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Mol Cell Biol, June 1998, p. 3257-3265, Vol. 18, No. 6
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Basal Extracellular Signal-Regulated Kinase
Activity Modulates Cell-Cell and Cell-Matrix Interactions
Qun
Lu,
Mercedes
Paredes,
Jimin
Zhang, and
Kenneth S.
Kosik*
Received 24 October 1997/Returned for modification 8 December
1997/Accepted 16 March 1998
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ABSTRACT |
Suppression of the basal extracellular signal-regulated kinase
(ERK) activity in PC12 cells markedly altered their phenotype. Wild-type cells grew in a dissociated pattern adherent to the substrate. The stable expression of an ERK inhibitory mutant resulted in the formation of calcium-dependent aggregates which were less adherent to the substrate. Concomitantly, the cells reorganized their
actin cytoskeleton and increased their expression of several adherens
junction proteins, particularly cadherin. Metabolic labeling demonstrated an increased synthesis of cadherin and 
-catenin in
these cells. Nontransfected PC12 cells and a
ras-transformed MDCK cell line also formed aggregates and
increased their expression of adherens junction proteins following
treatment with the selective MEK inhibitor PD98059. A peptide
containing the HAV cadherin recognition sequence attenuated the
aggregation. These studies suggest that in PC12 and epithelial cells,
ERKs are pivotally positioned to enhance substrate interactions when
active or to release homotypic interactions when suppressed.
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INTRODUCTION |
To achieve the complexity of
multicellularity, organisms must strike a highly regulated balance
between cell-cell interactions, such as the adherens junction, and
interactions with the substrate, such as adhesion plaques. Although
first described as morphological entities, many of the individual
molecules within various cellular contacts have been identified
(18, 22), and some of the components involved in adhesive
interactions, such as -catenin, also function in signaling systems
that control early development and differentiation. The necessity to
generate diverse types of junctions on individual cells must require
highly intertwined signaling cascades that can readily modulate
responses between various pathways. In situ cells engage in both
homotypic contacts with other cells and interactions with the
substrate; however, for most adherent cells in culture, focal adhesions
and interactions with the substrate predominate. The formation of
adherens junctions and the expression of those proteins which reside in
these junctions, the cadherins and catenins, are associated with the
transition of cell populations from a dispersed pattern to an
aggregated compact one.
The mitogen-activated protein (MAP) kinases integrate multiple
intracellular signals following activation by a variety of external
signals. The extracellular signal-regulated kinases (ERKs) are the most
highly studied members of the MAP kinase family, which in mammalian
cells also includes the JNK/SAPK and p38/RK subfamilies
(10). The ERK subfamily is defined by dual phosphorylation on the TEY motif in domain VIII (1). These kinases lie
downstream in a highly conserved signal transduction cascade that
begins with ligand binding to a receptor tyrosine kinase or a G
protein-coupled receptor (23). The ERKs exert control over
cellular proliferation (41, 43) and morphological
transformation (41) by phosphorylating both nuclear and
cytoplasmic substrates, including the transcription factors
elk-1/p62TCF (19, 26, 49), c-jun
(3, 37), c-myc (3), NF-IL6 (33), and TAL1 (12), as well as RNA polymerase II
(15), and the cytoplasmic substrates pp90rsk
(13, 44), cytosolic phospholipase A2, stathmin
(25), epidermal growth factor (EGF) receptor (34,
46), Raf-1 (4, 24), and MAP kinase kinase
(27). The cascade of regulatory molecules involved in the
attachment of cells to the substrate can lead to the activation of ERKs
(11, 30, 40). Signaling via integrin receptors, which
includes the activation of ERKs as one of many downstream elements
(28), plays an important role in the formation of substrate
interactions. On the other hand, little is known regarding the
relationship of ERK signal transduction to cell-cell adhesion.
We prepared stable PC12 cell lines in which both the basal activity of
the ERKs and their activity after nerve growth factor (NGF) stimulation
were inhibited. These cells had a markedly altered phenotype: they
developed cell-cell contacts, became less adherent to the substrate,
reorganized their actin filaments, and increased expression of proteins
found in adherens junctions. We conclude that the maintenance of
substrate interactions in preference to cell-cell contacts requires a
basal level of ERK activity.
