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The Journal of Neuroscience, May 1, 1999, 19(9):3345-3352
Tonic Dopamine Inhibition of L-Type Ca2+ Channel
Activity Reduces  1D Ca2+ Channel Gene
Expression
Daniel M.
Fass1,
Koichi
Takimoto2,
Richard E.
Mains3, and
Edwin S.
Levitan2
1 Department of Neuroscience, University of Pittsburgh,
Pittsburgh, Pennsylvania 15260, 2 Department of
Pharmacology, University of Pittsburgh School of Medicine, Pittsburgh,
Pennsylvania 15261, and 3 Neuroscience Department, Johns
Hopkins University School of Medicine, Baltimore, Maryland 21205
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ABSTRACT |
Hormones and neurotransmitters have both short-term and long-term
modulatory effects on the activity of voltage-gated
Ca2+ channels. Although much is known about the
signal transduction underlying short-term modulation, there is far less
information on mechanisms that produce long-term effects. Here, the
molecular basis of long-lasting suppression of Ca2+
channel current in pituitary melanotropes by chronic dopamine exposure
is examined. Experiments involving in vivo and in
vitro treatments with the dopaminergic drugs haloperidol,
bromocriptine, and quinpirole show that D2 receptors persistently
decrease  1D L-type Ca2+ channel mRNA
and L-type Ca2+ channel current without altering
channel gating properties. In contrast, another L-channel
(1C) mRNA and P/Q-channel
(1A) mRNA are unaffected. The downregulation of
1D mRNA does not require decreases in cAMP levels or
P/Q-channel activity. However, it is mimicked and occluded by
inhibition of L-type channels. Thus, interruption of the positive
feedback between L-type Ca2+ channel activity and
1D gene expression can account for the long-lasting
regulation of L-current produced by chronic activation of D2 dopamine receptors.
Key words:
L-type Ca2+ channel; dopamine; D2
receptor; melanotrope; nimodipine; haloperidol; quinpirole
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INTRODUCTION |
The activity of voltage-gated
Ca2+ channels in neurons can be regulated on a
variety of time scales. Much is known about short-term (seconds to
minutes) regulation in which acute application of hormones or
neurotransmitters triggers transient modulation of Ca2+ channels via G-proteins or phosphorylation
(Catterall, 1997 ). In contrast, little is known about mechanisms by
which chronic exposure to hormones or neurotransmitters may produce
long-term (hours to days) changes in Ca2+ channel
activity. This latter type of regulation is likely to play a role in
long-lasting forms of neuroplasticity in physiological and pathological
processes. For example, in schizophrenics, chronic therapy with drugs
that alter dopaminergic neurotransmission is required to alleviate
psychotic symptoms. This chronic therapy leads to changes in the
electrical activity of midbrain dopamine neurons of animal models
(Grace et al., 1997). These changes in electrical activity are likely
the result of long-term regulation of ion channels. Cell heterogeneity
and synaptic complexity in the brain complicate the study of long-term
Ca2+ channel regulation. However, a long-term effect
of dopamine on Ca2+ channels has been identified in
the relatively simple system of the pituitary intermediate lobe (IL).
Rat IL is ideal for the study of regulation of Ca2+
channels by a dopaminergic synaptic input. The IL contains only one
type of excitable cell, the melanotrope (Millington and Chronwall, 1989). Melanotropes secrete peptides derived from the precursor pro-opiomelanocortin (POMC). They are predominantly controlled by direct synapses from hypothalamic neurons that tonically inhibit peptide secretion by activating D2-like dopamine (D2) receptors (for
review, see Millington and Chronwall, 1989). One of the effects of
chronic D2 receptor activation is a long-lasting (i.e., for days)
suppression of total high-voltage-activated (HVA)
Ca2+ current in melanotropes (Cota and Hiriart,
1989). To date, in vivo studies of this current suppression
have been performed using neonatal, but not adult, melanotropes (Gomora
et al., 1996). A similar phenomenon is observed in lactotrophs in
vitro (Lledo et al., 1991). Long-lasting suppression of
Ca2+ current likely plays a significant role in
dopamine inhibition of hormone release because exocytosis is dependent
on Ca2+ influx raised to the third power in both of
these pituitary cell types (Thomas et al., 1990; Fomina and Levitan,
1995).
