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Volume 16, Number 16,
Issue of August 15, 1996
pp. 4994-5003
Copyright ©1996 Society for Neuroscience
Neural Influence on Protein Kinase C Isoform Expression in
Skeletal Muscle
Lutz Hilgenberg,
Simone Yearwood,
Stuart Milstein, and
Kathryn Miles
Department of Anatomy and Cell Biology, The State University of New
York Health Science Center at Brooklyn, Brooklyn, New York 11203
 ABSTRACT
- INTRODUCTION
- MATERIALS AND METHODS
- RESULTS
- DISCUSSION
- FOOTNOTES
- REFERENCES
ABSTRACT 
Protein kinase C (PKC) is a family of enzymes involved in synapse
formation and signal transduction at the neuromuscular junction. Two
PKC isoforms, classical PKC  and novel PKC  , have been shown to
be enriched in skeletal muscle or localized to the endplate. We
examined the role of nerve in regulating the expression of these PKC
isoforms in rat skeletal muscle by denervating diaphragm muscle and
measuring PKC protein expression at various postoperative times. nPKC
protein levels decreased 65% after denervation, whereas cPKC levels increased 80% compared with control hemidiaphragms. These
results suggest that innervation regulates PKC and isoform
expression in skeletal muscle. To explore further how nerve regulates
PKC expression, we characterized PKC isoform expression in rat myotubes
deprived of neural input. Myoblast expression of nPKC was low, and
the increase in nPKC expression that occurred during
differentiation into myotubes resulted in levels of nPKC significantly below adult skeletal muscle. cPKC expression in
myoblasts increased during differentiation to levels that exceeded
expression in adult skeletal muscle. Coculturing myotubes with a
neuroblastoma X glioma hybrid clonal cell line (NG108-15) increased
nPKC expression, but not cPKC , suggesting that nPKC in
skeletal muscle and myotubes is regulated by nerve contact or by a
factor(s) provided by nerve. Treating myotubes with tetrodotoxin did
not affect either basal- or NG108-15 cell-stimulated nPKC expression. Together these results suggest that expression of nPKC in skeletal muscle is regulated by a transynaptic interaction with
nerve that specifically influences nPKC expression.
Key words:
protein kinase C;
cPKC ;
nPKC ;
neuromuscular junction;
NG108-15 cells;
denervation
INTRODUCTION
Protein phosphorylation is involved in synapse
formation and function at the neuromuscular junction. In particular,
protein kinase C (PKC), a Ca+2- and
phospholipid-sensitive protein kinase, has been implicated as a
participant in these processes. For example, decreased expression of
the nicotinic acetylcholine receptor (nAChR) has been linked to muscle
activity and activation of PKC (Klarsfeld et al., 1989 ; Huang et al.,
1992). Application of phorbol esters, which activate PKC, to myotubes
inhibits both basal and acetylcholine receptor inducing activity
(ARIA)-stimulated nAChR synthesis (Burstajn et al., 1988; Altiok et
al., 1995). Treatment of myotubes with phorbol esters disrupts
spontaneously formed nAChR clusters and abolishes the activity of
agrin, an nAChR clustering factor (Burstajn et al., 1988; Ross et al.,
1988; Wallace et al., 1991), suggesting that PKC may play a role in the
distribution of nAChRs in the postsynaptic membrane. The amplitude of
currents induced by the iontophoretic application of acetylcholine to
chick myotubes and frog endplates is diminished by the activation of
PKC (Eusebi et al., 1985; Caratsch et al., 1986). An accelerated decay
in nAChR currents in oocytes injected with nAChR subunit mRNA was
obtained by treating oocytes with phorbol esters (Mileo et al., 1995).
A reduction in the magnitude of the voltage-gated sodium channel
current and a slowing of the current inactivation rate have been
attributed to phosphorylation of the sodium channel by PKC in myotubes
(Numann et al., 1994). Although the phosphorylation events that mediate
these effects have not yet been identified, several important molecules
in the neuromuscular junction have been demonstrated to be substrates
for PKC. PKC phosphorylates the Torpedo nAChR in
vitro (Safran et al., 1987), whereas PKC may be directly or
indirectly responsible for phosphorylating the nAChR in myotubes (Ross
et al., 1988; Miles et al., 1994). Potential PKC phosphorylation sites
have been identified on the nAChR  subunit and on the adult skeletal
muscle sodium channel subunit (Miles and Huganir, 1988; Bendahhou
et al., 1995). Neither the first messenger that stimulates PKC activity
nor the PKC isoforms involved in phosphorylating substrates in the
neuromuscular junction have yet been identified.
The PKC family of enzymes is comprised of multiple isoforms, each
encoded by a separate gene. PKC isoforms consist of a single
polypeptide chain and are grouped according to the homologous amino
acid sequences contained within their regulatory and catalytic domains
(Nishizuka, 1992; Hug and Sarre, 1993; Newton, 1995). Classical PKCs
(cPKC) contain a calcium-binding or selectivity (C2) domain that is
absent in the novel PKCs (nPKC). Both classic and novel isoforms of PKC
contain a binding site (C1) for diacylglycerol and phorbol ester, each
of which stimulates kinase activity. The multiplicity of PKC isoforms
and their differences in tissue distribution raise the question as to
whether they function distinctly within different tissues or cells.
Skeletal muscle is enriched for the mRNA encoding cPKC and nPKC compared with other known isoforms of PKC, suggesting that these are
the most abundant PKC isoforms present in this tissue (Osada et al.,
1992). cPKC appears to be ubiquitously expressed, whereas nPKC is exclusively expressed in skeletal muscle, hematopoietic tissue, and
testes (Osada et al., 1992; Baier et al., 1993; Chang et al., 1993;
Mischak et al., 1993; Hilgenberg and Miles, 1995). Previously, our
laboratory demonstrated that nPKC expression is developmentally
regulated in postnatal skeletal muscle and is localized to the
neuromuscular junction (Hilgenberg and Miles, 1995). These results
suggested that nPKC may be specifically involved in events
associated with maturation of the neuromuscular junction. To explore
further the potential role of these two PKC isoforms in skeletal muscle
and the neuromuscular junction, we sought to determine the cellular
mechanisms that influence their expression.
