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Volume 16, Number 15,
Issue of August 1, 1996
pp. 4596-4603
Copyright ©1996 Society for Neuroscience
Involvement of a Phorbol Ester-Insensitive Protein Kinase C in
the  2-Adrenergic Inhibition of Voltage-Gated Calcium
Current in Chick Sympathetic Neurons
Stefan Boehm1, 2,
Sigismund Huck1, and
Michael Freissmuth2
Departments of 1 Neuropharmacology and
2 Pharmacology, University of Vienna, A-1090 Vienna,
Austria
 ABSTRACT
- INTRODUCTION
- MATERIALS AND METHODS
- RESULTS
- DISCUSSION
- FOOTNOTES
- REFERENCES
ABSTRACT 
 2-Adrenoceptors regulate the
efficacy at the sympatho-effector junction by means of a feedback
inhibition of transmitter release. In chick sympathetic neurons, the
mechanism involves an inhibition of N-type calcium channels, and we now
present evidence that this effect involves an atypical, phorbol
ester-insensitive protein kinase C (PKC). The inhibition of
voltage-gated Ca2+ currents by the specific
2-adrenergic agonist UK 14,304 was
significantly attenuated when the PKC inhibitors PKCI(19-36),
staurosporine, or calphostin C were included in the internal solution
used to fill the patch pipettes, or if staurosporine or calphostin C
were applied extracellularly; however, phorbol esters as classical
activators of PKC or oleoylacetylglycerol did not mimic the effect of
UK 14,304, and chronic exposure to 4- -phorbol dibutyrate (PDBu) did
not attenuate it, even though PKC and - isozymes were
translocated to plasma membranes by PDBu. The atypical isozyme PKC
was translocated by 100 µM arachidonic acid
(AA), but not by PDBu; 100 µM AA and linoleic
acid inhibited voltage-activated Ca2+ currents,
and this effect was attenuated when PKCI(19-36) was added to the patch
pipette solution. Our observations indicate that classical, new, and
atypical PKC isozymes are present in chick sympathetic neurons and that
an atypical, phorbol ester-insensitive PKC is involved in the
inhibition of voltage-activated calcium currents by
2-adrenoceptor activation.
Key words:
2-adrenoceptor;
calcium current;
chick
sympathetic ganglion;
protein kinase C isozymes;
phorbol ester;
arachidonic acid
INTRODUCTION
Norepinephrine reversibly inhibits voltage-gated
calcium channel currents in sympathetic neurons (Horn and McAfee, 1980 ;
Galvan and Adams, 1982; Bley and Tsien, 1990; Plummer et al., 1991;
Elmslie at al., 1992) by an activation of
2-adrenoceptors (Schofield, 1990; Boehm and
Huck, 1991; Song et al., 1991). This phenomenon has attracted
considerable interest not only because it served as a paradigm for
second messenger-dependent signal transduction (Beech et al., 1992;
Mathie et al., 1992; Delcour and Tsien, 1993; Golard and Siegelbaum,
1993; Shapiro et al., 1994; Ehrlich and Elmslie, 1995; Ikeda, 1996),
but also because a modulation of transmembrane calcium influx
subsequently affects the concentration of free intracellular calcium,
which is crucial for various biological processes such as transmitter
release (Lipscombe et al., 1989; Miller, 1990).
Nevertheless, the signaling cascade that links
2-adrenoceptors and calcium channel inhibition
in chick sympathetic neurons has yet to be elucidated. The effects of
2-adrenoceptor activation on calcium currents
and on transmitter release are abolished by a pretreatment of cultures
for 24 hr with pertussis toxin (Boehm et al., 1992), indicating that
inhibitory Go/Gi G-proteins
are involved. We do not know, however, whether an
(2-adrenoceptor) activated G-protein
interacts directly with calcium channels (Hescheler and
Schultz, 1993) or whether second messengers are involved. In line with
experiments in rat sympathetic cells (Schwartz and Malik, 1993), we
have reported recently that cAMP modulates but does not mediate the
inhibition of calcium channels and transmitter release by
2-adrenoceptor activation in chick sympathetic
neurons (Boehm et al., 1994). Our experiments also indicate an
intricate interaction of Gs and the
2-adrenoceptor-mediated inhibition of
transmitter release, because downregulation of
Gs by cholera toxin caused sensitization of
2-adrenergic effects in chick
sympathetic neurons (Boehm et al., 1996).