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MATERIALS AND METHODS |
Materials.
p42 MAP kinase (ERK2) cDNAs were from M. Cobb
(Dallas, Tex.). The mammalian expression vector pRc/CMV was from
Invitrogen (San Diego, Calif.). The lipofectin transfection kit was
from GIBCO (Grand Island, N.Y.). Flag antibodies were obtained from Eastman Kodak (New Haven, Conn.) and Santa Cruz Biotech (Santa Cruz,
Calif.). Affinity-purified polyclonal anti-MAP kinases were from Santa
Cruz Biotech, and anti-phosphorylated MAP kinase was a gift from M. Greenberg (Boston, Mass.). Monoclonal antibodies against 
-, -,
and 
-catenins, 1 and 3 integrins, and paxillin were from
Transduction Laboratories (Lexington, Ky.). Monoclonal anti-integrin
3A3 was a gift from D. Turner (Syracuse, N.Y.). Monoclonal and
polyclonal antibodies against the carboxyl terminus of chick
N-cadherins as well as monoclonal anti-E-cadherin (DECMA-1) were from
Sigma (St. Louis, Mo.). Rhodamine phalloidin was from Molecular Probes
(Eugene, Oreg.). [-32P]ATP and
[35S]methionine were from Amersham (Arlington Heights,
Ill.), and unless otherwise indicated, all chemicals were from Sigma.
Subcloning and transfection.
The cloning and mutagenesis of
ERK2 were described previously (8, 39). The product was then
subcloned into pRc/CMV (Invitrogen), and the flag sequence DYKDDDDK was
fused to the amino-terminal end as an epitope tag. The primary
structure of p42 flag-ERK2 and the mutation sites were validated by DNA
sequencing. Transfections of PC12 cells were performed in accordance
with the GIBCO instructions for the lipofectin transfection assay. The
stable PC12 cells were selected and maintained in medium containing
neomycin.
Cell cultures and immunohistochemistry.
PC12 cells were
plated onto Nunc culture dishes with a Nunclon 
-treated surface
(Fisher Scientific, Pittsburgh, Pa.), and they were maintained in
Dulbecco's modified Eagle medium (DMEM) with 10% horse serum and 5%
fetal bovine serum. For some experiments, the dishes were coated with
rat tail type I collagen (Becton Dickinson, Bedford, Mass.) to confirm
the growth characteristics. For those cells which were stimulated with
100 ng of NGF per ml to study PC12 cell differentiation, the culture
dishes were coated with polylysine. Neurite outgrowth was scored when
the length of the processes exceeded the cell diameter. Ras-transformed
MDCKf3 cells were grown in DMEM with 10% fetal bovine serum
(5). Cells used for fluorescence studies were fixed in 4%
paraformaldehyde and permeabilized with 0.2% Triton X-100. Following
staining, the cells were mounted and photographed with a Zeiss
Axioskope equipped with epifluorescence.
Aggregation/reaggregation assays and suspension cultures.
To
assess the calcium dependence of cell aggregation, extracellular
calcium was depleted by adding 5 mM EDTA to the culture medium.
Reaggregation was assessed after the cells were returned to normal
calcium-containing medium for 1, 3, 7, 10, and 21 days. To study the
aggregation properties of nontransfected PC12 cells, spinner cultures
with magnetic flasks (Bellco Biotech, Vineland, N.J.) were prepared.
The MEK inhibitor PD98059 (>95% pure as determined by a
high-performance liquid chromatograph [New England Biolabs, Beverly,
Mass.]) was dissolved in dimethylsulfoxide and stored at 25 mM as
stock. Control cultures were treated simply with 0.1% dimethyl
sulfoxide. PD98059 at a concentration of 25 µM was included in the
medium for 2 days before cell lysis. Similar experiments with PD98059
were performed on MDCKf3 cells.
To test whether the aggregation of PC12 cells in suspension is mediated
by cadherin, the synthetic decapeptide LRAHAVDVNG-amide (Peninsula Lab,
Belmont, Calif.) was used in control or PD98059-treated PC12 cells.
Before transferring the PC12 cells to spinner flasks, the peptide was
incubated in culture medium for 30 min. Afterward, the PC12 cells were
returned to the incubator for 2 days in the presence or absence of the
peptide. The cells were then photographed with a Leitz inverted light
microscope.
Protein kinase assay.
Stable PC12 cells were lysed in
immunoprecipitation buffer (10 mM Tris [pH 7.4], 50 mM NaCl, 1 mM
EDTA, 1 mM EGTA, 0.2% Nonidet P-40, 0.1% deoxycholate) containing
protease and phosphatase inhibitors (1 mM phenylmethylsulfonyl
fluoride, 1 mM benzamidine, 10 µg of aprotinin per ml, 10 µg of
pepstatin A per ml, 10 µg of leupeptin per ml, 1 mM sodium
orthovanadate, 10 mM sodium pyrophosphate, 20 mM sodium fluoride). The
cell lysates were centrifuged to remove cell debris, and the
supernatants were immunoprecipitated with affinity-purified antibodies.
