 |
 Previous Article | Next Article 
The Journal of Neuroscience, August 1, 1999, 19(15):6394-6404
Delayed Rectifier Currents in Rat Globus Pallidus Neurons Are
Attributable to Kv2.1 and Kv3.1/3.2 K+ Channels
Gytis
Baranauskas,
Tatiana
Tkatch, and
D. James
Surmeier
Department of Physiology/Northwestern University Institute for
Neuroscience, Northwestern University Medical School, Chicago, Illinois
60611
 |
ABSTRACT |
The symptoms of Parkinson disease are thought to result in part
from increased burst activity in globus pallidus neurons. To gain a
better understanding of the factors governing this activity, we
studied delayed rectifier K+ conductances in
acutely isolated rat globus pallidus (GP) neurons, using whole-cell
voltage-clamp and single-cell RT-PCR techniques. From a holding
potential of  40 mV, depolarizing voltage steps in identified GP
neurons evoked slowly inactivating K+ currents.
Analysis of the tail currents revealed rapidly and slowly deactivating
currents of similar amplitude. The fast component of the current
deactivated with a time constant of 11.1 ± 0.8 msec at 40 mV
and was blocked by micromolar concentrations of 4-AP and TEA
(KD ~140 µM). The slow
component of the current deactivated with a time constant of 89 ± 10 msec at 40 mV and was less sensitive to TEA
(KD = 0.8 mM) and 4-AP
(KD ~6 mM). Organic
antagonists of Kv1 family channels had little or no effect on somatic
currents. These properties are consistent with the hypothesis that the
rapidly deactivating current is attributable to Kv3.1/3.2 channels and the slowly deactivating current to Kv2.1-containing channels. Semiquantitative single-cell RT-PCR analysis of Kv3 and Kv2 family mRNAs supported this conclusion. An alteration in the balance of these
two channel types could underlie the emergence of burst firing after
dopamine-depleting lesions.
Key words:
globus pallidus; delayed rectifier; Kv2.1; Kv3.1/3.2; voltage clamp; single-cell RT-PCR; TEA; 4-AP; potassium channels
| |
INTRODUCTION |
Parkinson's disease (PD) is a
common neurodegenerative disease characterized by rigidity, tremor, and
bradykinesia (Bergman et al., 1998 ). The symptoms of disease are
attributable to the loss of dopaminergic neurons in the substantia
nigra pars compacta (Albin et al., 1989). These dopaminergic neurons
richly innervate basal ganglia nuclei, particularly the striatum
(Graybiel, 1990). Studies in primate models of PD surprisingly have
found few changes in striatal activity (Nisenbaum et al., 1988).
However, clear changes have been detected in the activity of one of the
major targets of the striatum the globus pallidus (GP). Following
N-methyl-phenyl-1,2,3,6-tetrahydropyridine (MPTP) lesions of
dopaminergic neurons, neurons in the external segment of the GP exhibit
a greater degree of synchrony and burst firing (Filion et al., 1991;
Hutchison et al., 1994; Nini et al., 1995). The bursting activity
patterns found in this model are correlated with muscle tremor (Bergman
et al., 1998). Neural recordings in humans suffering from PD have noted
similar alterations in GP activity (Lozano et al., 1996; Taha et al.,
1996). The proposition that this pathophysiology plays an important
role in determining the motor symptoms of PD is consistent with the
success of pallidotomy (Lozano and Lang, 1998).
The intrinsic mechanisms that permit the emergence of burst firing in
GP neurons are poorly defined. Although several factors are likely to
be involved, voltage-dependent K+ channels must be
key enablers of this anomalous activity pattern. For example, delayed
rectifier channels regulate spike repolarization and afterpotentials
that determine refractory periods and the ability to discharge at high
frequencies. At least five gene families are known to code for subunits
having delayed rectifier-like properties (Kv1, Kv2, Kv3, eag,
KCNQ) (Pongs, 1992; Shi et al., 1997, 1998; H. Wang et al.,
1998). Of these, Kv3.1/3.2 channels are unique in their ability to
deactivate within 1 msec at 60 mV (Vega-Saenz de Miera et al.,
1994; Robertson, 1997). Several studies have concluded that
these channels underlie a "fast-spiking" pattern found primarily in
GABAergic interneurons (Du et al., 1996; Massengill et al., 1997;
Martina et al., 1998; L. Wang et al., 1998). For example,
blocking a rapidly deactivating Kv3-like K+ current
reduces the ability of interneurons to discharge at high frequencies.
On the other hand, Kv2.1/2.2 channels are more slowly deactivating
(Hwang et al., 1992; Kirsch et al., 1993). The prolonged deactivation
of these channels at negative membrane potentials should increase the
relative refractory period, effectively slowing discharge rates. By
regulating the coexpression of these Kv3 and Kv2 family channels,
neurons may tune their discharge patterns effectively. This view
is consistent with recent studies of hippocampal pyramidal neurons and
interneurons that used combined patch-clamp and mRNA profiling
techniques (Martina et al., 1998).
It is not clear whether globus pallidus neurons use similar mechanisms
to control discharge patterning. As a first step toward evaluating this
possibility, acutely isolated rat GP neurons were studied with
voltage-clamp and single-cell reverse transcription-PCR (scRT-PCR)
techniques. These studies revealed the presence of both a rapidly
deactivating current attributable to Kv3.1/3.2 channels and a slowly
deactivating current attributable to Kv2.1/2.2 channels. The amplitude
of these currents at depolarized potentials was nearly the same,
suggesting that modest changes in the relative expression of either
subunit could have substantial effects on critical current properties
and discharge patterning in GP neurons.
| |
MATERIALS AND METHODS |
Tissue preparation. Globus pallidus, neostriatal, and
basal forebrain neurons from young adult rats were dissociated acutely, using procedures similar to those we have described previously (Surmeier et al., 1995). In brief, the rats were anesthetized with
methoxyflurane and decapitated; brains were removed quickly, iced, and
blocked for slicing. Sagittal slices (300 µm) were cut with a
Microslicer (Dosaka, Kyoto, Japan) while bathed in zero Ca2+ solution containing (in mM): 140 sodium isethionate, 2 KCl, 4 MgCl2, 23 glucose, and
15 HEPES, pH 7.4 (300-305 mOsm/l). Slices were incubated for 1-6 hr
at room temperature (20-22°C) in NaHCO3-buffered saline
bubbled with 95% O2/5% CO2 containing
(in mM): 126 NaCl, 2.5 KCl, 2 CaCl2, 2 MgCl2, 26 NaHCO3, 1.25 NaH2PO4, 1 pyruvic acid, 0.2 ascorbic
acid, 0.1 NG-nitro-L-arginine, 1 kynurenic acid, and 10 glucose, pH 7.4 (300-305 mOsm/l). Then the
slices were removed into the zero Ca2+ solution, and
regions of globus pallidus or dorsal neostriatum were dissected with
the aid of a dissecting microscope and placed in an oxygenated
Cell-Stir chamber (Wheaton, Millville, NJ) containing Pronase (1-2
mg/ml; Sigma protease type XIV, St Louis, MO) in HEPES-buffered HBSS
(Sigma) at 35°C. After 20-40 min of enzyme digestion, the tissue was
rinsed three times in zero Ca2+ buffer and
dissociated mechanically with a graded series of fire-polished Pasteur
pipettes. Then the cell suspension was plated into a 35 mm Lux Petri
dish containing HEPES-buffered HBSS saline, and the dish was mounted on
the stage of an inverted microscope. All reagents were obtained from Sigma.
Electrophysiological methods. Whole-cell recordings used
standard techniques (Hamill et al., 1981; Song and Surmeier,
1996). Electrodes were pulled from Corning (Corning, NY) 7052 glass and were fire-polished before use. The internal solution
consisted of (in mM): 30-60
K2SO4, 30-60
N-methyl-D-glucamine, 2 MgCl2, 40 HEPES, 5 EGTA, 12 phosphocreatine, 2 Na2ATP, 0.2 Na3GTP, and 0.1 leupeptin, pH 7.2, with H2SO4 (osmolarity, 260-270 mOsm/l). The
external solution consisted of (in mM): 140 Na-isethionate, 2 KCl, 4 MgCl2, 10 HEPES, 12 glucose, and 0.001 TTX,
pH 7.35, with NaOH (osmolarity, 295-305 mOsm/l).
In all experiments Na+ currents were blocked with
TTX, and Ca2+ currents were eliminated by replacing
the calcium with magnesium in the external solution. In some
experiments, 4-aminopyridine (4-AP; Sigma) or tetraethylammonium
chloride (TEA; Sigma) was applied. When 4-AP was included in the
extracellular solutions, the pH was adjusted to 7.35 by using
H2SO4. When 4-AP and TEA were applied at
concentrations >1 mM, the osmolarity was adjusted by
reducing the concentration of Na-isethionate. Solutions were applied by
a gravity-fed sewer pipe system. An array of application capillaries
(~400 µm inner diameter) was positioned a few hundred micrometers
from the cell under study. Solution changes were effected by altering
the position of the array with a DC drive system controlled by a
microprocessor-based controller (Newport, Irvine, CA). Solution changes
were complete within <1 sec.
