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The Journal of Neuroscience, April 1, 2001, 21(7):2268-2277
D1/D5 Dopamine Receptor Activation
Differentially Modulates Rapidly Inactivating and Persistent Sodium
Currents in Prefrontal Cortex Pyramidal Neurons
Nicolas
Maurice1,
Tatiana
Tkatch1,
Miriam
Meisler2,
Leslie K.
Sprunger2, and
D. James
Surmeier1
1 Department of Physiology/Institute for Neuroscience,
Northwestern University Medical School, Chicago, Illinois 60611, and
2 Department of Human Genetics, University of Michigan, Ann
Arbor, Michigan 48109
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ABSTRACT |
Dopamine (DA) is a well established modulator of prefrontal cortex
(PFC) function, yet the cellular mechanisms by which DA exerts its
effects in this region are controversial. A major point of contention
is the consequence of D1 DA receptor activation. Several
studies have argued that D1 receptors enhance the
excitability of PFC pyramidal neurons by augmenting voltage-dependent
Na+ currents, particularly persistent
Na+ currents. However, this conjecture is based on
indirect evidence. To provide a direct test of this hypothesis, we
combined voltage-clamp studies of acutely isolated layer V-VI
prefrontal pyramidal neurons with single-cell RT-PCR profiling.
Contrary to prediction, the activation of D1 or
D5 DA receptors consistently suppressed rapidly inactivating Na+ currents in identified
corticostriatal pyramidal neurons. This modulation was attenuated by a
D1/D5 receptor antagonist, mimicked by a
cAMP analog, and blocked by a protein kinase A (PKA) inhibitor. In the
same cells the persistent component of the Na+
current was unaffected by D1/D5 receptor
activation suggesting that rapidly inactivating and persistent
Na+ currents arise in part from different channels.
Single-cell RT-PCR profiling showed that pyramidal neurons coexpressed
three  -subunit mRNAs (Nav1.1, 1.2, and 1.6) that code for the
Na+ channel pore. In neurons from Nav1.6 null mice
the persistent Na+ currents were significantly
smaller than in wild-type neurons. Moreover, the residual persistent
currents in these mutant neuronswhich are attributable to Nav1.1/1.2
channelswere reduced significantly by PKA activation. These
results argue that D1/D5 DA receptor activation reduces the rapidly inactivating component of
Na+ current in PFC pyramidal neurons arising from
Nav1.1/1.2 Na+ channels but does not modulate
effectively the persistent component of the Na+
current that is attributable to Nav1.6 Na+ channels.
Key words:
voltage-clamp; scRT-PCR; neuromodulation; monoamine; Na+ channel; molecular biology; protein kinase A; DA
receptor; corticostriatal
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INTRODUCTION |
Disordered dopaminergic signaling in
the prefrontal cortex (PFC) has been implicated in a number of
neuropsychiatric disorders, including schizophrenia. Despite its
importance, the mechanisms by which dopamine (DA) modulates the
activity of PFC neurons are controversial. In vivo studies
suggest that spontaneous firing of PFC neurons is decreased either by
activation of the mesocortical dopaminergic pathway or by application
of iontophoretic DA (Bernardi et al., 1982 ; Mantz et al., 1988; Pirot
et al., 1992). DA also has been shown to inhibit evoked activity in the
PFC (Ferron et al., 1984). A number of in vitro studies are
consistent with the conclusion that DA suppresses the excitability of
layer V pyramidal neurons (Geijo-Barrientos and Pastore, 1995; Gulledge
and Jaffe, 1998). However, other in vitro studies suggest
that DA enhances the excitability of these neurons (Penit-Soria et al.,
1987; Yang and Seamans, 1996; Shi et al., 1997; Gorelova and Yang,
2000).
The excitatory effects of DA in the PFC have been attributed to the
activation of D1 class dopaminergic receptors. It
has been argued that D1 receptor activation
enhances Na+ currents, particularly
persistent Na+ currents, in PFC pyramidal
neurons (Yang and Seamans, 1996; Gorelova and Yang, 2000). However,
this conclusion is based solely on recordings from neurons in slices in
which it is virtually impossible to control adequately the
electrotonically remote regenerative Na+
currents. In studies in which these distal dendritic regions have been
eliminated to achieve adequate voltage control, the consequences of
D1 receptor stimulation appear to be
qualitatively different. In both striatal and hippocampal neurons
D1 receptors have been shown to suppress rapidly
inactivating Na+ currents via the
activation of protein kinase A (PKA) (Surmeier et al., 1992; Surmeier
and Kitai, 1993; Schiffmann et al., 1995; Cantrell et al., 1997, 1999).
These studies are consistent with work in heterologous expression
systems showing that PKA phosphorylation of Nav1.1 or Nav1.2
Na+ channels reduces rapidly inactivating
Na+ currents (Gershon et al., 1992; Li et
al., 1992, 1993; Smith and Goldin, 1996, 1998).
In contrast to rapidly inactivating currents, the modulation of
persistent Na+ currents by PKA has not
been explored as thoroughly. This component of the
Na+ current has been attributed to a
"persistent" gating mode of channels underlying the rapidly
inactivating current (Patlak, 1991; Alzheimer et al., 1993; Crill,
1996). Although both Nav1.1 and Nav1.6 channels produce currents with
prominent persistent components in heterologous systems (Goldin, 1999),
studies of brain neurons have implicated primarily the Nav1.6 channels
in the generation of persistent currents (de Miera et al., 1997; Raman
et al., 1997). It is unclear at this point how PKA phosphorylation of
the Nav1.6 channel modulates its gating. This uncertainty makes it
possible that, if Nav1.6 channels are major determinants of persistent
Na+ currents in PFC pyramidal neurons,
D1 receptor activation of PKA alters channel
gating in a qualitatively different way than in previously studied cell types.
Our aim was to answer three questions. First, how does the activation
of D1 receptors modulate rapidly inactivating
Na+ currents in PFC pyramidal neurons in a
preparation in which these currents can be voltage-clamped adequately?
