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The Journal of Neuroscience, April 15, 2001, 21(8):2571-2579
Physiological Patterns of Electrical Stimulation Can Induce
Neuronal Gene Expression by Activating N-Type Calcium Channels
Teresa A.
Brosenitsch and
David M.
Katz
Department of Neurosciences, Case Western Reserve University School
of Medicine, Cleveland, Ohio 44106
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ABSTRACT |
Activity-dependent neuronal gene expression is thought to require
activation of L-type calcium channels, a view based primarily on
studies in which chronic potassium (K+)
depolarization was used to mimic neuronal activity. However, N-type
calcium channels are primarily inactivated during chronic depolarization, and their potential contribution to gene expression induced by physiological patterns of stimulation has not been defined.
In the present study, electrical stimulation of dissociated primary
sensory neurons at 5 Hz, or treatment with elevated
K+, produced a large increase in the percentage of
neurons that express tyrosine hydroxylase (TH) mRNA and protein.
However, blockade of L-type channels, which completely inhibited
K+-induced expression, had no effect on TH
expression induced by patterned stimulation. Conversely, blockade of
N-type channels completely inhibited TH induction by patterned
stimulation, whereas K+-induced expression was
unaffected. Similar results were obtained for depolarization-induced
expression of the immediate early genes Nurr1 and
Nur77. In addition, TH induction by patterned
stimulation was significantly reduced by inhibitors of PKA and PKC but
was unaffected by inhibition of the mitogen-activated protein kinase (MAPK) pathway. On the other hand, K+-induced
TH expression was significantly reduced by inhibition of the MAPK
pathway but was unaffected by inhibitors of PKA or PKC. These results
demonstrate that N-type calcium channels can directly link phasic
membrane depolarization to gene expression, challenging the view that
activation of L-type channels is required for nuclear responses to
physiological patterns of activity. Moreover, our data show that phasic
and chronic depolarizing stimuli act through distinct mechanisms to
induce neuronal gene expression.
Key words:
activity-dependent gene expression; PKA; PKC; CREB; Nurr1; dopamine
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INTRODUCTION |
Activity-dependent,
calcium-regulated gene expression plays a critical role in diverse
neural functions, including differentiation (Gu and Spitzer, 1997 ;
Buonanno and Fields, 1999) and survival (Ghosh et al., 1994) of
neurons, formation of synaptic connections (Lein and Shatz, 2000), and
learning and memory (Svoboda and Mainen, 1999). The importance of
calcium-regulated gene expression has led to numerous studies examining
molecular mechanisms that link membrane depolarization, and subsequent
elevation of intracellular calcium levels, with gene expression
(Finkbeiner and Greenberg, 1998). One conclusion of these studies is
that activation of L-type calcium channels is required for
depolarization-mediated gene induction.
Most studies that have examined mechanisms of activity-dependent gene
expression have used chronic membrane depolarization, induced by
elevated K+ or glutamate, to raise
intracellular calcium levels and stimulate gene expression. Although
these methods are effective at elevating intracellular calcium, they
produce a nonphysiological chronic membrane depolarization and tonic
elevation of intracellular calcium, conditions that do not mimic
cellular responses to physiological patterns of phasic neuronal
activity. In fact, the importance of patterned stimulation, or
oscillating levels of intracellular calcium, in mediating gene
expression (Fields et al., 1997; Dolmetsch et al., 1998; Li et al.,
1998), neurotrophin release (Balkowiec and Katz, 2000), and neuronal
differentiation (Gu and Spitzer, 1997) is clear. For example, Fields
and colleagues (1997) demonstrated that the level of c-fos
expression in primary sensory neurons is correlated with the time
interval between bursts of action potentials rather than with the
amplitude of calcium influx. In addition, Balkowiec and Katz (2000)
demonstrated recently that, although short-term continuous membrane
depolarization is completely ineffective at releasing brain-derived
neurotrophic factor from primary sensory neurons, patterned stimulation
for the same period of time increases release 20-fold. Thus, the use of
chronic stimulation as a model for neuronal activity is unlikely to
provide a complete understanding of mechanisms that underlie
activity-dependent signaling events.
We demonstrated previously that activation of L-type calcium channels
by chronic K+ depolarization alters short-
and long-term regulation of tyrosine hydroxylase (TH) expression in
primary sensory neurons, despite the fact that N-type calcium channels
carry the majority of the voltage-activated calcium current in these
cells (Brosenitsch et al., 1998). However, under conditions of
sustained membrane depolarization, N-type calcium channels are
inactivated (Nowycky et al., 1985; Hirning et al., 1988) and their
potential contribution to activity-dependent events cannot be
evaluated. Therefore, in the present study, we evaluated the role of N-
and L-type calcium channels in activity-dependent gene expression by
comparing the effects of K+ depolarization
and patterned electrical field stimulation. Our findings demonstrate
that, in sharp contrast to chronic membrane depolarization, patterned
electrical stimulation acts through N-type calcium channels to induce
neuronal gene expression. Moreover, we show that expression induced by
electrical stimulation requires activation of intracellular protein
kinase pathways distinct from those activated by chronic
K+ depolarization.