Another obvious pathway that might convey the
2-adrenergic effect includes activation of
protein kinase C (PKC), possibly secondary to an
2-adrenoceptor-mediated regulation of
phospholipase C (PLC) or phospholipase A2
(PLA2). Numerous reports have implicated PKC in
neurotransmitter-induced modulation of Ca2+
channels, because both phorbol esters and diacylglycerol analogs
mimicked receptor-mediated effects, and PKC inhibitors or chronic
exposure to phorbol esters attenuated the action of neurotransmitters
(Rane and Dunlap, 1986; Werz and Macdonald, 1987; Ewald et al., 1988;
Marchetti and Brown, 1988; Mochida and Kobayashi, 1988; Rane et al.,
1989; Boland et al., 1991; Diverse-Pierluissi and Dunlap, 1993).
The present experiments were initiated to investigate further the
signaling cascade of the
2-adrenoceptor-mediated inhibition of
transmitter release in cultured chick sympathetic neurons. We focused
our attention on the effects of 2-adrenoceptor
agonists on voltage-gated calcium currents and on the modulation of
these effects by various substances known to activate or block the PKC
system, because our previous experiments indicated that the N-type
calcium channel represents the final effector of the
2-adrenoceptor-mediated autoinhibition of
transmitter release in these neurons (Boehm and Huck, in press).
MATERIALS AND METHODS
Cell cultures. The procedures for dissociation and
culture of chick sympathetic neurons have been described previously
(Boehm et al., 1991, 1994). Briefly, paravertebral sympathetic ganglia
were dissected from 12-d-old chick embryos, trypsinized (0.1% for 30 min at 36°C), triturated, resuspended in DMEM (Gibco 041-01885M; Life
Technologies, Gaithersburg, MD) containing 2.2 g/l glucose, 10 mg/l
insulin, 25,000 IU/l penicillin, and 25 mg/l streptomycin (Gibco
043-05140D), 10 µg/l nerve growth factor (Gibco 0436050), and 5%
fetal calf serum (Gibco 011-0620H), and plated on
poly-D-lysine-coated (Sigma 1149; Sigma, St.
Louis, MO) tissue culture dishes (Nunc 153066; Nunc, Naperville, IL)
(~5 × 105 neurons per dish). Non-neural
cells were reduced to <5% by differential plating, as described
elsewhere (Boehm et al., 1994), when the cellular distribution of PKC
isoforms was investigated.
Electrophysiology. Whole-cell Ca2+
currents were recorded at room temperature (20-24°C) from cell
bodies of sympathetic neurons after 24-48 hr in vitro, as
described elsewhere (Boehm and Huck, 1991). The internal (pipette)
solution contained (in mM): 115 N-methyl-D-glucamine, 20 tetraethylammonium chloride, 1.6 CaCl2, 2 Mg-ATP,
2 Li-GTP, 10 EGTA, 10 glucose, and 20 HEPES, adjusted to pH 7.3 with
HCl, which results in a nominal calcium concentration of 0.011 µM. For applications of arachidonic acid (AA)
or linoleic acid (LinA), cells were dialyzed with 200 U/ml superoxide
dismutase (SOD) via the recording pipette to prevent the formation of
free radicals (Chan et al., 1988; Keyser and Alger, 1990). The external
(bathing) solution consisted of (in mM): 120 choline chloride, 5 CaCl2, 20 glucose, and 10 HEPES, adjusted to pH 7.3 with KOH. Ca2+ currents
were elicited by depolarizations from a holding potential of  80 to 0 mV at a frequency of 2-4 min 1. To account for
the time-dependent rundown of Ca2+ currents (see
Fig. 3), drug effects were evaluated by measuring currents in the
presence of test drugs (B) and by comparing them with
control currents recorded before (A) and after (washout,
C) the application of the drugs (Boehm and Huck, 1991),
according to 200 × B/(A + C) = % of control current.
Fig. 3.