To assay for total ERK activity, the cell lysates were
immunoprecipitated with polyclonal anti-MAP kinase C16 and polyclonal
anti-flag D8 was used to immunoprecipitate flag-ERK kinase only. The
immunoprecipitates were captured by protein A-agarose and incubated
with myelin basic protein in the presence of 150 µM ATP and 1 to 2 µCi of [-32P]ATP. After 30 min of incubation, the
samples were then resolved by sodium dodecyl sulfate-15%
polyacrylamide gel electrophoresis (SDS-15% PAGE) and exposed to
Kodak film.
Metabolic labeling.
PC12 cells were preincubated in labeling
medium (DMEM-fetal bovine serum minus methionine) for 20 min. The
medium was then removed, and 800 µCi of [35S]methionine
was added to the cells in a total volume of 4 ml of labeling medium in
10-cm dishes. After the cells were labeled for several time points,
they were rinsed and then solubilized in a mixture containing 50 mM
NaCl, 10 mM PIPES
[piperazine-N,N'-bis(2-ethanesulfonic acid); pH
6.8], 3 mM MgCl2, 0.5% Triton X-100, 300 mM sucrose, 1.2 mM phenylmethylsulfonyl fluoride, and 10 µg of leupeptin per ml for
20 min at 4°C on a rocking platform. The cells were scraped off from
the dishes and centrifuged in a microcentrifuge for 10 min to collect
both the supernatant (Triton-soluble fraction) and the pellet
(Triton-insoluble fraction).
Immunoprecipitation.
Before incubation with primary
antibody, cell lysates (soluble and insoluble fractions) were
precleared with protein G plus protein A-agarose beads followed by
centrifugation to remove the beads. The supernatants were then
immunoprecipitated with the respective cadherin or catenin antibody for
1 h at 4°C. Thirty microliters of protein G plus protein
A-agarose beads was added to the samples for an additional 2 h at
4°C. The samples were washed sequentially with immunoprecipitation
buffer (15 mM Tris [pH 7.5], 5 mM EDTA, 2.5 mM EGTA, 1% Triton
X-100, 1% Na deoxycholate, 0.1% SDS, 120 mM NaCl, 25 mM KCl),
high-salt buffer (15 mM Tris [pH 7.5], 5 mM EDTA, 2.5 mM EGTA, 1%
Triton X-100, 1% Na deoxycholate, 0.1% SDS, and 1 M NaCl), and a
low-salt buffer (15 mM Tris [pH 7.5], 5 mM EDTA). Immunoprecipitates
were separated by SDS-PAGE and transferred to polyvinylidene difluoride
for immunoblotting.
The stable PC12 cells were lysed as described above. Thirty micrograms
of total protein was loaded and resolved by SDS-10%
PAGE. Proteins
transferred to a polyvinylidene difluoride membrane
were blotted and
then developed by using the Amersham enhanced
chemiluminescence system.
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RESULTS |
Phenotype induced by the expression of an ERK
inhibitory mutant (p42YF185) in PC12 cells.
A mutant
ERK2, p42YF185, in which tyrosine 185 was replaced with phenylalanine
in kinase subdomain VIII, was fused to a flag sequence and subcloned
into pRc/CMV. The substitution of the tyrosine within the TEY motif is
believed to function as a dominant negative by binding to the upstream
kinase, MEK, and preventing it from phosphorylating all of the ERK
isoforms (35). The flag sequence can be detected
specifically with monoclonal antibody M5 or polyclonal antibody D8.
Wild-type ERK2, designated p42wt, was subcloned in the same way.
Studies utilizing these stable transfectants were done with independent
isolates of p42YF185 and p42wt. Immunoblots demonstrated the stable
expression of flagged constructs in the PC12 cells (Fig.
1). Although the mock-transfected PC12
cells remained isolated and rounded in culture (Fig.
2A), PC12 cells expressing the inhibitory
mutant p42YF185 formed large aggregates and did not adhere well to the
culture dishes (Fig. 2D). On culture dishes coated with collagen, these
cells grew as clusters and remained aggregated when they were
triturated for passage. In contrast, PC12 cells that overexpressed
p42wt became flatter and were more adherent to the culture dishes (Fig.
2G).
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FIG. 1.
Expression of p42 flag-ERK in PC12 cells. (A)
Immunoblots of lysates taken from representative stable PC12 clones
expressing the p42wt or p42YF185 mutant labeled with anti-MAP kinase
(Erk2); (B) immunoblots of lysates taken from representative stable
PC12 clones expressing the p42wt or p42YF185 mutant labeled with
anti-flag (M5 monoclonal antibody). Molecular weight markers (in
thousands) are indicated to the left of the immunoblots.
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FIG. 2.