We investigated whether nerve regulates PKC expression and found
that nPKC levels decreased whereas cPKC levels increased after
denervation of skeletal muscle. To delineate further the underlying
mechanisms responsible for these changes, we explored PKC isoform
expression in aneural myotubes. nPKC expression in myoblasts was
significantly below levels detected in adult skeletal muscle and
remained so after myogenic differentiation, suggesting that the absence
of nerve deprives myotubes of a factor(s) influencing expression of
this isoform. Coculture of myotubes with a neuroblastoma X glioma
hybrid clonal cell line (NG108-15) (Christian et al., 1977) that is
capable of forming functional synapses on myotubes resulted in
significantly enhanced expression of nPKC by the myotubes. These
observations support the hypothesis that nPKC expression is
regulated transynaptically at the neuromuscular junction and that this
PKC isoform plays a role in the formation and function of this
synapse.
MATERIALS AND METHODS
Denervation or nerve crush of rat skeletal muscle.
Adult Sprague-Dawley rats (300-500 gm) were anesthetized with sodium
pentobarbital and unilateral denervation, or nerve crush was performed
on hemidiaphragms via a thoracic incision. A 3-5 mm segment of the
phrenic nerve was either excised or crushed with a forceps within 2 mm
of its entrance into the diaphragm. The wounds were sutured, and the
rats were allowed to recover.
Tissue culture. Rat primary myotube cultures were
established from hindlimb muscles of 20-21 d embryos as described
previously (Miles et al., 1994). Myoblasts were plated on
collagen-coated 35 mm tissue culture dishes unless otherwise stated and
were grown in DMEM supplemented with 20% (v/v) fetal calf serum (FCS)
and 33 mM glucose. After 2 d, this medium
was replaced with medium containing 10% (v/v) horse serum and 2%
(v/v) chicken embryo extract. Primary rat fibroblast cultures were
established by preplating an embryonic hindlimb muscle cell preparation
for 1 hr on non-collagen-coated tissue culture dishes and then gently
washing off the myoblasts. The remaining fibroblast-enriched cultures
were treated according to the same regimen as for primary
myoblast/myotube cultures. National Institutes of Health 3T3 cells were
grown in DMEM with 10% FCS. NG108-15 cells, a gift from M. Nirenberg
(National Institutes of Health, Bethesda, MD), were grown in DMEM
containing 1× hypoxanthine-aminopterin-thymidine and 10% FCS on
tissue culture dishes. NG108-15 cells were induced to differentiate,
when they reached 80% confluency, by applying differentiation medium
composed of NG108-15 cell growth medium containing 200 µM isobutylmethylxanthine (Sigma, St. Louis,
MO) and 5% horse serum substituted for FCS. Cocultures were
established by adding dispersed NG108-15 cells in growth medium to
primary myotube cultures. After a few hours to permit adhesion of the
NG108-15 cells, the medium was removed and replaced with NG108-15 cell
differentiation medium. Indirect cocultures were established by plating
NG108-15 cells onto collagen-coated tissue culture inserts (Nunc,
Naperville, IL), allowing the NG108-15 cells to differentiate, and then
placing the inserts onto myotube cultures. The tissue culture inserts
were composed of 45-µm-thick polycarbonate semipermeable membranes,
containing pores of determined sizes, that provided a surface for cell
adhesion and growth. The inserts rested 1 mm above the underlying
tissue culture dish, thereby separating the cells growing on the
membrane from those on the tissue culture dish while permitting the
exchange of medium and diffusible factors. The two cell populations can
be assayed separately. During indirect coculture of myotubes and
NG108-15 cells, both the cocultures and control myotubes were cultured
in NG108-15 cell differentiation medium. NG108-15 cell-conditioned
medium was obtained by collecting medium from NG108-15 cells cultured
for 3 d in differentiation medium. The medium was centrifuged for
15 min at 1000 × g, and the supernatant was added in
place of myotube differentiation medium. All cultures were maintained
at 37°C in a 5% CO2 atmosphere.
Subcellular fractionation of rat skeletal muscle and cells in
culture. Rat diaphragms were dissected, rinsed in PBS at 4°C,
frozen in liquid nitrogen, and pulverized using a mortar and pestle.
The powdered tissue was homogenized, using a Dounce homogenizer, in
Buffer A (10 ml/gm wet weight) containing 20 mM
Tris, pH 7.5, 10 mM EDTA, 10 mM EGTA, 25 µg/ml aprotinin, 50 µg/ml
leupeptin, 10 mM benzamidine, 10 mM phe- nylmethylsulfonyl fluoride, and 10 mM  -mercaptoethanol. Cells in culture were
scraped from the dish and homogenized in Buffer A (75 µl/35 mm tissue
culture dish). The homogenates were centrifuged at 6000 × g for 2 min, and supernatants were collected and centrifuged
at 95,000 × g for 45 min. The resulting supernatants
(cytosolic fractions) were collected, and the pellets (membrane
fractions) were solubilized in Buffer A containing 1% Triton X-100 (30 µl/pellet). Samples were adjusted such that either an equal amount of
total protein (PKC expression per µg protein) or an equal
representative volume (PKC expression per tissue culture dish) from
each of these two fractions was analyzed as indicated. Protein
concentrations were determined using the Bio-Rad (Hercules, CA) protein
assay based on Coomassie brilliant blue binding. NG108-15 cell membrane
fractions were obtained from cells cultured for several days in
differentiation medium, homogenized in PBS instead of Buffer A, and
centrifuged as described above. The pellet from the high-speed
centrifugation was resuspended in PBS and applied to myotubes.