Second, are persistent Na+ currents in PFC
pyramidal neurons modulated by D1 receptor
activation? Third, if persistent Na+
currents respond in a qualitatively different way to
D1 receptor activation, is this difference
attributable to channel heterogeneity? To answer these questions, we
studied acutely isolated rodent layer V-VI PFC pyramidal neurons with
voltage-clamp and single-cell RT-PCR techniques.
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MATERIALS AND METHODS |
Acute dissociation procedure. Prelimbic and
infralimbic PFC pyramidal cells were obtained from young adult (3-4
weeks) Sprague Dawley rats (Harland, Indianapolis, IN). In some
experiments Nav1.6 null mutant
(Scn8amed) and congenic control mice
(3 weeks) were used (Burgess et al., 1995; Kohrman et al., 1996). In
both cases the neurons were acutely dissociated by using procedures
similar to those previously described (Surmeier et al., 1995). Briefly,
animals were anesthetized with isoflurane and decapitated; then brains
were removed quickly, iced, and blocked for slicing. Sagittal slices
(350 µm) were cut with a Leica VT1000S slicer (Leitz, Nussloch,
Germany) while being bathed in a high-sucrose solution [containing (in
mM): 250 sucrose, 11 glucose, 15 HEPES, 4 MgSO4, 1 Na2HPO4, 2.5 KCl, 1 kynurenic acid, 1 N-nitro-L-arginine,
and 0.1 glutathione, pH 7.4, 300-305 mOsm/l]. Then the slices were
incubated for 1-6 hr at room temperature (20-22°C) in a
NaHCO3-buffered saline solution 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]. All
reagents were obtained from Sigma (St. Louis, MO). Next the slices were
removed into low Ca2+ HEPES-buffered
saline [containing (in mM): 140 Na-isothionate, 2 KCl, 4 MgCl2, 0.1 CaCl2,
23 glucose, and 15 HEPES, pH 7.4, 300-305 mOsm/l]; with the aid of a
dissecting microscope the deep layers of the PFC were dissected and
placed in an oxygenated Cell-Stir chamber (Wheaton, Millville, NJ)
containing Pronase (1-2 mg/ml, Sigma protease type XIV) in
HEPES-buffered HBSS at 37°C. In some experiments papain (20 U/ml,
Worthington Biochemical, Lakewood, NJ) was used instead of Pronase.
After 35-40 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 Petri dish (Nalge
Nunc, Naperville, IL) containing saline; next, the dish was placed on
the stage of an inverted microscope.
Retrograde labeling. In some cases PFC pyramidal cells were
identified as projecting to the nucleus accumbens by retrograde labeling. For this purpose, 2-3 d before recording the animals were
anesthetized with a mixture of ketamine (100 mg/kg; Fort Dodge Animal
Health, Fort Dodge, IA) and xylazine (100 mg/kg; Phoenix Scientific,
St. Joseph, MO); Fluoro-Gold (3% w/v; Fluorochrome, Denver, CO) was
injected stereotaxically into the core of the nucleus accumbens with a
microsyringe needle. Retrogradely labeled neurons, obtained by
following the procedures described above, were observed with a
fluorescence microscope, using a wide-band ultraviolet excitation filter.
Pharmacological agents. All of the stock solutions were
prepared in water. Stock solutions of cBIMPS and Rp-cAMPS (Biolog Life
Science Institute, Bremen, Germany) were aliquoted and frozen. Stock
solutions of SKF 81297 and SCH 23390 (Sigma) were prepared freshly and
protected from ambient light. Each of the stocks was diluted to the
appropriate concentrations in the external recording solution
immediately before the experiment.
Whole-cell recordings. Electrodes were pulled from Corning
(Corning, NY) 7052 glass, coated with Sylgard (Dow Corning, Midland, MI), and fire-polished before use. The internal solution consisted of
(in mM) 130 N-methyl-D-glucamine, 20 HEPES, 20 CsCl, 2 MgCl2, 12 phosphocreatine, 2 Mg-ATP, 0.7 Na2GTP, and 0.1 leupeptin, pH 7.2, with
CsOH/H2SO4 (osmolarity,
260-270 mOsm/l). The external solution consisted of (in
mM) 15 NaCl, 110 tetraethylammonium chloride
(TEA-Cl), 10 HEPES, 1 MgCl2, 2 BaCl2, and 0.3 CdCl2, pH
7.4, with CsOH (osmolarity, 300-305 mOsm/l). The persistent Na+ current was recorded by using an
external solution containing (in mM) 115 NaCl, 45 TEA-Cl, 10 HEPES, 10 CsCl, 1 MgCl2, 2 BaCl2, and 0.3 CdCl2, pH
7.4, with CsOH (osmolarity, 300-305 mOsm/l). 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). Solutions
changes were complete within <1 sec. Recording were obtained with an
Axon Instruments 200 patch-clamp amplifier (Foster City, CA) and
controlled and monitored with a Macintosh computer running Pulse
software (version 8.3, HEKA Elektronik, Lambrecht, Germany) with an
ITC-Computer interface (Instrutech, Great Neck, NY). Electrode
resistance was typically 1.5-3 M in the bath. After formation of
the gigaohm seal and subsequent cell rupture, series resistance was
compensated (80-85%) and monitored periodically.
Data analyses. These were performed with IgorPro
(WaveMetrics, Lake Oswego, OR) and Systat 5 running on a Macintosh
computer (Systat, Evanston, IL). Curve fitting was done with IgorPro,
using a least-squares criterion. Sample statistics are given as means or medians and ranges. Small nonmatched samples were analyzed with
Kruskal-Wallis ANOVA. Box plots were used for graphic presentation of
the data because of the small sample sizes (Tukey, 1977). The box plot
represents the distribution as a box, with the median as a central line
and the hinges as the edges of the box (the hinges divide the upper and
lower halves of the distributions in two). The inner fences (shown as a
line originating from the edges of the box) run to the limits of the
distribution, excluding outliers [defined as points that are >1.5
times the interquartile range beyond the inner fence (Tukey, 1977)].
The outliers are shown as circles.
