated with Sr or Ca substitution
for Ba were more likely attributable to an increase in plateau open
probability than to a change in single-channel conductance. This notion
is supported by a preliminary analysis of steady-state activation
at the single-channel level (not shown) and is consistent with previous
studies (Shuba et al., 1991). Overall, the single-channel data support
the uniqueness of the permeation properties of
1E as compared with the other neuronal Ca
channel subtypes.
Fig. 5.
Dependence of the single-channel conductance
on the type of external permeant ion. The histogram in a
summarizes the results obtained with the four
1 subunits coexpressed
2 and 1b. The
conductance of 1E is not significantly
different with 100 mM Ba, Ca, or Sr as permeant
ion, whereas 1C, 1A,
and 1B exhibit larger conductances in Ba than
in Ca. Error bars indicate SD. b,
1E and 1C
I-V relations and current traces evoked
by a step depolarization from 100 to 0 mV. Solid lines in
the current-voltage relations are linear regressions through the
data.
[View Larger Version of this Image (26K GIF file)]
The distinct properties of 1E are not dependent on
the expression system
To exclude contributions of the amphibian cellular
environment to the distinct properties of 1E,
we investigated the whole-cell properties of
1E transiently expressed in human embryonic
kidney cells (HEK 293). In this series of experiments, the
1E subunit was coexpressed with
2a to slow inactivation, thereby maximizing
resolution of peak currents. As expected from the Ca-induced shift in
V0.5, macroscopic Ba currents were
initially larger than Ca currents at modest depolarizations (15 mV),
but Ca currents exceed Ba currents at stronger depolarization (to +5
and +25 mV). A comparison of Figure 6 and Figure 1 shows
a similar 1E dependence on permeant ion type
in both oocytes and mammalian cells. These results indicate that the
distinctive properties of 1E are attributable
to the intrinsic permeation and gating properties of the channel and
are independent of the expression system.
Fig. 6.
Comparison of Ba and Ca whole-cell currents of
1E as expressed in HEK 293 cells.
Left, Whole-cell Ba and Ca currents elicited by the
indicated test depolarizations from a holding potential of 90 mV. The
tail potential is 80 mV. Records have been leak-subtracted by a P/8
algorithm, filtered at 2 kHz (4-pole Bessel filter), and sampled at 10 kHz. Right, Peak current versus test voltage relation.
Smooth curves are drawn by eye. Series resistance of 5 M,
compensated by 70%; cell capacitance of 34 pF. All recordings at room
temperature.
[View Larger Version of this Image (14K GIF file)]
DISCUSSION
1E permeation properties resemble those of
low-threshold Ca channels
In contrast with the higher threshold
1A, 1B, and
1C Ca channels, the biophysical and
pharmacological properties of 1E do not
exactly match any of the established classes of native Ca channels.
That 1E represents a novel type of neuronal
mid- to low-threshold Ca channel that is distinct from the commonly
accepted T-type channel has been a subject of controversy (Soong et
al., 1993; Zhang et al., 1993; Williams et al., 1994). It has been
suggested that the 1E isoform from human brain
encodes a high voltage-threshold channel (Williams et al., 1994).
Similarly, an 1E homolog from the marine ray
nervous system (Ellinor et al., 1993) exhibits
I-V characteristics more similar to high
voltage-threshold Ca channels and has been correlated with a rat
granular cell Ca current resistant to dihydropyridines, -conotoxin
GVIA, and -agatoxin IVA (termed ``R-type''; Zhang et al., 1993).