Immunoblot analysis. Proteins were subjected to
SDS-PAGE (8.5%) and then transferred electrophoretically to
nitrocellulose membranes. The membranes were incubated overnight at
4°C in Blotto buffer containing 200 mM NaCl, 50 mM Tris, 0.1% Triton X-100, 0.2% Tween-20, 5%
nonfat dry milk (w/v), and 0.4% Ficoll-400, pH 7.4, to block
nonspecific binding. nPKC was detected using S22 antiserum
(Hilgenberg and Miles, 1995). cPKC was detected using a previously
characterized monoclonal antibody, M6 (Leach et al., 1988) (UBI, Lake
Placid, NY), followed by a rabbit anti-mouse secondary antibody (Dako,
Carpinteria, CA). Membranes were then incubated with
125I-labeled protein A (ICN Biochemicals, Costa
Mesa, CA), washed, and exposed to X-ray film. Radioactivity was
quantitated using a PhosphorImager and ImageQuant software
(Molecular Dynamics, Sunnyvale, CA). The area to be quantitated was
defined visually, and identical areas were used to quantitate sample as
well as background for each PKC isoform. Background and maximal
PhosphorImager measurements obtained were in the range of 500 to 10,000 units, respectively. The data obtained were within the linear range of
the assay and the instrument for each experiment.
-Bungarotoxin binding assay. nAChR were assayed using
[125I]-bungarotoxin (DuPont NEN, Boston, MA)
in cultures solubilized in 1% Triton X-100 according to established
methods (Schmidt and Raftery, 1973).
Northern blot analysis. Rat skeletal muscle was dissected,
frozen in liquid nitrogen, and pulverized. Total RNA was extracted from
frozen pulverized tissue or from cells in culture using RNAzol
(Tel-Test, Friendswood, TX). Poly(A+)-enriched
RNA, isolated by oligo-dT chromatography, was electrophoresed through
0.8% agarose gels containing 7% formaldehyde and transferred to
Hybond-N+ nylon membranes (Amersham, Arlington
Heights, IL). Membranes were hybridized overnight at 65°C with a
32P-random-primed labeled cDNA probe encoding
nPKC , kindly provided by Shin-ichi Osada (Vanderbilt University,
Nashville, TN) (nt  23-2262; Genbank accession number D11091[GenBank]) in a
buffer containing 50 mM polyethylene glycol 8000, 7% SDS, 1.5× SSPE, and 250 µg/ml salmon sperm DNA. The membranes
were washed at 65°C in 0.2× SSC containing 0.1% SDS and exposed for
autoradiography. Some blots were reprobed under the same conditions
with a 32P-random-primed labeled 250 bp fragment
of the mouse cardiac -actin gene (nt 940-1190; Leader et al., 1986;
Genbank accession number M15501[GenBank]), kindly provided by L. Moscoso and J. Sanes (Washington University, St. Louis, MO). This actin probe
cross-hybridizes with skeletal muscle actins.
RESULTS
PKC isoform expression is altered after rat skeletal
muscle denervation
To explore the role of nerve in regulating PKC isoform expression,
we unilaterally severed or crushed the phrenic nerve to rat diaphragm
muscle and measured PKC expression at various times during
postoperative recovery. nPKC expression relative to total protein
in hemidiaphragms was found to decrease rapidly, reaching a maximal
decrease of 65% 2 weeks after nerve cut compared to the untreated
hemidiaphragm in the same rat (Fig.
1A). Temporary denervation, in the
form of nerve crush, led initially to a decrease in nPKC expression
with the same time course observed after nerve cut, followed by a
recovery in expression over a 2 week time period (Fig.
1A). These data suggest that expression of nPKC in skeletal muscle is regulated by innervation.
Fig. 1.
Time course of nerve crush or axotomy on PKC
expression in skeletal muscle. The phrenic nerve to rat diaphragm
muscle was unilaterally severed (axotomy) ( ) or crushed ( ), and
the rats were allowed to recover for the indicated times. Diaphragms
were then removed, homogenized, and separated into cytosolic and
membrane protein fractions by ultracentrifugation. Cytosolic
(c) and membrane (m) proteins (50 µg) from both
denervated and control hemidiaphragms from each rat were separated by
SDS-PAGE and transferred to nitrocellulose membranes. Immunoblots were
probed with antiserum specific to nPKC (A) or antibody
specific to cPKC (B) followed by a secondary antibody
and 125I-labeled protein A. The blots were
exposed for autoradiography, and radioactivity was quantitated by
PhosphorImager analysis using ImageQuant software. Data are expressed
as percent decrease in nPKC (A) or increase in cPKC (B) expression in cytosolic plus membrane fractions of
experimental compared with control hemidiaphragms of the same rat.
Error bars represent SEM. For each point, n = 3 or 4 rats. C shows a representative autoradiogram of an
immunoblot from 14 d axotomized () and control (+)
hemidiaphragms.
[View Larger Version of this Image (27K GIF file)]
In contrast, cPKC expression was found to increase 80% in
hemidiaphragms 14 d after nerve cut compared with control
hemidiaphragms (Fig. 1B). cPKC protein levels were also
observed to increase initially after nerve crush followed by a return
to control levels after 4 weeks (Fig. 1B). The increase in
cPKC expression after nerve crush occurred at an initial rate that
paralleled the increase in cPKC seen after nerve cut but was slower
than the changes in nPKC expression induced by denervation. Taken
together, these results demonstrate that PKC and isoforms are
differentially regulated in skeletal muscle by innervation.
It is possible that denervation affects PKC isoform expression in
skeletal muscle due to the absence of nerve-evoked muscle activity
and/or nerve-derived trophic factors as well as by the initiation of
mononuclear cell proliferation. We turned to primary rat myotubes in
culture as a strategy to explore these mechanisms.