Single-cell reverse transcription-PCR procedures. In some
experiments the neurons were aspirated after a recording in the whole-cell configuration. In these cases the recording solution was
made RNase-free, and the total volume was kept to ~5 µl in the
electrode. The capillary glass used for the electrodes was autoclaved
to 200°C for 1 hr. Sterile gloves were worn during all of the
procedures to minimize RNase contamination. After aspiration the
electrode was removed from the holder, and the content was ejected into
a 0.5 ml Eppendorf tube (Madison, WI) containing 2.9 µl of diethyl
pyrocarbonate-treated water, 0.7 µl of RNasin (28,000 U/ml), 0.7 µl
of BSA (0.14 µg/µl), and 0.7 µl of oligo-dT (0.5 µg/µl). The
mixture was heated to 70°C for 10 min and incubated on ice for 1 min.
Single-strand cDNA was synthesized from the cellular mRNAs 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 to 70°C for 15 min and then cooling
it to 0°C. The RNA strand in the RNA-DNA hybrid was removed by
adding 1 µl of RNase H (2 U/ml) 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 from a single PFC 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
D1 and D5 DA receptors and
for calmodulin kinase II (CaMKII) have been described previously (Yan
et al., 1997; Vysokanov et al., 1998). Nav1.1 mRNA (GenBank accession
number X03638) was detected with a pair of primers 5'-GAC CGG GTG ACA
AAG CCA ATC (position 6210) and 5'-CCC TTT ACG CTG GTC CCT ACA GTC T
(position 6538), which give a PCR product of 353 base pairs (bp).
Nav1.2 mRNA (GenBank accession number X03639) was detected with a pair
of primers 5'-CCT TCC ACA ACT TCT CCA CCT TCC TA (position 6109) and
5'-ATA TGG CAG GTG TGG CAG TTA AAA CA (position 6614), which give a PCR product of 531 bp. Nav1.5 mRNA (GenBank accession number M27902) was
detected with a pair of primers 5'-TCT CCA GAT AGG GAC CGA GAG TCT
(position 6225) and 5'-GGG TTA AGG AGA GGC AGT GTG AAC (position 6643),
which give a PCR product of 442 bp. Nav1.6 mRNA (GenBank accession
number L39018) was detected with a pair of primers 5'-AGA GGT CAG
GGA GTC CAA GTG CTA (position 5907) and 5'-CGT CTG CCC AAG CGA TAG GAG
(position 6142), which give a PCR product of 256 bp.
PCR techniques were performed by following procedures designed to
minimize the chance of cross-contamination. 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.
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RESULTS |
PFC neurons from layers V-VI were acutely isolated for study,
because previous studies have focused on the deeper cortical layers.
Pyramidal neurons from these layers had a characteristic pyramidal
shape with one apical dendrite (Fig.
1A) and expressed CaMKII mRNA (see Figs. 3A, 4C) (Benson et al.,
1992). To provide an additional level of certainty, we retrogradely
labeled PFC pyramidal neurons projecting to the nucleus accumbens with
Fluoro-Gold (Fig. 1A). The functional measures taken
from these retrogradely labeled neurons were very similar to those
derived from the majority of unlabeled neurons.
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Figure 1.
Steady-state activation and inactivation
characteristics of transient Na+ currents in rat PFC
neurons projecting to nucleus accumbens. A, A PFC
pyramidal neuron that was retrogradely labeled from the nucleus
accumbens with Fluoro-Gold (3%). Left, A bright-field
photomicrograph of the acutely isolated neuron. Right,
The epifluorescent view of the same field. B,
Representative protocols and current traces (TTX-subtracted) that were
used to study the voltage dependence of activation (top)
and steady-state inactivation (bottom).
C, Plot of the peak conductance as a function of the
test pulse voltage (filled circles) and of the
postpulse currents as a function of prepulse voltage (open
circles). The lines are the best fit to the
Boltzmann equation (activation: Vh =  40 mV, Vc = 6.7 mV; inactivation:
Vh = 64 mV,
Vc = 5.5 mV).
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PFC pyramidal neurons display both rapidly inactivating and
persistent Na+ currents
Both rapidly inactivating and slowly inactivating/persistent
Na+ currents could be evoked in acutely
isolated PFC pyramidal neurons. Rapidly inactivating currents were
examined in an external solution containing a low
Na+ concentration (15 mM) to
reduce current amplitudes and to gain adequate control of the
transmembrane voltage (the Na+
concentration of the recording internal solution was ~3
mM). At this external Na+
concentration the properties of the currents evoked by depolarization were very similar to those in which the
Na+ gradient was reversed, making the
currents nonregenerative. Currents were evoked by standard activation
and inactivation protocols (Fig. 1B), and
steady-state plots were constructed by subtracting TTX-insensitive leak
currents. Activation data were fit with a third-order Boltzmann
function, whereas inactivation data were fit with single first-order
Boltzmann function (Fig. 1C). The voltage dependence of
activation (half-activation voltage,
Vh = 38.4 ± 1.7 mV;
slope factor, Vc = 5.8 ± 0.4 mV;
n = 10) and inactivation (half-inactivation voltage,
Vh = 66.2 ± 0.9 mV; slope
factor, Vc = 6.2 ± 0.3 mV;
n = 10) were similar to those found in a variety of
other brain neurons (Surmeier et al., 1992; Cantrell et al., 1997).
All of the rat PFC pyramidal neurons that were tested
(n = 31) exhibited a prominent persistent
Na+ current (Crill, 1996). This component
of the whole-cell Na+ current was defined
operationally as the TTX-sensitive current, which was evoked by slowly
ramping the membrane voltage from 80 to 0 mV (40 mV/sec; Fig.
2A) in physiological
concentrations of Na+ (115 mM). As shown in Figure 2A,
this component of the Na+ current began to
activate near 70 mV, peaked near 50 mV, and remained active at
depolarized potentials. These properties are very similar to those
described for persistent Na+ currents in
cerebellar Purkinje cells, entorhinal cortex pyramidal neurons, and
somatosensory cortex pyramidal neurons (Alzheimer et al., 1993; Kay et
al., 1998; Magistretti and Alonso, 1999).
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Figure 2.