AA and LinA, but not phorbol esters or OAG,
inhibit Ca2+ currents. A, Time course
of peak current amplitudes (normalized to the first amplitude) and
effects of OAG, PDBu, and AA. These drugs were applied to cells
dialyzed for at least 10 min with standard pipette solution (open
circles), with 200 U/ml SOD (open squares), or with SOD
plus 10 µM of the peptide inhibitor
PKCI(19-36) (filled squares). n = 5-6.
B, Inhibition of Ca2+ currents by 30 µM OAG, 3 µM PDBu, 10 µM SC-10, 100 µM AA, or
100 µM LinA, calculated as % inhibition = 100 (200 b/a + c), where
a, b, and c are the current amplitudes
measured after 60, 120, and 180 sec, respectively, as indicated in
A. Neurons were dialyzed for at least 10 min with standard
pipette solution (open bars), with SOD (hatched
bars), or with SOD plus 10 µM of the
peptide inhibitor PKCI(19-36) (filled bars), which
significantly attenuates the effects of AA and LinA. Levels of
significance for the difference between corresponding bars are
indicated. n = 5-6.
[View Larger Version of this Image (33K GIF file)]
Determination of the cellular distribution of PKC isoforms.
Pure (>95%) neuronal cell cultures were subjected to long-term (24 hr) or short-term (10 min) treatment of a number of known PKC
activators, including 4--phorbol dibutyrate (PDBu),
oleoylacetylglycerol (OAG), AA, and LinA. As a control for
PKC-independent effects of phorbol esters, the inactive isomer
4--phorbol dibutyrate (PDBu) was used. Thereafter, cultures were
rinsed twice with the bathing solution described above, incubated with
50 mM -glycerophosphate, 6 mM EGTA, 5 µM leupeptin,
and 1 mM phenylmethylsulfonylfluoride in bathing
solution, and rapidly frozen by adding liquid nitrogen. After they were
thawed, cells were scraped off the dishes and subjected to a second
freeze-thaw cycle. Cytosolic and membrane fractions were separated by
centrifugation (50,000 × g for 30 min at 2°C).
Cytosolic proteins were precipitated with trichloroacetic acid (14%
final concentration) and subsequently dissolved in Laemmli sample
buffer supplemented with 2% SDS and 40 mM
dithiothreitol, whereas pellets were dissolved directly in supplemented
Laemmli sample buffer. Samples corresponding to 1-2.5 × 105 cells were applied to SDS-polyacrylamide gels
(running gel: 8% acrylamide, 0.21% N,N-methylene
bisacrylamide). Proteins were subsequently transferred to
nitrocellulose and stained with Ponceau S to verify that comparable
amounts had been loaded. The nitrocellulose blots were probed with
commercially available peptide antisera specific for PKC (Santa Cruz
Biotechnology, Tebu, France, 1:200 dilution), PKC (Santa Cruz, 1:200
dilution), PKC (Life Technologies, 1:500 dilution, or Santa Cruz,
1:200). Additional isoforms were probed with antisera specific for PKC
I/II,  ,  , and  (Santa Cruz, 1:200). The specificity of
antigen-antibody reactions was checked by probing nitrocellulose blots
with antibodies that had been preincubated with their corresponding
immunogenic peptides. Immunostaining was carried out with a second
antibody conjugated to horseradish-peroxidase using Amersham
ECL-reagents (Amersham, Madison, WI). The immunoreactive bands from
chick sympathetic cultures comigrated with immunoreactive bands
detected in rat cerebral cortical homogenates.
Statistics. Data are given as arithmetic mean ± SEM,
unless indicated otherwise; n = number of individual
cells in whole-cell recordings. Significance of differences between
single data points was evaluated by the unpaired Student's
t test, unless indicated otherwise.
Drugs and reagents. AA, LinA, OAG, and SOD were from Sigma
(Vienna, Austria);
N-(n-heptyl)-5-chloro-1-naphthalenesulfonamide (SC-10),
5-bromo-N-(4,5-dihydro-1-H-imidazol-2-yl)-6-quinoxalinamine
(UK 14,304), staurosporine, and calphostin C were from Research
Biochemicals (Natick, MA); PDBu and PDBu, the pseudosubstrate
peptide inhibitor of PKC [PKCI(19-36)], a noninhibitory analog
peptide [glu27-PKCI(19-36)], and a peptide
inhibitor of PKA [PKI(6-22)amide] were from Life Technologies.