The mechanism of suppression of melanotrope HVA Ca2+
current by chronic D2 receptor activation is unknown. However, the
effect is mimicked by transcription and translation inhibitors (Cota and Hiriart, 1989; Gomora et al., 1996) or application of antisense oligonucleotides directed against c-fos mRNA (Chronwall et al., 1995).
These observations suggest the involvement of gene expression regulation. Melanotrope D2 receptors cause a decrease in adenylyl cyclase activity, leading to a reduction in cAMP levels (Meunier and
Labrie, 1982). The cAMP pathway has been shown to be involved in
regulation of numerous genes (e.g., c-fos,
neurotensin, POMC, prolactin) by dopaminergic drugs (Maurer, 1981; Cote
et al., 1986; Adams et al., 1997). In addition, D2 receptors induce
inhibition of spontaneous action potential firing in melanotropes
(Douglas and Taraskevich, 1978), leading to a reduction in
Ca2+ influx through voltage-gated
Ca2+ channels. A decrease in Ca2+
influx contributes to D2 receptor-induced downregulation of prolactin (Elsholtz et al., 1991) and likely also POMC (Loeffler et al., 1988).
Thus, D2 receptors may regulate melanotrope gene expression by lowering
both cAMP and Ca2+ influx.
These data suggested that the rat IL would provide a unique opportunity
to study the hypothesis that ongoing physiological release of a
neurotransmitter at the synapse regulates Ca2+
channel gene expression. At one time, it was assumed that dopamine targets L-channels (e.g., Chronwall et al., 1995). However, Ciranna et
al. (1996) recently found that melanotropes express an HVA Ca2+ current that consists of P/Q-type
Ca2+ currents (~60%), as well as L-type
Ca2+ current (~40%). The pore-forming and
voltage-sensing 1 subunits of these HVA
Ca2+ channels are encoded by the genes
1C and 1D (L-channels) and 1A (P/Q-channels) (Birnbaumer et al., 1994). Thus, the
present study tests (1) whether chronic D2 receptor activation
downregulates 1A, 1C, or
1D mRNA in adult rat melanotropes both in
vivo and in vitro; (2) whether the corresponding type
of HVA current is subject to long-lasting suppression; and (3) whether
the D2 receptor effect is mediated by decreases in cAMP and
Ca2+ influx. Our results indicate that dopamine acts
via inhibition of L-channel activity (but not a reduction in
P/Q-channel activity or cAMP levels) to specifically downregulate the
1D L-channel gene.
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MATERIALS AND METHODS |
In vivo drug treatments. Drugs (Research
Biochemicals, Natick, MA) or vehicle were injected intraperitoneally
into female Sprague Dawley rats (200-225 gm; Charles River
Laboratories, Wilmington, MA). Haloperidol (5 mg/ml) or bromocriptine
(2 mg/ml) were dissolved in a vehicle of 20 mM tartaric
acid and 10% EtOH and injected at 5 mg/kg. Each treatment group
included three to four animals. Animals were killed by metofane
inhalation anesthesia or CO2 exposure, followed by
decapitation. Neurointermediate lobes (NILs) were dissected out
and immediately frozen on dry ice. The NILs from all animals within a
treatment group were pooled. Thus, n refers to the number of
independent experiments performed, not the number of animals used.
RNA isolation and analysis. Total RNA was isolated from
frozen NILs or cultured cells by the acid guanidinium
thiocyanate-phenol-chloroform extraction method of Chomczynski and
Sacchi (1987). Yeast RNA (50 µg) was added during the isolation
procedure to serve as a carrier. Frozen NILs were homogenized by
repeated passes through an 18 gauge needle. mRNA levels were analyzed
by RNase protection assay as described previously (Takimoto et al.,
1993). Samples were subject to overnight solution hybridization at
50°C with 105 ( -actin) or
106 (all others) cpm of 32P-labeled RNA
probes. Antisense RNA probes were made by in vitro transcription of the following templates: 1D,
plasmid rbDHE470 (Fomina et al., 1996), linearized with
HindIII, transcribed with T7 polymerase;
1C, plasmid rbCES337 [equivalent to plasmid
"5' rbC" (Lievano et al., 1994)], linearized with DraI,
transcribed with T7 polymerase; 1A, plasmid
rbANP550 [consisting of nucleotides 178-684 of the rat
1A gene subcloned into pBluescript KS (Stratagene, La
Jolla, CA)], linearized with XbaI, transcribed with
T3 polymerase; -actin, plasmid pTRI--actin-125-rat (Ambion,
Austin, TX), transcribed with T7 polymerase; and cyclophilin, plasmid
CycPA100 (Fomina et al., 1996), linearized with HindIII,
transcribed with T7 polymerase. For presentation, the air-dried gels
were exposed to x-ray film with an intensifying screen for ~15 hr at
 80°C. For quantitation, the gels were exposed to phosphor screens
for 1-3 hr, and the density of bands corresponding to target mRNAs was
measured by analysis in a phosphorimager (Molecular Dynamics,
Sunnyvale, CA). To control for variation in the amount of sample loaded
into each gel lane, Ca2+ channel mRNA levels have
been normalized to -actin or cyclophilin mRNA, except in the case in
which comparisons are made between control and 8-Bromo-cAMP
(Br-cAMP)-treated melanotropes (see Fig. 4), because it was
clear that Br-cAMP regulated -actin mRNA levels. It is unlikely that
Ca2+ channel mRNAs found in our samples came from
fibroblasts and glial-like cells of the NIL, because these cells do not
express L-, P-, and Q-type voltage-gated Ca2+
channels (Beatty et al., 1996).
