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Molecular and Cellular Biology, July 2001, p. 4369-4378, Vol. 21, No. 13
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.13.4369-4378.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Complex Functions of AP-1 Transcription Factors in
Differentiation and Survival of PC12 Cells
Sirpa
Leppä,1,2,*
Minna
Eriksson,1
Rainer
Saffrich,3
Wilhelm
Ansorge,3 and
Dirk
Bohmann3,*
European Molecular Biology Laboratory,
D-69117 Heidelberg, Germany,3 and
Haartman Institute, Department of Pathology, FIN-00014
University of Helsinki,1 and Department
of Oncology, Helsinki University Central Hospital, FIN-00029
Huch,2 Finland
Received 10 November 2000/Returned for modification 10 January
2001/Accepted 28 April 2001
 |
ABSTRACT |
c-Jun activation by mitogen-activated protein kinases has been
implicated in various cellular signal responses. We investigated how
JNK and c-Jun contribute to neuronal differentiation, cell survival,
and apoptosis. In differentiated PC12 cells, JNK signaling can induce
apoptosis and c-Jun mediates this response. In contrast, we show that
in PC12 cells that are not yet differentiated, the AP-1 family member
ATF-2 and not c-Jun acts as an executor of apoptosis. In this context
c-Jun expression protects against apoptosis and triggers neurite
formation. Thus, c-Jun has opposite functions before and after neuronal
differentiation. These findings suggest a model in which the balance
between ATF-2 and Jun activity in PC12 cells governs the choice between
differentiation towards a neuronal fate and an apoptotic program.
Further analysis of c-Jun mutants showed that the differentiation
response requires functional dimerization and DNA-binding domains and
that it is stimulated by phosphorylation in the transactivation domain.
In contrast, c-Jun mutants incompetent for DNA binding or dimerization and also mutants lacking JNK binding and phosphorylation sites that
cannot elicit neuronal differentiation efficiently protect PC12 cells
from apoptosis. Hence, the protective role of c-Jun appears to be
mediated by an unconventional mechanism that is separable from its
function as a classical AP-1 transcription factor.
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INTRODUCTION |
Jun NH2-terminal kinases
(JNKs), a subfamily of the stress-activated mitogen-activated protein
kinases (MAPKs), have complex functions in the control of programmed
cell death, or apoptosis. Perhaps best understood is the role of JNK
during neuronal cell death. Targeted mutagenesis experiments in the
mouse have demonstrated the existence of an excitotoxin-induced
signaling pathway that leads, via the activation of JNK-3 (a
neuron-specific form of JNK) and the subsequent phosphorylation of the
transcription factor c-Jun on serines 63 and 73, to the induction of
cell death in hippocampal neurons (reviewed in references 4 and
20). The thus-triggered apoptotic program appears to involve de
novo transcription, activated by phosphorylated c-Jun (1).
The function of c-Jun phosphorylation by JNK as a trigger for neuronal
apoptosis is further supported by a large body of experimental
evidence, obtained in model systems such as PC12 cells or explanted
primary neurons (see below).
The ability of JNKs to mediate cell death is not restricted to neurons.
JNK-deficient (jnk1
/ and
jnk2/) mouse embryonic fibroblasts are
incompetent to undergo apoptosis in response to UV light
(29). Unexpectedly, the primary effect of JNKs as
mediators of UV-induced apoptosis in primary mouse embryonic
fibroblasts appears to involve cytochrome c release from
mitochondria and does not require gene transcription. In a different
paradigm, however
the apoptotic response of 3T3 fibroblasts to DNA
damageJNK instructs cells to commit suicide via transcriptional activation of the Fas ligand CD95-L (16). Evidently, there
are multiple mechanisms by which JNK stimulation can direct cells towards suicide. The complex role of JNK in the control of apoptosis is
further illustrated by the phenotype displayed by JNK 1- and 2-deficient mice (17). As expected based on the
experiments described above, certain apoptotic responses are abolished
in these animals, leading for example to reduced cell degeneration during hindbrain and neural tube formation. In contrast, however, forebrain cells undergo apoptosis much more frequently in
jnk1/ jnk2/ mice
than in wild-type controls. This indicates that, depending on the
biological context, loss of JNK function can lead both to excessive and
to insufficient levels of cell death.