Recordings were obtained with an Axon Instruments 200 patch-clamp
amplifier and controlled and monitored with a PC running pClamp
software (version 7.0) with a 125 kHz interface (Axon Instruments, Foster City, CA). Electrode resistance was typically 1.5-2.2 M in
the bath. After seal rupture the series resistance (4-10 M) was
compensated (75-90%) and monitored periodically. Potentials were not
corrected for the liquid junction potential, which was estimated to be
1-2 mV. All averaged data are presented as an average ± SEM. All
data fits were obtained with Igor Pro (version 3.12, WaveMetrics, Lake
Oswego, OR) software by the least-squares method. Activation data were
fit with a Boltzmann equation of the form: 1/(1 + exp
[(Vh V)/Vc], where V
stands for membrane potential, Vh is the
half-activation voltage, and Vc is the slope constant. Dose-response data were fit with a Langmuir isotherm of the
form: C/(C + IC50), where
C stands for a concentration of the blocking agent.
Statistical analyses were run with SYSTAT (version 5.2; Evanston, IL);
small, nonmatched samples were analyzed with Kruskal-Wallis ANOVA.
Single-cell RT-PCR (scRT-PCR). Two types of scRT-PCR
profiling were performed. To maximize mRNA yields, we aspirated some neurons without recording. Isolated neurons were patched in the cell-attached mode and lifted into a stream of control solution. Neurons then were aspirated into the electrode. Electrodes contained ~5 µl of sterile water. In other experiments the neurons briefly were subjected to whole-cell voltage-clamp recordings before
aspiration. In these cases the electrode recording solution was made
nominally RNase-free, and the total volume was kept near 5 µl. In
both sets of experiments the capillary glass used for making the
electrodes was autoclaved and heated to 200°C for 1 hr. Sterile
gloves were worn during the procedure to minimize RNase contamination.
After aspiration of the neuron the electrode was removed from the
holder and broken; the contents were ejected into a 0.5 ml Eppendorf tube containing 3.6 µl of diethyl pyrocarbonate-treated water, 0.7 µl of RNasin (28,000 U/ml), and 0.7 µl of oligo-dT (0.5 µg/µl). The mixture was heated to 70°C and incubated on ice for 1 min. Single-strand cDNA was synthesized from the cellular mRNA by the addition of SuperScript II RT (1 µl, 200 U/µl), 10× PCR buffer, MgCl2 (2 µl, 25 mM), DTT (2 µl, 0.1 M), and mixed dNTPs (1 µl, 10 mM), followed
by incubation at 42°C for 50 min. The reaction was terminated by
heating the mixture at 70°C for 15 min and then icing it. The RNA
strand in the RNA-DNA hybrid was removed by adding 1 µl of RNase H
(2 U/µl) and was incubated for 20 min at 37°C. All reagents except
RNasin (Promega, Madison, WI) were obtained from Life
Technologies (Grand Island, NY). The cDNA from the reverse transcription (RT) of RNA in a single neuron was subjected to PCR to
detect the expression of various mRNAs. Conventional PCR was performed
with a thermal cycler (MJ Research, Watertown, MA). PCR primers were
developed from GenBank with the commercially available software OLIGO
(National Biosciences, Plymouth, MN). Primers for choline
acetyltransferase (ChAT), GAD67, Kv3.4, and parvalbumin (PV) were
described previously (Song and Surmeier, 1996; Yan and Surmeier, 1996;
Tkatch et al., 1998; Vysokanov et al., 1998). Kv2.1 mRNA
(GenBank accession X16476) was detected with a pair of primers
5'-CAACTTCGAGGCGGGAGTC (position 2244) and 5'-TCCAGTCAACCCTTCTGAGGAGTA
(position 2449), which give a PCR product of 229 bp. Kv2.2 mRNA
(GenBank accession M77482) was detected with a pair of primers
5'-ACCAGGAGGTTAGCCAAAAAGACT (position 1861) and
5'-AGGCCCCTTATCTCTGCTTAGTGT (position 2283), which give a PCR product
of 446 bp. Kv3.1 mRNA (GenBank accession X62840) was detected with a
pair of primers 5'-CCAACAAGGTGGAGTTCATCAAG (position 1089) and
5'-TGGTGTGGAGAGTTTACGACAGATT (position 1704), which give a PCR product
of 640 bp. Kv3.2 mRNA (GenBank accession X62839) was detected with a
pair of primers 5'-ACCTAATGATCCCTCAGCGAGTGA (position 1417) and
5'-CAAAATGTAGGTGAGCTTGCCAGAG (position 1692), which give a PCR product
of 302 bp.
PCR procedures were performed following procedures designed to minimize
the chance of cross-contamination (Cimino et al., 1990). Negative
controls for contamination from extraneous and genomic DNA were run for
every batch of neurons. To ensure that genomic DNA did not contribute
to the PCR products, we aspirated and processed neurons in the normal
manner, except that the reverse transcriptase was omitted.
Contamination from extraneous sources was checked by replacing the
cellular template with water. Both controls were consistently negative
in these experiments.
| |
RESULTS |
Our previous work has shown that ~15-20% of the neurons
dissociated from the globus pallidus region express ChAT mRNAa marker of cholinergic neurons (Tkatch et al., 1998). Because it is believed that all globus pallidus projection neurons are exclusively GABAergic (Rouzaire-Dubois et al., 1980; Gritti et al., 1993), these neurons are
considered to be displaced cholinergic neurons from the adjacent basal
forebrain nucleus of Meynert (Armstrong et al., 1983; Tkatch et al.,
1998). Unless otherwise noted, all of the GP neurons reported here
expressed mRNA for glutamate decarboxylase (67 kDa isoform) (GAD67),
but not ChAT. Of these, 24 GP neurons were subject to physiological
analysis, and an additional sixty-three were sampled for scRT-PCR alone.
Tail currents were bi-exponential
Delayed rectifier currents were evoked by depolarizing voltage
steps from a holding potential of 40 mV. Previous work had shown that
A- and D-type K+ currents inactivate within seconds
at this potential (Stefani et al., 1992, 1995; our unpublished
observations). The currents evoked by this protocol were either
noninactivating or slowly inactivating (Fig.
1A). To estimate the
voltage dependence of activation and deactivation kinetics, we
measured tail currents at 40 mV immediately after the test
voltage step. As shown in Figure 1B, tail current
amplitudes saturated for test steps above ~0 mV. Kinetic analysis
of the tails clearly indicated that there were fast and slow components
of the tail currents (see the semilog plot inset, Fig.
1B). The time constant of each component was estimated from a bi-exponential fit of the tail currents after a step
to +20 mV. The fast component had a time constant of 11.1 ± 0.8 msec, and the slow component had a time constant of 89 ± 10 msec
(n = 10; at 40 mV). These time constants then were
used to constrain the bi-exponential fit of tail currents after steps to less depolarized potentials. The fast and slow components of the
tail separated in this way are shown in Figure 1, C and
D, respectively. Plots of the fast and slow tail amplitude
as a function of test voltage were fit with a Boltzmann function (Fig.
1E). Although there was a tendency for the slow
component to activate at more negative potentials
(Vh = 18 mV;
Vc = 7 mV) than the fast component
(Vh = 13 mV;
Vc = 5 mV), this difference was not statistically significant (p > 0.05;
n = 4; Kruskal-Wallis ANOVA). In addition to being
similar in voltage dependence, these two components were similar in
size. The amplitude of the rapidly deactivating current was, on
average, 56 ± 3% of the total current (n = 10).
The conductance density of the rapidly deactivating currents was, on
average, 3.8 ± 0.9 nS/pF, whereas the slowly deactivating current
was 3.0 ± 0.8 nS/pF (n = 10).
View larger version (28K):
[in this window]
[in a new window]
|
Figure 1.
Delayed rectifier currents in GP neurons have
rapidly and slowly deactivating components that differ in activation
voltage dependence. A, Currents evoked during
voltage-clamp experiment by protocol shown at the top of
each panel. B, Tail currents obtained during experiment
shown in A at 40 mV membrane potential after
increasingly more depolarized voltage steps. C, Rapidly
deactivating component of tail currents shown in B
obtained by subtraction of steady-state and slow components of
double-exponential fit. D, Slowly deactivating component
of tail currents obtained by subtraction of steady-state and fast
components of double-exponential fit. E, Plot of rapidly
(open circles) and slowly (filled
circles) deactivating tail current amplitudes as a function of
the preceding voltage step for the cell shown in A. The
lines show Boltzmann fits of the experimental data;
Vh is the half-activation voltage, and
Vc is the slope constant.
|
|
Because previous studies have suggested that PV expression may be an
important predictor of functional properties of GP neurons (Kita, 1994;
Kawaguchi et al., 1995), GAD-expressing GP neurons having detectable
levels of PV mRNA were compared with those that lacked such expression.
Although these two populations did not differ significantly in their
current amplitudes, the ratio of the rapidly to slowly deactivating
current was significantly larger in neurons having detectable levels of
PV mRNA (median = 1.5; n = 4) than in neurons
lacking detectable PV mRNA (median = 0.9; n = 5;
p < 0.02; Kruskal-Wallis ANOVA).
Rapidly and slowly deactivating currents were
pharmacologically distinguishable
The differences in the voltage dependence of the rapidly
and slowly deactivating currents suggest that they are attributable to
distinct channel proteins. To test this hypothesis, we used pharmacological tools.
First, the sensitivity of each component of the tail current to TEA was
examined. TEA commonly is found to block delayed rectifier currents
(Rudy, 1988). At the lowest concentration tested in this cell (100 µM), TEA significantly reduced currents evoked by a test
step to +40 mV from a holding potential of 60 mV (Fig.