Primary culture of rat melanotropes. NILs were dissected out
of male or female Sprague Dawley rats (200-225 gm, from Hilltop or
Charles River) and dissociated into individual cells by either sequential digestion with trypsin and viokase (for current recordings only; Fomina and Levitan, 1995) or collagenase and trypsin (for current
recordings or RNA isolation; Mains and Eipper, 1979). For current
recordings, cells were plated onto poly-lysine (Sigma, St. Louis,
MO)-coated glass coverslips in 35 mm culture dishes or protamine
(Sigma)- and Nu-Serum IV (Becton Dickinson Labware, Bedford,
MA)-treated 35 mm culture dishes at a density of 0.5 NILs per dish in
Roswell Park Memorial Institute 1640 medium with 10% FBS or
DMEM with 10% FBS (Life Technologies, Gaithersburg, MD). For
RNA isolation, cells were plated onto protamine- and Nu-Serum IV-coated
four-well plates (15 mm well; Nunc, Naperville, IL) at a density of 3.5 NILs per well in DMEM with 10% FBS. The dishes were kept in a 5%
CO2 incubator at 37°C. In both cases, the medium was
changed every 2 d. Quinpirole (Research Biochemicals) was added to
medium from aliquoted 5 mM stock solutions in
H2O or PBS. Other drug stock solutions were as
follows: nimodipine (5 mM in EtOH; Research Biochemicals);
 -agatoxin IVA (100 µM in H2O;
generous gift from Dr. Nicholas A. Saccomano, Pfizer, Groton, CT); and
-conotoxin MVIIC (100 µM in H2O;
Peptides International, Louisville, KY).
Electrophysiology. Recordings were made by standard
whole-cell patch-clamp methodology (Hamill et al., 1981) using an
Axopatch 200A amplifier with PCLAMP6 software (Axon Instruments, Foster City, CA) or an EPC9 amplifier with PULSE software (Heka Elektronik, Lambrecht/Pfalz, Germany). Leak subtraction was performed by p/5 protocols contained in the software. Sixty percent series
resistance compensation was used. Electrodes (model 7052; Garner Glass,
Claremont, CA) were filled with a solution containing (in
mM): 130 CsCl, 2 MgCl2, 1 CaCl2, 10 EGTA, 10 HEPES, 2.5 Na2ATP,
and 0.05 GTP, pH 7.4. The bath solution used during recordings
contained (in mM): 10 BaCl2, 140 TEACl,
and 10 HEPES, pH 7.4. Except where indicated, both solutions contained
the specific L-channel activator Bay K 8644 (Research Biochemicals) at
1 µM (from a 5 mM stock in EtOH). Currents
were recorded within 1.5 min after achieving the whole-cell configuration of the patch-clamp electrode to avoid errors in estimation of current density caused by rundown. In experiments involving melanotropes that had been cultured in the presence of
quinpirole, recordings were made from cells that had been washed five
times in agonist-free saline 1-3 hr earlier to allow reversal of the
acute effects of D2 receptor activation (Cota and Hiriart, 1989).
Data analysis. Comparisons between two groups were performed
using Student's t tests. The layered Bonferroni test was
applied when multiple comparisons were required. Data are expressed as mean ± SEM.