The persistent Na+ current
evoked in PFC neurons is not solely attributable to a window current.
A, Persistent Na+ currents evoked by
slow voltage ramps (35 mV/sec, from 70 to 0 mV) in high external
Na+ concentration (115 mM). The current
was blocked completely by the application of TTX (300 nM).
Inset, Leak-subtracted trace. B, In the
same cell, in recording conditions (external Na+
concentration, 15 mM) allowing for an adequate control of
the transient Na+ currents, the steady-state
activation and inactivation curves overlapped, generating a window
current prominent between 65 and 35 mV. The window current has been
increased 85-fold. C, D, The voltage
dependence of the conductance underlying the persistent
Na+ current is compared with the conductance
resulting from the window current in two different cells. The predicted
window current is represented by a dashed
line, the conductance underlying the observed persistent
current is represented by a thick solid
line, and the difference current showing the real persistent
current is represented by a thin solid line. In
C, the window current contributes to 45% of the
persistent current when this participation is 25% in the cell shown in
D. In both cells there is a clear difference between the
window current and the persistent current.
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In several neurons there was a prominent "hump" in the
current-voltage relationship near 50 mV (see Fig.
2A,C). These are precisely the position and shape
expected of a window current (Hodgkin and Huxley, 1990). In this narrow
voltage range there is a nonzero probability that a channel will be
activated, but not inactivated, in the steady state. To estimate the
contribution of this current to the measured persistent currents, we
computed window currents by taking the product of the Boltzmann
functions fit to the rapidly inactivating steady-state activation and
inactivation plots in the same cell. An example of the estimated window
current is shown on a normalized scale in Figure 2B.
The window was significant between approximately 65 and 35 mV in
most of the neurons that were examined (n = 10). The
maximum window conductance was typically near 1% of the peak
conductance of the rapidly inactivating current. The maximum
conductance of the window current was estimated from that of the
rapidly inactivating conductance and compared with that of the
persistent current. At the peak of the persistent current (near 55
mV) the median contribution of the window current was estimated to be
25% of the total (n = 9). The maximum persistent conductance was 410 ± 86 pS, whereas the maximum potential
contribution from a window conductance was 110 ± 49 pS
(n = 9) in the same cells. Two examples are shown in
Figure 2, C and D, in which the persistent
estimated window and difference currents are plotted. Although the
window current appears to be capable of making a larger contribution to
the persistent current in PFC pyramidal neurons than in Purkinje
neurons (Kay et al., 1998), it always has been a relatively small
component of the total current. Moreover, at more positive membrane
potentials (more than 35 mV) the window current is very small, but
the persistent current is substantial. Together, these data argue that
window currents make, at best, a small contribution to the persistent
Na+ currents in PFC pyramidal neurons.
D1/D5 receptor activation decreases
rapidly inactivating Na+ currents in PFC pyramidal
neurons
In agreement with previous studies (Bergson et al., 1995; Gaspar
et al., 1995), single-cell reverse transcription (scRT-PCR) analysis
consistently revealed that PFC pyramidal neurons (n = 6) had detectable levels of D1 and/or
D5 receptor mRNAs (Fig. 3A). In most of the PFC
pyramidal cells that were tested (84%, 16 of 19 neurons), the
application of the D1/D5
receptor agonist SKF 81297 (1 µM) reversibly
suppressed the rapidly inactivating Na+
currents evoked by a step from the holding potential (70 mV) to 30
mV (average peak suppression, 27.6 ± 3.6%; n = 16; Fig. 3B,D). This
D1/D5 receptor modulation
also was observed in PFC pyramidal neurons retrogradely labeled from
the nucleus accumbens (n = 5). Application of the
D1/D5 receptor antagonist
SCH 23390 (1 µM) significantly reduced the
effect of equimolar SKF 81297 (average peak suppression, 10.7 ± 2.1%; n = 7; p < 0.05, Kruskal-Wallis; Fig. 3D), confirming that the observed
effect resulted from D1/D5 receptor activation. Dopamine (50 µM) also
reversibly suppressed the rapidly inactivating
Na+ currents in these neurons (average
peak suppression, 37.7 ± 2.8%; n = 3; Fig.
3C,D). A mixture of dopamine (50 µM)
and the D2 receptor antagonist sulpiride (5 µM) had a similar effect (data not shown).
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Figure 3.
D1/D5 receptor
activation reduces the rapidly inactivating Na+
current. A, The scRT-PCR revealed that D1
and/or D5 mRNA was expressed in PFC neurons. Shown are
photographs of gels derived from two pyramidal neurons expressing
CaMKII mRNA. One had detectable levels of D1 receptor mRNA;
the other had detectable levels of D5 receptor mRNA. The
sizing ladder is in the left-most lane of both gels.
B, Plot of peak Na+ current evoked by
a step from a holding potential of 80 to 30 mV as function of time.
D1/D5 receptor agonist SKF 81297 (1 µM) reversibly suppresses the peak current.
Inset, Representative currents used to construct
B. C, Plot of peak Na+
current evoked by a step from a holding potential of 80 to 35 mV as
function of time. Dopamine application (50 µM) also
reversibly suppresses the peak current. Inset,
Representative currents used to construct C.
D, Box plot summary of the modulation of
Na+ transient current. SCH 23390 (1 µM) blocked the effect of SKF 81297 (1 µM;
n = 7). This effect was mimicked by cBIMPS (50 µM; n = 7), a PKA activator, and was
blocked by Rp-cAMPS (10 µM; n = 4), a
PKA inhibitor, indicating the involvement of the PKA in the response
that was observed. E, A representative
steady-state inactivation plot derived from a PFC pyramidal neuron. SKF
81297 (1 µM) reduced the maximum current evoked by a step
to 30 mV and shifted the voltage dependence of steady-state
inactivation to slightly more negative potentials (Control:
Vh = 62 mV,
Vc = 5 mV; SKF:
Vh = 65 mV,
Vc = 4.9 mV). F, Current
traces and protocols used to construct the steady-state inactivation
plot shown in D.