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MATERIALS AND METHODS |
Cell culture. Pregnant dams (Sprague Dawley rat;
Zivic-Miller, Zelienople, PA) were rapidly killed by exposure to carbon
dioxide. The uterine horns were removed and placed into PBS
containing 10% glucose, and the embryos were excised. To assign
gestational ages, the day after mating was designated embryonic day (E)
0.5. E16.5 petrosal ganglia (PG) were digested in Dispase (Roche
Molecular Biochemicals, Mannheim, Germany) for 30 min at 37°C,
followed by trituration through siliconized, fire-polished Pasteur
pipettes. Cells were plated onto glass coverslips coated with Growth
Factor Reduced Matrigel Matrix (diluted 1:10; Becton Dickinson,
Bedford, MA) at a density of one ganglion per well. Dissociate cultures were grown in Neurobasal medium supplemented with B-27 serum-free supplement, 1% penicillin-streptomycin-neomycin antibiotic mixture, and 0.5 mM L-glutamine
(Life Technologies, Gaithersburg, MD). All cultures were supplemented
with recombinant human brain-derived neurotrophic factor (a gift from
Regeneron Pharmaceuticals Inc., Tarrytown, NY) at a concentration of 10 ng/ml. Neurons were cultured for a total of 4 d before stimulation
for 6 or 24 hr with either 40 mM KCl or patterned
electrical impulses (see below). For experiments examining TH protein
expression, the medium was replaced immediately after stimulation, and
the cultures were grown for an additional 12 hr in control conditions
to permit new protein synthesis. For experiments examining TH mRNA or
Nur-related factor (Nurr) expression, cultures were fixed immediately
after stimulation.
Stimulation protocols and reagents. PG cultures were
electrically stimulated in 24-well plates fitted with a pair of
platinum electrodes connected in parallel to a stimulator (MultiStim
System; Digitimer, Hertfordshire, UK). Cultures were stimulated with
0.2 msec pulses of alternating polarity delivered at 5 Hz continuously or at 25 Hz in 2-sec-long bursts delivered once every 10 sec. These two
stimulation paradigms produce an equivalent number of pulses over the 6 hr stimulation period. The drugs used are as follows.  -Conotoxin
GVIA (Sigma, St. Louis, MO) and tetrodotoxin (Sigma) were used at final
concentrations of 1 and 1.5 µM, respectively. Nimodipine (Sigma), dissolved in methanol, was used at a final concentration of 2 µM. PD98059 (Calbiochem, La
Jolla, CA) and H-89 (Calbiochem), dissolved in dimethylsulfoxide
(DMSO), were used at final concentrations of 50 and 3 µM, respectively. Membrane-permeable forms of
the protein kinase A (PKA) inhibitor PKI14-22
amide-myristoylated (Calbiochem), the protein kinase C (PKC) inhibitor
PKC-I19-27-myristoylated (Calbiochem), and the
calcium/calmodulin kinase (CaMK) II inhibitor autocamtide-2 inhibitory
peptide-myristoylated (Calbiochem) were used at a final concentration
of 50 µM. These concentrations of kinase
inhibitors have been shown previously to be efficacious and specific
(Eichholtz et al., 1993; Alessi et al., 1995; Ishida et al., 1995;
Harris et al., 1997). Actinomycin D (Sigma) was used at a final
concentration of 0.5 µg/ml.
D,L-2-Amino-5-phosphonovaleric acid (APV) (Sigma)
was used at a concentration of 50 µM.
6-Cyano-7-nitroquinoxaline-2,3-(1H,4H)-dione (CNQX) (Sigma) was
dissolved in DMSO and used at a final concentration of 10 µM. In each experiment, the final DMSO
concentration never exceeded 0.02%. Pertussis toxin (Calbiochem) was
used at a final concentration of 1 µg/ml, and cultures were
preincubated with the toxin for 20 hr before the onset of stimulation.
Immunocytochemistry. All cultures were fixed with 4%
paraformaldehyde in 0.1 M sodium phosphate buffer
(PFA), pH 7.4, for 30 min. The following antibodies were used for
double-immunostaining: polyclonal anti-TH (Pel-Freez Biologicals,
Rogers, AR), polyclonal anti-Nurr1/Nur77 (Santa Cruz Biotechnology,
Santa Cruz, CA), polyclonal anti-phosphorylated cAMP response
element-binding protein (pCREB) (Upstate Biotechnology, Lake Placid,
NY), monoclonal anti-neurofilament (NF) protein
(NF160,68; Sigma), goat anti-rabbit IgG-FITC
(Roche Molecular Biochemicals), and goat anti-mouse IgG rhodamine
(Cappel, Durham, NC). TH-NF immunostaining was performed as described
previously (Brosenitsch et al., 1998). The protocol for Nurr and pCREB
immunostaining was the same as for TH-NF, except that cells were
incubated in 20% goat serum in PBS containing 0.5% Triton X-100
(PBS-Tx) before incubation in the primary antibodies, which was
performed at 4°C in anti-Nurr1/Nur77 (1:4000) or anti-pCREB (1:2000)
and anti-NF (1:100) diluted in PBS-Tx containing 2% goat serum.