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RESULTS |
Dopamine tonically downregulates 1D L-channel mRNA
in pituitary NIL in vivo
We initially sought to determine whether tonic D2 receptor
activation in vivo regulates expression of
1C, 1D, and
1A mRNAs in the rat pituitary NIL. RNase protection
assays were used to quantitate NIL Ca2+ channel mRNA
levels. Consistent with the greater relative size of P/Q-current versus
L-current in melanotropes (Ciranna et al., 1996), the intensity of the
mRNA signals on our autoradiographs followed the order of
1A > 1D > 1C. Because
normal dopamine regulation of the IL is tonic, we hypothesized that
chronic treatment with D2 receptor antagonists would produce an
elevation in Ca2+ channel mRNA levels by eliminating
a tonic downregulation. Indeed, Figure
1A shows that 6 hr
treatment with haloperidol (an antagonist used clinically as an
antipsychotic agent) produced an ~50% elevation in 1D
mRNA. In contrast, 6 hr treatment with bromocriptine (an agonist)
produced no statistically significant change. 1C mRNA levels were not changed by these dopaminergic drugs (Fig.
1B), indicating that the two L-channel mRNAs may be
regulated by different mechanisms. Moreover, 1A mRNA
levels were also unchanged (Fig. 1C). Longer treatments (30 hr or 7 d) with haloperidol produced similar increases in
1D mRNA (data not shown), indicating that the maximal
long-term effect of haloperidol treatment on L-channel mRNA is achieved
by 6 hr. These data suggest that 1D mRNA in melanotropes
is continuously suppressed in vivo by the tonic activation of D2 receptors by endogenous dopamine.
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Figure 1.
Haloperidol treatment in
vivo elevates NIL 1D mRNA but not
1C or 1A mRNAs. A,
Representative autoradiographs of RNase protection assays designed to
measure 1D and 1C (top) or
1A (bottom) mRNAs, along with -actin
or cyclophilin mRNA for normalization. Gel lanes contain the following:
Y, yeast RNA (50 µg); B,
C, and H, total NIL RNA from
bromocriptine, vehicle, and haloperidol treatment groups, respectively.
B, Effect of 6 hr in vivo dopaminergic
drug treatment on 1D (top;
n = 6), 1C (middle;
n = 3), and 1A
(bottom; n = 4) mRNA levels.
Quantitation was performed by phosphorimager analysis using short (1-3
hr) gel exposures. Note that only the effect of haloperidol on
1D mRNA was statistically significant.
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Chronic D2 receptor activation downregulates melanotrope
1D mRNA in vitro
In vivo treatments with haloperidol should alter
neurotransmission in all neuronal circuits that use D2 receptors, and
so the effect on melanotrope 1D mRNA could, in
principle, be caused by a polysynaptic indirect effect. To determine
whether the effect of haloperidol is attributable to a direct action on
melanotrope D2 receptors, we turned to melanotrope primary cultures.
These cultures do not retain the dopaminergic neurons that innervate the IL. Thus, it is necessary to add agonists to test for effects of D2
receptor activation on Ca2+ channel gene expression.
We found that 4 d treatment with the D2 receptor agonist
quinpirole (1 µM), initiated immediately after plating
the cultures, produced an ~35% decrease in 1D mRNA
(Fig. 2). Shorter treatments (such as 24 hr of drug after 3 d in culture) produced smaller decreases (data
not shown). As was the case in vivo, 1C
mRNA was not regulated. These in vitro data indicate that the specific upregulation of 1D mRNA produced by
haloperidol treatment in vivo can be attributed to a
direct action on melanotrope D2 receptors.
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Figure 2.
Chronic quinpirole treatment in
vitro downregulates melanotrope 1D mRNA but not
1C mRNA. A, Representative autoradiograph
of an RNase protection assay measuring 1D and
1C mRNAs. Gel lanes contain the following:
Y, yeast RNA (50 µg); C and
Q, total RNA from melanotropes cultured in control media
or media with quinpirole (1 µM), respectively.
B, Effect of 4 d quinpirole treatment on
1D (n = 15) and 1C
(n = 14) mRNA levels.
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Chronic D2 receptor activation induces a long-lasting
suppression of L-type Ca2+ channel current in
melanotropes
The observation that quinpirole treatment downregulated
1D mRNA suggested that chronic D2 receptor activation
would also produce a persistent decrease in the corresponding L-type
Ca2+ current in melanotropes. To test this idea, we
initially recorded total Ca2+ channel currents from
melanotropes cultured for 5-10 d in the absence or presence of
quinpirole. Figure 3A shows
examples of Ca2+ channel currents evoked by 100 msec
depolarizations from a holding potential of 50 mV in a control cell.