Morphology and growth characteristics of stable PC12
transfectants expressing p42 ERK2. (A to C) Mock-transfected PC12
cells; (D to F) PC12 cells transfected with p42YF185, the mutant ERK2
in which tyrosine 185 was mutated to phenylalanine; (G to I) PC12 cells
transfected with p42wt. (A, D, and G) Unstimulated PC12 cells; (B, C,
E, F, H, and I) PC12 cells stimulated with NGF for 4 days; (C, F, and
I) PC12 cells labeled with rhodamine phalloidin to stain F-actin.
Arrowheads indicate processes where F-actin is concentrated in
mock-transfected cells and p42wt-transfected PC12 cells. A honeycomb
pattern indicates that actin extends uniformly around the periphery of
cells transfected with p42YF185. Bars, 24 µm.
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To determine whether the transfections altered ERK activity, myelin
basic protein (MBP) was used as a substrate for the kinase
immunoprecipitated from total cell extracts with either an anti-flag
or
an anti-ERK antibody (Fig.
3 and
4A to D). Compared to control
mock-transfected cells, which have a low, but clearly detectable,
basal
ERK activity that rapidly increases after NGF treatment,
the
flag-p42YF185 mutant had reduced basal activity (Fig.
3A).
Densitometric analysis showed approximately 50% lower basal ERK
activity in p42YF185-transfected cells than in mock-transfected
cells
and more than 90% lower activity in p42YF185-transfected
cells than in
p42wt-transfected cells (Fig.
3B). p42YF185 cells
also visibly failed
to differentiate after NGF stimulation (Fig.
2E). In addition, the
flag-p42YF185 mutant had a minimal response
to NGF stimulation in
comparison to control mock-transfected cells
(Fig.
4A to D).
NGF-stimulated ERK activity peaked at 5 min, and
we found that p42YF185
cells followed a similar time course as
the control and p42wt cells did
but with reduced activity at each
time point tested (data not shown).
The inhibition of flag-ERK
activity in the flag-p42YF185 cells was
confirmed in a kinase
immunocomplex assay using anti-flag
immunoprecipitates (data not
shown). Transfection of flag-p42wt
resulted in increased basal
ERK activity in PC12 cells (Fig.
3), but,
compared to control
PC12 cells, p42wt-transfected cells did not show a
significantly
higher ERK activity in response to NGF stimulation (Fig.
4A and
B). However, p42wt cells displayed a more sustained activation
after NGF treatment that lasted for several days (Fig.
4C and
D).
Although these cells did not spontaneously develop long processes,
they
did elaborate stubby protrusions (Fig.
2G) that were focally
reactive
for F-actin. Upon NGF stimulation, p42wt cells formed
neurites in less
than 1 day, whereas control PC12 cells required
3 to 4 days to attain a
similar degree of differentiation (compare
Fig.
2G to I with Fig.
2A to
C). After NGF stimulation for 6 days,
ERK activity returned to
near-basal levels in control PC12 cells,
remained high in p42wt cells,
and dropped below basal levels in
p42YF185 cells (Fig.
4C and D).
Similar changes were observed
when ERK activity was examined with an
anti-phosphorylated ERK
antibody (Fig.
4E).
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FIG. 3.
Assay for basal MAP kinase (ERK) activity in PC12
transfectants. (A) Basal ERK activity is altered in PC12 cells
transfected with ERK cDNAs. (Upper panel) Basal activity of total ERK
in transfected PC12 cells as measured by immunoprecipitation and
incubation with MBP and [-32P]ATP. (Lower panel) ERK
immunoblot showing equal amounts of immunoprecipitated ERK. (B)
Quantification of ERK activity in p42YF185 cells, mock-transfected
cells, and p42wt cells. The values are means ± standard errors of
the means from three experiments.
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FIG. 4.
Assay for MAP kinase (ERK) activity in PC12
transfectants stimulated with NGF. (A) Activity of total ERK in
transfected PC12 cells treated with NGF for 45 min. It is important to
note the inhibition of ERK activity by p42YF185. (B) Quantification of
ERK activity in p42YF185 cells, mock-transfected cells, and p42wt
cells. The values are means ± standard errors of the means from
three experiments. (C) ERK activity is sustained in PC12 cells
expressing p42wt but not in those expressing p42YF185. After 6 days in
NGF, cell lysates were immunoprecipitated with anti-MAP kinase and
incubated with MBP and [-32P]ATP. (D) Quantification
of ERK activity in p42YF185 cells, mock-transfected cells, and p42wt
cells. The values are means ± standard errors of the means from
two experiments. (E) After 6 days in NGF, cell lysates were
immunoblotted with affinity-purified polyclonal antibody against
phosphorylated ERK. Similar to the results in panel C, there is
sustained activation of ERK in PC12 cells expressing p42wt but not
p42YF185.