PKC isoform distribution in rat primary myotubes in culture
Basal expression of PKC isoforms in cytosolic and membrane
subcellular fractions from cultured myotubes devoid of neural input was
analyzed to characterize this experimental model for exploring PKC
isoform expression. nPKC (79 kDa) expression, per µg protein, was
found to be concentrated in the membrane fraction of primary myotube
cultures (Fig. 2A) but varied in
extent between preparations. nPKC expression, per culture, was also
greater in the membrane fraction rather than the cytosolic fraction of
myotube cultures (Fig. 2B). This distribution profile is
similar to that observed for nPKC in adult skeletal muscle
(Hilgenberg and Miles, 1995).
Fig. 2.
Subcellular distribution of PKC and isoforms in primary rat myotubes. Primary myoblast cultures were
established and cultured for 8 d to permit differentiation into
myotubes. Myotube cultures were homogenized and separated into
cytosolic (c) and membrane (m) protein fractions
by ultracentrifugation. Fractions were adjusted either to equal protein
concentration (A, C, 100 µg/lane) or to equal
volume (B, D, 100 µl/lane) and were separated
by SDS-PAGE and transferred to nitrocellulose membranes. The
immunoblots were probed with anti-nPKC antiserum (A,
B) or anti-cPKC antibody (C, D) as
described in the legend to Figure 1 and were exposed for
autoradiography. nPKC and cPKC migrate as 79 and 82 kDa
proteins, respectively.
[View Larger Version of this Image (50K GIF file)]
In contrast, expression of cPKC (82 kDa) in myotube cultures was
found to be distributed predominantly in the cytosolic fraction
regardless of whether expression was assayed per µg protein (Fig.
2C) or per culture (Fig. 2D). This isoform
distribution is also similar to that seen in adult skeletal muscle
(Hilgenberg and Miles, 1995). Immunoblots of cPKC from cultured
cells using the M6 antibody resulted in the detection of
higher-molecular-weight proteins of unknown identity that are not seen
in adult skeletal muscle (Figs. 1C,
2C,D,
6C,D).
Fig. 6.
Effect of myotube indirect coculture with NG108-15
cells on PKC and expression. Primary myoblast cultures were
established and cultured for 7-8 d as described in the legend to
Figure 2. Myotubes were cultured in parallel for 2.5 d alone
(PMC) or were indirectly cocultured with 5 × 105 NG108-15 cells (NG108-15)
separated from the myotubes (PMC*) by a semipermeable
membrane of 3 or 8 µm pore size as indicated. After 3 d, myotube
cultures and NG108-15 and myotube indirect cocultures were each
harvested separately and homogenized, and protein (120 µg for nPKC
, 50 µg for cPKC ) from cytosolic and membrane fractions from
each cell population was analyzed as described in the legend to Figure
1. Immunoblots were probed with anti-nPKC antiserum (A,
B) or anti-cPKC antibody (C, D) as
described in the legend to Figure 2. Each lane represents a separate 35 mm tissue culture dish (PMC) or cell populations present in
separate compartments of individual coculture experiments performed in
triplicate (NG108-15, PMC*).
[View Larger Version of this Image (56K GIF file)]
PKC isoform protein expression during myogenic differentiation
To determine whether PKC isoform expression in skeletal muscle is
influenced by myogenic differentiation, we analyzed PKC isoform levels
in cultures in which myoblasts were undergoing terminal differentiation
to myotubes. In addition, these experiments also address the issue of
whether muscle cell activity plays a role in PKC expression because
well differentiated myotubes in culture contract spontaneously. Myotube
differentiation in culture was monitored by measuring nAChR levels.
Expression of nAChRs increased 10-fold between days 2 and 9 in culture
(Fig. 3A), in accordance with previous
studies (Evans et al., 1987).
Fig. 3.
Time course of the expression of nAChRs and PKC
and isoforms during myogenic differentiation in culture.
Primary myoblast cultures were established in parallel. At the
indicated days in culture, cells were solubilized and specific binding
of [125I]-bungarotoxin to nAChRs was
quantitated. Data are expressed as fmol of nAChR per 35 mm tissue
culture dish (A). Alternatively, cells were homogenized and
membrane (B) or cytosolic (C) proteins were
separated by SDS-PAGE and transferred to nitrocellulose membranes. The
immunoblots were probed with anti-PKC antiserum (B) or
anti-PKC antibody (C) and analyzed according to the
legend to Figure 1. PKC isoform levels in membrane or cytosolic
subcellular fractions (100 µg/lane) of cultured cells are expressed
as percent PKC isoform expression in membrane (B) or
cytosolic (C) protein (100 µg/lane) fractions of adult
skeletal muscle, respectively. Each experiment was performed in
triplicate. Error bars represent SEM.
[View Larger Version of this Image (11K GIF file)]
nPKC expression in myoblast culture membrane fractions was 90%
below levels in adult skeletal muscle membrane fractions and increased
only slightly during myogenic differentiation (Fig. 3B).
Because of spontaneous contractions, myotubes rarely survived beyond
9 d. In cultures that did survive 14 d, nPKC expression
was not found to exceed 15-20% of adult skeletal muscle levels. This
result is consistent with the observation that nPKC expression is
reduced in diaphragms after denervation (Fig. 1A).
Cytosolic fractions of myotube cultures had barely detectable levels of
nPKC throughout differentiation (data not shown), and this isoform
was not detected in primary fibroblast cultures. Taken together, these
data suggest that myogenic differentiation and spontaneous muscle cell
activity do not promote adult skeletal muscle levels of nPKC expression in myotubes.