2A). Increasing the
concentration of TEA progressively blocked more of the current, but a
component was left unblocked by the highest concentration tested (10 mM) in this cell (similar results were obtained with up to
50 mM TEA in other cells). Analysis of the fast and slow
components of the tail current revealed a differential sensitivity to
TEA. The fast component of the tail was very sensitive to TEA (Fig.
2C), having an IC50 of 0.14 mM
(Fig. 2E). On the other hand, the slow component of
the tail current was blocked significantly at higher concentrations
(Fig. 2D), having an IC50 (0.80 mM) nearly six times greater than the fast component (Fig. 2E).
View larger version (30K):
[in this window]
[in a new window]
|
Figure 2.
TEA differentially blocks rapidly and slowly
deactivating currents. A, Currents evoked in the
presence of different concentrations of TEA by the voltage-clamp
protocol shown above the traces. B, Tail
currents at 40 mV obtained during the experiment shown in
A. C, Rapidly deactivating tail currents
in increasing concentrations of TEA obtained by the subtraction method
described in Figure 1. D, Slowly deactivating tail
currents in increasing concentrations of TEA. E, Plot of
rapidly and slowly deactivating tail current amplitudes as a function
of TEA concentration. The lines represent Langmuir
first-order fits of experimental data.
|
|
Second, the sensitivity of each component of the tail current to 4-AP
was examined. In many vertebrate neurons, 4-AP preferentially blocks
A-like potassium current (Rudy, 1988), but recently it has been shown
that some types of delayed rectifier current are also sensitive to
submillimolar concentrations of 4-AP (Du et al., 1996; Massengill et
al., 1997; Martina et al., 1998; L. Wang et al., 1998). These
4-AP-sensitive delayed rectifiers typically deactivate rapidly (Du et
al., 1996), much like Kv3.1/3.2 channels (Vega-Saenz de Miera et al.,
1994). In GP neurons, low concentrations (0.1 mM) of 4-AP
significantly reduced the total current (Fig. 3A). As predicted, the rapidly
deactivating component of the current was more sensitive to 4-AP than
the slowly deactivating component (Fig. 3C,D). The estimated
IC50 for the fast component was 0.14 mM,
whereas it was >1 mM for the slow component of the tail
current (Fig. 3E).
View larger version (26K):
[in this window]
[in a new window]
|
Figure 3.
4-AP differentially blocks rapidly and slowly
deactivating currents. A, Currents evoked in the
presence of different concentrations of 4-AP by the voltage-clamp
protocol shown above the traces. B, Tail
currents at 40 mV obtained during the experiment shown in
A. C, Rapidly deactivating tail currents
in increasing concentrations of 4-AP obtained by the subtraction method
described in Figure 1. D, Slowly deactivating tail
currents in increasing concentrations of 4-AP. E, Plot
of rapidly and slowly deactivating tail current amplitudes as a
function of 4-AP concentration. The lines represent
Langmuir first-order fits of experimental data.
|
|
Last, the sensitivity of each component of the tail current to
margatoxin (MgTX) and  -dendrotoxin (DTX) was examined. These two
toxins block Kv1 family channels. DTX blocks Kv1.1, Kv1.2, and Kv1.6
channels, and MgTx blocks Kv1.2 and Kv1.3 channels (Grupe et al., 1990;
Grissmer et al., 1994; Vega-Saenz de Miera et al., 1994). Neither toxin
substantially reduced whole-cell currents. MgTx (5 nM)
reduced peak current by only 9 ± 3% at +40 mV (n = 4; data not shown). DTX (100 nM) did not have any
detectable effect in seven of nine cells tested (data not shown). In
two cells it reduced peak current by ~15% at +40 mV (data not
shown). These results argue that Kv1 family channels do not make a
major contribution to proximal somatodendritic K+
currents and are consistent with immunocytochemical studies suggesting an axonal and terminal location in globus pallidus neurons (Sheng et
al., 1992; Rhodes et al., 1997) and other cell types (Sheng et al.,
1993; Martina et al., 1998; Song et al., 1998) (but see Maletic-Savatic et al., 1995).
Single-cell RT-PCR analysis revealed Kv2.1 and
Kv3.1/3.2 coexpression
The biophysical and pharmacological properties of two components
of the delayed rectifier suggest that they are attributable to two
distinct channel types. Rapid deactivation and high affinity for both
TEA and 4-AP are characteristics typical of channels containing
Kv3.1/3.2 subunits (Vega-Saenz de Miera et al., 1994). The
insensitivity to MgTx and DTX is also consistent with this identification. In agreement with this conclusion, scRT-PCR analysis detected Kv3.1 mRNA in 21 of 31 GP neurons that were tested. Kv3.2 mRNA
was detected in a smaller percentage of GP neurons (6/13). To gain a
better understanding of the less than perfect detection probabilities,
we undertook semiquantitative analyses of Kv3.1 and Kv3.2 mRNA
abundance (Song et al., 1998; Tkatch et al., 1998). These studies used
a serial dilution technique to determine what fraction of the total
cellular cDNA was required to reach a standard detection threshold with
PCR. The higher the abundance of a particular template, the smaller
will be the fraction of the cellular cDNA required to reach the
detection threshold. Because this approach controls for differences in
reverse transcription and amplification efficiency, a transcript can be
compared across a single population or between populations. In the case
at hand, if two populations of GP neuron were presentone expressing
high levels of Kv3.1/3.2 and another expressing little or nonethe
distributions of detection thresholds should be bimodal. In fact, the
distributions of both Kv3.1 and Kv3.2 were mainly unimodal (Fig.
4B,C), arguing that, insofar as these mRNAs were concerned, GP neurons were approximately similar (these results do not exclude the possibility that there are
smaller quantitative differences between GP neurons). A comparison of
neurons having detectable levels of PV with those lacking detectable levels failed to reveal any significant differences in Kv3.1 or Kv3.2
expression levels. This conclusion is consistent with the electrophysiological data showing the presence of a rapidly
deactivating component of the tail current in all GP neurons,
regardless of PV detection.
View larger version (27K):
[in this window]
[in a new window]
|
Figure 4.
Serial dilution experiments demonstrate that Kv3.1
and Kv3.2 mRNAs are expressed by GP neurons and that variation in
detection frequency is not likely to reflect prominent subpopulations.
A, Representative serial dilution gel for Kv3.1 mRNA
detection in GP neuron. The first lane on the
left of gel is the marker. The first lane
on the right is for PV mRNA detection with no visible
PCR product band; hence, the cell was PV mRNA-negative. The
second band on the right is for ChAT mRNA
detection with no visible PCR product band; hence the neuron was not
ChAT-positive. The four lanes in between
were obtained after the use of an increasing (from left
to right) amount of total cellular cDNA (expressed in
log2 units) to detect Kv3.1 mRNA. Note that one-eighth of
the total cDNA was enough to detect Kv3.1 transcripts in this cell.
B, Summary of detection thresholds for Kv3.1 mRNA
detection in GP neurons. The thin line represents a
Gaussian fit. C, Summary of detection thresholds for
Kv3.2 mRNA detection in GP neurons.
|
|
Less clear is the identity of the slowly deactivating component of the
delayed rectifier currents. Kv2.1 channels are slowly deactivating,
with time constants similar to those seen here. They are also
relatively insensitive to 4-AP and insensitive to MgTx and DTXas is
the slowly deactivating current in GP neurons. The one notable
difference between the reported properties of Kv2.1 channels and the GP
current is their sensitivity to TEA. In heterologous expression
systems, rat Kv2.1 channels have a very low affinity for TEA, having
IC50 values between 3 and 10 mM (Frech et al.,
1989; Taglialatela et al., 1991; Ikeda et al., 1992). In contrast, our
estimated IC50 was <1 mM.
Two additional experiments were performed to test the linkage between
the slowly deactivating current and Kv2.1 channels. First, in addition
to slow deactivation, Kv2.1 channels inactivate slowly at depolarized
potentials (VanDongen et al., 1990). To determine whether the slowly
deactivating current also inactivated slowly, we isolated this
component of the current by recording in the presence of 0.3 mM TEA (approximately twice the IC50 of the
rapidly deactivating component). The inactivating component of the
remaining current was isolated by subtraction. As shown in Figure
5A, currents were evoked first
by a step to +40 mV from a holding potential of 60 mV. The
noninactivating part of the current was isolated by stepping to 0 mV
for 10 sec before the test step to +40 mV. Subtraction of the currents
evoked with the prepulse from those evoked without the prepulse
currents yielded an estimate of the inactivating current (Fig.
5B). The initial component of the current isolated by this
procedure inactivated more rapidly than currents attributable to Kv2.1
(VanDongen et al., 1990). Based on our profiling data (not shown), this
rapidly inactivating component of the current is attributable mainly to channels containing Kv3.4 subunits (Schroter et al., 1991; Vega-Saenz de Miera et al., 1994). These channels inactivate almost completely in
the first 500 msec of the step at +40 mV and should not contribute to
tail currents. So, in the presence of 0.3 mM TEA, currents late in the response should be attributable mainly to Kv2.1-like channels. In agreement with this conclusion, tail currents at the end
of the step were mainly slow (slow tail amplitude was ~80% of the
total), in contrast to the control condition in which the rapidly
deactivating component was ~60% of the peak current. Semilog plots
of evoked currents also showed that the late component of the currents
decayed with a time constant near 3 sec at +40 mV (Fig. 5B),
similar to that described for Kv2.1 current in heterologous systems
(VanDongen et al., 1990; Klemic et al., 1998). To determine TEA
sensitivity of this component, we recorded currents in increasing concentrations of TEA (Fig. 5A,C). A plot of the fraction of
the inactivating current (measured at the end of the step) blocked as a
function of TEA concentration is shown in Figure 5D. The IC50 estimated from a Langmuir isotherm fit of these data
was 0.8 mMthe same value obtained for the slowly
deactivating tail currents.
