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The Journal of Neuroscience, January 15, 1998, 18(2):590-600
Growth Factor Receptor Tyrosine Kinases Acutely Regulate Neuronal
Sodium Channels through the Src Signaling Pathway
Michael D.
Hilborn1,
Richard R.
Vaillancourt2, and
Stanley G.
Rane1
1 Department of Biological Sciences, Purdue University,
West Lafayette, Indiana 47907, and 2 Department of
Pharmacology and Toxicology, College of Pharmacy, University of
Arizona, Tucson, Arizona 85721
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ABSTRACT |
Growth factor receptor tyrosine kinase (RTK)-activated signaling
pathways are well established regulators of neuronal growth and
development, but whether these signals provide mechanisms for acute
modulation of neuronal activity is just beginning to be addressed. We
show in pheochromocytoma (PC12) cells that acute application of ligands
for both endogenous RTKs [trkA, basic FGF (bFGF) receptor, and
epidermal growth factor (EGF) receptor] and ectopically expressed
platelet-derived growth factor (PDGF) receptors rapidly inhibits
whole-cell sodium channel currents, coincident with a hyperpolarizing
shift in the voltage dependence of inactivation. Sodium channel
inhibition by trkA and PDGF receptors is mutually occlusive, suggestive
of a common signal transduction mechanism. Furthermore, specific
inhibitors for trkA and PDGF RTK activities abrogate sodium channel
inhibition in response to NGF and PDGF, respectively, showing that the
intrinsic RTK activity of these receptors is necessary for sodium
channel inhibition. Use of PDGF receptor mutants deficient for specific
signaling activities demonstrated that this inhibition is dependent on
RTK interaction with Src but not with other RTK-associated signaling
molecules. Inhibition was also compromised in cells expressing
dominant-negative Ras. These results suggest a possible mechanism for
acute physiological actions of RTKs, and they indicate regulatory
functions for Ras and Src that may complement the roles of these
signaling proteins in long-term neuronal regulation.
Key words:
PC12 cells; sodium channels; growth factor receptor
tyrosine kinases; PDGF receptors; NGF; Ras; Src
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INTRODUCTION |
Growth factors constitute a family
of polypeptides essential for the establishment and maintenance of the
mature nervous system. Expressed throughout the CNS and PNS, growth
factors act by binding to their cognate receptor tyrosine kinases
(RTKs), which autophosphorylate and subsequently activate a complex of
signaling proteins including the well characterized Ras and
mitogen-activated kinase (MAPK) pathway, phosphatidylinositol 3-kinase
(PI3-K), phospholipase C (PLC), and the Src family of nonreceptor
tyrosine kinases (for review, see Panayotou and Waterfield, 1993 ;
Johnson and Vaillancourt, 1994; Kaplan and Stephens, 1994;
Szeberényi and Erhardt, 1994; van der Geer et al., 1994). The
variety of neuronal responses to growth factors, including
proliferation and migration, establishment and maintenance of synaptic
connections, and survival of many mature neurons, ultimately depends on
the activation of specific components comprising this signaling network
(for review, see Korsching, 1993; Snider, 1994; van der Geer et al.,
1994; Bothwell, 1995; Lewin and Barde, 1996).
In addition to the wealth of information on long-term cellular effects,
there is increasing evidence that growth factors and their signaling
pathways play pivotal roles in the acute regulation of the mature
nervous system (for review, see Thoenen, 1995). In hippocampal neurons,
depolarizing stimuli and stimulation protocols that induce long-term
potentiation (LTP) increase neurotrophin mRNA levels (Lu et al., 1991;
Patterson et al., 1992). In turn, growth factors can modulate synaptic
activity in hippocampal neurons and developing Xenopus
neuromuscular junctions (Terlau and Seifert, 1989; Abe et al., 1991;
Kang and Schuman, 1995), as well as modulate short-term potentiation
and LTP (Lohof et al., 1993; Stoop and Poo, 1996). These studies
suggest that ion channel modulation may be an important component of
acute growth factor actions, and they are complemented by work showing
growth factors can acutely modulate the high-voltage-activated
Ca2+ channel and Ca2+-activated
K+ channels (Wildering et al., 1995; Holm et al.,
1997). However, the signaling paths underlying these physiological
events are undetermined, and although both NMDA receptors and the human
Kv1.5 K+ channel associate with the nonreceptor
tyrosine kinase Src (Holmes et al., 1996; Yu et al., 1997), it is not
yet known whether this interaction underlies a growth factor-initiated
action. Furthermore, studies suggesting that the activation of the MAPK
cascade is essential for events associated with long-term facilitation
in Aplysia neurons have not ascertained whether growth
factors are vital in initiating this response (Bailey et al., 1997;
Martin et al., 1997). Thus, there is much to be determined concerning how growth factors physiologically modulate the mature nervous system
and which signaling pathways are essential to this modulation.
Past efforts to examine the signaling mechanisms that mediate the
effects of chronic growth factor exposure in both the PNS and CNS have
used the well characterized rat pheochromocytoma (PC12) model neuronal
cell line (for review, see Chao, 1992; Keegan and Halegoua, 1993;
Marshall, 1995). Application of NGF causes PC12 cells to differentiate
into a neuronal-like phenotype characterized by numerous morphological
and physiological changes, including the persistent activation of the
Ras and MAPK pathway, cessation of cellular division, neurite
extension, the induction of immediate early and neuronal-specific
genes, and an induction of electrical excitability because of an
increase in ion channel expression (Greene and Tischler, 1982). Via the
analysis of PC12 cell lines expressing mutant receptors or
intracellular signaling molecules, the signaling mechanisms that
mediate these long-term changes have been well characterized (Rausch et
al., 1990; Szeberényi et al., 1990; Ginty et al., 1992; Traverse
et al., 1992; Fanger et al., 1993, 1997; Cavalié et al., 1994;
Cowley et al., 1994; Loeb et al., 1994; Stephens et al., 1994;
Vaillancourt et al., 1995; Pollock and Rane, 1996; Hilborn et al.,
1997). For example, analyses of PC12 cell lines expressing mutated
platelet-derived growth factor (PDGF) receptors deficient for
activating specific signaling pathways have determined that both Src
and PLC are required for growth factor-induced neurite extension
(Vaillancourt et al., 1995). An analysis of these same cell lines,
along with PC12 cells expressing the N17 Ras dominant-negative mutant,
demonstrated that although growth factor-induced upregulation of brain
type II/IIA Na+ channels is independent of Ras
activation, the activation of Src is important for establishing the
full functional expression of these channels (Fanger et al., 1993,
1997; Pollock and Rane, 1996).