It has been argued that the time course of inactivation seen with
transiently expressed 1E channels is slow
compared with that of native T-type channels. When RNA fractions
presumably encoding for T-type channels from thalamic neurons are
injected into Xenopus oocytes, however, the resulting
waveform is also slowed compared with the channels in their native
environment (Dzhura et al., 1994), suggesting that gating kinetics may
in some instances be a poor diagnostic for identifying native
counterparts to cloned Ca channels. The rat brain
1E channel shows two pronounced differences
compared with the residual R-type current (Zhang et al., 1993). First,
unlike 1E (de Leon et al., 1995), the R-type
current described by Zhang and coworkers (1993) exhibits a faster rate
of inactivation with Ca as the charge carrier. We could not detect a
similar effect on 1E channels in either oocytes or HEK
cells, although this property is readily observed for
1C channels expressed in these two systems
(Charnet et al., 1994; de Leon et al., 1995). Second, the permeation
profile of the residual R-type current indicates a higher permeation
for Ba over Ca (Zhang et al., 1993) and is significantly different from
that reported here for 1E.
As suggested by Soong and coworkers (1993), our results provide further
support for the notion that 1E possesses
properties consistent with a subset of neuronal low-threshold Ca
channels. As summarized in Table 1, most low-threshold
(T-type) Ca channels have been shown to carry larger whole-cell
currents with Ca compared with Ba. This effect is observed in various
cell types, including atrial and ventricular myocytes (Bean, 1985,
Nilius et al., 1986), skeletal and smooth muscle cells (Beam and
Knudson, 1988, Neveu et al., 1994), pancreatic B cells (Hiriat and
Matteson, 1988), and both peripheral and central neurons (Carbone and
Lux, 1987; Fox et al., 1987; Akaike et al., 1989; Takahashi et al.,
1991). An exception to this general trend is an unusual T-type channel
from the reticular nucleus of the thalamus, which exhibits larger
currents in Ba than in Ca (Huguenard and Prince, 1992). Overall, at
both the whole-cell and single-channel levels, our results with
1E are consistent with those reported for the
majority of native low voltage-threshold channels.
Table 1.
Relative Ca2+, Ba2+, and
Sr2+ conduction through native and cloned
Ca2+ channel subtypes
| Native
type |
T |
L |
N |
P/Q |
R |
|
| ICa/IBa |
1-1.8 |
0.2-0.6 |
0.6-0.8 |
0.5 |
0.8 |
|
(1,
2, 3, 4, 5, 6, 7, 8)a |
(1, 5, 6, 7, 9, 10, 11)a |
(1,
13)a |
(14)a |
(15)a |
| ISr/IBa |
1.5-1.9 |
0.6-0.8 |
0.7 |
? |
? |
|
(2,
4, 8)a |
(12,
13)a |
(13)a |
|
|
| Expressed
cDNA |
1E |
1C |
1B |
1A |
|
|
| ICa/IBa |
1.3 |
0.4 |
0.7 |
0.7 |
|
(16)a |
(16)a |
(16)a |
(16)a |
|
| ISr/IBa |
1.5 |
0.8 |
0.9 |
0.9 |
|
(16)a |
(16)a |
(16)a |
(16)a |
|
|
|
a
Numbers refer to some of the studies
showing the permeation properties of the different channels: 1, Fox et
al., 1987; 2, Akaike et al., 1989; 3, Nilus et al., 1984; 4, Carbone et
al., 1986; 5, Bean, 1986; 6, Beam and Knudson, 1988; 7, Hiriat and
Matteson, 1988; 8, Takahashi et al., 1992; 9, Hess and Tsien, 1984; 10, Almers and McCleskey, 1984; 11, Neveu et al., 1994; 12, Hagiwara and
Ohmori, 1982; 13, Kasai and Neher, 1992; 14, Regan, 1991; 15, Zhang et
al., 1993; 16, this study.
|
|
At the macroscopic level, Williams et al. (1994) reported that the
human 1E isoform (>95% identical to the rat
brain subtype) displayed a more prominent activity in Ba rather than in
Ca. The difference may be attributable to the small differences in
amino acid sequence between the species-specific isoforms.