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Induction of reorganized actin filaments and adherens junction
proteins in p42YF185 cells.
To understand the basis for the
observed phenotypic change in the p42YF185 stable transfectants, actin
filaments were labeled with rhodamine phalloidin. In control
mock-transfected PC12 cells and p42wt cells, actin filaments were not
uniformly distributed around the periphery; instead, they were most
concentrated within lamellipodia, and particularly within their distal
microspikes (Fig. 2C and I). However, actin filaments in p42YF185 cells
were arranged uniformly along the cell-cell boundaries, reminiscent of
adherens junctions seen among epithelial cell contacts (Fig. 2F).
Consistent with the presence of adherens junctions, cadherin staining
was evident at the periphery of PC12 cells expressing p42YF185 (Fig.
5A) while in control cells there was a
weak, diffuse cadherin staining in the cytoplasm (Fig. 5C). Markers of
focal adhesions such as 11 integrin were only weakly detectable
in PC12 cells (Fig. 5D) and did not localize to the cell-cell contact region in p42YF185 cells (Fig. 5B).
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FIG. 5.
Anti-N-cadherin (A and C) and anti-1-integrin (B and
D) immunofluorescence staining of p42YF185 (A and B) and
mock-transfected (C and D) cells. Bar, 30 µM.
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As suggested by the immunofluorescence studies, cadherin levels
detected by a monoclonal antibody against N-cadherin were
markedly
increased in p42YF185 compared to those of control mock-transfected
cells and p42wt cells (Fig.
6A). The
levels of the cytoplasmic
cadherin-binding proteins
-,
-, and
-catenin (Fig.
6A) were
also increased. On the other hand, proteins
involved in focal
adhesion and integrin function, such as
1 and
3
integrin, showed
no major alterations in expression (Fig.
6B), although
the levels
of
1 integrin and paxillin did appear to decrease
slightly in
the p42YF185 cells (Fig.
6B). p42wt cells that overexpress
ERK2
had focal collections of actin filaments at the plasma membrane
as
did the mock-transfected control cells (Fig.
2C and I), and
the
expression of cadherin and the catenins was suppressed even
relative to
that of the control cells (Fig.
6A).
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FIG. 6.
Immunoblots (IB) of cell lysates from representative
stable PC12 clones expressing p42wt and the inhibitory p42YF185 mutant.
(A) Adherens junction protein expression is markedly enhanced.
Immunoblots show that monoclonal anti--catenin labels a 102-kDa
protein in p42YF185 cells more strongly than in p42wt cells; monoclonal
anti--catenin specifically labels a 92-kDa protein in p42YF185 cells
and minimally detects the same-molecular-weight protein in p42wt cells;
monoclonal anti--catenin specifically labels an 83-kDa protein in
p42YF185 cells but only weakly labels the protein in p42wt cells;
monoclonal antibody against N-cadherin specifically labels a 120-kDa
protein in p42YF185 cells but not in p42wt cells. In all cases, the
control cells show an intermediate degree of labeling. (B) Focal
adhesion protein expression is only minimally affected by altered ERK
expression. Immunoblots show that monoclonal anti-1 integrin
strongly labels a doublet protein at ~130 kDa; monoclonal anti-3
integrin strongly labels a 90-kDa protein with two relatively weaker
bands in all clones; monoclonal anti-paxillin antibody specifically
stains a 70-kDa protein in all clones.
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The aggregation of p42YF185 cells is inhibited by low calcium.
Because adherens junctions are calcium sensitive (47), we
sought to test whether the maintenance of p42YF185 cell aggregates depended on Ca2+ levels. Trituration in DMEM containing 1.8 mM Ca2+ readily dissociated control PC12 cells, but this
same treatment failed to dissociate the p42YF185 cells (Fig.
7A). However, addition of 5 mM EDTA to
p42YF185 cell aggregates resulted in the rapid dissociation of the
cells (Fig. 7B).
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FIG. 7.
Aggregation-reaggregation properties of PC12 cells with
suppressed ERK activity. (A and B) p42YF185 cell aggregation is calcium
dependent. Phase images of p42YF185 cells triturated in DMEM containing
1.8 mM Ca2+ (A) or 5 mM EDTA (B) for 20 min are shown. Bar,
35 µM. (C and D) Reaggregation of p42YF185 cells. p42YF185 cells (C)
and mock-transfected PC12 cells (D) were dissociated in culture medium
containing both trypsin and EDTA. They were then returned to the
incubator and cultured in standard calcium-containing medium for 2 weeks. Reaggregation was apparent after 2 to 3 days, and by 10 days,
the cells formed large aggregates. (E and F) PC12 cell aggregation in
suspension is mediated through the cadherin pathway. Aggregates of PC12
cells were grown in suspension in the presence of PD98059 (E). PC12
cell aggregation was substantially reduced when similarly grown cells
were incubated with 1 mg of the cadherin cell adhesion recognition
peptide LRAHAVDVNG per ml (F). Bar, 30 µM.