c-Jun, one of the principle mediators of the transcriptional response
to JNK activation, plays an equally enigmatic role in the control of
cell death. c-Jun is a member of the AP-1 family of leucine zipper
transcription factors. It can form DNA-binding homodimers or
heterodimers with other family members such as JunD, c-Fos, and ATF-2
(reviewed in reference 15). Strong evidence identifies
c-Jun as an executor of death signals in neurons and neuronally
differentiated PC12 cells as well as in fibroblasts (16,
29). However, in other biological situations c-Jun acts as an
antiapoptotic factor. During mouse hepatogenesis (1, 6,
12), the presence of c-Jun prevents apoptosis. An antiapoptotic function has also been proposed based on studies with c-Jun-deficient fibroblasts, which became protected against stress-induced apoptosis upon reintroduction of c-Jun by a viral vector (36). The
molecular basis for the dual role of c-Jun in apoptosis is not fully
understood. It may depend on the target gene activated by c-Jun in the
respective cell type. As pointed out above, c-Jun can serve as a
transcriptional activator of the apoptosis-inducing Fas ligand
(16, 19) but also as a repressor of the tumor suppressor
and death agonist p53 (26), depending on the cell type.
To better understand the parameters that determine the specific
response to JNK signaling in the context of cell death, we performed
experiments with PC12 cell cultures, which provide a defined system for
studying differential responses to MAPK signaling. In particular, the
signaling events leading to apoptosis in PC12 cells can be dissected
using various gene transfer and chemical approaches. In response to
nerve growth factor (NGF) treatment, PC12 cells adopt a sympathetic
neuronal phenotype (27). Once differentiated, the cells
become NGF dependent, and removal of the neurotrophin triggers the JNK
signaling cascade and results in apoptosis (37).
Interestingly, c-Jun has been implicated both in neuronal
differentiation in response to NGF and in death upon NGF withdrawal. In
previously published studies, in which neuronally differentiated PC12
cells or sympathetic neurons were used, apoptosis induced by NGF
withdrawal was prevented by dominant-negative mutants or by
microinjected antibodies specific for c-Jun (7, 9, 37). In
addition, expression of an activated form of MEKK1, an upstream
activator of the JNK pathway, or of c-JunAsp, a
pseudophosphorylated and, hence, constitutively active mutant of c-Jun,
was sufficient to trigger apoptosis in cerebellar granule neurons
(34). Reproducing these findings, we observed that
microinjection of differentiated PC12 cells with a plasmid coding for
c-JunAsp reduced PC12 cell survival in comparison to cells
that received c-Junwt or c-JunAla, a mutant
which cannot be phosphorylated by JNK (S. Leppä, unpublished observation). Collectively, these results indicate that activation of
c-Jun causes apoptosis in differentiated PC12 and other neuronal cells.
Undifferentiated cells, however, behave differently. Here, c-JunAsp leads to differentiation and, importantly, has no
adverse effect on cell viability (21). MEKK1 activation,
on the other hand, efficiently triggers apoptosis in both the
differentiated and undifferentiated cells. These findings imply that
the mechanisms regulating apoptosis and the response to c-Jun
activation differ, depending on the differentiation state of the cell.
Here we compare the functions of c-Jun as a mediator of
differentiation, death, and survival. Our findings indicate that these
different responses require different biochemical functions of c-Jun.
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MATERIALS AND METHODS |
Plasmids.
Plasmids for cytomegalovirus (CMV) enhancer-driven
expression of epitope-tagged c-Junwt, c-JunAla,
c-JunAsp, c-Jun
31-57,
c-JunbZIP, c-Jun1-223NLS, and c-Fos mammalian
cells and nuclear 
-galactosidase and a reporter plasmid, 
60/+63
col LUC (see below), have been described (21, 23, 30, 31).