In parallel cultures, cPKC protein expression in the cytosol was
found to increase fivefold from days 2 to 6 in culture, concomitant
with cell fusion and the increase in nAChRs (Fig. 3C). cPKC
was found to be maximally expressed in myotubes at a significantly
higher level than that seen in adult skeletal muscle. An increase in
cPKC levels also was seen in the membrane fraction of myotube
cultures such that the proportion of cytosolic to membrane cPKC expression did not change (data not shown). These results, obtained in
aneural myotube cultures, are consistent with the previous experiments
in which cPKC expression in denervated diaphragm muscle increased
by 80% (Fig. 1B). The increase in cPKC expression
coinciding with myogenic differentiation is consistent with a role for
this PKC isoform in this process. These data also suggest that
innervation may suppress cPKC expression.
In our experiments, myotube cultures are composed of 80-90% myotubes.
Nevertheless, to determine whether the changes in cPKC expression
during myoblast differentiation in culture are attributable to the
proliferation of fibroblasts present in primary cultures rather than to
myotubes, cPKC expression was measured in the cytosolic and
membrane fractions of primary fibroblast cultures devoid of myotubes
during the same period in culture. Levels of cPKC in primary
fibroblasts were elevated only slightly compared with adult skeletal
muscle and did not change significantly over this culture period (data
not shown). These data rule out the possibility that primary fibroblast
proliferation accounts for the increase in cPKC expression observed
in differentiating myoblast cultures and support the hypothesis that
cPKC plays a role in proliferation of muscle cell precursors and
myogenic differentiation.
nPKC mRNA transcript expression during
myogenic differentiation
To determine whether the expression pattern of nPKC observed
during myogenic differentiation also occurred at the mRNA transcript
level, analysis of the mRNA transcripts encoding nPKC was performed
and compared in postnatal day 0 and adult skeletal muscle as well as
myoblasts and myotubes (Fig. 4). mRNA transcript levels
for nPKC were low in postnatal day 0 skeletal muscle but increased
severalfold in adult skeletal muscle (Fig. 4), supporting previous
observations that postnatal expression of nPKC protein is
developmentally regulated (Hilgenberg and Miles, 1995). nPKC mRNA
transcripts were undetectable in myoblasts and appeared only at low
levels in differentiated myotubes (Fig. 4). These observations parallel
those in which protein expression of nPKC in myotubes was found to
be significantly less than that in adult skeletal muscle (Fig.
3B). These data further argue that differentiation of
skeletal muscle and/or spontaneous muscle cell activity is not
sufficient to induce adult levels of expression of the nPKC isoform. A more likely possibility is that nPKC expression is
regulated by an interaction with nerve.
Fig. 4.
Developmental regulation of nPKC mRNA
transcripts in skeletal muscle and primary myoblast and myotube
cultures. Total RNA from rat postnatal day 0 skeletal muscle (P0),
adult skeletal muscle, and primary myoblast (day 1 in culture) and
myotube (day 7 in culture) cultures was isolated and quantitated.
Poly(A+)-enriched RNA obtained from total RNA
(300 µg) from each sample was isolated, electrophoresed, and
transferred to nylon membranes. Blots were probed with
32P-labeled nPKC cDNA and were exposed for
autoradiography. This figure represents one of three identical
experiments.
[View Larger Version of this Image (43K GIF file)]
PKC protein expression in myotubes cocultured with
NG108-15 cells
To explore further the role of nerve in regulating PKC isoform
expression, myotubes were cocultured in the presence of NG108-15 cells,
a neuroblastoma X glioma hybrid cell line that has been shown
previously to make synaptic contacts on myotubes in culture (Christian
et al., 1977). Coculture of myotubes with NG108-15 cells for 2.5 d
caused a maximal 3.5-fold increase in nPKC protein levels (Fig.
5). The initial increase and subsequent plateau of nPKC
protein in cocultured myotubes suggest that myotubes were exposed
to rising and subsequently saturating levels of either contact with or
a factor(s) provided by NG108-15 cells that increases nPKC expression in myotubes. Coculturing myotubes with National Institutes
of Health 3T3 cells, a transformed fibroblast cell line, had no effect
on nPKC expression (data not shown). In addition, NG108-15 cells
did not affect nPKC expression in fibroblast preplate cultures
lacking myotubes (data not shown). Taken together, these data suggest
that NG108-15 cells increased nPKC synthesis in myotubes.
Fig. 5.
Effect of coculture of myotubes with NG108-15
cells on nPKC expression. Primary myoblast cultures were
established and cultured for 7 d as described in the legend to
Figure 2. Myotubes were then cocultured for 2.5 d in the presence
of the indicated number of NG108-15 cells. The cultures were
homogenized and centrifuged at 6000 × g for 2 min.
Proteins contained in equal representative volumes from each
supernatant were separated by SDS-PAGE, transferred to nitrocellulose
membranes, and analyzed according to the legend to Figure 1. Data are
expressed as percent increase in nPKC expression compared with
parallel myotubes cultured in NG108-15 cell differentiation medium
without NG108-15 cells. For each point, n = 1.
[View Larger Version of this Image (11K GIF file)]
NG108-15 cells expressed detectable levels of cPKC , whereas nPKC
could not be detected by us in these cells. To control for the
possibility that the increase in nPKC expression detected in
cocultures was attributable to the induction of NG108-15 cells, rather
than myotubes, to express nPKC after coculture with myotubes, and
to examine cPKC expression in myotubes after exposure to NG108-15
cells, experiments were performed in which NG108-15 cells were
indirectly cocultured with myotubes (see Materials and Methods).
NG108-15 cells and myotubes were cultured in the same culture dish but
were separated from each other by semipermeable membranes of defined
pore sizes. Diffusion of medium and soluble factors, but probably not
direct cell contact, between these two cell populations is possible
with 0.2 µm pore size membranes. Larger size pores, 3 and 8 µm, are
likely to have facilitated passage of large molecules as well as
NG108-15 cell neuritic processes that may contact myotubes. After
indirect coculture with NG108-15 cells, using 3 or 8 µm pore size
membranes, a 3- and 3.7-fold increase, respectively, in nPKC expression was detected in myotube membrane fractions compared with
noncocultured myotube membrane fractions (Fig.