In situ hybridization. The digoxigenin (DIG)-labeled TH
sense and antisense RNA probes were prepared using as template a 280 bp
fragment of TH cDNA (1240-1521) cloned into the EcoRI site of pGEM-3 phagemid [generated in the laboratory of A. William Tank,
University of Rochester School of Medicine and Dentistry (Rochester,
NY), and generously provided by Kumi Nagomoto-Combs, Case Western
Reserve University]. Sense and antisense probes were synthesized with DIG-11-UTP (Roche Molecular Biochemicals) using an RNA
transcription kit (Stratagene, La Jolla, CA). For hybridization, cultures were fixed in PFA for 30 min, rinsed twice in PBS, acetylated with 0.25% acetic anhydride in 10 mM
triethanolamine, pH 8.0, for 10 min, rinsed in 1× SSC for 10 min, and
incubated in hybridization buffer (50% formamide, 5× SSC, 1 mg/ml
yeast tRNA, 100 µg/ml heparin, 1× Denhardt's reagent, 0.1%
Tween 20, 1 mg/ml
3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate, and 5 mM EDTA) without probe for 6 hr. Sense and
antisense probes were diluted 1:40 in hybridization buffer, and
cultures were hybridized for 16 hr at 50°C. After hybridization,
cultures were washed in 1× SSC at 60°C for 10 min and again for 30 min, washed in 0.1× SSC for 1 hr at 60°C, incubated in 20 µg/ml
RNase A at 37°C for 30 min, rinsed in 1 mM
dithiothreitol at 37°C for 30 min, washed in 0.1× SSC for 1 hr at
65°C, and washed in 2× SSC for 30 min. For immunological detection
of DIG-labeled hybrids, cultures were rinsed in PBS containing 0.1%
Triton X-100 and 2 mg/ml BSA (PBT), blocked with 20% sheep serum in
PBT for 6 hr, and incubated in sheep anti-DIG-alkaline
phosphatase-conjugated Fab fragments (Roche Molecular Biochemicals)
diluted 1:700 in PBT containing 20% sheep serum overnight at 4°C.
The next day, cultures were rinsed four times in PBT for 10 min each,
rinsed in buffer 2 (100 mM Tris, pH 9.5, 100 mM NaCl, and 50 mM
MgCl2), rinsed in buffer 2 containing 5 mM levamisole (Sigma), and incubated in buffer 2 containing 5 mM levamisole, 340 µg/ml nitroblue
tetrazolium (Roche Molecular Biochemicals), and 240 µg/ml
5-bromo-4-chloro-3-indolyl phosphate (Roche Molecular Biochemicals) for
30 hr. The reaction was stopped by rinsing the cultures with Tris-EDTA
buffer, pH 8.0, and the cultures were subsequently processed for
NF immunocytochemistry as described previously (Brosenitsch et al.,
1998).
Cell counts and statistical analysis. The number of neurons
in each culture was estimated by counting all cells within the central
10% of each coverslip. All cell counts were performed with the
investigator blinded to the experimental treatment. Experiments were
performed at least three times with at least two cultures per
experimental group. At least 1200 neurons per experimental group were
scored for TH, Nurr, or pCREB immunoreactivity. Data are presented as
the percentage of total neurons that expressed TH protein, TH mRNA,
Nurr, or pCREB. The intensity of TH immunoreactivity was measured from
randomly chosen fields of cells using SimplePCI imaging software
(Compix Inc., Cranberry, PA). Data are presented in arbitrary units
with the background subtracted. Intensity was measured on ~1700
neurons. For statistical analysis, percentages were normalized (arcsin
transformation) and values were compared using ANOVA, followed by
Duncan's multiple range test. p < 0.05 was considered significant.
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RESULTS |
PG primary sensory neurons provide a robust model for studying
activity-dependent neuronal gene expression. We found previously that
exposure of fetal PG neurons to chronic depolarizing stimuli in culture
leads to a fivefold increase in the percentage of ganglion cells that
express dopaminergic traits, including TH, without affecting neuronal
survival (Hertzberg et al., 1995; Brosenitsch et al., 1998). In the
present study, therefore, we sought to compare induction of
dopaminergic traits in response to chronic depolarization and more
physiological, patterned, electrical stimuli. Normally, only 10-15%
of PG neurons are dopaminergic (Katz et al., 1983; Finley et al.,
1992). Field stimulation of E16.5 PG neurons for 6 hr at either 5 Hz (a
physiological frequency; Bairam et al., 1993) continuously or 25 Hz for
2 sec, once every 10 sec, resulted in an approximate sixfold increase
in the percentage of neurons expressing TH protein, an increase
identical to that produced by 6 hr of chronic membrane depolarization
with elevated K+ (Fig.