View larger version (33K):
[in this window]
[in a new window]
|
Figure 5.
Slowly inactivating currents have
pharmacological properties similar to those of the slowly deactivating
currents. A, Currents evoked by the voltage-clamp
protocol shown at the top. The protocol was applied each
40 sec. The thin lines show currents evoked with a
prepulse to 0 mV. The protocol was applied in the presence of 0.3, 1, and 10 mM TEA. B, Semilogarithmic plot of
the current, obtained by stepping from 60 to 0 mV. The solid
line shows the exponential fit of the slow component of the
data; the time constant was 3.4 sec. C, Inactivating
fraction of the current at +40 mV. This current was obtained by
subtracting the currents evoked by the step to +40 mV without and with
the 10 sec prepulse to 0 mV. D, A graph depicts the
normalized amplitude of the block by TEA of the inactivating current
shown in C. It was assumed that 0.3 mM TEA
leaves the same fraction of inactivating current as seen Figure 2,
D and E.
|
|
Next, scRT-PCR experiments were performed to determine whether GP
neurons expressed Kv2.1 mRNA. In 12 of 16 GP neurons that were
examined, Kv2.1 mRNA was detected. Kv2.2 mRNA also was detected, but at
much lower frequencies (two of eight). Multiplex amplification consistently found coexpression of Kv2.1 and Kv3.1 mRNAs (data not
shown). Serial dilution experiments showed that Kv2.1 detection thresholds were distributed unimodally, arguing for a single population of GP neurons insofar as Kv2.1 expression was concerned. This again was
consistent with the electrophysiological data showing that all GP
neurons expressed the slowly deactivating current. Then an attempt was
made to correlate Kv2.1 detection thresholds in individual GP neurons
to current amplitudes recorded in that neuron. In these experiments the
amplitude of the inactivating current was measured (Fig. 5) rather than
the tail currents to avoid the possible contribution of KCNQ
family genesthese genes encode a noninactivating channel with a
pharmacological profile and deactivation kinetics similar to that of
Kv2.1 channels (H. Wang et al., 1998). In our sample of GP neurons the
amplitude of the slowly inactivating current measured in the presence
of 0.3 mM TEA and Kv2.1 detection thresholds were
positively correlated, but the correlation was not strong. For example,
at a given current amplitude the detection thresholds could vary by a
factor of two or more. Because the scRT-PCR was performed after
extended electrophysiological recording, the weakness of the
correlation is not particularly surprising. Variation in mRNA
degradation during recording, aspiration, or RT efficiency all could
have contributed to the failure to detect a correlation.
To overcome this obstacle, we altered our experimental strategy in two
ways. First, to increase the range of Kv2.1 mRNA expression in our
sample, we studied two additional populations of neuron. Basal
forebrain cholinergic neurons and striatal cholinergic interneurons both have Kv2.1-like currents but in very different relative
amplitudes. Initial profiling work suggested that basal forebrain
neurons expressed high levels of Kv2.1 mRNA, and cholinergic
interneurons expressed low levels. Second, rather than trying to
profile neurons after prolonged recording that could compromise our
ability to estimate Kv2.1 mRNA abundance accurately, we divided neurons
into two groups. One group was studied electrophysiologically to
determine the amplitude of the Kv2.1-like current. These neurons were
profiled only for phenotyping markers (GAD67, ChAT, PV). The other
group was simply aspirated and profiled without recording. Because
basal forebrain and striatal cholinergic neurons could be identified visually in the dissociated cell preparation, sampling from them was
relatively straightforward. Then these neurons were subjected to serial
dilution analysis of Kv2.1 mRNA abundance.
The serial dilution experiments are summarized in Figure
6. On the left side of each panel is a
representative gel from an individual neuron showing the serial
dilution of cellular cDNA. On the right of each panel is a histogram
showing the distribution of detection thresholds in our sample of
neurons. Each histogram is fit with a Gaussian function. Note that, as
with Kv3.1 mRNA, the detection thresholds in GP neurons were
distributed unimodally, arguing that there were not pronounced
differences in expression within this population. Explicit comparisons
of neurons having detectable levels of PV mRNA with those lacking
detectable levels failed to resolve a clear difference in Kv2.1 mRNA
abundance. As can be seen by comparing the distributions in the other
neuronal populations, Kv2.1 mRNA was of intermediate abundance in GP
neurons relative to that in basal forebrain cholinergic neurons and
striatal cholinergic interneurons.
View larger version (69K):
[in this window]
[in a new window]
|
Figure 6.
Serial dilution experiments demonstrate
differences in Kv2.1 mRNA abundance in three cell types. Representative
serial dilution gels for each cell type are shown on the left
side of each panel. The first lane on the
left of gels is the marker; the second
lane is a phenotyping transcript (GAD67 or ChAT). The
last five lanes are Kv2.1 amplicons produced by runs
with increasing fractions of total cellular cDNA (expressed in
log2 units). Note that in all three cells the use of
one-half of the total cellular cDNA resulted in detection. However,
only 1/16th of the total cDNA was sufficient in basal forebrain
cholinergic neurons. On the right side of each panel is
the distribution of detection thresholds for Kv2.1 mRNA in that cell
type. Note that Kv2.1 mRNA appeared to be most abundant in the basal
forebrain cholinergic neurons, of intermediate abundance in GP neurons,
and least abundant in striatal cholinergic interneurons. The
thin line is a Gaussian fit of the distribution.
|
|
Next, the amplitude of the inactivating current in the presence of 0.3 mM TEA and 100 nM DTX was measured with a
protocol like that described in Figure 5. Again, currents were measured at the end of the test step to minimize the contribution of Kv3.4 and
any other rapidly inactivating channel. A representative set of current
traces from a GP neuron is shown in Figure
7A. The mean Kv2.1-like
current measured in each population then was plotted against the mean
detection threshold (expressed as a fraction of total cDNA) for Kv2.1
mRNA in that same population. The result is shown in Figure
7B. The data were very well fit with a straight line
(R2 = 0.98) having a zero intercept.
The strength of the correlation argues that the slowly inactivating,
slowly deactivating current in GP neurons is attributable to
K+ channels containing Kv2.1 subunits.
View larger version (20K):
[in this window]
[in a new window]
|
Figure 7.
Kv2.1-like currents are related linearly to
estimates of Kv2.1 mRNA abundance. A,
K+ currents were evoked by the voltage-clamp
protocol shown above the traces. Currents evoked with
and without a prepulse to 0 mV are superimposed. Protocols were
separated by a 40 sec recovery period. B, Average
amplitudes of the measured current in three cell types
(filled circles) are plotted against the average
of detection threshold obtained from the data shown in Figure 6
(right panels). The line represents the
regression line fit to the data points
(R2 = 0.98). The thin
lines from the filled circles represent SEM for
the current amplitude (vertical lines) and for the
detection threshold (horizontal lines).
|
|
| |
DISCUSSION |
Our results show that delayed rectifier currents in rat GP neurons
have rapidly and slowly deactivating components that are approximately
equal in size. In addition to deactivation kinetics, these two currents
differed in their activation voltage dependence and their sensitivity
to the inorganic K+ channel blockers TEA and 4-AP.
These differences were consistent with their attribution to distinct
channel types. Although tail currents arising from the deinactivation
of rapidly inactivating A-like K+ channels have been
described (Demo and Yellen, 1991; Ruppersberg et al., 1991), these
currents are unlikely to have made a significant contribution to the
measurements here. These currents arise primarily from channels passing
through an open state in recovering from N-type inactivation. Two types
of A-like current were observed in GP neurons: a high-threshold,
TEA-sensitive current attributable to Kv3.4 channels (see Fig. 5) and a
low-threshold, TEA-insensitive current attributable to Kv4 family
channels (our unpublished observations). At 40 mV (where tail
currents were measured), Kv4 family channels are inactivated completely
(Serodio et al., 1994; Song et al., 1998), eliminating any concern
about the contribution of these channels to the tail currents. Although
potential contributors, the absence of a slow TEA-sensitive component
of the tail current argues that deinactivation of Kv3.4 channels was
not a significant factor in our paradigm (Ruppersberg et al.,
1991).
Rapidly deactivating currents are attributable to
Kv3.1/3.2 channels
The rapidly deactivating current was very sensitive to TEA and
4-AP, having IC50 values of 140 µM for both
blockers. On the other hand, this current was insensitive to DTX and
MgTX. In addition, this component of the current activated at
relatively depolarized potentials (Vh = 13 mV). All of these properties are similar to those described for
channels containing Kv3.1/3.2 subunits (Vega-Saenz de Miera et al.,
1994), with the exception of a slightly more negative activation
voltage dependence, which may be attributed to channel phosphorylation
(Murakoshi et al., 1997) or minor differences in recording conditions.
In agreement with this attribution, both Kv3.1 and Kv3.2 mRNA were
detected readily in GP neurons. This finding is in agreement with
previous studies localizing Kv3.1 mRNA in the globus pallidus (Weiser
et al., 1994). Serial dilution via scRT-PCR revealed that the abundance
of these mRNAs was mainly unimodal, suggesting that there were not
prominent subpopulations of the GP neuron, based on expression levels
of either mRNA. There also did not appear to be any significant
correlation between Kv3.1/3.2 mRNA expression and parvalbumin mRNA
expression. Additional studies will be required to determine whether
the expression of Kv3 family subunits or the properties of currents
arising from these channels are correlated with other features of GP
neurons, such as axonal projection site.