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Reaggregation assays of wild-type PC12 cells were complicated by the
fact that, unlike CHO cells, the PC12 cells spontaneously
formed
aggregates when dissociated from culture dishes and grown
in suspension
as spinner cultures. However, in contrast to p42YF185
cells, aggregates
of wild-type PC12 cells in suspension were dissociable
with trituration
and were not accompanied by increased cadherin
levels (data not shown).
When p42YF185 cells were dissociated
in EDTA, replating them in
calcium-containing buffer induced the
reaggregation of the p42YF185
cells (Fig.
7C). Reaggregation was
apparent after 2 to 3 days, and by
10 days, the cells formed large
aggregates. Mock-transfected PC12 cells
did not aggregate (Fig.
7D).
MEK inhibitor PD98059 enhanced cadherin expression of native PC12
cells in suspension culture and in ras-transformed MDCKf3
cells.
To demonstrate that the formation of adherens junctions and
increased cadherin levels were not an artifact of transfection, native
PC12 cells grown in suspension were treated with PD98059, a selective
synthetic MEK inhibitor (16). At 25 µM, a concentration capable of inhibiting the ERKs in vitro and in vivo (2),
PD98059 inhibited the phosphorylation of the ERKs in NGF-stimulated
PC12 cells (Fig. 8A). Incubation of PC12
cells grown in suspension with 25 µM PD98059 enhanced cadherin (Fig.
8B) and -catenin levels but not 1 integrin expression (data not
shown). This effect was most apparent when the cells were grown in
suspension; treatment with PD98059 was less effective on cells attached
to culture dishes. These data supported the finding in the transfected
cells that suppression of basal ERK activity releases the expression of
adherens junction proteins.
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FIG. 8.
Effects of the MEK inhibitor PD98059 on nontransfected
PC12 cells. (A) PD98059 inhibits NGF-induced ERK activity. Blots with
anti-phosphorylated ERK demonstrate immunoreactivity in control cells
but not in PD98059-treated cells. (B) Immunoblot of suspended PC12 cell
culture stained with monoclonal antibody against N-cadherin. Compared
to control cells, PD98059-treated cells have increased N-cadherin
immunoreactivity. WB, Western blot.
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The synthetic decapeptide which contains the tripeptide HAV, a sequence
common to all cadherins, blocks cadherin-mediated
interactions
(
7). A 1-mg/ml concentration of the peptide LRAHAVDVNG
was
incubated with PD98059-treated cells in spinner culture for
2 days. The
peptide significantly reduced the numbers of aggregates
(Fig.
7E and
F), while incubation with an unrelated protein did
not (data not
shown). These results demonstrated that the aggregation
properties of
ERK-suppressed PC12 cells are mediated through cadherin.
To demonstrate that this mechanism was not limited to PC12 cells, we
treated MDCKf3 cells with PD98059. MDCKf3 cells are a
ras-transformed MDCK cell line that displays a fibroblastic
phenotype,
does not aggregate, and has diminished E-cadherin-mediated
cell-cell
adhesion (
5). Incubation of MDCKf3 cells with
25 µM PD98059
reversed the phenotype of these cells from a
fibroblastic to an
epithelial morphology and led to the reexpression of
E-cadherin
at the cell-cell junction (data not shown). These data
strongly
support the conclusion that the inhibition of basal MAP kinase
activity releases the expression of proteins involved in adherens
junction formation.
p42YF185 cells have increased levels of cadherin and -catenin
synthesis and increased levels of -catenin associated with
cadherin-containing complexes.
The increased levels of adherens
junction proteins when ERK was suppressed may be due to increased
synthesis or decreased degradation. p42YF185 cells versus control
mock-transfected PC12 cells were metabolically labeled with
[35S]methionine, lysed, and immunoprecipitated with an
N-cadherin antibody or -catenin antibody (Fig.
9A). Among the immunoprecipitated proteins, those bands representing N-cadherin and -catenin were identified by immunoblotting the radiolabeled gel. In comparison to
epithelial cells, the relatively low synthesis rates of the cadherins
and -catenin in PC12 cells required longer periods of labeling.