6A; SEM for 3 µm: 0.06, SEM for 8 µm: 0.04; n = 3 for both tissue culture inserts).
Increased nPKC expression was also found in the cytosolic fraction
of myotubes indirectly cocultured with NG108-15 cells but to a lesser
extent than that seen in the membrane fraction (Fig. 6B). No
nPKC was detected in membrane or cytosolic fractions (Fig.
6A,B) from NG108-15 cells indirectly
cocultured with myotubes. Expression of cPKC did not change in
either the membrane or the cytosolic fraction of myotubes indirectly
cocultured with NG108-15 cells (Fig.
6C,D), and total protein expression in
myotubes indirectly cocultured with NG108-15 cells was
indistinguishable from control myotube cultures (data not shown). Taken
together, these results further support the hypothesis that NG108-15
cells specifically increase nPKC expression in myotubes.
The extent to which NG108-15 cells were able to stimulate an increase
in nPKC expression was found to be dependent on the pore size of
the semipermeable membrane separating the two cultures; a 70-80%
increase in nPKC expression was detected in myotubes separated from
NG108-15 cells by a 0.2 µm pore size membrane compared with a 250%
increase observed using membranes of 3 and 8 µm pore sizes (Fig.
7). These results suggest that a diffusible factor(s)
less able to pass through a 0.2 µm than a 3 or 8 µm opening, and/or
cell contact resulting from NG108-15 cell processes protruding through
the larger size pores, is responsible for stimulating nPKC expression in myotubes.
Fig. 7.
Quantitation of the effect of myotube culture with
NG108-15 cell conditioned medium, NG108-15 cell subcellular membrane
fraction, or NG108-15 cells on nPKC expression. Primary myoblast
cultures were established and cultured for 7-8 d as described in the
legend to Figure 2. Myotubes were cultured in parallel for 2.5 d
alone (CTL) or with conditioned medium (CM) from,
or the subcellular membrane fraction (MF) from,
5 × 105 NG108-15 cells. Alternatively,
myotubes were indirectly cocultured with 5 × 105 NG108-15 cells separated from the myotubes by
a semipermeable membrane of the indicated pore size. Myotubes were
homogenized, and equal protein (120 µg) was analyzed as described in
the legend to Figure 1. Data are expressed as percent increase in nPKC
expression in cytosolic plus membrane fractions of experimental
compared with control cultures. Each experiment was performed in
triplicate except for control (CTL) and 0.3 µm filters
where n = 15 for each. Error bars represent SEM.
[View Larger Version of this Image (11K GIF file)]
To pursue the possibility that a diffusible factor from NG108-15 cells
stimulates nPKC expression in myotubes, conditioned medium from
differentiated NG108-15 cells was applied to myotubes and was not found
to increase nPKC levels significantly compared with control
myotubes (Fig. 7). Subcellular membrane fractions from NG108-15 cells
were more potent than conditioned medium in increasing nPKC expression in myotubes, suggesting that this effect is mediated by a
factor(s) that is membrane-associated rather than diffusible. The
observation that NG108-15 cells separated from myotubes by 3 and 8 µm
filters resulted equally in an enhanced nPKC expression that
significantly surpassed that of intact cells separated by a 0.2 µm
filter, in which direct cell contact is expected to be minimal, further
supports this hypothesis. However, because NG108-15 cell subcellular
membrane fractions had a potency equal to that of intact cells
separated by a 0.2 µm filter, it is also possible that the factor(s)
is diffusible but labile and must be continuously replenished.
nPKC mRNA transcript expression in myotubes cocultured with
NG108-15 cells
To establish whether the increased nPKC protein expression
observed in myotubes cocultured with NG108-15 cells also occurred at
the mRNA transcript level, nPKC transcripts were measured in
myotubes cocultured with NG108-15 cells. A 2.5-fold increase in nPKC
mRNA was detected in myotubes cocultured with NG108-15 cells
compared with control myotube cultures (Fig. 8). No nPKC
mRNA transcripts were detected in NG108-15 cell populations (Fig.
8). These results suggest that regulation of nPKC expression in
myotubes by NG108-15 cells occurs at the mRNA transcript level. mRNA
transcript levels for the skeletal muscle isoform of -actin indicate
that differences in mRNA from myotubes cannot account for the increase
in nPKC mRNA detected in cocultures (Fig. 8).
Fig. 8.
Effect of coculture of myotubes with NG108-15
cells on nPKC mRNA transcript expression. Primary myoblast cultures
were established on 100 mm tissue culture dishes and cultured for
7 d as described in the legend to Figure 2. Myotubes were cultured
in parallel for 2.5 d alone (PMC) or in the presence of
1.4 × 106 NG108-15 cells (PMC + NG108-15). An equal number of NG108-15 cells was cultured
separately in parallel (NG108-15). Total RNA from each
culture and from adult skeletal muscle was isolated and quantitated.
Total poly(A+)-enriched RNA from each culture was
isolated, electrophoresed, and transferred to nylon membranes. Adult
skeletal muscle poly(A+)-enriched RNA, obtained
from an amount of total RNA equal to that present in the myotube
culture (~100 µg) (PMC), was loaded as a control
(skeletal muscle). Blots were probed with
32P-labeled nPKC cDNA and
exposed for autoradiography. Radioactivity was quantitated by
PhosphorImager analysis using ImageQuant software. This figure
represents one of three identical experiments in which the increase in
nPKC mRNA in cocultured myotubes was 2.5-fold ± 0.44 SEM
above control myotubes. The blot represented by the top
panel of this figure was subsequently reprobed with
32P-labeled -actin cDNA. Arrow
indicates skeletal muscle isoform of -actin mRNA transcripts.