1). Neuron survival was unaffected by
either electrical stimulation or K+
depolarization (control, 550 ± 57; 5 Hz, 428 ± 32; 25 Hz,
567 ± 83; KCl, 536 ± 37). In addition, stimulation at 5 Hz,
or with elevated K+, for 24 hr
significantly increased the percentage of neurons expressing TH mRNA as
determined by in situ hybridization (see Fig. 4). The
increase in TH protein expression after 6 hr of stimulation was
prevented by inhibition of mRNA synthesis with 0.5 µg/ml actinomycin D (Fig. 2A), without
affecting neuronal survival (control, 763 ± 106 neurons; 5 Hz,
662 ± 55; 5 Hz plus actinomycin, 594 ± 66). Moreover, the
effect of 5 Hz stimulation, but not that of elevated K+, was blocked by the sodium channel
antagonist tetrodotoxin (1.5 µM), indicating
that activation of voltage-gated sodium channels is required for TH
induction by electrical stimulation (Fig. 2B). These
initial experiments demonstrated that patterned stimulation and chronic
K+ depolarization are both effective at
inducing TH mRNA and protein in fetal PG neurons.
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Figure 1.
TH induction by electrical stimulation and
K+ depolarization. Dissociate cultures of E16.5 PG
neurons were stimulated at 5 Hz continuously (0.2 msec alternating
polarity pulses), at 25 Hz for 2 sec once every 10 sec, or chronically
with 40 mM KCl. After 6 hr of stimulation, neurons were
cultured for an additional 12 hr in control conditions and then
processed for TH-NF immunocytochemistry. Each bar
represents the percentage of total neurons exhibiting TH
immunoreactivity. Data are presented as the mean ± SEM.
Comparisons among groups were made using ANOVA followed by Duncan's
multiple range test; ***p  0.001.
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Figure 2.
TH induction by electrical stimulation requires
mRNA synthesis (A) and functional
voltage-activated sodium channels (B). E16.5 PG
neurons were stimulated at 5 Hz or with 40 mM KCl for 6 hr
in the presence or absence of 0.5 µg/ml actinomycin D
(A) or 1.5 µM tetrodotoxin
(B). Each bar represents the
percentage of total neurons exhibiting TH immunoreactivity. Data are
presented as the mean ± SEM. Comparisons among groups were made
using ANOVA followed by Duncan's multiple range test;
***p 0.001. Ctrl,
Control.
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To establish a semiquantitative measurement of the difference in TH
expression between neurons classified as TH-positive and TH-negative,
we measured their fluorescence intensity by digital imaging. In all
experimental groups, the average fluorescence intensity of neurons
classified as TH-positive was at least six times greater than the
average intensity of neurons classified as TH-negative (Table
1). Thus, the increase in the percentage of TH-positive neurons after 5 Hz stimulation and
K+ depolarization reflects highly
significant increases in TH expression per neuron. In addition, these
data show that both 5 Hz stimulation and
K+ depolarization induced, on average, a
similar level of TH expression per neuron.
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Table 1.
Fluorescence intensity measurements of neurons classified
as TH-positive or TH-negative in control and stimulated cultures, in
the absence or presence of calcium channel blockers
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We found previously that 68% of the high voltage-activated calcium
current in E16.5 PG neurons is blocked by the N-type channel antagonist
-conotoxin, whereas only 16% is blocked by the L-type channel
antagonist nimodipine (Brosenitsch et al., 1998). In the present study,
we used these antagonists to determine the role of high
voltage-activated calcium channels in gene expression induced by
patterned electrical stimulation. Inhibition of L-type channels had no
effect on the induction of TH protein (Fig.
3) or mRNA (Fig.
4) in response to 5 Hz stimulation but
completely blocked induction by chronic K+
depolarization, as described previously (Brosenitsch et al., 1998).
Conversely, N-type channel blockade completely abolished both TH
protein (Fig. 3) and mRNA (Fig. 4) induction after 5 Hz stimulation and
had no effect on induction by chronic K+
depolarization. In addition, nimodipine had no effect on the average
fluorescence intensity of TH-positive neurons in 5 Hz stimulated
cultures, and -conotoxin had no effect on the average fluorescence
intensity of TH-positive neurons in
K+-depolarized cultures (Table 1). Thus,
nimodipine and -conotoxin were not only ineffective in reducing the
percentage of TH-positive neurons in 5 Hz stimulated and
K+-depolarized cultures, respectively, but
also did not decrease the average level of TH-expression per neuron in
these groups. To determine whether N-type calcium channels are also
required for activity-dependent regulation of other dopaminergic
traits, we examined expression of the Nurr family of orphan nuclear
receptors using a pan-Nurr antibody that recognizes Nurr1 and Nur77
[nerve growth factor inducible-B (NGFI-B)]. Electrical
stimulation (5 Hz) induced a 10-fold increase in the percentage
of Nurr-immunoreactive neurons that was abolished by N-type channel
blockade and unaffected by inhibition of L-type channels (Fig.