In this report, we use this system to show that growth factors
can acutely inhibit voltage-gated Na+ currents in
undifferentiated and differentiated PC12 cells and that this inhibition
is dependent on RTK coupling to Src and Ras. This inhibition does not
share the mechanistic properties of Na+ current
inhibition induced by signaling molecules such as the cAMP-dependent
protein kinase (PKA) or protein kinase C (PKC), further suggesting that
this modulation relies on intracellular mechanisms distinguishable from
pathways such as those driven by receptors of the seven transmembrane
spanning region superfamily. Thus we show that signals mediated by
growth factors and their RTKs are capable of regulating an ion channel
fundamental to neuronal excitation and that this regulation occurs
through Src and Ras. Although Src is extensively expressed in the
mature PNS and CNS and contributes to long-term growth factor effects,
its physiological function has remained elusive. Our results suggest
that acute regulation of neuronal Na+ channels may
be one such function.
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MATERIALS AND METHODS |
Tissue culture. Stock PC12 cell cultures were grown
on rat tail collagen-coated Petri dishes and maintained in DMEM. For
cells ectopically expressing N17 Ras (for details of cell line
generation, see Szeberényi et al., 1990), the media were
supplemented with 5% fetal calf serum and 10% horse serum. For PC12
cells expressing either the human form of the  PDGF [wild-type PDGF
(wtPDGF)] receptor or mutant PDGF receptor (for details of cell line
generation, see Vaillancourt et al., 1995), the media were supplemented
with 2.5% fetal calf serum (Sigma, St. Louis, MO) and PDGF-deficient 12.5% plasma-derived horse serum (Sigma) to obviate differentiation. All cell lines were kept under G418 selection and maintained in 25 U/ml
penicillin and 25 µg/ml streptomycin. In preparation for electrophysiology, cells were seeded onto 35 mm collagen-coated dishes
and allowed to grow for 1 d in standard culture medium. Then,
fresh medium with either NGF (100 ng/ml), PDGF (20 ng/ml), or basic FGF
(bFGF) (50 ng/ml) was applied. Medium and growth factor were replaced
every other day.
Electrophysiology. Conventional patch-clamp techniques and
computer-assisted data acquisition and analysis (Pulse and PulseFit software; Instrutech Corporation, Great Neck, NY) (Pollock and Rane,
1996) were used to study whole-cell Na+ and
Ca2+ channel currents. All current records were leak
subtracted with a standard P/N procedure and filtered at 5 kHz before
storage on disk for off-line analysis. For recording
Na+ currents, the bath solution was 138 mM NaCl, 9 mM KCl, 1 mM
CaCl2, 1 mM MgCl2, 10 mM TEA-Cl, 200 µM CdCl2,
and 10 mM HEPES, pH 7.3. For recording voltage-gated
Ca2+ channel currents, the bath solution consisted
of 135 mM TEA-Cl, 4 mM KCl, 10 mM
BaCl2, 1 mM MgCl2, 5 mM glucose, 10 mM HEPES, and 1 µM
tetrodotoxin, pH 7.3. In all cases, the patch pipette solution was 150 mM CsCl, 2 mM MgATP, 0.5 mM GTP, 2 mM BAPTA, and 10 mM HEPES, pH 7.3. Whole-cell
capacitive transients, elicited by 20 mV depolarizing steps, were
compensated with the analog compensation circuitry of the patch-clamp
amplifier. Whole-cell capacitance, a measure of membrane area, was read
directly from the compensation control dial of the amplifier.
We waited from 2 to 5 min after establishing whole-cell patch-clamp
access before beginning experimental data collection. During this time,
the Na+ I-V relationship was assessed by
holding the cell at  90 mV and by evoking command steps from 60 to
60 mV in 10 mV increments at 1.5-3 sec intervals. Two changes were
observed when this protocol was repetitively administered. First, as
has been noted in a number of studies on voltage-gated currents, the
Na+ I-V relationship shifted to the left
by 5-10 mV during the first 30-90 sec of recording. We also observed
that in addition to this shift, current amplitudes increased at any
given voltage during the first 1-3 min of recording, and then they
stabilized. Growth factor inhibition of Na+ current
was assessed at the command voltage giving maximal current (as shown by
the I-V protocol) only after these spontaneous changes in
Na+ current were complete. Any cell that showed
continuous variations in current of >5% at this voltage was rejected.
To test for significant differences in growth factor inhibition of
Na+ current between experimental groups, we used a
two-tailed, nonpaired, t test (at p < 0.05). All experiments were performed at 22-25°C.
Growth factor and drug application. Growth factors dissolved
in the bath solution were acutely applied to cells via pressure ejection from blunt-tipped, fire-polished micropipettes positioned ~5-10 µm from the cell. For RTK and Src inhibitor studies,
tyrphostin AG9, tyrphostin AG879, and PP1 were dissolved in 70%
ethanol, 70% methanol, and DMSO, respectively, before dilution to
their appropriate concentrations in intracellular solution (for details of inhibitor specificity, see Bilder et al., 1991; Levitzki and Gilon,
1991; Ohmichi et al., 1993; Levitzki and Gazit, 1995; Hanke et al.,
1996). After whole-cell access, the intracellular solution containing
the inhibitor was allowed to diffuse into the cell for ~3-5 min
before recording. For all experiments, inclusion of inhibitors did not
affect basal Na+ current densities. Furthermore,
recordings with intracellular solutions containing only ethanol,
methanol, or DMSO did not alter basal Na+ channel
current densities or acute responses to growth factors.