Alternatively, as a significant degree of rundown of
1E currents occurs, the magnitude of the whole
currents may seem to decrease in some cells if the external solutions
are not applied cyclically (e.g., Ba to Ca and then back to Ba; not
shown). In our experiments, we minimized the possibility of induced
errors arising from rundown by performing a cyclic application of
divalent ions (see Materials and Methods).
For 1E, the whole-cell current magnitude
varied with the relative ratio Sr > Ca > Ba. In contrast,
the single-channel conductances were virtually identical with
either Ba, Ca, or Sr. On the basis of a preliminary analysis of the
open probability at the plateau of the activation curve, our results
suggest that the higher maximum slope conductances obtained in Sr and
Ca are attributable to an increase in the open probability of the
channel (see 1E single-channel traces in Fig.
5b) and a reduction in the number of blank sweeps (not
shown). A similar dependence of open probability on the type of
permeant ion has been described previously for native low-threshold
channels (McDonald et al., 1994).
Ca substitution for Ba differentially affects neuronal
Ca channels
A major goal of this study was to determine permeation
characteristics of the four major classes of cloned neuronal Ca
channels under identical conditions. A number of previous studies
indicate that native high voltage-threshold Ca channels carry larger
currents with Ba as the permeant ion as compared with Ca or Sr (see
Table 1). The most detailed descriptions of divalent cation permeation
has been carried out for native L-type Ca channels from both heart and
skeletal muscle (Almers and McCleskey, 1984; Hess et al., 1986; Yue and
Marban, 1990; McDonald et al., 1994). Current permeation models assume
double occupancy of the pore and electrostatic repulsion between both
ions (Almers and McCleskey, 1984; Hess and Tsien, 1984) and suggest
that Ca ions bind more tightly within the pore than Ba ions, which
results in a smaller current amplitude. This feature seems to be common
among all L-type Ca channels; however, the absolute value of the
conductance ratio in Ba and Ca shows some variability among channels
from different tissues (e.g., cardiac vs skeletal muscle) (Beam and
Knudson, 1988) and between distinct populations of L-type channels
present in a same tissue (e.g., in aortic myocytes) (Neveu et al.,
1994). There have also been reports demonstrating that both N-type (Fox
et al., 1987; Kasai and Neher, 1992) and P-type (Regan, 1991) channels
carry larger currents in Ba compared with Ca. Our results showing
increased whole-cell Ba currents for 1A,
1B, and 1C support
these studies. Similar to that observed with native cardiac and
neuronal L-type channels, Ca substitution for Ba also increased the
rate of inactivation and seemed to decrease the steepness of the
activation curve of the 1C L-type channel
(Byerly et al., 1985; Charnet et al., 1994; Galli et al., 1994; Imredy
and Yue, 1994; Neely et al., 1994; Perez-Reyes et al., 1994; de Leon et
al., 1995). Although it is possible that some of the effects observed
at the whole-cell level are attributable to altered channel kinetics
(McDonald et al., 1994), the single-channel records support the notion
that the dependence of the whole-cell conductance on the type of
permeant ion is an intrinsic property of the permeation pathway (all of
the high voltage-activated subtypes studied here exhibited smaller
single-channel conductances when the permeant ion was switched from Ba
to Ca). The 1E channels display a unique
dependence of nickel pore block on the type of permeant ion compared
with 1A and 1C
channels, consistent with the distinct permeation properties observed
with 1E (Zamponi et al., 1996).
Implications for models of Ca channel permeation
Concentration-conductance curves obtained for the four different
types of Ca channels revealed two additional qualitative features of Ca
channels. First, with the concentration-conductance curves scaled, the
data obtained in Ba and Ca superimposed for each of the Ca channel
isoforms. Second, the concentration-conductance curves obtained for
1C appeared steeper than those of the other
channel subtypes (at 40 mM, a concentration that
produces only a 70% saturation of each 1A,
1B, and 1E, currents
through 1C are essentially saturated).