Slowly deactivating currents are attributable to
Kv2.1 channels
The slowly deactivating delayed rectifier currents were relatively
insensitive to 4-AP (IC50 ~6 mM) but
possessed a moderate sensitivity to TEA (IC50 = 0.8 mM). These currents were insensitive to DTX and only
marginally sensitive to MgTX. This pharmacological profile suggests
that channels containing Kv1.1-3 and Kv1.6 subunits do not make a
major contribution to this somatodendritic current (Stuhmer et al.,
1989; Swanson et al., 1990; Leonard et al., 1992; Garcia-Calvo et al.,
1993; Grissmer et al., 1994; Tytgat et al., 1995), despite the fact
that several of these mRNAs (Kv1.1, 1.2, 1.5, and 1.6) were detected by
scRT-PCR analysis of GP neurons. The failure to detect substantial Kv1
family currents in the soma and proximal dendrites of GP neurons is
consistent with a number of other studies suggesting that these
channels are either in axonal or in distal dendritic regions (Sheng et
al., 1992; Song et al., 1998) (cf. Maletic-Savatic et al., 1995).
In contrast, Kv2 family channels possess a pharmacological profile
similar to that of the slowly deactivating current. Kv2.1 channels are
insensitive to DTX and MgTx (Knaus et al., 1995; Swartz and MacKinnon,
1995) and relatively insensitive to 4-AP (Frech et al., 1989; Kirsch et
al., 1993). In addition, Kv2.1 currents are slowly inactivating between
60 and 0 mV, much like the currents producing the slow tail current
(VanDongen et al., 1990). These properties differentiate Kv2.1 currents
from those attributable to either Kv1-, Kv3-, KCNQ-, or eag-family
channels. As discussed above, Kv1 family channels are unlikely to have
made a major contribution to the slowly deactivating delayed rectifier current. A contribution of Kv3-family channels, including the slowly
inactivating Kv3.3 channel, can be excluded on the basis of their
sensitivity to 4-AP (Schroter et al., 1991; Vega-Saenz de Miera et al.,
1994). KCNQ-family channels are unlikely to have contributed to any
significant extent because they exhibit very little inactivation at
potentials below +10 mV (Pusch et al., 1998; Tristani-Firouzi and
Sanguinetti, 1998; Yang et al., 1998) and are very insensitive to 4-AP
(Yang et al., 1998). Last, eag-family channels can be discarded as
important determinants of the observed currents because of their
relative insensitivity to both TEA and 4-AP (Faravelli et al., 1996;
Shi et al., 1998). These factors all point to Kv2 family channels as
being responsible for the slowly deactivating, slowly inactivating
delayed rectifier in GP neurons.
Another compelling argument that the kinetically slower delayed
rectifier current is attributable to channels containing Kv2.1 subunits
comes from the scRT-PCR experiments. First, semiquantitative scRT-PCR
profiles showed that Kv2.1 mRNA was expressed by GP neurons. On a
cell-by-cell basis, Kv2.1 mRNA abundance estimates were correlated positively with Kv2.1-like current amplitudes. When the range of Kv2.1
mRNA expression was expanded and profiling was performed only on
neurons that had not been subjected to extended dialysis, a very linear
relationship was found between Kv2.1 mRNA abundance and Kv2.1-like
conductance over a broad range. This relationship resembles that
reported between shal gene expression and A-current magnitude in lobster stomatogastric neurons (Baro et al., 1997). It is
difficult to imagine how this strong correlation could have arisen in
our case if Kv2.1 subunits were not participants in the channels
underlying these currents. This conclusion does not exclude the
possibility of heteromeric channels, but the available evidence
suggests that Kv2.1/Kv2.2 heteromultimeric channels are unlikely to be
important (Blaine and Ribera, 1998).
The only significant difference between the properties of the slowly
deactivating K+ current and those of Kv2.1 channels
in heterologous expression systems is TEA sensitivity. Kv2.1 channels
have been reported to have a TEA IC50 of 3-10
mM (Frech et al., 1989; Taglialatela et al., 1991; Ikeda et
al., 1992). In GP neurons the slowly deactivating current had a TEA
IC50 of 0.8 mM. The Kv2.1-like current in
striatal cholinergic interneurons and basal forebrain neurons possessed a similar TEA sensitivity (data not shown). There are several possible
explanations for this discrepancy. Post-translational modification of
the extracellular face of the channel (e.g., glycosylation) could alter
the apparent affinity for TEA (Kavanaugh et al., 1991). Another
possibility is that auxiliary subunits alter TEA sensitivity (Zagotta
et al., 1989). Auxiliary subunits are known to prolong deactivation
time constants (Kramer et al., 1998) and may be responsible for a
somewhat slower deactivation time constant in GP neurons at 40 mV
(~89 msec) than found in Xenopus oocytes (~45 msec). A
definitive test of the hypothesis that Kv2.1 subunits contribute to the
slowly deactivating channels will require alterations in Kv2.1
expression or function in situ. Negative-dominant strategies that use viral vectors currently are being explored to this end. Another means of providing a molecular identification would be the
application of Kv2-specific antibodies that disrupt channel function
(Murakoshi and Trimmer, 1999).
The ratio of rapidly to slowly deactivating currents may govern the
ability to discharge at high rates
Rapidly deactivating K+ currents like those
attributable to Kv3.1/3.2 channels have been associated with "fast
spiking" or the capacity to discharge at high rates for a sustained
period of time in a variety of brain neurons, including interneurons (Du et al., 1996; Massengill et al., 1997; Martina et al., 1998) and
auditory neurons (L. Wang et al., 1998). The speed with which these
channels deactivate minimizes hyperpolarizing K+
currents after spike repolarization, effectively shortening the relative refractory period. However, these rapidly deactivating currents typically are coexpressed with more slowly deactivating currents that can moderate their impact on discharge patterning and
rates. For example, Martina et al. (1998) found that the ratio of
rapidly to slowly deactivating currents in fast spiking hippocampal interneurons was ~2, whereas it was <0.5 in slowly spiking
hippocampal pyramidal neurons. In GP neurons having detectable levels
of PV mRNA, this ratio was close to that in hippocampal interneurons (~1.5), whereas it was significantly lower in neurons lacking detectable levels of PV mRNA (~0.9). This difference is consistent with reports that approximately three-fourths of the GP population (presumably PV-expressing neurons) in rat are capable of discharging repetitively at high rates (Kita and Kitai, 1991). A similar behavior is found in primates, for which a high, regular discharge rate is
thought to be functionally important (Wichmann and DeLong, 1996;
Bergman et al., 1998). Although our scRT-PCR profiling was not able to
resolve differences in Kv3.1 and Kv2.1 expression that could explain
the differences in the ratio of rapidly to slowly deactivating
currents, it is our working hypothesis that this simply reflects
current technical limitations in estimating small differences in mRNA
abundance in single cells.
After the loss of dopaminergic neurons innervating the basal ganglia,
many GP neurons begin to discharge more frequently in bursts and at
higher rates within bursts (Filion and Tremblay, 1991; Hutchison et
al., 1994). This aberrant high-frequency discharge is thought to be a
critical determinant in the emergence of tremor and rigidity in
Parkinson's disease (Taha et al., 1996; Wichmann and DeLong, 1996). In
rats that followed similar manipulations in dopamine levels, Kv3.1 mRNA
is upregulated in GP neurons (Chesselet et al., 1998). This
upregulation can be expected to alter the ratio of rapidly deactivating
(Kv3.1/3.2) channels to slowly deactivating Kv2.1 channels in GP
neurons. One consequence of this change would be an enhanced ability to
discharge at high frequencies, as observed after dopamine depletion.
Although other ionic conductances are likely to contribute to the
emergence of this altered pattern of activity, genetic manipulations
that serve to normalize the Kv3.1/Kv2.1 ratio should assist in
suppressing unwanted high-frequency activity.
| |
FOOTNOTES |
Received March 8, 1999; revised May 17, 1999; accepted May 21, 1999.
This work was supported by National Institute of Neurological Diseases
and Stroke Grants NS 26473 and NS 34696 to D.J.S.
Correspondence should be addressed to Dr. D. James Surmeier, Department
of Physiology/Northwestern University Institute for Neuroscience,
Northwestern University Medical School, Searle 5-474, 320 East Superior
Street, Chicago, IL 60611.
| |
REFERENCES |
-
Albin RL,
Young AB,
Penney JB
(1989)
The functional anatomy of basal ganglia disorders [see comments].
Trends Neurosci
12:366-375[Web of Science][Medline].
-
Armstrong DM,
Saper CB,
Levey AI,
Wainer BH,
Terry RD
(1983)
Distribution of cholinergic neurons in rat brain: demonstrated by the immunocytochemical localization of choline acetyltransferase.
J Comp Neurol
216:53-68[Web of Science][Medline].
-
Baro DJ,
Levini RM,
Kim MT,
Willms AR,
Lanning CC,
Rodriguez HE,
Harris-Warrick RM
(1997)
Quantitative single-cell reverse transcription-PCR demonstrates that A-current magnitude varies as a linear function of shal gene expression in identified stomatogastric neurons.