SC-10 (10 mM), staurosporine (1 mM), calphostin C (1 mM),
and OAG (30 mM) were dissolved initially in
dimethyl sulfoxide (DMSO); AA (100 mM) and LinA
(100 mM) were dissolved in ethanol. Drugs were
then diluted to the final concentrations (1:1000) in buffer, and
appropriate controls verified that neither DMSO nor ethanol at 0.1%
affected the parameters tested.
RESULTS
Effects of protein kinase inhibitors on
the 2-adrenergic inhibition of Ca2+
currents
In line with our previous observations (Boehm and Huck, 1991), the
specific 2-adrenoceptor agonist UK 14,304 reversibly inhibited voltage-activated calcium currents (Figs.
1, 2). The effect of UK 14,304 was reduced progressively
within minutes when the PKC pseudosubstrate inhibitor PKCI(19-36) (10 µM) (House and Kemp, 1987) was included in the
pipette solution (Figs. 1A,B,
2B). Peak calcium current amplitudes
in the absence of UK 14,304 were not affected significantly by
PKCI(19-36) [control: 756 ± 90 pA, n = 18;
PKCI(19-36): 633 ± 69 pA, n = 17;
p > 0.25]. Likewise, the dialysis of neurons with
calphostin C and staurosporine (both at 1 µM)
for 10 min significantly diminished the
2-adrenergic inhibition (Fig.
2A,B). A noninhibitory analogous
peptide [glu27-PKCI(19-36)] and a selective
peptide inhibitor of PKA [PKAI(6-22)amide] (Glass et al., 1989) had
no effect on the UK 14,304-induced inhibition (Figs.
1A,B, 2B). Even under
conditions in which these substances effectively blocked the action of
UK 14,304, neither PKCI(19-36) nor calphostin C or staurosporine had
any noticeable effect on the somatostatin-induced inhibition of calcium
currents (Figs. 1, 2A). In chick sympathetic
neurons, staurosporine has been shown previously not to block the
calcium current inhibition by somatostatin, although activation of PKC
(by pretreatment with OAG or phorbol-12-myristate-13-acetate)
significantly reduced the effects of somatostatin (Golard et al.,
1993). Because both substances are membrane-permeable, we could apply
staurosporine and calphostin C extracellularly after the effects of UK
14,304 had initially been established. Hence, in neurons exposed to 1 µM staurosporine or calphostin C, the
subsequent inhibition by UK 14,304 in the continuing presence of either
PKC inhibitor was reduced significantly (inhibition before
staurosporine or calphostin C: 34.6 ± 2.2%, n = 8; after >3 min staurosporine: 11.6 ± 3.0%, n = 4; p < 0.001; after >3 min calphostin C: 18.8 ± 3.0%, n = 4; p < 0.01).
Fig. 1.
The PKC inhibitor PKCI(19-36) prevents the
2-adrenoceptor-mediated but not the
somatostatin-mediated inhibition of Ca2+
currents. A, Calcium currents were induced from a holding
potential of 80 mV by depolarizing pulses to 0 mV. UK (10 µM) or somatostatin (1 µM) were applied to the same cells 3, 7, and 12 min after establishing the whole-cell condition. The recording pipette
contained 10 µM peptide inhibitor against
protein kinase C [PKCI(19-36)] (left panel) or 10 µM peptide inhibitor against protein kinase A
[PKI(6-22)amide] (right panel). Traces show currents
before, during, and after application of agonists. Calibration: 0.5 nA,
30 msec. B, Time-plots of recordings from the cells shown
above in A. Filled symbols indicate test pulses
in the absence or presence of 10 µM UK 14,304 (U) or 1 µM somatostatin
(S).
[View Larger Version of this Image (31K GIF file)]
Fig. 2.
2-Adrenoceptor-mediated
inhibition of Ca2+ currents: summary of effects
of PKC inhibitors. A, Inhibition of
Ca2+ currents by 10 µM UK
14,304 (left) or 1 µM somatostatin
(right) in cells dialyzed for at least 10 min with 0.1%
DMSO, 1 µM calphostin C, or 1 µM staurosporine. Traces show
currents before, during, and after the application of agonists.