5). Elevated
K+, on the other hand, produced a 16-fold
increase in the percentage of Nurr-positive cells that was prevented by
blockade of L-type calcium channels and unaffected by blockade of
N-type channels (Fig. 5). These data indicate, therefore, that
patterned electrical stimulation and chronic membrane depolarization,
respectively, induce TH and Nurr expression by activating distinct
populations of voltage-activated calcium channels.
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Figure 3.
Electrical stimulation (5 Hz) and
K+ depolarization induce TH expression by activating
distinct calcium channel subtypes. Each bar represents
the percentage of total neurons in stimulated and unstimulated
(Ctrl) cultures exhibiting TH immunoreactivity in
the absence or presence of 2 µM nimodipine, an L-type
calcium channel antagonist, or 1 µM -conotoxin, an
N-type calcium channel antagonist. Data are presented as the mean ± SEM. Comparisons among groups were made using ANOVA followed by
Duncan's multiple range test; ***p 0.001.
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Figure 4.
The effect of selective calcium channel
antagonists on stimulation-induced expression of TH mRNA.
A, TH mRNA expression in E16.5 PG cultures stimulated at
5 Hz or with 40 mM KCl for 24 hr in the presence or absence
of 1 µM -conotoxin (-Ctx) or 2 µM nimodipine (Nim). Scale bar, 50 µm.
B, Each bar represents the percentage of
total neurons exhibiting TH mRNA by in situ
hybridization. Data are presented as the mean ± SEM. Comparisons
among groups were made using ANOVA followed by Duncan's multiple range
test; *p 0.05; ***p 0.001. Ctrl, Control.
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Figure 5.
Electrical stimulation (5 Hz) and
K+ depolarization induce Nurr expression by
activating distinct calcium channel subtypes. Each bar
represents the percentage of total neurons in stimulated and
unstimulated (Ctrl) cultures exhibiting Nurr
immunoreactivity in the absence or presence of 2 µM
nimodipine or 1 µM -conotoxin. Data are presented as
the mean ± SEM. Comparisons among groups were made using ANOVA
followed by Duncan's multiple range test; **p 0.01; ***p 0.001.
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N-type calcium channels have been associated primarily with
neurotransmitter release at synaptic sites (Dunlap et al., 1995). This
raised the possibility that the TH and Nurr induction we observed after
5 Hz stimulation was secondary to electrically evoked transmitter
release at synaptic sites that may have developed between PG neurons in
our cultures. We considered this unlikely, because primary sensory
neurons do not form synapses in vitro in the presence of
ganglionic satellite cells (Cooper, 1984; Zhong et al., 1997), as in
our cultures. Nonetheless, we compared the effect of 5 Hz stimulation
on TH expression in the absence and presence of pharmacological
blockers of glutamate receptors, because glutamate is the principal
excitatory transmitter of PG neurons (Mizusawa et al., 1994). Addition
of the NMDA receptor antagonist APV (50 µM) and
the non-NMDA receptor antagonist CNQX (10 µM) had no effect on TH induction by 5 Hz stimulation (Fig.
6). In addition, application of pertussis
toxin (1 µg/ml), to prevent potential transmitter actions
through pertussis toxin-sensitive G-protein-linked receptors, had no
effect on stimulation-induced TH expression (data not shown). These
data argue strongly against a role for indirect effects of N-type
calcium channel activation on activity-dependent TH and Nurr induction
in our cultures.
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Figure 6.
TH induction by 5 Hz stimulation is unaffected by
treatment with ionotropic glutamate receptor antagonists. E16.5 PG
neurons were stimulated at 5 Hz for 6 hr in the presence or absence of
the NMDA receptor antagonist APV (50 µM) and the non-NMDA
receptor antagonist CNQX (10 µM). Each bar
represents the percentage of total neurons exhibiting TH
immunoreactivity presented as the mean ± SEM. Comparisons were
made using ANOVA followed by Duncan's multiple range test;