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The best-characterized consequence of D1 class
receptor stimulation is the activation of adenylyl cyclase, formation
of cAMP, and activation of PKA (Stoof and Kebabian, 1981). As in other cell types (Surmeier and Kitai, 1993; Cantrell et al., 1997), D1/D5 receptor activation
was mimicked by the membrane-permeant cAMP analog cBIMPS, a PKA
activator (50 µM; average peak suppression, 23.4 ± 5.5%; n = 7; Fig. 3D). Conversely, the
inclusion of the PKA inhibitor Rp-cAMPS (10 µM)
in the patch pipette significantly reduced the effect of SKF 81297 (average peak suppression, 4.7 ± 1.2%; n = 4;
p < 0.05, Kruskal-Wallis; Fig. 3D). These
results argue that D1/D5
receptor activation in layer V-VI PFC pyramidal neurons decreases
rapidly inactivating Na+ currents via a
PKA-dependent mechanism.
The D1/D5 receptor-mediated
modulation of Na+ currents was produced
primarily by a reduction in the peak open probability. There was also a
consistent negative shift (Kruskal-Wallis, 0.1 > p > 0.05) in the voltage dependence of steady-state
inactivation [Vh (control) = 66.5 ± 1.2 mV; Vh
(D1/D5 agonist) = 70.1 ± 1.4 mV; n = 7; Figure 3E,F].
There was no detectable change in the voltage dependence of activation
(data not shown). This pattern is very similar to that reported
previously for striatal and hippocampal neurons (Surmeier et al., 1992;
Cantrell et al., 1997).
D1/D5 receptor activation does not
modulate the persistent Na+ current efficiently
SKF 81297 (1 µM) failed to alter significantly the
persistent Na+ current in any of the rat
pyramidal neurons that were studied (n = 21). An
example drawn from one of these experiments is shown in Figure
4A. To provide a
positive control for the efficacy of the receptor activation, we
examined the ability of SKF 81297 to modulate the rapidly inactivating
Na+ current in the same neuron after
testing the persistent current. As shown in the inset of Figure
4A, the
D1/D5 receptor agonist consistently reduced the rapidly inactivating currents in this paradigm. In four neurons that were tested in this way, the peak of the
rapidly inactivating current was reduced by 31 ± 5%, whereas the
persistent current was not altered significantly (Fig.
4A). In those cells in which the peak of the rapidly
inactivating current was reduced substantially by SKF 81297, it was
difficult to discern the modulation 10-15 msec into the step response
(Fig. 4B; median modulation, 0%; n = 5), providing additional evidence for a differential modulation of the
persistent currents.
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Figure 4.
The persistent Na+ current is
not modulated by D1/D5 receptor
stimulation. A, SKF 81297 (1 µM) failed to
modulate the persistent Na+ current but decreased
the fast transient Na+ current (shown in
inset) in the same cell (protocol for the
inset is the same as in Fig. 3B). The
persistent Na+ current traces are TTX-subtracted and
fit with a polynomial function. B, In cells in which the
peak of the rapidly inactivating current was reduced by SKF 81297 (1 µM), the modulation was not seen 10-15 msec into the
step pulse where only the persistent current would remain.
Inset, Box plot summary of the percentage of modulation
induced by SKF 81297 (1 µM) in the rapidly inactivating
current at the peak (peak) and at 20 msec into
the step pulse (late) in 15 mM
Na+ (n = 6) and in persistent
(n = 6) Na+ current measured at
25 mV, using the ramp protocol in 115 mM
Na+. C, Single-cell RT-PCR profile of
a PFC pyramidal neuron showing a coexpression of Nav1.1, 1.2, and 1.6 Na+ channel -subunit mRNAs. D, Bar
graph summarizing Nav1.1, 1.2, 1.5, and 1.6 mRNA detection in 40 PFC
pyramidal neurons (including 21 retrogradely labeled corticoaccumbal
neurons); the total length of each bar codes the
percentage of the sample in which a particular mRNA was detected.
|
|
PFC pyramidal neurons coexpress Na+ channel
-subunit mRNAs
The simplest interpretation of the differential sensitivity of
rapidly inactivating and persistent Na+
currents to D1/D5 receptor
activation is that they are attributable to different channel types.
The pore-forming -subunit of the Na+
channel is the principal target of PKA (Costa et al., 1982; Costa and
Catterall, 1984; Rossie and Catterall, 1987, 1989; Murphy et al., 1993;
Cantrell et al., 1997). If the pattern of modulation is attributable to
different channel types, then pyramidal neurons should express more
than one -subunit mRNA. To test this hypothesis, we profiled 40 PFC
pyramidal neurons by using scRT-PCR techniques for Nav1.1, 1.2, 1.5, and 1.6 mRNAsthe four -subunit mRNAs known to be expressed in the
adult brain (Goldin, 1999; Hartmann et al., 1999). Twenty-one of these
were retrogradely labeled corticoaccumbal neurons. Nav1.1, 1.2, and 1.6 mRNAs were seen consistently, with the most common pattern being the
codetection of all three (Fig. 4C). A summary of the
detection frequencies for each of these mRNAs is shown in Figure
4D. There were no significant differences in the
expression of Nav1.1, 1.2, and 1.6 mRNAs in corticoaccumbal and
unlabeled deep layer PFC neurons. Nav1.5 mRNA was not detected in layer
V-VI pyramidal neurons but was seen in pooled mRNA from either the PFC
or the septum, in agreement with in situ hybridization experiments (Hartmann et al., 1999). The scRT-PCR profiling of septal
neurons readily detected Nav1.5 mRNA, indicating that the transcript
was detectable with single-cell techniques.
Nav1.6 Na+ channels make a prominent
contribution to persistent Na+ currents
As shown above, the persistent Na+
current in pyramidal PFC neurons cannot be attributed to a window
current alone. A similar conclusion has been drawn for other cell types
(Kay et al., 1998; Magistretti and Alonso, 1999). A commonly held view
is that this current reflects an alternative, persistent gating mode of
channels underlying the rapidly inactivating currents (Patlak, 1991;
Crill, 1996). Studies in heterologous expression systems have shown
that Nav1.1, Nav1.2, and Nav1.6 Na+
channels give rise to rapidly inactivating and persistent
Na+ currents (Goldin, 1999). Nav1.1 and
Nav1.6 channels appear to enter this gating mode more frequently and
produce more persistent current than Nav1.2 channels. However, several
studies have suggested that Nav1.1 and Nav1.6 channels do not
contribute equally to persistent currents that are found in brain
neurons. For example, in cerebellar Purkinje neurons Nav1.6 channels
appear to dominate persistent Na+ currents
that are seen with somatic electrodes (Raman et al., 1997).