Calibration: 0.5 nA for DMSO, 0.25 nA for staurosporine, 0.1 nA for
calphostin C; 30 msec. B, Inhibition of peak
Ca2+ current amplitudes
(ICa) by 10 µM UK
14,304 under control conditions (ctl) or with 10 µM PKCI(19-36), a peptide inhibitor of protein
kinase C (PKCI); 10 µM
glu27-PKCI(19-36), a noninhibitory analog
peptide (PKCnI); 10 µM
PKAI(6-22)amide, a peptide inhibitor of PKA (PKAI);
0.1% DMSO (DMSO); 1 µM calphostin C
(calph); 1 µM staurosporine
(stau); or 1 µM PDBu added to the
pipette solution. Alternatively, cells pretreated for 24 hr with 10 µM -phorbol-12,13-dibutyrate (24 hr
PDBu) were tested with 10 µM UK 14,304 using regular pipette solution. Currents were recorded 10 min or later
after breaking the cell membrane. **, p < 0.01 vs
control; ##, p < 0.01 vs DMSO; n indicated
in the bars.
[View Larger Version of this Image (25K GIF file)]
To investigate further the role of PKC, a subset of cultures was
treated with 10 µM PDBu for 24 hr. Long-lasting
exposure of neurons to active phorbol esters downregulates PKC and
results, for example, in a marked reduction of stimulated transmitter
release (Matthies et al., 1987) or an attenuation of neuropeptide
Y-mediated inhibition of voltage-activated calcium currents (Ewald et
al., 1988). This treatment, however, failed to alter the
2-adrenergic inhibition of
Ca2+ currents (Fig. 2B).
Effects of PKC activators on Ca2+ currents and on the
2-adrenergic inhibition
Our observation that the effects of UK 14,304 on voltage-activated
calcium currents were attenuated by inhibitors of PKC, but were
independent of a phorbol ester-induced PKC downregulation, indicate the
involvement of phorbol ester-insensitive PKC isoforms. In line with
this hypothesis, we found no effect of extracellularly applied 3 µM PDBu, 30 µM OAG, or
10 µM SC-10 (an activator of
Ca2+-dependent PKC isoforms) (Ito et al., 1986)
on voltage-gated calcium currents (Fig. 3). In addition,
neither intracellular (Fig. 2) nor extracellular (not shown)
applications of 1 µM PDBu significantly reduced
the 2-adrenergic inhibition.
By contrast, the application of 100 µM AA (Fig.
3A,B) or LinA (Fig. 3B) for 1 min reduced
Ca2+ currents in a partially reversible manner.
Both AA and LinA have been shown previously to activate not only
classical but also atypical, phorbol ester-insensitive PKCs (Asaoka et
al., 1992; Nishizuka, 1992; Nakanishi and Exton, 1992). Lower
concentrations of AA (30 µM) were also
effective (not shown) but less well distinguishable from the rundown of
current that occurs in this and other preparations to a variable extent
(Kostyuk et al., 1981). The effects of AA and LinA were reduced
significantly when 10 µM PKCI was added to the
patch pipette solution (Fig. 3A,B).
Pharmacological sensitivities of PKC isoforms in chick
sympathetic neurons
At least 12 distinct subtypes of PKC have been characterized and
categorized further into three groups (Nishizuka, 1992; Dekker and
Parker, 1994): groups A and B comprise ``classical'' and ``new''
enzymes, all of which can be activated by active phorbol esters or
diacylglycerol analogs. By contrast, group C consists of ``atypical''
PKC enzymes, which are insensitive to diacylglycerol and phorbol esters
(Nishizuka, 1992). In view of the inhibitory action of PKC inhibitors
and the lack of effects of phorbol esters on the
2-adrenoceptor-mediated inhibition of calcium
currents, we investigated which of the various isoforms of PKC were
present in chick sympathetic neurons. Immunoblot analysis with peptide
antisera specific for PKC isoforms revealed the presence of ,
I/II, , , and , but not and , in both the cytosolic
and membrane fractions obtained from pure neuronal cell cultures (not
shown). Subsequently, PKC, , and as representatives of
classical, new, and atypical PKC subtypes, respectively (Nishizuka,
1992), were investigated further.