***p 0.001. Ctrl, Control.
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Previous studies demonstrated that different calcium influx sites
mediate neuronal gene expression through distinct protein kinase
pathways and promoter elements. For example, in hippocampal neurons,
calcium entry through either NMDA or L-type channels increases
expression of the immediate early response gene c-fos; however, CaMK II is required only for c-fos induction after
activation of L-type channels (Bading et al., 1993). To begin examining
whether patterned electrical stimulation and activation of N-type
channels induce gene expression through intracellular signaling
pathways distinct from those recruited in response to chronic
K+ depolarization and L-type channel
activation, we compared TH induction by these two protocols in the
absence or presence of specific protein kinase inhibitors. Inhibition
of PKA with the specific peptide inhibitor
PKI14-22 (50 µM) (Harris
et al., 1997) or PKC with the specific peptide inhibitor
PKC-I19-27 (50 µM)
(Eichholtz et al., 1993) resulted in a significant 57% reduction in
the percentage of TH-positive neurons induced by 5 Hz stimulation but
had no effect on K+-induced TH expression
(Fig. 7). A similar result was observed with the structurally distinct PKA antagonist H89 (3 µM; data not shown). Conversely, the
mitogen-activated protein kinase (MAPK) pathway inhibitor PD98059 (50 µM) (Alessi et al., 1995) did not significantly
alter TH induction by 5 Hz stimulation but reduced TH induction by
chronic K+ depolarization by 41.5% (Fig.
7). Inhibition of CaMK II with the specific peptide inhibitor
autocamtide-2 inhibitory peptide (50 µM)
(Ishida et al., 1995) had no effect on TH expression after either 5 Hz
stimulation or K+ depolarization (Fig. 7).
To rule out the possibility that the PKA and PKC inhibitors decreased
the level of TH expression per neuron in
K+-depolarized cultures without affecting
the percentage of TH-positive neurons, we measured the fluorescence
intensity of TH-positive neurons in these groups. Neither inhibitor
significantly altered the average fluorescence intensity of TH-positive
neurons in K+-depolarized cultures (KCl,
54.3 ± 5.8, n = 56 neurons; KCl plus PKA
inhibitor, 64.5 ± 8.3, n = 38 neurons; KCl plus
PKC inhibitor, 51.0 ± 6.03, n = 37 neurons).
Similarly, PD98059 did not significantly alter the average fluorescence
intensity of TH-positive neurons in 5 Hz-stimulated cultures (5 Hz,
56.7 ± 9.9, n = 25 neurons; 5 Hz plus PD98059,
64.7 ± 10.1, n = 34 neurons). Moreover, none of
the kinase inhibitors significantly affected neuronal survival (Table
2). Together, these data indicate that TH
expression is regulated by distinct protein kinase pathways after
patterned electrical stimulation and chronic
K+ depolarization, respectively.
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Figure 7.
TH induction by 5 Hz stimulation and potassium
depolarization, respectively, requires activation of distinct
intracellular kinase pathways. E16.5 PG neurons were stimulated for 6 hr at 5 Hz (gray bars) or with 40 mM
KCl (black bars) in the presence or absence of the PKA
antagonist PKI14-22 amide-myristoylated, the PKC
antagonist PKC-I19-27-myristoylated, the CaMK II inhibitor
autocamtide-2 inhibitory peptide-myristoylated, or the MAPK pathway
inhibitor PD98059. Cultures were incubated for 1 hr with each drug (50 µM) before stimulation. After stimulation, cultures were
grown an additional 12 hr in control conditions. Each
bar represents the percentage of total neurons
exhibiting TH immunoreactivity presented as the mean ± SEM.
Comparisons were made using ANOVA followed by Duncan's multiple range
test; *p 0.05 compared with KCl alone;
***p 0.001 compared with 5 Hz stimulation alone;
n.s., not significantly different from 5 Hz stimulation
alone. Ctrl, Control.
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The time course of calcium-induced CREB phosphorylation has been shown
previously to be dependent on the route by which calcium enters a
neuron (Hardingham et al., 1999). To determine whether K+-induced activation of L-type calcium
channels and 5 Hz activation of N-type channels lead to distinct
profiles of CREB phosphorylation, we examined expression of pCREB in PG
neurons after 5 Hz stimulation and K+
depolarization for varying periods of time. Both 5 Hz stimulation and
K+ depolarization led to a marked increase
in the percentage of pCREB-expressing neurons after 15 min exposure to
either protocol (Fig. 8). However,
K+ depolarization produced a sustained
increase in the percentage of pCREB-positive neurons that could still
be observed after 2 hr of continuous depolarization, whereas pCREB was
almost undetectable after 2 hr of continuous 5 Hz stimulation (Fig. 8).
These data demonstrate a dynamic regulation of pCREB during patterned
stimulation, possibly by phosphatase activity (Bito et al., 1996),
which is not seen in response to chronic membrane depolarization.
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Figure 8.
Electrical stimulation (5 Hz) and potassium
depolarization lead to distinct temporal patterns of CREB
phosphorylation. E16.5 PG neurons were stimulated at 5 Hz or with 40 mM KCl for 15, 30, 60, or 120 min. Immediately after the
stimulation period, the cultures were fixed and processed for pCREB-NF
immunocytochemistry. Each bar represents the percentage
of total neurons exhibiting pCREB immunoreactivity. Data are
presented as the mean ± SEM. At each time point, except 120 min,
5 Hz and KCl are significantly different from corresponding controls;
p 0.001. At 120 min, only KCl is significantly
different from control; p 0.001.