[View Larger Version of this Image (25K GIF file)]
Role of myotube activity on nPKC expression
To examine further whether muscle activity plays a role in
nerve-dependent expression of nPKC , myotubes were preincubated with
tetrodotoxin (TTX) to block spontaneous contractions. Application of
TTX to cultures silenced myotube contractions but had little effect on
basal nPKC expression in myotubes (Fig. 9).
Moreover, the presence of TTX failed to alter the extent to which
subcellular membrane fractions from NG108-15 cells stimulated nPKC expression in myotubes (Fig. 9). These data confirm our observation
that the acquisition of contractile activity in myotubes had only a
minor effect on nPKC protein expression. Furthermore, these data
support the hypothesis that nPKC expression in skeletal muscle is
mediated by an interaction between muscle and nerve that is independent
of muscle activity.
Fig. 9.
Effect of tetrodotoxin on myotube nPKC expression. Primary myoblast cultures were established and cultured for
7 d as described in the legend to Figure 2. Myotubes were
preincubated for 3 hr with (TTX) or without
(CTL) 500 nM tetrodotoxin. The
subcellular membrane fraction from 1 × 106
NG108-15 cells (+MF) or buffer alone was added, and
the cultures were incubated for 2 d in the continued presence of
500 nM tetrodotoxin. Myotube cultures were
homogenized, and equal protein (100 µg) was analyzed as described in
the legend to Figure 1. Data are expressed as percent increase in nPKC
expression in cytosolic plus membrane fractions of experimental
compared with control (CTL) cultures. Each experiment was
performed in triplicate. Error bars represent SEM.
[View Larger Version of this Image (12K GIF file)]
DISCUSSION
We investigated the cellular mechanisms that regulate PKC isoform
expression in rat skeletal muscle. Our study focused on the most
abundant PKC isoforms in skeletal muscle, nPKC and cPKC ,
members of the novel and classic categories of PKC, respectively. Our
previous results demonstrated that nPKC is enriched in skeletal
muscle and is localized to the neuromuscular junction (Hilgenberg and
Miles, 1995). We also showed a progressive increase in skeletal muscle
expression of this isoform during early postnatal development. Based on
these observations, we hypothesized that nPKC plays a role in
maturation of the neuromuscular junction and/or in signal transduction
at this synapse.
To gain insight into the roles that these PKC isoforms play in skeletal
muscle, we first sought to define the cellular mechanisms that regulate
PKC isoform expression. Innervation has been shown to regulate the
expression of numerous proteins in the neuromuscular junction (Brockes
et al., 1975; Trimmer et al., 1990; Valenzuela et al., 1995). To
determine whether innervation of skeletal muscle affects the expression
of PKC isoforms, we denervated rat diaphragm muscle and observed that
expression of nPKC decreased rapidly within the first week after
denervation to early postnatal levels. Expression of nPKC diminished more rapidly than the enhanced expression of nAChRs induced
by denervation of skeletal muscle (Merlie at al., 1984). In contrast,
levels of cPKC increased in denervated diaphragm muscle. Together,
these data suggest that PKC isoform expression is regulated by nerve.
Further support for this hypothesis was obtained by experiments in
which nerve crush, resulting in a transient denervation of muscle, led
to a complete recovery of PKC isoform levels with a time course
consistent with that of reinnervation of skeletal muscle (Valenzuela et
al., 1995). These data indicate that innervation can affect the
expression of individual PKC isoforms in distinct ways, supporting the
idea that PKC and may perform different functions in developing
and adult skeletal muscle.
Denervation deprives skeletal muscle of nerve-evoked contractile
activity and of motor neuron-derived factors that influence muscle
development and maintain trophic interactions between these two tissues
(Grinnell, 1995). To investigate factors that might maintain PKC
isoform levels in skeletal muscle, we examined PKC isoform expression
in rat primary myotube cultures that are not innervated. The
subcellular distributions of cPKC in the cytosolic and nPKC in
the membrane fractions of myotubes were found to be similar to the
subcellular distributions of these two isoforms in adult skeletal
muscle, suggesting that innervation does not play a role in regulating
the subcellular distribution of these enzymes.
PKC isoform expression was examined in cells undergoing differentiation
from myoblasts to myotubes in the absence of nerve. nPKC expression
in myoblasts, at both the protein and the mRNA transcript level, was
significantly below levels seen in adult skeletal muscle, and the
increase in expression that occurred during differentiation suggests
that this process is not sufficient to induce adult skeletal muscle
levels of nPKC . On the other hand, during myogenic differentiation,
increased expression of cPKC , to levels exceeding those in adult
skeletal muscle, suggests that this enzyme may play a role in
myogenesis. Although fibroblasts also express cPKC , the increased
levels of this isoform found in primary myotube cultures could not be
attributed to the presence of fibroblasts or to their proliferation
over the culture period.
The differences seen in PKC and levels in myotubes versus adult
skeletal muscle lead to several hypotheses. PKC isoform expression in
myotubes parallels PKC expression seen after skeletal muscle
denervation and may indicate innervation-dependent regulation of PKC
expression. Although it is possible that nerve-evoked contraction
influences PKC isoform expression, an alternative hypothesis is that
nerve influences PKC and expression in skeletal muscle by
virtue of other interactions.
cPKC levels may rise in denervated skeletal muscle because of the
proliferation of muscle precursor cells (Hess and Rosner, 1970),
similar to the proliferation of myoblasts that occurs in culture. PKC
has been shown to play a role in myoblast fusion (David et al., 1990;
Vaidya et al., 1991), and enhanced PKC activity in the soluble fraction
of myotubes compared with myoblasts has been demonstrated (Adamo et
al., 1989). Perhaps this activity is attributed to cPKC . The
skeletal muscle-specific transcription factor myogenin is a substrate
for PKC, and phosphorylation of myogenin by PKC causes the factor to
lose DNA-binding activity (Olsen, 1992). It is possible that cPKC plays a role in these early myogenic events that occur in the absence
of nerve.