PKC and migrated with an apparent molecular mass of ~80 and
~90-95 kDa, respectively. Immunoblots with antisera specific for
PKC from two different sources (Life Technologies and Santa Cruz)
detected two bands migrating, with an estimated molecular mass of 72 and 78 kDa (Figs. 4, 5). These bands were also detected
in homogenates (Fig. 4) and in membrane fractions from rat neocortex
(not shown). The predicted molecular mass of PKC is 68 kDa; the
enzyme purified from renal tissue migrated at ~78 kDa (Nakanishi and
Exton, 1992), and expression of the cDNA directed the synthesis of a
~64 kDa protein in COS-7 cells (Ono et al., 1989) and of an ~80 kDa
protein in insect and mammalian cells (Liyanage et al., 1992). Thus, it
is not clear whether the 72 kDa band observed in sympathetic neurons
corresponds to a post-translationally modified PKC (e.g., by
phosphorylation and/or proteolytic cleavage, known to occur in
vivo) (Hug and Sarre, 1993), or to a different atypical
PKC-isoform. PKC, for instance, shows not only a 72% identity with
PKC, but an antibody raised against PKC also recognizes PKC
(Selbie et al., 1993). For practical purposes, we subsequently refer to
both bands as PKC.
Fig. 4.
Translocation of PKC, , and isozymes by
phorbol esters and AA. The distribution of protein kinase C isoforms
was investigated by immunoblots after a 10 min incubation of cultures
with 100 µM AA, with the inactive
phorbol ester PDBU, or with the active phorbol ester
PDBU, both at 1 µM. Cells were
lysed as described in Materials and Methods; aliquots of the pellet and
supernatant corresponding to 2 × 105 cells
were applied to SDS-polyacrylamide gels. Nitrocellulose blots were
probed with peptide antisera specific for PKC (A), PKC
(B), and PKC (C). Standard: 10 µg protein
from rat neocortical homogenate. Arrows indicate the
position of bands that were suppressed when antibodies had been
preincubated with the corresponding immunogenic peptide (not shown).
Data are representative of three additional experiments performed on
different preparations.
[View Larger Version of this Image (26K GIF file)]
Fig. 5.
Downregulation of classical, but not atypical, PKC
isozymes by phorbol esters. The distribution of protein kinase C
isoforms was analyzed by immunoblots after a 24 hr treatment of
cultures with 100 µM AA, with 1 µM of the inactive and active phorbol esters
PDBU and PBDU, respectively, or with the
vehicle 0.1% DMSO. Cells were lysed as described in Materials and
Methods; aliquots of the pellet and supernatant corresponding to 2 × 105 cells were applied to SDS-polyacrylamide
gels. Nitrocellulose blots were probed with peptide antisera specific
for PKC (A), PKC (B), and PKC
(C). Arrows indicate the position of bands that
were blocked when antibodies had been preincubated with the
corresponding immunogenic peptide (not shown). Data are representative
of three additional experiments performed on different
preparations.
[View Larger Version of this Image (29K GIF file)]
A 10 min incubation of neurons with 1 µM of the
active phorbol ester PDBu induced an almost complete translocation of
PKC and PKC from the cytoplasm to the membrane, whereas the
distribution of the PKC-bands was unaffected (Fig. 4). Exposure of
the neurons to 30 µM OAG mimicked the effects
of PDBu (not shown). PDBu, the inactive analog of PDBu, did not
affect the distribution of any of the PKC subtypes (Fig. 4). AA (100 µM), which also activates PKC (Nakanishi and
Exton, 1992), trans- located all three isoforms from the cytosol to
the membrane (Fig. 4) .
Long-term exposure (24 hr) of cultures to PDBu (1 µM), but not PDBu, eliminated PKC from
both the cytoplasmic and the membrane fraction (Fig.