The peak currents during the depolarization (normalized to membrane
capacitance) versus voltage are plotted in Figure 3B. Total
Ca2+ channel currents in quinpirole-treated cells
were smaller at all voltages, although quinpirole-containing media had
been replaced with drug-free saline 1-3 hr before the recordings. This
could reflect long-lasting decreases in the levels of any of several types of Ca2+ currents expressed in melanotropes
(Cota and Hiriart, 1989; Ciranna et al., 1996).
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Figure 3.
Chronic quinpirole treatment in
vitro induces a long-lasting suppression of total
Ca2+ channel currents in melanotropes.
A, Currents recorded in the presence of 1 µM Bay K 8644 using 100 msec depolarizations from a
holding potential of 50 mV to several potentials from a
representative control cell. B, Plot of peak currents
(normalized to membrane capacitance) recorded during 100 msec
depolarizations to various potentials versus voltage in melanotropes
cultured in the absence or presence of quinpirole for 5-10 d. Data in
A and B were obtained from melanotropes
dissociated by trypsin-viokase digestion (see Materials and
Methods).
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To isolate L-current from other types of Ca2+
current in melanotropes (Fig.
4A), tail currents were
recorded at 50 mV after 100 msec depolarizations from a holding
potential of 50 mV in the absence and presence of Bay K 8644 (1 µM). This relatively depolarized holding potential
inactivated low-voltage-activated Ca2+ channels that
can produce slowly decaying components of the tail current. The
resulting tail current recorded in the absence of Bay K 8644 (Fig.
4A, top) is monoexponential, with a
rapid deactivation rate. At 2.4 msec after repolarization to 50 mV
(Fig. 4A, arrow), the current has returned
to baseline, and thus all L-, P-, and Q-type Ca2+
channels have deactivated. The presence of Bay K 8644 induces two
distinct slow components of the tail current (Fig.
4A, bottom). These two components are
similar to two Bay K 8644-revealed components of L-current in
GH3 clonal pituitary cells that arise from the ability of
L-channels to access multiple open states (Fass and Levitan, 1996a,b).
Because the two components are induced by the specific slowing of
deactivation of L-current, the 2.4 msec time point (Fig.
4A, arrow) reflects only the activity of
L-channels (i.e., L-channels are active, but P- and Q-channels are
completely deactivated at 2.4 msec into the tail current). Therefore,
we used the amplitude at 2.4 msec into the tail current recorded in the
presence of Bay K 8644 as a specific measure of L-current.
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Figure 4.
Chronic quinpirole treatment in
vitro induces a long-lasting suppression of L-type
Ca2+ channel current density without changing its
functional properties. A, Illustration of the method of
isolating L-channel tail current from total Ca2+
channel current in melanotropes (see Results for details). Noisy traces
are 10 msec portions of tail currents recorded at 50 mV after a step
depolarization to +75 mV. The smooth traces are
exponential curves fit to the currents. The time constants are 0.16 msec (monoexponential curve in top) and 2.5 and 21.9 msec (biexponential curve in bottom). The
arrows are placed at 2.4 msec after repolarization to
50 mV. B, Chronic quinpirole treatment does not alter
L-channel deactivation properties. Data were obtained with
biexponential curve-fitting analysis of Bay K 8644-slowed tail currents
in control and quinpirole-treated cells. Bars on the
left and right halves of the graph
correspond to the left and right y-axes, respectively.
C, Chronic quinpirole treatment does not alter the
voltage-dependence of activation of L-channels. Normalized conductance
(G) versus step depolarization potential (Vm)
data for control and quinpirole-treated cells are fitted with Boltzmann
equations (smooth curves). D, Maximal
L-current density in melanotropes cultured for 6-10 d in control
or quinpirole-containing media. Maximal L-current density values
were 46.3 ± 6.6 pA/pF in control cells and 30.1 ± 4.1 pA/pF
in quinpirole-treated cells. Data in B-D come from 9 control cells and 13 quinpirole-treated cells.