J Neurosci
17:6597-6610[Abstract/Free Full Text].
-
Bergman H,
Feingold A,
Nini A,
Raz A,
Slovin H,
Abeles M,
Vaadia E
(1998)
Physiological aspects of information processing in the basal ganglia of normal and parkinsonian primates.
Trends Neurosci
21:32-38[Web of Science][Medline].
-
Blaine JT,
Ribera AB
(1998)
Heteromultimeric potassium channels formed by members of the Kv2 subfamily.
J Neurosci
18:9585-9593[Abstract/Free Full Text].
-
Chesselet MF,
Delfs JM,
Mackenzie L
(1998)
Dopamine control of gene expression in basal ganglia nuclei: striatal and nonstriatal mechanisms.
Adv Pharmacol
42:674-677.
-
Cimino GD,
Metchette K,
Isaacs ST,
Zhu YS
(1990)
More false-positive problems [letter and comment].
Nature
345:773-774[Medline].
-
Demo SD,
Yellen G
(1991)
The inactivation gate of the Shaker K+ channel behaves like an open-channel blocker.
Neuron
7:743-753[Web of Science][Medline].
-
Du J,
Zhang L,
Weiser M,
Rudy B,
McBain CJ
(1996)
Developmental expression and functional characterization of the potassium-channel subunit Kv3.1b in parvalbumin-containing interneurons of the rat hippocampus.
J Neurosci
16:506-518[Abstract/Free Full Text].
-
Faravelli L,
Arcangeli A,
Olivotto M,
Wanke E
(1996)
A HERG-like K+ channel in rat F-11 DRG cell line: pharmacological identification and biophysical characterization.
J Physiol (Lond)
496:13-23[Abstract/Free Full Text].
-
Filion M,
Tremblay L
(1991)
Abnormal spontaneous activity of globus pallidus neurons in monkeys with MPTP-induced parkinsonism.
Brain Res
547:142-151[Web of Science][Medline].
-
Frech GC,
VanDongen AM,
Schuster G,
Brown AM,
Joho RH
(1989)
A novel potassium channel with delayed rectifier properties isolated from rat brain by expression cloning.
Nature
340:642-645[Medline].
-
Garcia-Calvo M,
Leonard RJ,
Novick J,
Stevens SP,
Schmalhofer W,
Kaczorowski GJ,
Garcia ML
(1993)
Purification, characterization, and biosynthesis of margatoxin, a component of Centruroides margaritatus venom that selectively inhibits voltage-dependent potassium channels.
J Biol Chem
268:18866-18874[Abstract/Free Full Text].
-
Graybiel AM
(1990)
Neurotransmitters and neuromodulators in the basal ganglia.
Trends Neurosci
13:244-254[Web of Science][Medline].
-
Grissmer S,
Nguyen AN,
Aiyar J,
Hanson DC,
Mather RJ,
Gutman GA,
Karmilowicz MJ,
Auperin DD,
Chandy KG
(1994)
Pharmacological characterization of five cloned voltage-gated K+ channels, types Kv1.1, 1.2, 1.3, 1.5, and 3.1, stably expressed in mammalian cell lines.
Mol Pharmacol
45:1227-1234[Abstract].
-
Gritti I,
Mainville L,
Jones BE
(1993)
Codistribution of GABA- with acetylcholine-synthesizing neurons in the basal forebrain of the rat.
J Comp Neurol
329:438-457[Web of Science][Medline].
-
Grupe A,
Schroter KH,
Ruppersberg JP,
Stocker M,
Drewes T,
Beckh S,
Pongs O
(1990)
Cloning and expression of a human voltage-gated potassium channel. A novel member of the RCK potassium channel family.
EMBO J
9:1749-1756[Web of Science][Medline].
-
Hamil OP,
Marty A,
Neher E,
Sakmann B,
Sigworth FJ
(1981)
Improved patch-clamp techniques for high resolution current recording from cells and cell free membrane patches.
Pflügers Arch
391:85-100[Web of Science][Medline].
-
Hutchison WD,
Lozano AM,
Davis KD,
Saint-Cyr JA,
Lang AE,
Dostrovsky JO
(1994)
Differential neuronal activity in segments of globus pallidus in Parkinson's disease patients.
NeuroReport
5:1533-1537[Web of Science][Medline].
-
Hwang PM,
Glatt CE,
Bredt DS,
Yellen G,
Snyder SH
(1992)
A novel K+ channel with unique localizations in mammalian brain: molecular cloning and characterization.
Neuron
8:473-481[Web of Science][Medline].
-
Ikeda SR,
Soler F,
Zuhlke RD,
Joho RH,
Lewis DL
(1992)
Heterologous expression of the human potassium channel Kv2.1 in clonal mammalian cells by direct cytoplasmic microinjection of cRNA.
Pflügers Arch
422:201-203[Web of Science][Medline].
-
Kavanaugh MP,
Varnum MD,
Osborne PB,
Christie MJ,
Busch AE,
Adelman JP,
North RA
(1991)
Interaction between tetraethylammonium and amino acid residues in the pore of cloned voltage-dependent potassium channels.
J Biol Chem
266:7583-7587[Abstract/Free Full Text].
-
Kawaguchi Y,
Wilson CJ,
Augood SJ,
Emson PC
(1995)
Striatal interneurones: chemical, physiological, and morphological characterization.
Trends Neurosci
18:527-535[Web of Science][Medline].
-
Kirsch GE,
Shieh CC,
Drewe JA,
Vener DF,
Brown AM
(1993)
Segmental exchanges define 4-aminopyridine binding and the inner mouth of K+ pores.
Neuron
11:503-512[Web of Science][Medline].
-
Kita H
(1994)
Parvalbumin-immunopositive neurons in rat globus pallidus: a light and electron microscopic study.
Brain Res
657:31-41[Web of Science][Medline].
-
Kita H,
Kitai ST
(1991)
Intracellular study of rat globus pallidus neurons: membrane properties and responses to neostriatal, subthalamic, and nigral stimulation.
Brain Res
564:296-305[Web of Science][Medline].
-
Klemic KG,
Shieh CC,
Kirsch GE,
Jones SW
(1998)
Inactivation of Kv2.1 potassium channels.
Biophys J
74:1779-1789[Web of Science][Medline].
-
Knaus HG,
Koch RO,
Eberhart A,
Kaczorowski GJ,
Garcia ML,
Slaughter RS
(1995)
[125I]margatoxin, an extraordinarily high-affinity ligand for voltage-gated potassium channels in mammalian brain.
Biochemistry
34:13627-13634[Medline].
-
Kramer JW,
Post MA,
Brown AM,
Kirsch GE
(1998)
Modulation of potassium channel gating by coexpression of kv2.1 with regulatory kv5.1 or kv6.1 -subunits.
Am J Physiol
274:C1501-C1510.
-
Leonard RJ,
Garcia ML,
Slaughter RS,
Reuben JP
(1992)
Selective blockers of voltage-gated K+ channels depolarize human T lymphocytes: mechanism of the antiproliferative effect of charybdotoxin.
Proc Natl Acad Sci USA
89:10094-10098[Abstract/Free Full Text].
-
Lozano AM,
Lang AE
(1998)
Pallidotomy for Parkinson's disease.
Neurosurg Clin N Am
9:325-336[Web of Science][Medline].
-
Lozano A,
Hutchison W,
Kiss Z,
Tasker R,
Davis K,
Dostrovsky J
(1996)
Methods for microelectrode-guided posteroventral pallidotomy [see comments].
J Neurosurg
84:194-202[Web of Science][Medline].
-
Maletic-Savatic M,
Lenn NJ,
Trimmer JS
(1995)
Differential spatiotemporal expression of K+ channel polypeptides in rat hippocampal neurons developing in situ and in vitro.
J Neurosci
15:3840-3851[Abstract].
-
Martina M,
Schultz JH,
Ehmke H,
Monyer H,
Jonas P
(1998)
Functional and molecular differences between voltage-gated K+ channels of fast-spiking interneurons and pyramidal neurons of rat hippocampus.
J Neurosci
18:8111-8125[Abstract/Free Full Text].
-
Massengill JL,
Smith MA,
Son DI,
O'Dowd DK
(1997)
Differential expression of K4-AP currents and Kv3.1 potassium channel transcripts in cortical neurons that develop distinct firing phenotypes.
J Neurosci
17:3136-3147[Abstract/Free Full Text].
-
Murakoshi H,
Trimmer JS
(1999)
Identification of the Kv2.1 K+ channel as a major component of the delayed rectifier K+ current in rat hippocampal neurons.
J Neurosci
19:1728-1735[Abstract/Free Full Text].
-
Murakoshi H,
Shi G,
Scannevin RH,
Trimmer JS
(1997)
Phosphorylation of the Kv2.1 K+ channel alters voltage-dependent activation.
Mol Pharmacol
52:821-828[Abstract/Free Full Text].
-
Nini A,
Feingold A,
Slovin H,
Bergman H
(1995)
Neurons in the globus pallidus do not show correlated activity in the normal monkey, but phase-locked oscillations appear in the MPTP model of parkinsonism.
J Neurophysiol
74:1800-1805[Abstract/Free Full Text].
-
Nisenbaum ES,
Stricker EM,
Zigmond MJ,
Berger TW
(1988)
Spontaneous activity of type II but not type I striatal neurons is correlated with recovery of behavioral function after dopamine-depleting brain lesions.
Brain Res
473:389-393[Web of Science][Medline].