To determine whether the persistent Na+
currents in PFC pyramidal neurons are dominated by Nav1.6 channels
also, we studied cells from a Nav1.6 null mutant
(Scn8amed) mouse (Burgess et al.,
1995; Kohrman et al., 1996). As shown in Figure
5A-C, the rapidly
inactivating Na+ currents in PFC pyramidal
neurons from the null mutants were indistinguishable in steady-state
activation (wild-type: Vh = 31.9 ± 1.3 mV, Vc = 6.8 ± 0.2 mV, n = 13; null:
Vh = 35 ± 1.6 mV,
Vc = 6.2 ± 0.3 mV,
n = 8) and inactivation (wild-type:
Vh = 63.4 ± 1.1 mV,
Vc = 6.1 ± 0.3 mV,
n = 13; null: Vh = 61.8 ± 0.5 mV, Vc = 5.3 ± 0.3 mV, n = 8) properties from wild-type neurons. As
expected from this result, the predicted window currents in wild-type
and null neurons also were indistinguishable (see inset,
Fig. 5C). However, the amplitude of the persistent
Na+ current was reduced dramatically in
pyramidal neurons from null mice (Fig. 5D). As shown in
Figure 5E, the median persistent current density at 25 mV
(outside the window region) was reduced by a factor of 3 in the Nav1.6
null mice [median current density, 1.5 pA/pF (n = 7);
wild-type median current density, 4.6 pA/pF (n = 9);
p < 0.05, Kruskal-Wallis; Fig. 5E]. In
contrast, the density of the rapidly inactivating
Na+ current in neurons from Nav1.6 null
mice was reduced less substantially (Fig. 5F;
p > 0.05, Kruskal-Wallis). These data indicate that Nav1.6 channels are major determinants of the persistent
Na+ current in wild-type PFC pyramidal
neurons, as in cerebellar Purkinje neurons.
View larger version (44K):
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Figure 5.
A significant proportion of the persistent
Na+ current is attributable to
Na+ channels containing the Nav1.6 -subunit.
A, B, Comparison of the basic
characteristics of the steady-state activation and inactivation
kinetics of the rapidly inactivating Na+ currents in
the wild-type (A) and null Nav1.6 allele mice
(B) indicates that they are similar.
C, The window current (inset) resulting
from the rapidly inactivating Na+ currents is not
modified in null allele mice (solid lines) as compared
with controls (dotted lines).
D, The persistent Na+ current is
smaller in the null allele mice as compared with controls. The current
traces represent the average of four cells in each case, and the
solid lines are the best corresponding polynomial
fit. E, Box plot summary of the density of
persistent Na+ current in wild-type
(n = 7) and null allele mice (n = 7). F, Box plot summary of the density of the rapidly
inactivating Na+ current indicating that there is no
decrease in the null allele mice (n = 8) as
compared with the control (n = 12).
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|
Nav1.6 channels are modulated inefficiently by PKA activation in
PFC pyramidal neurons
As described above, activation of the
D1/D5 receptor/PKA cascade
in wild-type PFC pyramidal neurons efficiently modulated the rapidly
inactivating Na+ currents but failed to
alter persistent Na+ currents
significantly. Our working hypothesis was that this differential
modulation was attributable to inefficient modulation of the channels
underlying the persistent current. An alternative hypothesis was that
PKA phosphorylation of the Na+ channel
-subunit altered gating in the rapidly inactivating, but not the
persistent, mode. If the first hypothesis is correct, then persistent
Na+ currents in neurons from the Nav1.6
null mutant should be modulated more efficiently by the activation of
PKA than in wild-type neurons. Why? In mutant neurons the residual
persistent Na+ current is attributable to
Nav1.1/1.2 channels that have entered the alternative gating mode. As
noted above, these channels are modulated efficiently by PKA
phosphorylation. On the other hand, if the alternative hypothesis is
correct, there should be no difference in the modulation of the
persistent current in wild-type and null neurons.
As shown in Figure 6, activation of PKA
with cBIMPS (50 µM) in neurons from Nav1.6 null mutants
produced a robust reduction of persistent
Na+ currents (mean reduction at 25 mV,
26.2 ± 5.5%; n = 5). In contrast, in neurons
from wild-type mice, cBIMPS only modestly reduced persistent currents
(mean reduction at 25 mV, 11.5 ± 2.7%; n = 10;
p < 0.05, Kruskal-Wallis). The reduction of the
persistent current seen in wild-type neurons is close to that expected
from a modulation of Nav1.1/1.2 channels alone. On the basis of the
change in persistent current density in the Nav1.6 null neurons,
~32% of the persistent current is attributable to Nav1.1/1.2
channels. If PKA phosphorylation results in a 26% decline in the
persistent (and rapidly inactivating) currents of Nav1.1/1.2 channels,
then in wild-type neurons there should be an 8% decline (26 × 32%) in the mixed persistent Na+
currentsif Nav1.6 channels are unaffected completely. This is not
significantly different from what was observed (11%). The modulation
of the rapidly inactivating Na+ currents
by cBIMPS was indistinguishable in wild-type (n = 4) and mutant neurons (n = 3) (p > 0.05, Kruskal-Wallis). These data argue that the Nav1.6 channels that
are mainly responsible for the persistent
Na+ currents in PFC pyramidal neurons are
not modulated by PKA activation.
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Figure 6.
PKA activator decreases the persistent
Na+ current in the Nav1.6 null mice.