After 4 h of labeling, there was no significant difference in the
levels of newly synthesized cadherin between p42YF185 cells and control
cells; however, by 22 h, there was approximately three times more
cadherin in the p42YF185 cells (Fig. 9B). The level of newly
synthesized -catenin was also higher in p42YF185 cells than in
control cells (data not shown). Thus, increased synthesis contributes
to the increased levels of adherens junction proteins in p42YF185
cells. The rather long half-lives of these proteins in PC12 cells
compared to MDCK cells made it difficult to assess the contribution of
turnover in pulse-chase experiments. Semiquantitative support for the
observation of increased synthesis in the p42YF185 cells was derived
from reverse transcription-PCR analysis where, after 25 cycles, the
levels of both N-cadherin and -catenin PCR products were higher in
the p42YF185 cells than in the control cells (data not shown).
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FIG. 9.
Metabolic labeling demonstrates that N-cadherin
synthesis is increased in p42YF185 cells compared to that in
mock-transfected cells. (A) N-cadherin was immunoprecipitated from cell
lysates, separated by SDS-PAGE, and visualized by autoradiography. (B)
The relative amounts of newly synthesized N-cadherin in control versus
p42YF185 cells were quantified. O.D., optical density.
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-Catenin is present in cells in at least two pools: one associated
with cadherin in the adherens junctions and a soluble
pool which lies
in the Wnt pathway. We wanted to determine whether
the increased
-catenin in the p42YF185 cells was present in the
pool associated
with adherens junctions. First,
-catenin levels
were determined in
Triton X-100-soluble and -insoluble pools.
Relative to the control
cells, p42YF185 cells showed an increase
in the level of
-catenin
recovered by immunoprecipitation in
both the insoluble pool and the
soluble pool (Fig.
10A). N-cadherin
antibody was then used for coimmunoprecipitations from p42YF185
cells;
higher levels of
-catenin were recovered in the cadherin
complex
than from immunoprecipitations from control cells (Fig.
10B).
Therefore, at least a portion of the increased
-catenin
was
associated with cadherins and Triton-insoluble actin cytoskeletons
in
p42YF185 cells.
View larger version (24K):
[in this window]
[in a new window]
|
FIG. 10.
-Catenin in p42YF185 cells is associated with
adherens junctions. (A) The level of -catenin in both Triton
X-100-soluble (TXs) and -insoluble pools (TXi) was higher in p42YF185
cells than in mock-transfected cells. Samples were immunoprecipitated
with mouse monoclonal antibody to -catenin and immunoblotted with
-catenin antibody. (B) The level of -catenin pool associated with
cadherin is higher in p42YF185 cells than in mock-transfected control
cells. Samples were immunoprecipitated (IP) with a polyclonal antibody
against N-cadherin and immunoblotted (IB) with anti--catenin. The
cell lysates were prepared as described in Materials and Methods. The
amounts of -catenin which remained in the supernatant (sup) of
control and p42YF185 cells after the cadherin complex was pelleted were
approximately equal.
|
|
| |
DISCUSSION |
We have provided evidence that markers for homotypic interactions
found in adherens junctions, such as cadherins and catenins, were
upregulated when ERKs were inhibited in unstimulated PC12 cells.
Concomitantly, these cells formed calcium-dependent cell aggregates and
reorganized their actin filaments. Conversely, the overexpression of
ERK2 resulted in the reduced expression of both cadherins and catenins.
We suppressed basal ERK activity by using several independent
experimental conditions. Confirmation of our observations that the
phenotypic alterations arose from changes in ERK activity came from (i)
the replication of the findings for independent clones from different
transfections; (ii) the induction of a distinct and, in some senses,
opposite phenotype after wild-type ERK transfection; (iii) the absence
of changes after control vector transfections; and (iv) the induction
of a similar expression pattern of adherens junction proteins when the
ERKs were inhibited by the MEK inhibitor PD98059. Furthermore, repeated
passages of the p42YF185 mutants resulted in a gradual disassembly of
the aggregates as the cells lost the transfected plasmid and the
expression of the mutant kinase decreased as monitored on immunoblots.
The conclusion that upregulation of adherens junction proteins can
occur by the inhibition of basal ERK activity also applies to an
epithelially derived cell line, the MDCKf3 cells.
Many signaling systems converge upon members of the MAP kinase family,
enzymes whose effects are highly dependent upon the degree and duration
of their activity as well as their localization. The data here show the
requirement for a basal level of ERK activity to maintain PC12 cells in
a dissociated state adherent to the substrate. Unstimulated PC12 cells
have a low basal ERK activity, and much of this constitutively active
pool of ERKs is associated with the microtubules (31). How
might the suppression of the ERKs result in the induction of homotypic
interactions? It is possible that effectors in the ERK pathway also
suppress homotypic adhesive interactions that are released in a default
manner when ERK activity falls below a certain level. Alternatively,
the regulation of homotypic and substrate adhesive interactions may
operate with distinct sets of intermediates that would allow the cell
to engage effectors in these pathways in parallel.