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DISCUSSION |
The present findings demonstrate that calcium influx through
N-type channels can directly link phasic electrical stimulation to
changes in neuronal gene expression. Although N-type calcium channels
have been associated predominately with transmitter release (Dunlap et
al., 1995), our results are consistent with the fact that N-type
calcium channels carry the majority of the high voltage-activated calcium current in many populations of cells, including primary sensory
(Nowycky et al., 1985; Mendelowitz and Kunze, 1992; Brosenitsch et al.,
1998) and sympathetic (Hirning et al., 1988; Plummer et al., 1989)
neurons, as well as pheochromacytoma (PC12) cells (Plummer et
al., 1989). Moreover, although N-type calcium channels are localized in
discrete patches, presumably at synaptic sites, in mature neurons
(Westenbroek et al., 1992, 1998; Haydon et al., 1994; Mills et al.,
1994), this is not true during early development. Before
synaptogenesis, N-type channels are diffusely expressed over the entire
neuronal surface (Jones et al., 1989; Bahls et al., 1998). Thus, in
immature neurons, N-type calcium channels are required for multiple
cellular events, including neuronal migration (Komuro and Rakic, 1992),
axon outgrowth (Doherty et al., 1991), and, as indicated by the present
findings, activity-dependent gene expression.
In other neuron types, action potentials, in the absence of synaptic
activity, are ineffective at triggering specific intracellular responses, such as TH enzyme activation (Chalazonitis and Zigmond, 1980), CREB phosphorylation (Deisseroth et al., 1996), or
c-fos expression (Luckman et al., 1994). For example,
Deisseroth and colleagues (1996) demonstrated that CREB phosphorylation
induced by patterned stimulation of hippocampal neurons absolutely
requires NMDA receptor activation, despite the fact that bulk
intracellular and nuclear calcium levels were increased by stimulation
alone. This requirement for transynaptic activation has been linked to the fact that L-type calcium channels have relatively slow activation kinetics and are only fully activated by sustained, EPSP-like depolarizations (Nakazawa and Murphy, 1999; Mermelstein et al., 2000),
whereas N-type channels are rapidly activating and inactivating (Nowycky et al., 1985; Hirning et al., 1988). In the present study, exposure of sensory neurons to sustained high
K+, or rapid, phasic electrical stimuli,
induced gene expression by activating L- and N-type channels,
respectively. These findings are consistent with the distinct
biophysical properties of L- and N-type channels and supports the
hypothesis that their differential activation in vivo allows
neurons to distinguish between different types of depolarization
(Mermelstein et al., 2000). Specifically, N-type calcium channels could
transduce rapid depolarizations, such as those resulting from action
potentials, whereas L-type channels would preferentially respond to
slow, EPSP-like depolarizations. Our findings demonstrate that these
two different temporal patterns of depolarization can be encoded by
activation of distinct intracellular signaling pathways. Although our
data show that dopaminergic traits are induced in sensory neurons by
both chronic and phasic depolarizing stimuli, it is possible that
expression of other genes is differentially regulated by activation of
L- and N-type channels, respectively.
Based on previous studies, in which K+
depolarization was used to model neuronal activity, the prevailing view
has been that activation of L-type calcium channels links membrane
depolarization to calcium-induced gene expression. For example,
K+-induced expression of immediate early
genes, such as c-fos, requires calcium influx through L-type
calcium channels (Morgan and Curran, 1986). In addition, regulation of
late response genes, such as transmitter receptor subunits (De Koninck
and Cooper, 1995; Gault and Siegel, 1997), transmitter-related proteins
(Ai et al., 1998; Brosenitsch et al., 1998; Cigola et al., 1998), ion
channels (Schorge et al., 1999), and growth factors (Zafra et al.,
1990; Ghosh et al., 1994) by chronic depolarization has been attributed
to calcium influx exclusively through L-type calcium channels. However,
in these models, N-type channels were most likely inactivated by the
level of sustained depolarization produced by chronic
K+ treatment and thus unable to flux
calcium. For example, we found previously that primary sensory neurons
treated with 40 mM KCl exhibit membrane
potentials of approximately  20 mV, a voltage at which 72% of the
total calcium current is inactivated after a 2 sec conditioning pulse
(Brosenitsch et al., 1998). This finding suggests that the use of
chronic elevated K+ as a model of neuronal
activity may generally preclude the ability to assess the role of
N-type calcium channels in gene expression. On the other hand,
post-translational events, such as TH enzyme activation by short-term
(90 sec) exposure to elevated K+, have
been shown to require N-type channels (Rittenhouse and Zigmond, 1991,
1999).