The Renilla luciferase control vector driven by the human
ubiquitin promoter was a gift from Carsten Weiss. CMV enhancer-driven
expression vectors for hemagglutinin (HA)-tagged mutant forms of c-Jun
were constructed by replacing the PstI-HpaI
fragment of c-Junwt with a mutated fragment derived from
pHJ19 MUT series (2). The murine JunD and JunB cDNAs were
provided by M. Yaniv; they were cloned into a CMV enhancer-driven
expression vector, and an HA epitope tag was inserted C terminally. The
constructs for mammalian expression for ATF-2 derivatives were provided
by P. Angel, and the construct for constitutively active MEKK1
(35) was provided by R. J. Davies.
Cell culture, microinjection, and transfections.
Rat
pheochromocytoma PC12 cells were routinely cultured in collagen-coated
dishes in a humidified 7.5% CO2 atmosphere at 37°C in
Dulbecco modified Eagle medium supplemented with 10% horse serum and
5% fetal calf serum. For microinjection, cells were seeded on
laminin-coated plastic plates (20 µg of mouse laminin [Sigma] per
ml) to provide better adhesion and to facilitate neurite outgrowth.
Microinjections were performed using an automated injection system and
a Zeiss inverted microscope. All plasmids were injected into the
nucleus at a concentration of 50 µg of expression vector per ml
unless otherwise stated. A total of 100 to 150 cells were injected per
experiment. Human 293 cells were cultured in a humidified 5%
CO2 atmosphere at 37°C in Dulbecco modified Eagle medium
with 10% fetal calf serum. Transient transfections into PC12 cells and
293 cells were done with Fugene reagent according to the
manufacturer's instructions (Roche).
Immunostaining.
Cells were fixed with 2% paraformaldehyde
in phosphate-buffered saline (PBS), washed with PBS, and permeabilized
with 0.1% Triton X-100 in PBS on ice. Blocking with 1% bovine serum
albumin (BSA) in PBS for 30 min and incubations with primary antibodies in 1% BSA-PBS for 1 h were done at room temperature. Antibodies included a monoclonal antibody (MAb) against -galactosidase
(Promega), a MAb against the HA epitope (clone 12CA5), a MAb against
the myc epitope (clone 9E10), and a polyclonal antibody against
c-Jun (2). After several washes, bound antibodies were
visualized using a fluorescein isothiocyanate (FITC)-conjugated
secondary antibody (Jackson Laboratories) for 1 h at room
temperature. The morphology of the cells was visualized using
tetramethyl rhodamine isothiocyanate (TRITC)-labeled phalloidin
(Sigma). Cells were further washed extensively with PBS, and Hoechst
dye 33258 (Sigma) was included in the last wash to stain the nuclei.
Finally, the cells were mounted under a coverslip using Mowiol. Samples
were examined using a Zeiss LSM410 confocal imaging system. For
quantification of neurite outgrowth, the cells forming neurites longer
than twice the diameter of the cell body were scored as differentiated.
TUNEL (terminal deoxynucleotidyltransferase-mediated dUTP-biotin nick end labeling) staining was performed according to the manufacturer's instructions (Roche). The statistical significance of differences seen
in cell survival and neurite formation assays was analyzed using
Student's t test. All P values were two tailed.
Western blot analysis.
293 cells were lysed directly in
sodium dodecyl sulfate (SDS) sample buffer and sonicated with a
microtipped Branson sonifier. Samples were separated on an SDS-10%
polyacrylamide gel and transferred onto nitrocellulose membranes by
electroblotting. Detection was performed using a MAb against the HA
epitope. Horseradish peroxidase-conjugated secondary antibodies were
purchased from Jackson Laboratories. The blots were developed using an
enhanced chemiluminescence protocol (Amersham).
Luciferase assays.
AP-1 activity was assayed using a
reporter plasmid, 60/+63 col LUC (30). The plasmid
carries a luciferase gene under the control of an AP-1-responsive
element present within a collagenase gene promoter. The activity of
collagenase reporter was normalized to the activity of the control
reporter (Renilla). Dual luciferase assays were performed
according to the manufacturer's instructions (Promega).