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RESULTS |
Initial characterization of growth factor-induced
Na+ channel current inhibition in PC12 cells
expressing wild-type PDGF receptors
In PC12 cells, cellular differentiation is mediated by NGF binding
to its cognate RTK. The wtPDGF receptor, when expressed in PC12 cells,
mediates neuronal differentiation in a manner characteristic of NGF;
both growth factors induce the persistent activation of the Ras and
MAPK pathway and of PLC, induce the expression of the early gene
c-fos, and upregulate Na+ channels and
other neuronal-specific mRNAs (Heasley and Johnson, 1992; Fanger et
al., 1993, 1997). Furthermore, observations with mutant PDGF receptors
demonstrate that both Src and PLC are important in regulating
morphological differentiation (Vaillancourt et al., 1995). Thus, wtPDGF
and mutant PDGF receptors serve as reasonable models for neurotrophin
receptors and the signaling pathways underlying their actions.
We first confirmed the robustness of signaling in PC12 cells
ectopically expressing the wtPDGF receptor by showing that chronic application of PDGF (20 ng/ml) could induce both morphological and
physiological differentiation. In agreement with previous observations
(Heasley and Johnson, 1992; Vaillancourt et al., 1995), the
morphological differentiation elicited by chronic application of PDGF
for a week, specifically neurite extension, was comparable with that in
cells treated with NGF (100 ng/ml) for the same period of time (data
not show). To determine whether morphological differentiation was
accompanied by ion channel upregulation, we used whole-cell patch-clamp
electrophysiology to examine whether chronic application of PDGF to
PC12 cells expressing wtPDGF receptors could increase functional
Na+ channel expression. Peak Na+
currents of undifferentiated and differentiated PC12 cells were normalized to whole-cell capacitance (as an indirect measure of cell
size) and used as an estimation of the Na+ channel
current density in individual cells. In accordance with previous
observations (Fanger et al., 1995, 1997), PDGF elicited an
approximately threefold increase in the functional expression of
Na+ channels, elevating Na+
current densities from 32.7 ± 5.9 pA/pF (n = 14)
in undifferentiated cells to 90.3 ± 8.4 pA/pF (n = 17) in differentiated cells, which paralleled an increase in
Na+ current densities observed in cells that had
been differentiated with NGF (85.9 ± 12.5 pA/pF;
n = 22). As an additional control, we compared
Ca2+ current densities in both undifferentiated
cells and cells differentiated with PDGF and found that PDGF elicited
an increase in Ca2+ current densities comparable
with increases seen in positive controls treated with NGF (data not
shown). These results, combined with previous observations from other
laboratories (Heasley and Johnson, 1992; Fanger et al., 1995, 1997;
Vaillancourt et al., 1995), demonstrated that PC12 cells differentiated
with PDGF are both morphologically and physiologically comparable with
PC12 cells differentiated with NGF and thus serve as an excellent model for examining the signaling mechanisms underlying the physiology of
fully differentiated neurons. Furthermore, the similarities in chronic
effects of wtPDGF and NGF receptor activation suggest similarities in
their signaling mechanisms, making the wtPDGF receptor a valuable
surrogate for analyzing neurotrophin receptor signaling.
To analyze the possibility that NGF could acutely regulate
Na+ channels, we differentiated PC12 cells with PDGF
(20 ng/ml) over a period of 4-6 d during which Na+
current densities are upregulated. Cells differentiated with PDGF were
stepped to voltages that induced peak Na+ current
amplitudes (typically between 10 and 0 mV) and then were subjected to
acute application of NGF (100 ng/ml). Figure 1, A and C, shows
that NGF caused a rapid decrease in Na+ current
amplitude (36.5 ± 3.0%; n = 13) that was
partially recoverable to 80.0 ± 4.0% (n = 6) of
the total current observed before NGF application. NGF-induced
inhibition was not associated with any change in the voltage dependence
or time course of the currents. Because future experiments would entail
analyzing Na+ channel currents in PC12 cells
expressing mutant receptors, it was essential to determine whether PDGF
could acutely modulate Na+ currents in a manner
similar to NGF. Figure 1, B and C, shows that
application of PDGF (20 ng/ml) to cells differentiated with NGF (100 ng/ml) also caused an acute decrease in Na+ current
amplitudes (54.0 ± 3.8%; n = 21) that was
partially reversible to 71.5 ± 7.3% (n = 12) of
the total current observed before PDGF application. Again, this was not
the result of a shift in the voltage dependence of activation or
current kinetics. A comparison of cells acutely treated with NGF and
PDGF showed that, in general, the time to maximal PDGF-induced
Na+ current inhibition (160 ± 15 sec;
n = 21) was slow relative to the NGF time course
(82 ± 11 sec; n = 12). Furthermore, the magnitude of inhibition observed in cells acutely treated with PDGF was generally
greater than was the inhibition caused by NGF.
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Figure 1.
Growth factors inhibit Na+
currents. A, Representative time course of NGF-induced
inhibition of whole-cell Na+ currents in PC12 cells
expressing wtPDGF receptors. PC12 cells were differentiated with 20 ng/ml PDGF for a period of 4-6 d. Differentiated cells were then held
at 90 mV and given sequential 10 mV steps from 60 to 60 mV in 1.5 sec intervals to determine the voltage of peak current amplitude.
Command steps to induce peak current amplitudes (open
diamonds) were then given every 5 sec before, during, and after
acute application of 100 ng/ml NGF (horizontal bar);
*selected current traces shown in the
inset. B, Representative time course of
20 ng/ml PDGF-induced inhibition of whole-cell Na+
currents in PC12 cells differentiated by chronic treatment with 100 ng/ml NGF. Electrophysiological protocols are identical to those
described in A; * indicates selected current
traces that are shown in the inset.