5A). The response of PKC was variable: in two
of four neuronal cultures, the levels of PKC were essentially
unaffected (Fig. 5B), whereas a clear-cut decline was
observed in the two remaining experiments (not shown). The reason for
this variability is not clear but is indicative of a relative
refractoriness of PKC to phorbol ester-dependent downregulation. The
extent to which PKC can be downregulated by phorbol esters is known
to vary in different cell lines (Hug and Sarre, 1993). Unlike PKC
and , PKC-bands were affected in no instance by long-term
incubation with the phorbol ester (Fig. 5C).
By contrast to the downregulation of PKC and PKC by PDBu, a 24 hr
exposure to 100 µM AA consistently
increased the immunoreactivity for all three PKC isoforms
(, , and ) in the particulate fraction. This indicates that AA
induced a persistent translocation of the three different PKC subtypes
to the membranes but failed to downregulate any of the enzymes (Fig.
5).
DISCUSSION
Inhibitors of PKC antagonize the effect of UK 14,304, but phorbol
esters have no effect on calcium current and on the
2-adrenoceptor-mediated modulation
In line with our previous observations, the activation of
2-adrenoceptors by UK 14,304 caused an
inhibition of voltage-activated calcium current in chick sympathetic
neurons (Boehm and Huck, 1991). This inhibition was reduced
significantly when the pseudosubstrate peptide inhibitor of PKC
[PKCI(19-36), 10 µM] (House and Kemp, 1987)
was included in the pipette solution. A noninhibitory analogous peptide
[glu27-PKCI(19-36)] had no effect.
Staurosporine and calphostin C, two membrane-permeant inhibitors of
PKC, exerted effects similar to those of PKCI(19-36), regardless of
whether they were applied through the recording pipette or
extracellularly.
These results imply that PKC is part of the signaling cascade that
leads to an inhibition of voltage-gated calcium channels by UK 14,304. In fact, numerous reports have provided evidence that effects of
neurotransmitter receptor activation on calcium currents involve PKC
(Diverse-Pierluissi and Dunlap, 1993). Neither the phorbol ester PDBu
nor the synthetic diacylglycerol analog OAG, however, were able to
mimic the effects of UK 14,304, and downregulation of PKC by a 24 hr
incubation of cultures with PDBu did not attenuate the inhibition of
calcium currents by UK 14,304. In rat sympathetic neurons, OAG (50 µM) was reported to inhibit calcium currents,
but because L-type currents were affected along with N-type currents,
and because PKC inhibitors like PKCI(19-31) did not affect
transmitter-mediated inhibitions of calcium currents, a direct
involvement of PKC on both transmitter- and OAG-mediated effects was
ruled out (Plummer et al., 1991). Bley and Tsien (1990) also found no
evidence for a PKC-mediated pathway of a peptidergic inhibition in frog
sympathetic neurons, because phorbol esters did not mimic the
inhibition of calcium currents and the PKC inhibitor staurosporine did
not block the peptidergic effects. By contrast, the summary of our
observations implies a phorbol ester-insensitive (atypical) PKC as part
of the signaling cascade of
2-adrenoceptor-mediated effects in chick
sympathetic neurons.
At present, we cannot exclude the possibility that additional signaling
pathways independent of PKC may be involved, particularly because a
small inhibition of calcium currents by UK 14,304 persisted in the
presence of PKCI(19-36). In chick sensory neurons,
2-adrenoceptors couple to two types of
pertussis toxin-sensitive G-proteins and use two separate pathways to
regulate N-channel function. One includes G-protein  -subunits as
well as PKC, whereas the second signal cascade seems to be independent
of PKC but involves Go (Diverse-Pierluissi et
al., 1995).
Phorbol ester-sensitive and -insensitive PKC isoforms are expressed
in chick sympathetic neurons
To date, three major groups of PKC isozymes have been
characterized (Asaoka et al., 1992: Nishizuka, 1992; Dekker and Parker,
1994): groups A and B comprise ``classical'' and ``new'' enzymes,
all of which can be activated by active phorbol esters or
diacylglycerol analogs. Group C, by contrast, consists of
``atypical'' PKC enzymes that are insensitive to diacylglycerol and
phorbol esters (Nishizuka, 1992).