A, Application of cBIMPS (50 µM) produced
only a small decrease of the persistent Na+ current
in the control mice. B, Conversely, the application of
cBIMPS in the Nav1.6 null mice induced a significant reduction of the
persistent Na+ current. C, Box plot
summarizes the reduction of the Na+ current in the
wild-type mice (n = 10) and in the Nav1.6 null mice
(n = 5).
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|
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DISCUSSION |
Rapidly inactivating Na+ currents are suppressed
by the activation of D1/D5 receptors
D1/D5 DA receptor
activation suppresses rapidly inactivating
Na+ currents in layer V-VI PFC pyramidal
neurons. The modulation was similar in all responsive pyramidal
neurons, including those that were retrogradely labeled from the
nucleus accumbens. The attribution of the modulation to activation of
D1 and/or D5 receptors is
based on the ability of the D1 class agonist SKF
81297 to elicit the response, the ability of SCH 23390 to antagonize
it, and the expression of D1 and/or
D5 receptor mRNAs in responsive neurons. Both
D1 and D5 receptors are
positively coupled to adenylyl cyclase (AC) and the production of cAMP
(Stoof and Kebabian, 1981; Sibley, 1995). As expected, the
membrane-permeant cAMP analog cBIMPS mimicked the response to SKF
81297. Furthermore, a competitive antagonist of cAMP, Rp-cAMPS, blocked
receptor-triggered modulation of Na+
currents. These results strongly suggest that PKA is an obligate component of the signaling linkage between
D1/D5 receptors and Na+ channels. This view is consistent with
the similarity in the biophysical signature of the modulation in PFC
pyramidal neurons and that seen in other neurons after the activation
of D1 class receptors or PKA (Surmeier et al.,
1992; Surmeier and Kitai, 1993; Schiffmann et al., 1995; Cantrell et
al., 1997). Studies in heterologous systems (Smith and Goldin, 1998;
Catterall, 2000) have shown that PKA phosphorylation of
Na+ channel Nav1.1 or Nav1.2 -subunits
produces a very similar modulation to that seen in native expression
systems that follow the activation of D1 class receptors.
D1/D5 receptor activation
inefficiently modulated persistent Na+ currents
In contrast, persistent Na+ currents
were not affected noticeably by
D1/D5 receptor activation.
This was true in all of the PFC pyramidal neurons that were examined,
including those in which the
D1/D5 receptor agonist SKF
81297 clearly reduced the rapidly inactivating currents. Why was there
a difference in the susceptibility of these two components of the
Na+ current to modulation? This is an
important question for a number of reasons. Previous studies have shown
that this current is an important determinant of repetitive activity
and synaptic integration in pyramidal neurons (Geijo-Barrientos and
Pastore, 1995; Crill, 1996; Yang et al., 1996). It is also a key
element in several models of dopaminergic regulation of PFC pyramidal
neurons (Geijo-Barrientos and Pastore, 1995; Yang et al., 1999).
An important first step toward understanding the differential
modulation is determining the origin of the persistent current itself.
There are three commonly advanced hypotheses. Perhaps the oldest is
that the persistent current is a "window" current (Hodgkin and
Huxley, 1990). Within a narrow range of membrane voltage at the foot of
steady-state activation and inactivation gating curves, there is a
finite probability that there will be a steady-state or persistent
Na+ current. Although this hypothesis has
been dismissed in other cell types (Kay et al., 1998), window currents
do appear to be capable of making a modest contribution to the
persistent Na+ currents in PFC pyramidal
neurons at potentials near 50 mV. However, at more depolarized
potentials (approximately 25 mV) the contribution of the window
current is vanishingly small, demonstrating that another mechanism must
be responsible for the lion's share of the persistent current.
There are two other explanations of the persistent current that have
been offered. One is that the persistent current reflects the entry of
rapidly inactivating Na+ channels into an
alternative, persistent gating mode (Patlak, 1991; Alzheimer et al.,
1993; Crill, 1996). All of the Na+
channels expressed at significant levels in PFC pyramidal neurons (Nav1.1, 1.2, and 1.6) produce currents with rapidly inactivating and
persistent components in heterologous expression systems (Smith and
Goldin, 1998; Goldin, 1999). In the presence of auxiliary  -subunits
the persistent Na+ currents of Nav1.1 and
Nav1.6 channels are 2-5% of the rapidly inactivating componentin
reasonable agreement with the amplitude of the currents observed here.
Nav1.2 channels exhibit significantly less ( 1%) persistent gating.
The other explanation is that persistent currents arise from a distinct
Na+ channel (de Miera et al., 1997; Raman
et al., 1997; Kay et al., 1998; Magistretti et al., 1999). Raman et al.
(1997) have demonstrated that Nav1.6 channels are major contributors to
both persistent and resurgent Na+ currents
in Purkinje neurons, based on studies of mice lacking Nav1.6 channels.
Similarly, on the basis of mRNA distribution, de Miera et al. (1997)
suggested that in cerebellar Purkinje neurons the rapidly inactivating
Na+ current in cerebellar Purkinje neurons
was attributable to Nav1.1 channels, whereas the persistent current was
attributable to Nav1.6 channels.
Our results are consistent with view that Nav1.6 channels are key
determinants of persistent Na+ currents in
PFC pyramidal neurons. There are four pieces of evidence supporting
this conclusion. First, scRT-PCR profiling found that these neurons
express Nav1.6 -subunit mRNA in addition to mRNAs for Nav1.1 and
Nav1.2 subunits. Second, window currents cannot account for the
persistent currents, particularly at depolarized membrane potentials.
Third, in PFC pyramidal neurons from Nav1.6 null mice (Burgess et al.,
1995; Kohrman et al., 1996) persistent Na+
current density was reduced to ~30% of that in wild-type neurons. Last, persistent Na+ currents were
modulated inefficiently by the activation of PKA in wild-type neurons
conversely to persistent Na+ currents in
neurons from Nav1.6 null micein this case because of Nav1.1 and
Nav1.2 Na+ channels. The fact that
previous studies have shown that both Nav1.1 and Nav1.2 channels are
readily modulated by PKA phosphorylation (Smith and Goldin, 1998;
Goldin, 1999) suggests that much of the persistent
Na+ current is ascribable to another
channel typeimplicating Nav1.6 channels.