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Using this L-current isolation method, we measured L-currents in
melanotropes maintained in culture for 6-10 d in the absence or
presence of quinpirole (1 µM). Initially, the effect of
chronic quinpirole treatment on the functional properties of L-channels was assessed. First, we analyzed the rate of deactivation of
melanotrope L-type Ca2+ currents (Fig.
4B). The two time constants ("fast" and
"slow") obtained from biexponential curve fits were similar in
control and quinpirole-treated melanotropes. Also, the proportion of
the tail current made up by each component was not changed. Second, we
analyzed the voltage-dependence of activation of L-currents (Fig.
4C). L-currents isolated in tail currents recorded after step depolarizations over a range of potentials were normalized to
their maximal amplitude to obtain the plot of normalized conductance (G) versus step depolarization voltage
(V). Data points were fit with
Boltzmann equations to determine activation parameters. In control and
quinpirole-treated cells, L-currents were half-maximally activated by
28 ± 1 and 29 ± 1 mV; the slope factors were 8.9 ± 1.0 and 7.8 ± 0.9, respectively. Thus, the voltage-dependence of activation of L-currents was not altered by chronic quinpirole treatment. In contrast, acute application of D2 receptor agonists does
induce a 5 mV rightward shift in the voltage-dependence of activation
of total Ca2+ currents in melanotropes (Cota and
Hiriart, 1989). Thus, by the measures of deactivation kinetics (Fig.
4B) and voltage-dependence of activation (Fig.
4C), chronic quinpirole treatment does not persistently
alter melanotrope L-channel gating properties.
Finally, we measured the effect of chronic quinpirole treatment on
maximal L-channel tail current amplitude. Average membrane capacitance
was identical in control and quinpirole-treated melanotropes (6.6 ± 1.2 and 6.7 ± 0.9 pF, respectively), suggesting that chronic D2 receptor activation did not alter melanotrope cell surface area.
Therefore, we normalized isolated maximal L-channel tail currents to
membrane capacitance to obtain maximal L-current density. Figure
4D shows that 6-10 d quinpirole treatment suppresses
maximal L-current density by ~35%. Thus, chronic D2 receptor
activation induces a decrease in melanotrope L-current density that
persists long after agonist removal. This decrease is consistent with
the downregulation of 1D mRNA. Together with the lack of
change in L-channel gating properties, these data suggest that a
decrease in the number of L-channels underlies the suppression of
L-current density by chronic D2 receptor activation.
Blockade of L-channel activity mimics and occludes
downregulation of 1D mRNA by chronic D2 receptor
activation
We next sought to determine the signaling mechanism underlying D2
receptor-mediated downregulation of 1D mRNA. Initially, the role of the decrease in cAMP produced by melanotrope D2 receptors (Meunier and Labrie, 1982) was tested. First, cAMP levels were elevated
by application of the membrane-permeant nonhydrolyzable analog Br-cAMP.
Then, the effectiveness of 4 d quinpirole treatment was assessed
in the absence and presence of Br-cAMP. To show that our manipulation
of cAMP levels with Br-cAMP was sufficient to alter D2
receptor-mediated gene regulation, we measured POMC mRNA, which is
regulated in part via changes in cAMP levels (Loeffler et al., 1988).
In confirmation, quinpirole downregulation of POMC was significantly
reversed by 1 mM Br-cAMP (n = 3;
p < 0.01); quinpirole reduced POMC mRNA levels to
39 ± 2 and 64 ± 2% of control in the absence and presence
of Br-cAMP, respectively. Figure 5 shows
that Br-cAMP produces a approximately twofold increase in 1D mRNA (p < 0.01). This
suggests that cAMP does play some role in the regulation of
1D mRNA. However, quinpirole-induced downregulation of
1D mRNA was actually slightly enhanced by the presence
of Br-cAMP (although this was not statistically significant). Thus, the
clear failure of Br-cAMP to reduce the effect of quinpirole suggests
that decreases in cAMP levels likely do not mediate downregulation of
1D mRNA by chronic activation of D2 receptors.
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Figure 5.
Br-cAMP fails to prevent dopaminergic
downregulation of 1D mRNA. Effect of 4 d treatment
with 1 µM quinpirole on 1D mRNA levels in
melanotropes cultured in the absence (control) or presence of 1 mM Br-cAMP (n = 3). Note that Br-cAMP
had no statistically significant effect on quinpirole-induced
downregulation of 1D mRNA (downregulation in the absence
and presence of Br-cAMP was 34 ± 5 and 47 ± 4%,
respectively; p > 0.05 for the comparison between
these two percentage downregulation values).