C, Cumulative data for the inhibition and recovery of
Na+ currents in response to acute application of
either 100 ng/ml NGF or 20 ng/ml PDGF. Whole-cell
Na+ currents recorded during or after growth factor
treatment were normalized to whole-cell currents recorded before growth
factor applications. Error bars represent the mean ± SEM of
normalized Na+ currents for the indicated growth
factor;  The current after recovery from growth factor
inhibition is statistically significant from the fully inhibited
current. The values of n for experimental groups are,
from left to right, 13, 6, 21, and 12.
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We also examined whether the acute responses to NGF and PDGF were the
result of signaling mechanisms specific to the differentiated phenotype. Undifferentiated cells expressing wtPDGF receptors were
exposed to acute application of NGF (100 ng/ml) or PDGF (20 ng/ml). As
seen in differentiated cells, NGF elicited a decrease in
Na+ current levels (40.6 ± 4.3%;
n = 18) with an onset of 96 ± 13 sec
(n = 15) and a rapid partial recovery to 90.0 ± 4.8% (n = 7) of the total current observed before NGF
application. Likewise, PDGF induced a decrease in
Na+ current (42.4 ± 3.4%; n = 12) with an onset of 154 ± 17 sec (n = 12) which
was partially reversible to 80.4 ± 6.1% (n = 4)
of the total current observed before PDGF application. These results suggest that the signaling pathways required for growth factor-induced Na+ current inhibition were present in both
undifferentiated and differentiated cells expressing wtPDGF receptors
and thus are not dependent on physiological events necessary for
neuronal differentiation. In subsequent studies, however, we limited
our experiments to the acute regulation involved in differentiated PC12
cells because the presence of several markers specific for neuronal
differentiation was necessary to ensure that the effects of mutant PDGF
receptors were specific to the inhibitory response (see below).
To test whether the acute effects of growth factors were dependent on
the activation of their respective RTKs, we took advantage of a family
of protein tyrosine kinase inhibitors, the tyrphostins (for review, see
Levitzki and Gilon, 1991; Levitzki and Gazit, 1995), specifically
tyrphostin AG9, which inhibits PDGF receptor autophosphorylation and
the ability of the receptor to phosphorylate intracellular signaling
molecules (Bilder et al., 1991), and AG879, which prevents the
activation of the NGF receptor and neurite extension in PC12 cells
(Ohmichi et al., 1993). For our experiments, individual cells were
loaded with the appropriate inhibitor by including either AG9 or AG879
in the intracellular recording solution and by allowing the solution to
diffuse into the cell for 3-5 min before recording
Na+ current responses to growth factor application
(Fig. 2). We found that inclusion of AG9
(10 µM) in the intracellular solution dramatically reduced PDGF inhibition of Na+ currents (10.4 ± 4.8%; n = 13), whereas the acute effects of NGF
remained unaffected (38.9 ± 5.9%; n = 9). The
converse was true in differentiated cells loaded with AG897 (25 µM). The inhibition of Na+ current
caused by NGF (13.6 ± 4.6%; n = 11) was
significantly reduced, whereas the inhibition caused by PDGF (29.2 ± 2.7%; n = 11) was only slightly affected when
compared with the inhibition observed in control cells. These results
strongly suggest that growth factors inhibit Na+
channels via the activation of their cognate RTKs.
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Figure 2.
Inhibition of Na+
currents by NGF (100 ng/ml) or PDGF (20 ng/ml) is reduced by inhibitors
specific for the wtPDGF and trkA receptors. A,
Representative time courses of NGF- and PDGF-induced inhibition of
whole-cell Na+ currents in differentiated cells
loaded with either 25 µM AG879 (open
diamonds) or 10 µM AG9 (closed
diamonds). Differentiation protocols and electrophysiological
protocols for determining voltages of peak current amplitudes are
identical to those described in Figure 1. After achieving whole-cell
access, the intracellular solution containing the indicated inhibitor
was allowed to diffuse into the cell for a period of 3-5 min. Peak
Na+ current amplitudes were subsequently recorded
before and during acute application of the indicated growth factor
(horizontal bar). For comparison, currents were
normalized to the total whole-cell current recorded before growth
factor application. B, Representative current
traces selected from A.
Traces depict total whole-cell current and the total
current remaining after the indicated growth factor in the presence of
the indicated inhibitor reached its maximum effect. C,
Cumulative data from A. Error bars represent mean ± SEM of peak Na+ currents normalized to the total
current recorded before indicated growth factor application;  indicates a statistically significant difference from cells that were
not subjected to RTK inhibitors. The values of n for
experimental groups are, from left to
right, 13, 11, 9, 10, 11, and 13.
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Finally, because there is significant conservation of signaling
mechanisms among the growth factor RTKs, especially in early events
(Chao, 1992; Marshall, 1995), we asked whether other growth factors
were capable of acutely modulating Na+ channels
(Fig. 3). In addition to the NGF RTK
trkA, PC12 cells express RTKs for epidermal growth factor (EGF) and
bFGF. Therefore, either EGF (100 ng/ml) or bFGF (50 ng/ml) was acutely
applied to cells that had been differentiated with NGF. Like PDGF and NGF, acute application of EGF inhibited Na+ currents
by 44.4 ± 3.6% (n = 7) with a time to maximum
inhibition of ~50-75 sec and a recovery to 80.2 ± 6.5%
(n = 6) of the total current observed before growth
factor application. Likewise, bFGF initiated a 38.7 ± 3.1%
(n = 8) decrease in Na+ current with
a time to maximum inhibition of ~15-30 sec and a recovery to
86.5 ± 3.9% of the total current observed before growth factor
application. Combined, these results demonstrate that the acute effects
of NGF and PDGF on Na+ channels are shared by other
growth factors and that the magnitude of current inhibition and
recovery is remarkably preserved throughout the growth factor receptor
family, although the time to reach maximum inhibition was dependent on
the individual growth factor. The results again suggest that
Na+ current inhibition is most likely mediated via a
signaling pathway that is conserved among growth factor RTKs.
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Figure 3.
Activation of either EGF or bFGF receptors
inhibits Na+ current. A,
B, Results are shown from two PDGF receptor-expressing PC12 cells that had been differentiated by chronic NGF treatment. Peak
Na+ current amplitudes (open
diamonds) are plotted as a function of time, showing inhibition
in response to EGF (A) or bFGF
(B) application (horizontal bars).