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RESULTS |
c-Jun protects undifferentiated PC12 cells from 
MEKK1-induced
apoptosis.
As pointed out in the introduction, the effect of c-Jun
in the control of cell death may vary depending on the biological context. The differentiation state of the cell, for example, may influence whether c-Jun activation causes cell death. To directly examine if and how the consequences of c-Jun and JNK signaling on
apoptosis differ between differentiated and undifferentiated PC12
cells, we undertook microinjection experiments. Consistent with
previous studies (21, 37), deliberate activation of the JNK pathway by microinjection of a plasmid coding for the
signal-independent catalytically active domain of MEKK1 (MEKK1)
induced prominent apoptosis in undifferentiated cells, as characterized
by TUNEL staining (Fig. 1). This response
was accompanied by morphological changes that are characteristic of
apoptosis, including shrinkage of the cell bodies, membrane blebbing,
and disruption of the nuclear membranes (Fig.
2A). At 36 h after
injection with the MEKK1 expression vector, only 5% of the cells
were alive (Fig. 2B), whereas most of the control cells (91%) injected
with an expression vector for a nuclear -galactosidase survived
(Fig. 2B).
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FIG. 1.
c-Jun expression rescues PC12 cells from MEKK-induced
apoptosis. (A) Induction of apoptosis in PC12 cells expressing MEKK.
PC12 cells were transfected with expression vectors for MEKK and
nuclear -galactosidase (-gal). After 24 h, the cells were
fixed and double stained with anti--galactosidase antibody to detect
transfected cells and with TUNEL reagent to mark cells undergoing
apoptosis. Nuclei of cells expressing MEKK appear red (left panel),
and apoptotic cells are visualized in green (middle panel). (B)
Quantification of apoptosis. The percentage of TUNEL-positive cells
among the transfected cells was determined. The data are the means ± standard errors of two separate experiments.
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FIG. 2.
Jun proteins but not ATF-2 rescue PC12 cells from
MEKK-induced apoptosis. (A) Morphology of PC12 cells expressing
MEKK alone or MEKK with increasing concentrations of c-Jun, as
indicated. Nuclear -galactosidase was coexpressed to mark the
injected cells. After 36 h, the cells were fixed and stained with
anti--galactosidase. Injected cells were detected using FITC-labeled
secondary antibodies (green), and the morphology of the cells was
visualized by actin staining (red). Cells were examined by confocal
microscopy. (B and D) Quantification of cell survival. The percentage
of viable cells was determined. In apoptotic cells, -galactosidase
staining is punctate, and the cell bodies have shrunk. (C and E)
Quantitation of neurite outgrowth. The percentage of the cells with
neurites exceeding twice the cell length among the microinjected (FITC
positive) cells is shown. c-Jun, JunB, JunD, and ATF-2 were compared
for their ability to counteract MEKK-induced cell death (D) and to
induce neuronal differentiation (E). The data are the means ± standard errors of two or three separate experiments. Statistically
significant differences from values for MEKK-expressing cells are
indicated as follows: *, P < 0.05; **,
P < 0.01; ***, P < 0.001.
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c-Jun is expressed at very low levels in undifferentiated PC12 cells,
even after activation of the JNK pathway (
21), suggesting
that it may not be involved in the observed apoptotic effect of
MEKK1. To examine whether c-Jun might, nevertheless, be able
to
contribute to
MEKK1-induced apoptosis of undifferentiated
PC12
cells, as it does in differentiated ones, we coinjected expression
plasmids for both c-Jun and
MEKK1. Surprisingly, c-Jun did not
enhance cell death but prevented it in the undifferentiated PC12
cells
(Fig.
1 and
2). This effect was concentration dependent;
even when the
amount of the c-Jun expression vector was decreased
from the standard
concentration of 50 µg/ml in the injection solution
to 2 µg/ml,
cell survival was still significantly increased (
P = 0.005). Suppression of apoptosis by c-Jun expression was
accompanied
by the formation of long neurites from the cell bodies, as
was
previously reported (
21) (Fig.