-
Pongs O
(1992)
Molecular biology of voltage-dependent potassium channels.
Physiol Rev
72:S69-S88.
-
Pusch M,
Magrassi R,
Wollnik B,
Conti F
(1998)
Activation and inactivation of homomeric KvLQT1 potassium channels.
Biophys J
75:785-792[Web of Science][Medline].
-
Rhodes KJ,
Strassle BW,
Monaghan MM,
Bekele-Arcuri Z,
Matos MF,
Trimmer JS
(1997)
Association and colocalization of the Kv
 1 and Kv2 -subunits with Kv1 -subunits in mammalian brain K+ channel complexes.
J Neurosci
17:8246-8258[Abstract/Free Full Text]. -
Robertson B
(1997)
The real life of voltage-gated K+ channels: more than model behaviour.
Trends Pharmacol Sci
18:474-483[Medline].
-
Rouzaire-Dubois B,
Hammond C,
Hamon B,
Feger J
(1980)
Pharmacological blockade of the globus palidus-induced inhibitory response of subthalamic cells in the rat.
Brain Res
200:321-329[Web of Science][Medline].
-
Rudy B
(1988)
Diversity and ubiquity of K channels.
Neuroscience
25:729-749[Web of Science][Medline].
-
Ruppersberg JP,
Frank R,
Pongs O,
Stocker M
(1991)
Cloned neuronal IKA channels reopen during recovery from inactivation [see comments].
Nature
353:657-660[Medline].
-
Schroter KH,
Ruppersberg JP,
Wunder F,
Rettig J,
Stocker M,
Pongs O
(1991)
Cloning and functional expression of a TEA-sensitive A-type potassium channel from rat brain.
FEBS Lett
278:211-216[Web of Science][Medline].
-
Serodio P,
Kentros C,
Rudy B
(1994)
Identification of molecular components of A-type channels activating at subthreshold potentials.
J Neurophysiol
72:1516-1529[Abstract/Free Full Text].
-
Sheng M,
Tsaur ML,
Jan YN,
Jan LY
(1992)
Subcellular segregation of two A-type K+ channel proteins in rat central neurons.
Neuron
9:271-284[Web of Science][Medline].
-
Sheng M,
Liao YJ,
Jan YN,
Jan LY
(1993)
Presynaptic A-current based on heteromultimeric K+ channels detected in vivo.
Nature
365:72-75[Medline].
-
Shi W,
Wymore RS,
Wang HS,
Pan Z,
Cohen IS,
McKinnon D,
Dixon JE
(1997)
Identification of two nervous system-specific members of the erg potassium channel gene family.
J Neurosci
17:9423-9432[Abstract/Free Full Text].
-
Shi W,
Wang HS,
Pan Z,
Wymore RS,
Cohen IS,
McKinnon D,
Dixon JE
(1998)
Cloning of a mammalian elk potassium channel gene and EAG mRNA distribution in rat sympathetic ganglia.
J Physiol (Lond)
511:675-682[Abstract/Free Full Text].
-
Song WJ,
Surmeier DJ
(1996)
Voltage-dependent facilitation of calcium channels in rat neostriatal neurons.
J Neurophysiol
16:2290-2306.
-
Song WJ,
Tkatch T,
Baranauskas G,
Ichinohe N,
Kitai ST,
Surmeier DJ
(1998)
Somatodendritic depolarization-activated potassium currents in rat neostriatal cholinergic interneurons are predominantly of the A type and attributable to coexpression of Kv4.2 and Kv4.1 subunits.
J Neurosci
18:3124-3137[Abstract/Free Full Text].
-
Stefani A,
Calabresi P,
Mercuri NB,
Bernardi G
(1992)
A-current in rat globus pallidus: a whole-cell voltage-clamp study on acutely dissociated neurons.
Neurosci Lett
144:4-8[Web of Science][Medline].
-
Stefani A,
Pisani A,
Bonci A,
Stratta F,
Bernardi G
(1995)
Outward potassium currents activated by depolarization in rat globus pallidus.
Synapse
20:131-136[Web of Science][Medline].
-
Stuhmer W,
Ruppersberg JP,
Schroter KH,
Sakmann B,
Stocker M,
Giese KP,
Perschke A,
Baumann A,
Pongs O
(1989)
Molecular basis of functional diversity of voltage-gated potassium channels in mammalian brain.
EMBO J
8:3235-3244[Web of Science][Medline].
-
Surmeier DJ,
Bargas J,
Hemmings Jr HC,
Nairn AC,
Greengard P
(1995)
Modulation of calcium currents by a D1 dopaminergic protein kinase/phosphatase cascade in rat neostriatal neurons.
Neuron
14:385-397[Web of Science][Medline].
-
Swanson R,
Marshall J,
Smith JS,
Williams JB,
Boyle MB,
Folander K,
Luneau CJ,
Antanavage J,
Oliva C,
Buhrow SA,
Bennett C,
Stein RB,
Kaczmarek LK
(1990)
Cloning and expression of cDNA and genomic clones encoding three delayed rectifier potassium channels in rat brain.
Neuron
4:929-939[Web of Science][Medline].
-
Swartz KJ,
MacKinnon R
(1995)
An inhibitor of the Kv2.1 potassium channel isolated from the venom of a Chilean tarantula.
Neuron
15:941-949[Web of Science][Medline].
-
Taglialatela M,
Vandongen AM,
Drewe JA,
Joho RH,
Brown AM,
Kirsch GE
(1991)
Patterns of internal and external tetraethylammonium block in four homologous K+ channels.
Mol Pharmacol
40:299-307[Abstract].
-
Taha JM,
Favre J,
Baumann TK,
Burchiel KJ
(1996)
Characteristics and somatotopic organization of kinesthetic cells in the globus pallidus of patients with Parkinson's disease.
J Neurosurg
85:1005-1012[Web of Science][Medline].
-
Tkatch T,
Baranauskas G,
Surmeier DJ
(1998)
Basal forebrain neurons adjacent to the globus pallidus coexpress GABAergic and cholinergic marker mRNAs.
NeuroReport
9:1935-1939[Web of Science][Medline].
-
Tristani-Firouzi M,
Sanguinetti MC
(1998)
Voltage-dependent inactivation of the human K+ channel KvLQT1 is eliminated by association with minimal K+ channel (minK) subunits.
J Physiol (Lond)
510:37-45[Abstract/Free Full Text].
-
Tytgat J,
Debont T,
Carmeliet E,
Daenens P
(1995)
The -dendrotoxin footprint on a mammalian potassium channel.
J Biol Chem
270:24776-24781[Abstract/Free Full Text].
-
VanDongen AM,
Frech GC,
Drewe JA,
Joho RH,
Brown AM
(1990)
Alteration and restoration of K+ channel function by deletions at the N- and C-termini.
Neuron
5:433-443[Web of Science][Medline].
-
Vega-Saenz de Miera E,
Weiser M,
Kentros C,
Lau D,
Moreno H,
Serodio P,
Rudy B
(1994)
Shaw-related K+ channels in mammals.
In: Handbook of membrane channels, pp 41-78 New York: Academic.
-
Vysokanov A,
Flores-Hernandez J,
Surmeier DJ
(1998)
mRNAs for clozapine-sensitive receptors colocalize in rat prefrontal cortex neurons.
Neurosci Lett
258:179-182[Web of Science][Medline].
-
Wang HS,
Pan Z,
Shi W,
Brown BS,
Wymore RS,
Cohen IS,
Dixon JE,
McKinnon D
(1998)
KCNQ2 and KCNQ3 potassium channel subunits: molecular correlates of the M-channel [see comments].
Science
282:1890-1893[Abstract/Free Full Text].
-
Wang LY,
Gan L,
Forsythe ID,
Kaczmarek LK
(1998)
Contribution of the Kv3.1 potassium channel to high-frequency firing in mouse auditory neurones.
J Physiol (Lond)
509:183-194[Abstract/Free Full Text].
-
Weiser M,
Vega-Saenz de Miera E,
Kentros C,
Moreno H,
Franzen L,
Hillman D,
Baker H,
Rudy B
(1994)
Differential expression of Shaw-related K+ channels in the rat central nervous system.
J Neurosci
14:949-972[Abstract].
-
Wichmann T,
DeLong MR
(1996)
Functional and pathophysiological models of the basal ganglia.
Curr Opin Neurobiol
6:751-758[Web of Science][Medline].
-
Yan Z,
Surmeier DJ
(1996)
Muscarinic (m2/m4) receptors reduce N- and P-type Ca2+ currents in rat neostriatal cholinergic interneurons through a fast, membrane-delimited, G-protein pathway.
J Neurosci
16:2592-2604[Abstract/Free Full Text].
-
Yang WP,
Levesque PC,
Little WA,
Conder ML,
Ramakrishnan P,
Neubauer MG,
Blanar MA
(1998)
Functional expression of two KvLQT1-related potassium channels responsible for an inherited idiopathic epilepsy.
J Biol Chem
273:19419-19423[Abstract/Free Full Text].
-
Zagotta WN,
Germeraad S,
Garber SS,
Hoshi T,
Aldrich RW
(1989)
Properties of ShB A-type potassium channels expressed in Shaker mutant Drosophila by germline transformation.
Neuron
3:773-782[Web of Science][Medline].