Currents were evoked every 5 sec; *Selection of raw data
traces shown in the insets.
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Growth factors affect steady-state inactivation but not
steady-state activation of Na+ channels
Similar to the acute effects observed with NGF and PDGF on PC12
Na+ current, phosphorylation of rat brain
Na+ channels by either PKA or PKC results in a
reduction of Na+ current amplitude; however, changes
in kinetic behavior differ among individual inhibitory agents,
suggesting different mechanisms of action. For example, application of
purified PKA to excised membrane patches reduces peak
Na+ current amplitudes without any effect on time
course or the voltage dependence of activation or inactivation (Li et
al., 1992), whereas phosphorylation of Na+ channels
by PKC slows inactivation in addition to reducing peak current
amplitude (Numann et al., 1994).
Current-voltage relationships for morphologically differentiated PC12
cells acutely treated with either NGF or PDGF indicated that the growth
factor-induced reduction in current amplitude was not the consequence
of a shift in the voltage dependence of channel activation. For
differentiated PC12 cells held at 90 mV, the voltage threshold for
activation of both control and growth factor-inhibited whole-cell
Na+ currents is approximately 50 mV, and the
currents reach a maximum amplitude between 10 and 0 mV (Fig.
4A). Analysis of the
steady-state inactivation of control cells and cells acutely treated
with growth factors, however, demonstrated that acute application of
NGF and PDGF shifted the voltage dependence of inactivation by
10.0 ± 1.3 mV (n = 10) and 8.5 ± 0.8 mV
(n = 6), respectively (Fig. 4B). This
suggests that the acute inhibition caused by NGF and PDGF is a direct
result of a negative shift in the voltage dependence of
Na+ channel inactivation. The similarity in NGF and
PDGF effects on the Na+ current steady-state
inactivation relationship also suggests that both receptors share a
common mode of signaling in modulating Na+
current.
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Figure 4.
Current-voltage and steady-state inactivation
plots for Na+ currents inhibited by growth factor
receptor activation. A, Results are shown from two
wtPDGF receptor-expressing cells that had been differentiated by
chronic application of 20 ng/ml PDGF (left) or 100 ng/ml
NGF (right). Cells were held at 90 mV, and command steps from 60 to 60 mV in 10 mV intervals were given every 5 sec
before growth factor application (closed diamonds) and
after the acute application of the indicated growth factor had reached its maximum effect (open diamonds). B,
Results are shown from two wtPDGF receptor-expressing cells that had
been differentiated by chronic PDGF (left) or NGF
(right) treatment. Cells were sequentially held at each
of the indicated potentials for 3 sec before a command step to 10 mV
to evoke Na+ current. The protocol was then repeated
in the presence of acutely applied NGF (100 ng/ml) or PDGF (20 ng/ml).
Peak current amplitudes were normalized to the current obtained from
the 110 mV hold. Fitted curves are of the form:
I/Imax = 1/1 + exp(Vhold V1/2/k), where
Vhold is the holding voltage from which the
command step was evoked, V1/2 is the voltage
corresponding to half-inactivation of the current, and k
is the slope constant. The mean ± SEM shift in
V1/2 in response to NGF was 10.0 ± 1.3 mV (n = 10 cells). The mean ± SEM shift in
V1/2 in response to PDGF was 8.5 ± 0.8 mV (n = 6 cells).
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Analysis of acute effects of growth factors on PC12 cells
expressing mutant PDGF receptors
The use of exogenously expressed PDGF receptors in PC12 cells
assumes that the physiological responses induced by these recep- tors
are mediated by signaling cascades shared by endogenous RTKs that
mediate similar, physiological events. One method of testing this
possibility is to determine whether the application of one growth
factor can occlude, or "mask," the response of the second growth
factor. We used this approach to determine whether NGF and PDGF
modulate Na+ channel currents via similar, if not
identical, signaling pathways. NGF was acutely applied to cells (Fig.
5A). As expected, NGF induced an inhibition of Na+ current (29.2 ± 2.4%;
n = 13), but subsequent application of PDGF after NGF
reached its maximum effect caused only minor inhibition of
Na+ current (10.5 ± 3.0%; n = 13). Similarly, acute application of PDGF to differentiated cells (Fig.
5B) caused an inhibition of Na+ current
(30.4 ± 3.5%; n = 10), whereas the inhibition of
Na+ current caused by subsequent NGF treatment
(7.7 ± 1.6%; n = 10) was dramatically reduced
relative to inhibition in response to NGF alone. In conjunction with
previous observations that signals from PDGF receptors serve as models
for NGF-induced signaling in wild-type PC12 cells, our results strongly
favor a common signaling pathway for growth factor-mediated
Na+ channel modulation.
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Figure 5.
NGF- and PDGF-induced
Na+ current inhibition are both mutually occlusive,
suggesting a common signaling pathway. A,
Na+ currents (open diamonds) were
recorded from differentiated PC12 cells expressing the wtPDGF receptor.
During whole-cell recording sessions, NGF (100 ng/ml) was applied
(upper bar). When the NGF response reached a maximum,
PDGF (20 ng/ml) was then applied (lower bar).
Inset, Representative Na+ current
traces depicting total current, the current remaining after subsequent application of NGF, and the current remaining after
application of PDGF. B, Na+ currents
were recorded from differentiated PC12 cells expressing the wtPDGF
receptor. During whole-cell recording sessions, PDGF (20 ng/ml) was
applied (upper bar). When the PDGF response
reached a maximum, NGF (100 ng/ml) was then applied (lower
bar). Inset, Representative
Na+ current traces depicting total
current, the current remaining after subsequent application of PDGF,
and the current remaining after the application of NGF.