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Next, we assessed the role of the inhibition of Ca2+
channel activity in quinpirole downregulation of 1D
mRNA. Melanotrope HVA Ca2+ channels were blocked
with a combination of the P/Q-channel blocker -agatoxin IVA (500 nM) and the L-channel blocker nimodipine (1 µM). Also, the effects of individual blockers [1
µM either nimodipine or the N/P/Q-channel blocker
-conotoxin MVIIC (Hillyard et al., 1992; McDonough et al., 1996)]
were tested. Figure 6 shows that 4 d
treatments with either the blocker combination or nimodipine alone
produced a downregulation of 1D mRNA equal in magnitude to the quinpirole effect. Treatment with -conotoxin MVIIC alone had
no effect on 1D mRNA. Therefore, the effect of the
blocker combination can be attributed, in whole, to nimodipine.
Furthermore, nimodipine had no effect on 1C mRNA (data
not shown). Thus, inhibition of L-channel activity with nimodipine
mimics the specific effect of quinpirole on 1D mRNA.
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Figure 6.
Inhibition of L-channels, but not P/Q-channels,
mimics and occludes D2 receptor-induced downregulation of
1D mRNA. 1D mRNA levels in control and
quinpirole-treated melanotropes cultured for 4 d in control media
(No blockers; n = 15) or in the
absence or presence of the indicated Ca2+ channel
blockers (n = 3 in all cases). ns,
Not statistically significant. The dashed line indicates
the level of 1D mRNA in quinpirole-treated cells
cultured in the absence of Ca2+ channel blockers.
Note that the L-channel inhibitor nimodipine mimics and occludes the
effect of the D2-receptor agonist quinpirole. In contrast, P/Q-channel
blockers have no effect.
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We next examined the effectiveness of 4 d treatments with
quinpirole in the presence of the channel blockers. Quinpirole produced no further downregulation of 1D mRNA in the presence of
either the blocker combination or nimodipine alone. In contrast,
quinpirole was effective at inducing downregulation in the presence of
-conotoxin MVIIC. Thus, nimodipine both mimics and occludes the
effect of quinpirole, whereas the P/Q-channel blockers have no effect.
The occlusion effect of nimodipine is not caused by loss of D2 receptor function because quinpirole does produce downregulation of POMC mRNA in
the presence of nimodipine (data not shown). Therefore, inhibition of
L-type Ca2+ channel activity is sufficient to fully
account for downregulation of 1D mRNA by chronic D2
receptor activation.
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DISCUSSION |
This study examined the mechanism of long-term suppression of
voltage-gated Ca2+ channels induced by chronic
activation of D2 receptors in adult rat melanotropes. We hypothesized
that D2 receptors act by decreasing cAMP levels and
Ca2+ influx to downregulate HVA
Ca2+ channel mRNAs, leading to a reduction in
Ca2+ current. Indeed, the 1D L-type
Ca2+ channel mRNA was specifically downregulated
both in vivo (Fig. 1) and in vitro (Fig. 2). The
corresponding L-type Ca2+ current was also
suppressed (Fig. 4). However, elevating cAMP levels with Br-cAMP had no
effect on quinpirole downregulation of 1D mRNA (Fig. 5).
Thus, a decrease in cAMP is not necessary for the D2 receptor effect.
Instead, the effect appears to involve only inhibition of L-channel
activity, because nimodipine completely mimics and occludes
downregulation of 1D mRNA induced by quinpirole (Fig.
6).
Figure 7 illustrates a mechanism that can
explain our data in live adult rats and cultured melanotropes. In the
absence of dopamine, melanotropes spontaneously fire action potentials.
The depolarization of the spontaneous action potentials activates L-type Ca2+ channels. The fact that nimodipine
downregulates 1D mRNA (Fig. 6) suggests that L-channel
activity normally stimulates the expression of 1D mRNA.
This forms a positive feedback loop, leading to the expression of more
L-channels. P/Q-type Ca2+ channels are also
activated by action potentials. However, the facts that supplementing
nimodipine with -agatoxin IVA produces no greater effect on
1D mRNA and that -conotoxin MVIIC fails to
downregulate 1D mRNA indicate that P/Q-channels do not
participate in the positive feedback loop. These results are consistent
with previous studies indicating that L-channels (Morgan and Curran, 1986; Murphy et al., 1991; Bading et al., 1993), but not
P/Q-channels (Deisseroth et al., 1998), can trigger nuclear events
associated with the activation of gene expression. However, the
demonstration that the activity of a Ca2+ channel
can specifically regulate the expression of its own mRNA is novel.