Our data indicate that the intracellular signaling cascades required
for gene expression in response to patterned electrical stimulation are
distinct from those recruited by chronic membrane depolarization. This
differential requirement for specific intracellular protein kinases
could arise from differences in the amplitude of the cytosolic or
nuclear calcium signal (Hardingham et al., 1997; Chawla et al., 1998),
the frequency or kinetics of calcium influx (Buonanno and Fields,
1999), or the fact that the route of calcium entry activated by these
two stimulation paradigms are distinct (Finkbeiner and Greenberg,
1998). Over the past few years, evidence has accumulated that the route
by which calcium enters the cytosol is important for determining which
intracellular signaling pathways are recruited and, subsequently, which
genes are expressed (Bading et al., 1993; Lerea and McNamara, 1993; Deisseroth et al., 1996; Hardingham et al., 1999; Hu et al., 1999). For
example, K+-induced L-type calcium channel
activation in hippocampal neurons leads to sustained pCREB and
activation of CREB-binding protein-dependent transcription
through a CaMK IV-dependent mechanism, whereas activation of NMDA
receptors results in transient pCREB and CamK IV-independent transcription (Hardingham et al., 1999). In addition,
K+-induced L-type channel activation in
cortical neurons results in transient CaMK II activity and weak PKA
activity, whereas NMDA receptor activation produces more sustained CaMK
II activity and no PKA activation (Hu et al., 1999). These studies
demonstrate clear differences in the intracellular response to
activation of two distinct classes of calcium channels, i.e.,
ligand-gated ionotropic glutamate receptors and voltage-gated L-type
calcium channels. Our data indicate that activation of distinct
intracellular signaling pathways also occurs when calcium enters
through different subtypes of voltage-activated calcium channels. An
additional possibility, however, is that the requirement for distinct
kinases results from different levels or spatial patterns of calcium
influx produced by each stimulation paradigm. For example, Hardingham and colleagues (1997) demonstrated that an increase in nuclear calcium
is required for CRE-mediated transcription in response to L-type
channel activation, whereas an increase in cytoplasmic calcium, in the
absence of nuclear calcium elevation, is not sufficient to induce
CRE-mediated transcription, although serum response element-dependent transcription is maintained. Thus, stimuli
sufficient to elevate nuclear calcium could induce gene expression
through mechanisms that are distinct from stimuli that produce only
local cytoplasmic elevations in intracellular calcium.
Previous studies examining the role of kinases in calcium-activated
gene expression have implicated numerous intracellular cascades in this
process depending on the cell type, stage of development, and type of
stimulation. Our data indicate that at least two kinases, PKA and PKC,
are required for TH induction by patterned stimulation of fetal primary
sensory neurons. PKA can be activated by intracellular calcium influx
and has been implicated previously in calcium-induced gene expression
in primary neurons, as well as PC12 cells (Ginty et al., 1991; Thompson
et al., 1995). K+-induced TH expression,
on the other hand, was independent of PKA and PKC and was only
partially attenuated by a MAPK pathway inhibitor, suggesting that
kinases other than MAPK, PKA, PKC, and CaMK II are involved.
Alternatively, inhibition of one kinase could be compensated for by
activation of multiple cascades by calcium influx. For example,
depolarization of hippocampal neurons leads to parallel activation of
the MAPK pathway, as well as CaMK, each of which is sufficient for
maximum CREB phosphorylation (Hardingham et al., 1999). In addition,
extensive cross talk between the PKA, PKC, and MAPK pathways has been
demonstrated (Grewal et al., 1999; Impey et al., 1999). Finally,
although our data suggest that CaMK II is not required for
activity-dependent TH induction in sensory neurons, we cannot exclude a
role for CaMK IV, which has been localized to the nucleus and can
mediate calcium-induced gene expression (Bito et al., 1996; Chawla et
al., 1998).
In summary, our findings demonstrate that phasic and chronic
depolarizing stimuli induce neuronal gene expression through distinct
signaling mechanisms, including activation of different calcium channel
subtypes and intracellular kinases. It is possible that the role of
N-type calcium channels in gene induction by patterned stimulation is
unique to immature neurons in general or to fetal sensory neurons in
particular. Nonetheless, the present findings challenge the prevailing
view that activation of L-type calcium channels is required for nuclear
responses to physiological patterns of neuronal stimulation.
| |
FOOTNOTES |
Received Nov. 20, 2000; revised Jan. 16, 2001; accepted Jan. 24, 2001.
This work was supported by National Institutes of Health Grants
HL25830 (Project 2; to D.M.K.) and 5T32NS07118. We thank Drs. Lynn
Landmesser, Gary Landreth, Evan Deneris, Vance Lemmon, and Karl Herrup
for their very helpful discussions of this work. We also thank Drs. R. Douglas Fields and Agnieszka Balkowiec for advice regarding electrical
field stimulation of neuronal cultures.
Correspondence should be addressed to Dr. David M. Katz, Department of
Neurosciences, Case Western Reserve University School of Medicine,
10900 Euclid Avenue, Cleveland, OH 44106. E-mail: dmk4{at}po.cwru.edu.
| |
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TOP
ABSTRACT
INTRODUCTION