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Use of PC12 cells expressing mutant PDGF receptors proved advantageous
in identifying the signaling molecules necessary for neurite extension
and for the chronic upregulation of Na+ channels
during PC12 cell neuronal differentiation (Vaillancourt et al., 1995;
Fanger et al., 1997). The tyrosine phosphorylation sites of the
receptor are well characterized, and point mutations of these residues
result in the inability of the receptor to associate with and activate
specific signaling molecules. PLC associates with residues 1009 and
1021, PI3-K associates with residues 740 and 751, the nonreceptor
tyrosine phosphatase Syp associates with tyrosine 1009, and the
GTPase-activating protein (GAP) associates with the tyrosine at
position 771. The tyrosine at position 716 enhances binding with Grb2
and is thought to be involved in Ras activation, although phenylalanine
substitutions of this particular tyrosine have been unable to inhibit
Ras activation to any great extent (for review, see Claesson-Welsh,
1994; van der Geer et al., 1994). Therefore, to elucidate the signaling
pathways underlying the PDGF-induced acute Na+
current inhibition that we observed, we took advantage of the following
paradigm: cells expressing exogenous mutant PDGF receptors were
morphologically differentiated with NGF; then, during recording sessions, the ability of PDGF to acutely inhibit Na+
currents was analyzed (Fig.
6A,B).
View larger version (35K):
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Figure 6.
Analysis of growth factor-induced inhibition of
Na+ current in PC12 cells expressing mutant PDGF
receptors or a dominant-negative Ras mutant. A, PC12
cells expressing either F5, F579/581, F5/579, or F5/581 mutant PDGF
receptors were differentiated by chronic treatment with 100 ng/ml NGF.
Peak Na+ current amplitudes (open
diamonds) are plotted as a function of time, showing inhibition
in response to 20 ng/ml PDGF (horizontal bars).
Recording protocols are described in Figure 1; *Raw data traces selected for insets.
B, Cumulative data for experiments described in
A are shown. Whole-cell currents recorded during growth
factor application were normalized to whole-cell currents recorded
before growth factor application. Error bars represent the mean ± SEM of normalized Na+ current amplitudes;
Statistically significant difference from PC12 cells
expressing the wtPDGF receptor. The values of n for each
experimental group are, from left to right, 10, 20, 20, 15, and 14. C, Cumulative data for experiments with 17-2 PC12 cells,
which express the dominant-negative mutant N17 Ras, are shown. Error
bars represent the mean ± SEM of normalized whole-cell
Na+ currents after acute application of 100 ng/ml
NGF (solid columns) or 50 ng/ml bFGF (shaded
columns) reached its maximum effect in either 17-2 cells or
PC12 cells expressing the wtPDGF receptor; Statistically
significant difference from PC12 cells expressing the wtPDGF receptor.
The values of n for each experimental group are, from
left to right, 10, 8, 10, and 10.
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The F5 mutant PDGF receptor is characterized by five
tyrosine-to-phenylalanine substitutions at residues 740, 751, 771, 1009, and 1021. Biochemical analyses of this receptor in PC12 cells and
other cell lines suggest that it is unable to associate with or
activate PLC, Syp, PI3-K, or GAP (Valius and Kazlauskas et al.,
1993; Vaillancourt et al., 1995). Despite the inability of this
receptor to activate these signaling pathways, PC12 cells expressing
the F5 receptor respond to PDGF with the extension of neurites and with
the induction of mRNA for c-fos, Na+
channels, and the neural-specific metalloprotease transin (Vaillancourt et al., 1995; Fanger et al., 1997). As expected, our cell lines, when
chronically treated with NGF, upregulated the functional expression of
Na+ channels, elevating current densities to
92.6 ± 8.8 pA/pF (n = 22). Furthermore, acute
application of PDGF elicited a 39.8 ± 3.1% (n = 20) decrease in Na+ channel currents, suggesting
that PLC, Syp, PI3-K, and GAP have little effect on growth
factor-mediated Na+ current inhibition.
Because of the presence of tyrosine residues 579 and 581 located at the
juxtamembrane region, the F5 PDGF receptor still retains its ability to
activate members of the Src family nonreceptor tyrosine kinases. We
next analyzed two PDGF mutants containing the same five-point
substitution motif characteristic of the F5 receptor but possessing
additional tyrosine-to-phenylalanine substitutions at either residue
579 (F5/579 receptor) or 581 (F5/581 receptor) and a third receptor
with substitutions at residues 579 and 581 (F579/581 receptor) with the
remainder of the intracellular region intact. Despite similarities in
substitution motifs, the ability of each receptor to associate with Src
and to induce Src phosphorylation differ, with PC12 cells expressing
the F579/581 or F5/579 receptor showing no Src association or
phosphorylation, whereas the F5/581 receptor shows modest Src
association and phosphorylation (Vaillancourt et al., 1995). To test
the ability of these mutant receptors to mediate PDGF-induced
Na+ current inhibition, we differentiated cells
expressing these receptors via chronic treatment with NGF. In agreement
with previous observations (Fanger et al., 1997), NGF induced
morphological differentiation and upregulated Na+
channel currents, increasing current densities to 46.6 ± 5.7 pA/pF (n = 19), 78.3 ± 12.1 pA/pF
(n = 14), and 44.6 ± 7.4 pA/pF (n = 13) in morphologically differentiated cells expressing, respectively, the F579/581, F5/579, and F5/581 mutant receptors. However, we found
that the ability of PDGF to inhibit Na+ current was
reduced in cells expressing the F579/581, F5/579, or F5/581 receptors.