Although the multi-ion nature of the pore precludes us from estimating
a precise Kd value for binding of permeant
ions to proposed intrapore sites, these qualitative observations
suggest a stronger affinity of both Ca and Ba ions for the pore of
1C than with the remaining channel subtypes.
Second, the results also suggest that each of the channel types becomes
similarly saturated with either ion.
The half-saturation concentration is mainly dependent on the depth of
the energy wells in the pore, whereas the maximal conductance at
saturating concentrations depends predominantly on the height of the
exit barrier toward the cytoplasmic side (Hille, 1992). We observed an
effect of the type of permeant ion only on maximal conductance, and the
data suggest that the unique properties observed for
1E may be attributable to the distinct
properties of its exit barrier. Amino acids in the pore-forming regions
of the Ca channel isoforms are highly conserved across the Ca channel
isoforms (for review, see Stea et al., 1995b). It has been proposed
recently that four glutamate residues in the pore are the most crucial
determinant of permeation (Tang et al., 1993; Yang et al., 1993). The
glutamates are thought to cooperate in forming a high-affinity
interaction between the channel and permeating ions (Ellinor et al.,
1995). Electrostatic repulsion between two Ca ions ultimately drives
ions across the pore, as proposed previously for native L-type channels
(Almers and McCleskey, 1984; Hess and Tsien, 1984). Because all Ca
channels cloned to date, including 1E, possess
the four glutamate residues in similar positions, the data presented in
this study suggest that additional structural determinants within the
channel pore are likely to play a role in ion permeation. The existence
of additional determinants for permeation is also supported by the
recent report that an aspartate residue in the pore of the cardiac
1C isoform is critical for Ca binding and Cd
block (Parent et al., 1995). One conspicuous difference between
1E and the remaining Ca channel subtypes
occurs in domain I, where 1E lacks a conserved
aspartate residue at position 264. The absence of a negatively charged
residue may affect the shape of the barrier profile within the pore.
Future studies involving site-directed mutagenesis of each of the Ca
channel subtypes may identify additional amino acid residues involved
in permeation. In this regard, the unique properties of the
1E channel may prove particularly useful.
In conclusion, our data are consistent with the previous proposal
(Soong et al., 1993) that 1E channels reflect
a subset of native neuronal mid- to low-threshold Ca channels, and it
is likely that additional gene products encode other types of T-type Ca
channels. Ultimately, antisense and/or gene knockout experiments are
required to establish conclusively the exact nature of the native
counterpart of 1E channels.
FOOTNOTES
Received Feb. 29, 1996; revised May 23, 1996; accepted May 28, 1996.
This work was supported by postdoctoral fellowships from European
Molecular Biology and Institut National de la Santé et de la
Recherche Médicale to E.B. and by postdoctoral fellowships from
the Medical Research Council (MRC) of Canada to G.W.Z. and A.S.; G.W.Z.
also holds a postdoctoral fellowship from the Alberta Heritage
Foundation for Medical Research. T.W.S. is supported by a postdoctoral
fellowship and is on leave from the National Institute of Molecular and
Cell Biology, National University of Singapore. B.A.L. and L.P.J. are
supported by the National Institutes of Health Medical Scientist
Training Program. D.T.Y. is supported by a Presidential Faculty
Fellowship of the National Science Foundation. T.P.S. is an MRC
Scientist and is supported by grants from the MRC and the Howard Hughes
Medical Institute International Research Scholars Program. Travel
support was provided by NATO Grant CRG 890374 to Joël Nargeot. We
thank Drs. John Hanrahan and Mary Gilbert for comments on this
manuscript and Dr. Andy Randall for providing unpublished information
concerning R-type currents.
Correspondence should be addressed to Dr. Terry P. Snutch,
Biotechnology Laboratory, Room 237, 6174 University Boulevard,
University of British Columbia, Vancouver, British Columbia, Canada V6T
1Z3.
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