Copyright © 1999 Society for Neuroscience 0270-6474/99/19156394-11$05.00/0
This article has been cited by other articles:
|
|
|
|
 
C. A. Deister, C. S. Chan, D. J. Surmeier, and C. J. Wilson
Calcium-Activated SK Channels Influence Voltage-Gated Ion Channels to Determine the Precision of Firing in Globus Pallidus Neurons
J. Neurosci.,
July 1, 2009;
29(26):
8452 - 8461.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Day, D. Wokosin, J. L. Plotkin, X. Tian, and D. J. Surmeier
Differential Excitability and Modulation of Striatal Medium Spiny Neuron Dendrites
J. Neurosci.,
November 5, 2008;
28(45):
11603 - 11614.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. D. Johnson and C. C. McIntyre
Quantifying the Neural Elements Activated and Inhibited by Globus Pallidus Deep Brain Stimulation
J Neurophysiol,
November 1, 2008;
100(5):
2549 - 2563.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
T. S. Gertler, C. S. Chan, and D. J. Surmeier
Dichotomous Anatomical Properties of Adult Striatal Medium Spiny Neurons
J. Neurosci.,
October 22, 2008;
28(43):
10814 - 10824.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. Gunay, J. R. Edgerton, and D. Jaeger
Channel Density Distributions Explain Spiking Variability in the Globus Pallidus: A Combined Physiology and Computer Simulation Database Approach
J. Neurosci.,
July 23, 2008;
28(30):
7476 - 7491.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. N. Mercer, C. S. Chan, T. Tkatch, J. Held, and D. J. Surmeier
Nav1.6 Sodium Channels Are Critical to Pacemaking and Fast Spiking in Globus Pallidus Neurons
J. Neurosci.,
December 5, 2007;
27(49):
13552 - 13566.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. Guan, T. Tkatch, D. J. Surmeier, W. E. Armstrong, and R. C. Foehring
Kv2 subunits underlie slowly inactivating potassium current in rat neocortical pyramidal neurons
J. Physiol.,
June 15, 2007;
581(3):
941 - 960.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Saito, Y. Murai, H. Sato, Y.-C. Bae, T. Akaike, M. Takada, and Y. Kang
Two Opposing Roles of 4-AP-Sensitive K+ Current in Initiation and Invasion of Spikes in Rat Mesencephalic Trigeminal Neurons
J Neurophysiol,
October 1, 2006;
96(4):
1887 - 1901.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Gruhn, J. Guckenheimer, B. Land, and R. M. Harris-Warrick
Dopamine Modulation of Two Delayed Rectifier Potassium Currents in a Small Neural Network
J Neurophysiol,
October 1, 2005;
94(4):
2888 - 2900.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. A. Ariano, C. Cepeda, C. R. Calvert, J. Flores-Hernandez, E. Hernandez-Echeagaray, G. J. Klapstein, S. H. Chandler, N. Aronin, M. DiFiglia, and M. S. Levine
Striatal Potassium Channel Dysfunction in Huntington's Disease Transgenic Mice
J Neurophysiol,
May 1, 2005;
93(5):
2565 - 2574.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Toledo-Rodriguez, B. Blumenfeld, C. Wu, J. Luo, B. Attali, P. Goodman, and H. Markram
Correlation Maps Allow Neuronal Electrical Properties to be Predicted from Single-cell Gene Expression Profiles in Rat Neocortex
Cereb Cortex,
December 1, 2004;
14(12):
1310 - 1327.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
T. M. Cabrera-Vera, S. Hernandez, L. R. Earls, M. Medkova, A. K. Sundgren-Andersson, D. J. Surmeier, and H. E. Hamm
RGS9-2 modulates D2 dopamine receptor-mediated Ca2+ channel inhibition in rat striatal cholinergic interneurons
PNAS,
November 16, 2004;
101(46):
16339 - 16344.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. S. Chan, R. Shigemoto, J. N. Mercer, and D. J. Surmeier
HCN2 and HCN1 Channels Govern the Regularity of Autonomous Pacemaking and Synaptic Resetting in Globus Pallidus Neurons
J. Neurosci.,
November 3, 2004;
24(44):
9921 - 9932.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
T. Shevchenko, R. Teruyama, and W. E. Armstrong
High-Threshold, Kv3-Like Potassium Currents in Magnocellular Neurosecretory Neurons and Their Role in Spike Repolarization
J Neurophysiol,
November 1, 2004;
92(5):
3043 - 3055.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. T. Perez-Garcia, O. Colinas, E. Miguel-Velado, A. Moreno-Dominguez, and J. R. Lopez-Lopez
Characterization of the Kv channels of mouse carotid body chemoreceptor cells and their role in oxygen sensing
J. Physiol.,
June 1, 2004;
557(2):
457 - 471.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
W. Shen, S. Hernandez-Lopez, T. Tkatch, J. E. Held, and D. J. Surmeier
Kv1.2-Containing K+ Channels Regulate Subthreshold Excitability of Striatal Medium Spiny Neurons
J Neurophysiol,
March 1, 2004;
91(3):
1337 - 1349.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Lewis, Z. A. McCrossan, and G. W. Abbott
MinK, MiRP1, and MiRP2 Diversify Kv3.1 and Kv3.2 Potassium Channel Gating
J. Biol. Chem.,
February 27, 2004;
279(9):
7884 - 7892.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Z. A. McCrossan, A. Lewis, G. Panaghie, P. N. Jordan, D. J. Christini, D. J. Lerner, and G. W. Abbott
MinK-Related Peptide 2 Modulates Kv2.1 and Kv3.1 Potassium Channels in Mammalian Brain
J. Neurosci.,
September 3, 2003;
23(22):
8077 - 8091.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Z. Tiran, A. Peretz, B. Attali, and A. Elson
Phosphorylation-dependent Regulation of Kv2.1 Channel Activity at Tyrosine 124 by Src and by Protein-tyrosine Phosphatase epsilon
J. Biol. Chem.,
May 2, 2003;
278(19):
17509 - 17514.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C.-C. Lien and P. Jonas
Kv3 Potassium Conductance is Necessary and Kinetically Optimized for High-Frequency Action Potential Generation in Hippocampal Interneurons
J. Neurosci.,
March 15, 2003;
23(6):
2058 - 2068.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. A. Malin and J. M. Nerbonne
Delayed Rectifier K+ Currents, IK, Are Encoded by Kv2 alpha -Subunits and Regulate Tonic Firing in Mammalian Sympathetic Neurons
J. Neurosci.,
December 1, 2002;
22(23):
10094 - 10105.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
N. Ottschytsch, A. Raes, D. Van Hoorick, and D. J. Snyders
Obligatory heterotetramerization of three previously uncharacterized Kv channel alpha -subunits identified in the human genome
PNAS,
June 11, 2002;
99(12):
7986 - 7991.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Day, P. A. Olson, J. Platzer, J. Striessnig, and D. J. Surmeier
Stimulation of 5-HT2 Receptors in Prefrontal Pyramidal Neurons Inhibits Cav1.2 L-Type Ca2+ Currents Via a PLCbeta /IP3/Calcineurin Signaling Cascade
J Neurophysiol,
May 1, 2002;
87(5):
2490 - 2504.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. Terman, J. E. Rubin, A. C. Yew, and C. J. Wilson
Activity Patterns in a Model for the Subthalamopallidal Network of the Basal Ganglia
J. Neurosci.,
April 1, 2002;
22(7):
2963 - 2976.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C.-C. Lien, M. Martina, J. H Schultz, H. Ehmke, and P. Jonas
Gating, modulation and subunit composition of voltage-gated K+ channels in dendritic inhibitory interneurones of rat hippocampus
J. Physiol.,
January 15, 2002;
538(2):
405 - 419.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. T. Blaine and A. B. Ribera
Kv2 Channels Form Delayed-Rectifier Potassium Channels In Situ
J. Neurosci.,
March 1, 2001;
21(5):
1473 - 1480.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. Hernandez-Lopez, T. Tkatch, E. Perez-Garci, E. Galarraga, J. Bargas, H. Hamm, and D. J. Surmeier
D2 Dopamine Receptors in Striatal Medium Spiny Neurons Reduce L-Type Ca2+ Currents and Excitability via a Novel PLC{beta}1-IP3-Calcineurin-Signaling Cascade
J. Neurosci.,
December 15, 2000;
20(24):
8987 - 8995.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. A Wigmore and M. G Lacey
A Kv3-like persistent, outwardly rectifying, Cs+-permeable, K+ current in rat subthalamic nucleus neurones
J. Physiol.,
September 15, 2000;
527(3):
493 - 506.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A J Cooper and I M Stanford
Electrophysiological and morphological characteristics of three subtypes of rat globus pallidus neurone in vitro
J. Physiol.,
September 1, 2000;
527(2):
291 - 304.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Vincent, N. J. Lautermilch, and N. C. Spitzer
Antisense Suppression of Potassium Channel Expression Demonstrates Its Role in Maturation of the Action Potential
J. Neurosci.,
August 15, 2000;
20(16):
6087 - 6094.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
W.-J. Song, T. Tkatch, and D. J. Surmeier
Adenosine Receptor Expression and Modulation of Ca2+ Channels in Rat Striatal Cholinergic Interneurons
J Neurophysiol,
January 1, 2000;
83(1):
322 - 332.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
K. C. Chen, E. M. Blalock, O. Thibault, P. Kaminker, and P. W. Landfield
Expression of alpha 1D subunit mRNA is correlated with L-type Ca2+ channel activity in single neurons of hippocampal "zipper" slices
PNAS,
April 11, 2000;
97(8):
4357 - 4362.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
TOP
ABSTRACT
INTRODUCTION