In these cells PDGF inhibited Na+ currents by only
20.2 ± 3.6% (n = 20), 17.0 ± 3.0%
(n = 14), or 6.7 ± 3.0% (n = 15), respectively. This suggested that PDGF receptors with mutations in
their Src binding domains were unable to mediate Na+
inhibition in comparison with their wild-type counterparts, despite their ability to initiate morphological differentiation (with the
exception of the F5/579 receptor), activate the Ras and MAPK pathway,
and induce both c-fos and transin mRNA in a PDGF-dependent manner (Vaillancourt et al., 1995; Fanger et al., 1997). To confirm further that the decrease in PDGF-induced inhibition was the result of
loss of Src activation, we loaded cells expressing the wtPDGF receptor
with the Src kinase inhibitor PP1 (Hanke et al., 1996) by including the
inhibitor in the intracellular recording solution and allowing the
solution to diffuse into the cells for 3-5 min after establishment of
whole-cell access and before PDGF application. Addition of PP1 (1 µM), which inhibits Src and other members of the Src
family of kinases, including Fyn and Lyk, had little to no effect on
Na+ current densities in cells that had been
differentiated with either NGF [139.1 ± 13.1 pA/pF
(n = 18) compared with 115.6 ± 11.4 pA/pF
(n = 18) in cells without PP1] or PDGF [103.2 ± 17.5 pA/pF (n = 14) compared with 107.8 ± 14.7 pA/pF (n = 14) in cells without PP1]. However, PP1
effectively reduced Na+ current inhibition by both
NGF (15.1 ± 3.4%; n = 14) and PDGF (17.2 ± 3.0%; n = 21), arguing further that the Src family of nonreceptor tyrosine kinases plays a role in growth factor-induced Na+ current inhibition.
Analysis of acute effects of growth factors in PC12 cells
expressing a dominant-negative mutant form of Ras
In PC12 cells, activation of the Ras and MAPK pathway is essential
for a variety of morphological and physiological events, including
neurite extension (Szeberényi et al., 1990; Traverse et al.,
1992; Cowley et al., 1994; Loeb et al., 1994; Stephens et al., 1994)
and the upregulation of Ca2+ channels (Pollock and
Rane, 1996). Furthermore, there is evidence that signals mediated by
Src are required for the activation of Ras, suggesting that Ras might
lie downstream of Src in certain RTK signaling cascades (Kremer et al.,
1991; Rusanescu et al., 1995). The long-term upregulation of
Na+ channels during PC12 cell differentiation,
however, is completely independent of Ras (Fanger et al., 1993),
although activation of Src seems to be important for establishing fully
functional Na+ channel expression (Fanger et al.,
1997).
To determine whether the signaling mechanisms underlying acute
regulation paralleled those responsible for long-term
Na+ expression, we examined the ability of NGF to
acutely regulate Na+ channels in 17-2 cells, a PC12
cell line that overexpresses the N17 Ras dominant-negative mutant (Fig.
6C). In these cells, NGF and bFGF fail to induce
morphological differentiation and the early-response genes
c-fos, c-jun, and zif268 (Szeberényi et al., 1990), and are incapable of upregulating Ca2+
channels (Pollock and Rane, 1996). However, the upregulation of type
II/IIA Na+ channel mRNA and functional
Na+ channels is unaffected (Fanger et al.,
1997).
We chronically treated 17-2 cells with either NGF or bFGF (50 ng/ml)
for a period of 5-7 d. As expected, the cells failed to extend
neurites but expressed elevated levels of Na+
channels (data not shown). In cells that had been chronically treated
with bFGF, acute NGF application reduced Na+ current
by only 13.8 ± 1.0% (n = 10). Likewise, the
ability of bFGF to inhibit Na+ currents in cells
chronically treated with NGF was also impaired (15.9 ± 1.0%;
n = 10) relative to our previous observations. Because we showed previously that growth factor-induced inhibition of Na+ currents does not depend on differentiation, it
is unlikely that the decrease in inhibition is the result of the
inability of Ras to induce differentiation. Therefore, these results
indicate a role for Ras in the acute effects of growth factors on
Na+ currents.
| |
DISCUSSION |
Our results are the first to ascertain that growth factors can
acutely inhibit mammalian Na+ channels, which are
fundamental for the regulation of electrical excitability in neuronal
cells. Application of growth factors to differentiated PC12 cells,
which express the PN-1 and brain type II/IIa Na+
channels (Mandel et al., 1988; D'Arcangelo et al., 1993), resulted in
a rapid, partially reversible inhibition of whole-cell
Na+ current. The inhibition was dependent on the
tyrosine kinase activity of the associated growth factor receptors,
because RTK inhibitors reduced inhibition by at least two-thirds. These
observations are consistent with an increasing amount of evidence that
in addition to their ability to upregulate ion channel expression
during neuronal development, growth factors and their signaling
pathways may play another, fundamental role as acute regulators of ion
channel activity in both developing and mature nervous systems. Indeed,
in rat brain neurons, both neurotrophin-3 (NT-3) and NGF are capable of
activating Ca2+-activated K+
channels (Holm et al., 1997), which contribute to action potential repolarization and often underlie the modulation of action potential frequency. Additionally, both NMDA receptors and the human Kv1.5 K+ channel possess Src-specific SH3 binding domains,
associate with Src, and are modulated by this association (Holmes et
al., 1996; Yu et al., 1997), further arguing that signals activated by
RTKs, particularly Src, are intimately involved with ion channel
regulation. In agreement with this, our own observations with PDGF
receptors deficient in activating the Src family of kinases demonstrate that Src is essential for growth factor-induced Na+
channel inhibition. It should be noted, however, that neither the  subunits of the PN-1 and type II/IIa Na+ channels
nor the subunits possess the RPLPXXP SH3-binding domain motif
indicative of direct Src association, suggesting that the influence of
Src on Na+ channels is not direct and occurs via
downstream effectors.
It is interesting to note, then, that studies indicate that Src, Ras,
and MAP kinases act in sequence to initiate the induction of early
genes and morphological differentiation in PC12 cells (Kremer et al.,
1991; D'Arcangelo and Halegoua, 1993; Rusanescu et al., 1995). Because
PDGF receptors deficient in activating the Ras and MAPK pathway have
yet to be successfully expressed, we turned to the 17-2 PC12 cell line,
which overexpresses the dominant-negative mutant N17 Ras, to analyze
the role of Ras in Na+ current inhibition. Although
we could not definitively conclude that Src lies upstream of Ras, it is
intriguing to note that the block of growth factor-induced inhibition
was comparable between cells loaded with RTK inhibitors and cell lines
deficient for either Src or Ras signaling, which would be expected if
these molecules are activated in series. Still, it is possible that Ras
and Src inhibit Na+ channels via parallel, redundant
pathways; thus we cannot eliminate the possibility that activation of
one signaling molecule can partially compensate for inactivity of the
other. Furthermore, Na+ channel inhibition is not
completely blocked in cell lines deficient in Src or Ras signaling,
which suggests that pathways independent of Ras and Src could also be
contributing to acute Na+ channel regulation.