Activation of D2 receptors induces hyperpolarization and inhibition of
spontaneous action potential firing (Douglas and Taraskevich, 1978),
thus removing the stimulus that activated the L-channel positive
feedback loop. Thus, chronic D2 receptor activation can induce a
long-lasting suppression of melanotrope L-current by interrupting the
positive feedback between L-channel activity and 1D gene
expression. This mechanism may also be applicable to lactotrophs
because suppression of Ca2+ current in lactotrophs
by chronic D2 receptor activation is also insensitive to Br-cAMP (Lledo
et al., 1991).
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Figure 7.
Model of long-lasting suppression of L-current
induced by D2 receptor-triggered interruption of positive feedback
between L-channel activity and 1D gene expression. See
Discussion for detailed explanation. Dopamine occupation of D2
receptors induces hyperpolarization and inhibition of spontaneous
action potential activity (both indicated by line
drawings labeled membrane potential).
Haloperidol antagonizes activation of D2 receptors by endogenous
dopamine, thus allowing spontaneous action potential firing. L- and
P/Q-channels are activated by the depolarization of action potentials.
L-channel activity triggers both secretion and 1D gene
expression. P/Q-channels may also trigger secretion in
melanotropes.
|
|
Our finding that haloperidol upregulates 1D mRNA (Fig.
1) suggests that the long-lasting suppression is a consequence of ongoing tonic dopaminergic neurotransmission in the adult IL. In our
model (Fig. 7), the effect of haloperidol is caused by a disruption of
endogenous dopamine occupation of D2 receptors and the resulting
hyperpolarization and inhibition of spontaneous action potential
firing. This allows L-channels to be activated by the depolarization of
action potentials, which in turn stimulates 1D gene
expression. Thus, haloperidol prevents the tonic dopaminergic interruption of the positive feedback between L-channel activity and
1D gene expression.
Suppression of L-current is likely to play a significant role in
dopamine inhibition of melanotrope secretion. Nimodipine inhibits
secretion from melanotropes (Taraskevich and Douglas, 1986), and thus
L-channels can trigger exocytosis in these cells. Exocytosis in
melanotropes depends on Ca2+ influx to the
approximately third power (Thomas et al., 1990), and so a 35%
reduction in Ca2+ influx through L-channels might
have a much larger effect on secretion. The effect might be further
amplified if exocytosis in melanotropes is more tightly coupled to
L-channels than to P/Q-channels (Artalejo et al., 1994).
Haloperidol is used clinically as an antipsychotic agent.
Interestingly, a reduction in psychotic symptoms generally occurs only
with long-term drug use. Such chronic treatment induces
hyperexcitability in midbrain dopamine neurons of animal models (Grace
et al., 1997). The molecular basis of chronic haloperidol action is
thought to involve regulation of neural gene expression (Hyman and
Nestler, 1996). Therefore, it is intriguing to speculate that neuronal L-type Ca2+ channel gene expression may be elevated
during chronic haloperidol treatment, and the resulting increase in
L-current may be an important cellular mechanism of hyperexcitability
and the alleviation of psychotic symptoms.
| |
FOOTNOTES |
Received Nov. 13, 1998; revised Feb. 11, 1999; accepted Feb. 12, 1999.
This work was supported by National Institutes of Health Grants NS32385
and HL55312 (E.S.L.), National Institute on Drug Abuse Grant DA-00266
(R.E.M.), and predoctoral fellowships from the American Heart
Association and the Andrew Mellon Foundation (D.M.F). E.S.L. is an
Established Investigator of the American Heart Association. We thank C. Cheng (University of Pittsburgh) and A. M. Oyarce (Johns Hopkins
University) for excellent technical assistance, P. Shepard (University
of Maryland) for advice, and T. P. Snutch (University of British
Columbia) for plasmids used in the construction of 1
subunit probes.
Correspondence should be addressed to Edwin S. Levitan, Department of
Pharmacology, University of Pittsburgh School of Medicine, Pittsburgh,
PA 15261.
Dr. Fass's present address: Vollum Institute, Portland, OR 97201.
| |
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ABSTRACT
INTRODUCTION