PKC and PKC, as representatives of classical and new PKC
isoforms, responded to short-term incubations of cultures with PDBu and
OAG by a translocation from the cytosol to the membrane, indicating
that phorbol ester-sensitive PKC isoforms are present in the chick
sympathetic neurons. Our data also indicate the presence of
``atypical'' PKC, which was translocated by AA but not by PDBu or
OAG. All subtypes of PKC are likely to be inhibited by PKCI (House and
Kemp, 1987) and staurosporine (Nakadate et al., 1988), both of which
act at the catalytic domain highly conserved between all known PKC
subtypes (Nishizuka, 1992; Hug and Sarre, 1993). Likewise, calphostin
C, although acting at the regulatory domain of PKCs, seems to inhibit a
broad range of PKC isoforms, because it reduced the activity of
Ca2+-independent PKC isozymes at least as
potently as the classical Ca2+-dependent isoforms
(Ozawa et al., 1993). Hence, we may expect that PKCI, staurosporine,
and calphostin C all inhibit not only classical isoforms of PKC but
also atypical forms unresponsive to phorbol esters. Our experiments
indicate that such isoforms are present in chick sympathetic neurons
and may therefore mediate the 2-adrenergic
inhibition of calcium currents in a phorbol ester-insensitive manner.
PKC has been demonstrated in nervous tissue and has been suggested
as playing a role in the maintenance of long-term potentiation in the
hippocampal CA1 region (Sacktor et al., 1993).
AA induces translocation of all PKC isozymes and inhibits
voltage-activated calcium channel currents
AA and related fatty acids are known, but not exclusive,
activators of most PKC isozymes (Asaoka et al., 1992; Nishizuka, 1992).
Our experiments indicate that both short- and long-term incubations of
cultures with 100 µM AA induce translocation of
PKC and PKC as well as PKC from the cytosol to the membrane
fraction in chick sympathetic cultures. Extracellular applications of
100 µM AA or 100 µM
LinA also inhibited voltage-activated calcium currents, and these
effects were attenuated by >50% when PKCI(19-36) was included in the
pipette solution, indicating a PKC-specific component of the
phenomenon. Residual effects in the presence of the PKC inhibitor might
be attributable to a straight action on calcium channels, because AA
also affects transmembrane ion channels directly (Ordway et al., 1991;
Fraser et al., 1993; Meves, 1994).
The link between 2-adrenoceptors and the activation
of atypical PKC remains to be identified
Free AA, which may be generated by receptor-mediated activation of
PLA2 (Axelrod, 1990), exerts a plethora of
effects in the nervous system by the activation of PKC (Axelrod et al.,
1988; Keyser and Alger, 1990; Meves, 1994). We therefore tested whether
UK 14,304 would enhance cellular levels of AA, thus making AA not only
a pharmacological tool but also a physiological candidate in the signal
transduction pathway between 2-adrenoceptors
and the activation of atypical PKC. Our experiments were inconclusive,
however, because short-term incubations with UK 14,304 enhanced the
generation of free AA in only 7 of 12 experiments (S. Boehm, S. Huck,
and M. Freissmuth, unpublished observations). In addition, the high
concentrations required to inhibit calcium currents render AA an
unlikely candidate to mediate the effect of UK 14,304. Hence, in the
signaling cascade 2-adrenoceptors activation
of an atypical PKCinhibition of calcium currents, as delineated in
this description for chick sympathetic neurons, the missing link or
links between 2-adrenoceptors and atypical PKC
remain to be identified.
FOOTNOTES
Received Feb. 22, 1996; revised April 22, 1996; accepted May 13, 1996.
This study was supported by grants from the Austrian Science Foundation
(FWF) to M.F. (P10675) and from the
Anton-Dreher-Gedächtnisschenkung to S.B. (202/92 and 229/93). We
thank D. S. McGehee and V. O'Connor for valuable comments on this
manuscript. The perfect technical assistance of G. Koth, A. Motejlek,
and K. Schwarz and the skillful artwork of E. Tuisl are gratefully
acknowledged.
Correspondence should be addressed to Sigismund Huck, Department of
Neuropharmacology, University of Vienna, Waehringerstrasse 13A, A-1090
Vienna, Austria.
Dr. Boehm's present address: Department of Neurochemistry, Max Planck
Institute for Brain Research, Deutschordenstrasse 46, D-60528
Frankfurt, Germany.
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