However, the inability to completely block inhibition is probably the
result of a small amount of residual Src and Ras activity, because
growth factors applied to these cell lines are still capable of
inducing Src- and Ras-dependent responses to a minor degree
(Szeberényi et al., 1990; Kremer et al., 1991; D'Arcangelo and
Halegoua, 1993; Vaillancourt et al., 1995; Fanger et al., 1997).
Our results also support an increasing amount of evidence that
activation of Src and/or Ras through RTKs is a critical component of
ion channel regulation in both developing and mature nervous systems.
For example, chronic treatment of 17-2 PC12 cells with NGF or bFGF
fails to upregulate Ca2+ channels. Likewise, PC12
cells morphologically differentiated by oncogenic Ras fail to show an
increase in Ca2+ channel expression, suggesting that
Ras is necessary but not sufficient for this upregulation (Pollock and
Rane, 1996). PC12 cells induced to undergo morphological
differentiation by oncogenic Src, however, upregulate
Ca2+ channels in a manner comparable with wild-type
PC12 cells differentiated by NGF or bFGF (Rausch et al., 1990).
Furthermore, our own observations with PC12 cells expressing PDGF
receptors deficient in Src signaling suggest that Src may also be a
necessary component in this upregulation (M. D. Hilborn and S. G. Rane,
unpublished observations). Similar to the situation with
Ca2+ channels, the upregulation of
Na+ channel expression during growth factor-induced
PC12 cell differentiation seems to be partially dependent on the
activation of Src (Fanger et al., 1997). However, this upregulation is
independent of Ras activation (Fanger et al., 1993), an intriguing
difference from our own observations that Ras activation is necessary
for acute regulation. This difference in signaling, in conjunction with signals generated by sustained activation of RTKs, could account for
the ability of RTKs to regulate Na+ and other ion
channels both acutely and chronically. Further analysis of the role of
Src, Ras, and their downstream effectors in acute ion channel
regulation will perhaps resolve these issues.
Little is known about the receptor-mediated modulation of
Na+ channels. Activation of G-protein-coupled
pathways enhanced brain Na+ channel activity in
Chinese hamster ovary (CHO) cells (Ma et al., 1994), and inhibition of
cardiac Na+ channels by -adrenergic agonists can
also be mediated via G-proteins (Schubert et al., 1989). Stimulation of
2-adrenergic receptors expressed in Xenopus oocytes can
either enhance or attenuate Na+ currents, depending
on the levels of receptor expression (Smith and Goldin, 1992, 1996),
and both PKA and PKC have been shown to modulate Na+
channel currents by directly phosphorylating key residues on the
-subunit of rat brain channels (Rossie and Catterall, 1987, 1989;
Rossie et al., 1987; West et al., 1991; Murphy and Catterall, 1992; for
review, see Cukierman, 1996). Because NGF activates PLC and PKA
during differentiation and because activation of the PKA pathway has
been implicated in post-translational effects required for full,
functional Na+ channel expression during PC12 cell
differentiation (Kalman et al., 1990; Ginty et al., 1992; D'Arcangelo
et al., 1993), both PKA and PKC might be considered candidates for
mediating acute growth factor-induced Na+ channel
inhibition. However, attenuation of Na+ currents by
PKA phosphorylation occurs without a change in steady-state activation
or inactivation properties of the channel (Gershon et al., 1992; Li et
al., 1992, 1993; Smith and Goldin, 1996), an observation that differs
from our own observation that growth factor-induced
Na+ current inhibition is associated with a negative
shift in steady-state inactivation. Additionally, the F5 mutant PDGF
receptor, which is deficient in activating PLC, inhibited
Na+ current to a level comparable with that observed
with wild-type receptor, suggesting that downstream effectors of
PLC, including PKC, are not required for this response. Furthermore,
PKC inhibition of rat brain Na+ channels expressed
in CHO cells is accompanied by a slowing of inactivation (Numann et
al., 1994), and the attenuation of whole-cell Na+
currents is the consequence of a depolarizing shift in the voltage dependence of channel activation (Dascal and Lotan, 1991; Schreibmayer et al., 1991), both of which differ from the shift in steady-state inactivation that we observed. And although a negative shift in the
inactivation curve of Na+ channels in a mouse
neuroblastoma cell line was observed in response to some PKC activators
(Godoy and Cukierman, 1994a,b), a follow-up study demonstrated that the
channel attenuation was a direct effect of the PKC activators
(Renganathan et al., 1995).
Overall, our studies complement an increasing amount of evidence
that growth factors, particularly neurotrophins, are involved in acute
neuromodulatory processes in addition to their traditional roles in
neuronal development (for review, see Thoenen, 1995). The ability of
growth factors to modulate channels fundamental for regulating
electrical excitability provides a mechanistic basis for the growth
factor-dependent neural plasticity that has been observed in the
mammalian visual cortex and hippocampus. Our results establish roles
for Ras and Src as mediators of growth factor receptor-activated acute
ion channel regulation, in addition to their recognized contribution to
the long-term developmental actions of the growth factor receptor
family.
| |
FOOTNOTES |
Received Aug. 28, 1997; revised Oct. 23, 1997; accepted Oct. 24, 1997.
This work was supported by a grant from the Whitehall Foundation
(S.G.R.), Grant DK 08897 (R.R.V.), and a Predoctoral Fellowship from
the American Heart Association, Indiana Affiliate (M.D.H.). We are
grateful to Dr. S. Rossie for critical review of this manuscript.
Correspondence should be addressed to Dr. Stanley G. Rane, Department
of Biological Sciences, Lilly Hall, West Lafayette, IN 47907.
| |
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Top
Abstract
Introduction