The expression of another skeletal muscle-specific protein kinase has
been shown to be regulated by myogenic differentiation as well as by
electrical activity. Recently, a receptor tyrosine kinase, MuSK, has
been identified by cDNA cloning and revealed to be localized in the
neuromuscular junction (Valenzuela et al., 1995). In contrast to nPKC
, MuSK mRNA transcript levels are highest in embryonic muscle and
are downregulated postnatally in rat skeletal muscle. Similar to cPKC
, MuSK protein expression increases after axotomy or nerve crush and
during differentiation of C2 myoblasts to myotubes. The functional role
of MuSK and the underlying mechanisms regulating its expression in
skeletal muscle have not been completely elucidated.
To examine whether the presence of nerve influences PKC expression in
myotubes, we cocultured differentiated myotubes with NG108-15 cells.
NG108-15 cells form functional cholinergic synapses on myotubes
(Christian et al., 1977), and a factor from these cells promotes nAChR
clustering (Christian et al., 1978). Coculture of myotubes with
NG108-15 cells increases nAChR subunit tyrosine phosphorylation (K. Miles, unpublished observations), a phosphorylation pattern shared by
mature nAChRs in the neuromuscular junction (Qu et al., 1990). NG108-15
cell coculture with myotubes may mimic other events that occur during
synaptogenesis at the neuromuscular junction. Coculture of myotubes
with NG108-15 cells significantly enhanced nPKC protein and mRNA
transcript expression in myotubes. When the two cell populations were
cultured together separated by a porous membrane, the increase in nPKC
expression in myotubes caused by NG108-15 cells appeared to be
dependent on the pore size of the membranes separating myotubes from
NG108-15 cells. This result suggests that cell contact as well as a
diffusible factor(s) might be responsible for changes in nPKC expression. The observation that subcellular membrane fractions from
NG108-15 cells increased nPKC expression in myotubes to the same
extent as NG108-15 cells separated from myotubes by a 0.2 µm filter
supports this hypothesis. That cPKC levels in myotubes were
unaltered by NG108-15 cells suggests that the factor(s) from nerve that
increases PKC isoform expression in skeletal muscle is specific for
nPKC . In addition, these results support the hypothesis that
contact with nerve does not repress cPKC expression in myotubes,
although the possibility that an inhibitory factor is present in
motoneurons and absent from NG108-15 cells has not been eliminated.
Despite the lack of synaptic contact, myotubes in culture are
electrically active and contract spontaneously. Inhibition of
contractile activity by blocking voltage-sensitive sodium channels had
no effect on PKC expression in myotubes. Moreover, subcellular membrane
fractions from NG108-15 cells retained their ability to increase nPKC
expression in electrically silent myotubes, further demonstrating
that the effect of innervation on PKC expression is not likely to be
mediated directly by muscle activity. Rather, the ability of nerve to
contact muscle and increase nPKC expression may be attributable to
another, as yet undefined, transynaptic interaction.
Certain molecules are known to affect gene expression transynaptically
in skeletal muscle. ARIA, a factor belonging to the heregulin family of
proteins, is thought to be synthesized and secreted by motor neurons
into the extracellular matrix (Martinou et al., 1991; Corfas et al.,
1995; Loeb and Fischbach, 1995). ARIA appears to transduce its signal
intracellularly via the erbB family of receptor tyrosine kinases
(Corfas et al., 1995) and increases both nAChR and voltage-sensitive
sodium channel synthesis in myotubes (Corfas and Fischbach, 1993). In
addition, calcitonin gene-related peptide, a neuropeptide present in
motor neuron dense core vesicles (Villar et al., 1988), also increases
nAChR synthesis by raising intracellular cAMP levels (New and Mudge,
1986).
The observation that nPKC expression, but not cPKC ,
increases as a result of contact with a neuronal cell line supports the
hypothesis that nPKC plays a unique role in the neuromuscular
junction. Although specific substrates for nPKC have not yet been
identified, it is likely that ion channels, receptors, protein kinases,
and phosphatases that are concentrated in the neuromuscular junction
are substrates for nPKC . For example, because phorbol ester
activation of PKC in myotubes interrupts ARIA-induced
autophosphorylation on tyrosyl residues of members of the erbB receptor
family (Altiok et al., 1995), it is possible that nPKC is involved
in downregulating the erbB receptors. In addition, nPKC may also be
involved in modulating the signal transduction events initiated by
agrin, as suggested by the evidence that phorbol ester treatment of
myotubes inhibits both nAChR clustering and tyrosine phosphorylation
induced by agrin (Wallace et al., 1991). Perhaps nPKC kinase
activity acts as a negative regulator to balance events associated with
synapse formation and signal transduction at the neuromuscular
junction.
FOOTNOTES
Received March 5, 1996; revised May 29, 1996; accepted May 30, 1996.
This work was supported by U.S. Public Health Service Grant NS29356 to
K.M. We thank Drs. George Ojakian and Michael Wagner for critically
reading this manuscript.
Correspondence should be addressed to Kathryn Miles, Department of
Anatomy and Cell Biology, The State University of New York Health
Science Center at Brooklyn, Brooklyn, NY 11203.
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R. C. Y. Choi, N. L. Siow, A. W. M. Cheng, K. K. Y. Ling, E. K. K. Tung, J. Simon, E. A. Barnard, and K. W. K. Tsim
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R. C. Y. Choi, M. L. S. Man, K. K. Y. Ling, N. Y. Ip, J. Simon, E. A. Barnard, and K. W. K. Tsim
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A. A. Sneddon, M. I. Delday, and C. A. Maltin
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Substance via MeSH