The serum response element (SRE), which mediates immediate-early gene
expression, is one target of the ERK signal transduction pathway
(19, 21, 26); however, the expression of immediate-early genes is not a prominent feature of unstimulated PC12 cells. Therefore, basal ERK activity may not be sufficient to activate these genes, but
cytoplasmic substrates of the ERKs may be affected by basal ERK
activity. Among these substrates is pp90rsk
(13, 44), which partially suppresses GSK-3 (17,
45). GSK-3 is also inhibited by the Wg-Wnt signal
(14), which stabilizes -catenin and in PC12 cells
increases the expression of adherens junction proteins (9).
Because GSK-3 is positioned at a point where it could modulate
signals between the MAP kinase and the Wg-Wnt pathways, changes in its
activity may contribute to the observed phenotypic effects.
Cell culture is an artifactual condition which allows substrate
interactions to predominate, and in PC12 cells, one pathway that may
maintain basal ERK activity could be that initiated by the integrins.
In 3T3 or REF52 fibroblasts, MAP kinase is activated and translocates
to the nucleus when the cells adhere to integrin ligands such as
fibronectin or laminin (11). This pathway involves the
creation of multiple SH2 binding sites on FAK, and, in particular, the
binding of GRB2 leads to the formation of signaling complexes which
promote the activation of the Ras signaling pathway (40). Although proteins involved in focal adhesions such as 1 and 3 integrin and paxillin showed minimal changes in expression levels (Fig.
6B) in the p42YF185 cells, the ability of these molecules to trigger
ERK activation was probably blunted. Therefore, the ability to sustain
substrate interactions may require more than the presence of focal
adhesion components in cells, namely, the activation of the MAP kinase
pathway and possibly an undetected alteration in the functional state
of focal adhesion components. Also notable was the detection of a
similar basal ERK activity even when the cells were grown in
suspension, suggesting that integrin-mediated pathways arising from
substrate interactions are not exclusively responsible for maintaining
basal ERK activity.
Two completely independent ways of suppressing ERK activity both
resulted in the increased expression of adherens junctions proteins,
and in the p42YF185 cells, there was increased synthesis of cadherins
and -catenin. The more prolonged half-lives of these molecules in
PC12 cells did not allow us to determine whether stabilization of the
adherens junction proteins also occurred. Regulation of the cadherins
involves a multifactorial array of mechanisms (38), and the
cadherin levels themselves serve as one regulatory control over catenin
expression. For example, L cells contain significant levels of a
102-kDa catenin mRNA, but only after transfection with E-, N-, or
P-cadherin did significant quantities of protein appear
(32). The interaction of -catenin and the Tcf-Lef family
of transcription factors (6, 20, 29) may also lead to
altered expression patterns of gene products involved in the formation
of adherens junctions. Alternatively, the ERKs may directly regulate
catenins via the multiple potential ERK phosphorylation sites in
catenin family proteins.
PC12 cells may be able to regulate the levels of adherens junction
proteins via stimulation of the Wnt signaling pathway. Wnt-1 expression
in PC12 cells leads to an increased expression of -catenin and
E-cadherin and increased calcium-dependent cell-cell adhesion
(9). Following NGF stimulation, these cells do not undergo
tyrosine phosphorylation of the p44 (ERK1) and p42 (ERK2) MAP kinases
(48) or neurite extension (42). They also fail to
induce the neuronal marker SCG10 (42), a protein related to
stathmin, which is a downstream cytoplasmic substrate of MAP kinase
(36). To implement a repertoire of cellular behaviors that
leads to homotypic interactions, it may be necessary to suppress the
ERKs. Suppression of the ERKs in PC12 cells leads to a phenotypic conversion in which homotypic interactions predominate. Basal ERK
activity may be one of the key factors which establishes a set point to
balance homotypic and substrate interactions.
| |
ACKNOWLEDGMENTS |
This work was supported by NIH grants.
We thank M. Cobb for providing p42 (ERK2) MAP kinase cDNAs, M. Greenberg for polyclonal anti-phosphorylated ERK, D. Turner for
monoclonal anti-integrin, M. Medina for the reverse transcription-PCR, and J. Collard for MDCKf3 cells.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Center for
Neurologic Diseases, Brigham and Women's Hospital, Dept. of Neurology,
Harvard Medical School, 77 Avenue Louis Pasteur, Boston, MA 02115. Phone: (617) 525-5230. Fax: (617) 525-5252. E-mail:
Kosik{at}CND.BWH.Harvard.edu.
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Abstract
Introduction