However, our results are not consistent with the suggestion that Nav1.6
channels are solely responsible for the persistent Na+ current or that these channels do not
contribute to rapidly inactivating currents. There were persistent
currents in neurons from the Nav1.6 null mutant mouse that were
attributable to Nav1.1/1.2 channels. As mentioned above, all three
channels yield currents with both rapidly inactivating and persistent
components in heterologous expression systems (Goldin, 1999). Although
it failed to reach statistical significance with our small sample, the
median density of rapidly inactivating currents was smaller in neurons
from Nav1.6 mutants. Furthermore, all three channel proteins are
positioned appropriately in the somatodendritic membrane of cortical
pyramidal neurons (Westenbroek et al., 1989; Gong et al., 1999;
Caldwell et al., 2000). The most parsimonious interpretation of our
work is that, whereas all three channels may contribute to both
components of the somatodendritic Na+
currents, Nav1.6 channels make a disproportionately large contribution to the persistent Na+ current in PFC
pyramidal neurons.
The special role of Nav1.6 channels in pyramidal neurons provides a
foundation for explaining the differential modulation of rapidly
inactivating and persistent Na+ currents
by D1 receptor activation. As mentioned above,
PKA phosphorylation of sites in the I/II linker region lead to robust
modulation of Nav1.1 and Nav1.2 channels (Smith and Goldin, 1998;
Catterall, 2000). Our results argue that both the rapidly inactivating
and persistent gating modes of Nav1.1/1.2 channels are modulated in a
similar manner by PKA phosphorylation. However, of the five PKA
consensus sites in the I/II linker region of Nav1.2, only three are
present in Nav1.6 (Plummer et al., 1998; Smith et al., 1998). Moreover,
the Nav1.6 -subunit appears to lack a site in this region that is
necessary for the expression of the PKA-mediated modulation (A. Goldin,
personal communication).
Relationship to previous studies and functional implications
Our findings are clearly at odds with previous studies suggesting
that D1 class receptors enhance
Na+ currents in PFC pyramidal neurons
(Geijo-Barrientos and Pastore, 1995; Yang and Seamans, 1996; Gorelova
and Yang, 2000). The discrepancy cannot be ascribed to sampling
different neuronal populations. It is much more likely to stem from the
reliance on recordings in tissue slices in which dendritic regions that
were critical to the observed response were not controlled adequately.
Poor dendritic voltage control can lead to a variety of anomalous
results, including the appearance of pseudo-persistent
Na+ currents (White et al., 1995).
Although our findings strongly argue against the proposed involvement
of voltage-dependent Na+ channels in
DA-mediated enhancement of PFC excitability, they do not call into
question the basic integrative phenomena this conjecture sought to
explain. How is it that the activation of D1
class receptors can result in increased excitability in some situations
and decreased excitability in others? A very similar situation exists
in the literature bearing on the D1 receptor modulation of the excitability of striatal medium spiny neurons. What
has emerged from this apparent paradox is the recognition that the
neuromodulatory effects of D1 receptor activation
are state-dependent. Striatal medium spiny neurons move between
depolarized up states and hyperpolarized down states (Wilson and
Kawaguchi, 1996). When in the down state, the activation of
D1 receptors suppresses the response to
excitatory input by augmenting inwardly rectifying
K+ currents and suppressing
voltage-dependent Na+ currents (like those
described here) (Surmeier et al., 1992). However, in the depolarized up
state, D1 receptor stimulation enhances
excitability by augmenting L-type Ca2+
currents and possibly suppressing depolarization-activated
K+ currents (Surmeier and Kitai, 1993;
Surmeier et al., 1995; Hernandez-Lopez et al., 1997). This model not
only provides an explanation for seemingly contradictory excitatory and
inhibitory effects of D1 receptor stimulation but
provides fundamental new insights into how dopamine is shaping striatal function.
A very similar situation may exist in PFC pyramidal neurons. Pyramidal
neurons, like striatal medium spiny neurons, move between hyperpolarized down states and depolarized up states in which neurons
spike (Steriade et al., 1993; Cowan and Wilson, 1994). Coordination of
these state transitions and their associated spike activity has been
postulated to control similar transitions in the striatum (Wilson and
Kawaguchi, 1996). The transitions between these states are triggered by
excitatory synaptic input to dendritic regions. By leaving the
persistent Na+ currents mainly untouched,
by enhancing L-type Ca2+ currents
(Surmeier et al., 1995; Yang and Seamans, 1996), and by suppressing
dendritic K+ currents (Hoffman and
Johnston, 1998, 1999),
D1/D5 receptor activation in these regions (Goldman-Rakic, 1999) should promote the amplification of EPSPs at depolarized up-state potentials (Stafstrom et al., 1985;
Deisz et al., 1991; Markram et al., 1995; Schwindt and Crill, 1995;
Stuart and Sakmann, 1995; Jung et al., 1997). In contrast, at
hyperpolarized down-state membrane potentials,
D1/D5 receptor activation
should limit amplification of transient excitatory synaptic inputs by
rapidly inactivating dendritic Na+
channels. In this way,
D1/D5 receptor activation
could suppress the response to weak, temporally incoherent excitatory
inputs while augmenting the response to maintained, synchronized
excitatory inputs.
| |
FOOTNOTES |
Received Sept. 14, 2000; revised Dec. 13, 2000; accepted Dec. 21, 2000.
This work was supported by National Institutes of Health Grant NS 34696 to D.J.S. and Grant NS 34509 to M.M. We thank Sasha Ulrich for her help
in the scRT-PCR experiments, Dr. Leslie Sprunger for husbandry
assistance with the Nav1.6 mutant mice, Dr. Alan Goldin for his advice,
and Dr. Caroline Rick for her careful reading of this manuscript.
Correspondence should be addressed to Dr. D. James Surmeier, Department
of Physiology/Institute for Neuroscience, Northwestern University
Medical School, Searle Building 5-447, 320 East Superior Street,
Chicago, IL 60611. E-mail: j-surmeier{at}northwestern.edu.
| |
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TOP
ABSTRACT
INTRODUCTION