2A and
C).
The findings described above indicate that c-Jun not only serves as a
differentiation factor but in addition acts antiapoptotically
in
PC12 cells. To investigate whether one or both of these functions
may
be shared by related transcription factors, we tested several
other
members of the AP-1 family for their effects on undifferentiated
PC12
cells (Fig.
2C and D). Among the Jun proteins, JunD acts
very similarly
to c-Jun in that it effectively promotes neurite
outgrowth and prevents
apoptosis when expressed along with
MEKK1.
JunB, on the other hand,
suppresses apoptosis to the same extent
as c-Jun and JunD but is a very
inefficient inducer of neuronal
differentiation. The AP-1 family member
ATF-2 can neither suppress
apoptosis nor drive PC12 cells into neuronal
differentiation.
All AP-1 proteins were expressed at comparable levels,
based on
immunostaining. Two Jun family members, c-Jun and JunD, shared
the ability to induce neuronal differentiation, an activity that
JunB
does not have. However, all three Jun proteins can protect
against
apoptosis. Thus, the capacities to promote differentiation
and to
prevent death are not coupled, suggesting that they might
be mediated
by separable molecular
activities.
The protective effect of c-Jun is independent of JNK binding and
phosphorylation.
JNK activates c-Jun by phosphorylating Ser 63 and
73 and Thr 91 and/or Thr 93 residues in the transactivation domain
(1, 5, 11, 18, 23, 25). Homologous phosphorylation sites are found in JunD yet are absent in JunB (14). Thus, the
presence of these sites correlates with the ability of Jun proteins to induce neuronal differentiation in the previous experiment but not with
the antiapoptotic effect. To directly address the significance of c-Jun
phosphorylation by JNK for the survival function, we expressed MEKK1
along with c-JunAla, in which all the above-mentioned sites
are replaced by alanine residues and which therefore cannot be
phosphorylated by JNK (Fig. 3A). After 36 to 48 h, the numbers of cells which survived and/or differentiated
were scored. We found that the apoptotic effect of MEKK1 was
significantly suppressed by c-JunAla and that this
suppression was quantitatively similar to that obtained with
c-Junwt or c-JunAsp. The latter is a
gain-of-function mutant of c-Jun in which the MAPK phosphorylation
sites are replaced by negatively charged phosphate-mimetic aspartic
acid residues. Thus, the ability of c-Jun to antagonize MEKK-initiated
apoptosis is independent of phosphorylation by JNK (Fig. 3C). In
contrast, MEKK1 expression increased the efficiency of neuronal
differentiation elicited by c-Junwt expression. This was,
presumably, due to phosphorylation of c-Jun by JNK, since the moderate
neurite outgrowth observed after expression of c-JunAla was
not increased when MEKK1 was also introduced into the cells (compare
Fig. 3B and D). We conclude that the function of c-Jun as a survival
factor does not require MAPK phosphorylation, whereas this modification
is important for its role in differentiation.
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FIG. 3.
c-Jun-mediated protection from MEKK-induced apoptosis
is JNK independent. (A) Morphology of cells expressing c-Jun
derivatives and MEKK. PC12 cells were injected with
c-Junwt, c-Jun31-57, c-JunAla,
or c-JunAsp expression vectors in the presence or absence
of MEKK, as indicated. Nuclear -galactosidase was coexpressed to
mark the injected cells. The cells were fixed after 40 h, stained
with anti--galactosidase (green) and TRITC-phalloidin (red), and
examined by confocal microscopy. (B to D) Quantification of cell
survival and neurite outgrowth was performed as for Fig. 1. The data
are means ± standard errors of two or three separate experiments.
Statistically significant differences from values for
MEKK-expressing cells are indicated as follows: *, P < 0.05; **, P < 0.01; ***, P < 0.001. (E) c-Jun31-57 is phosphorylated in
response to MEKK. HA-tagged c-Jun and c-Jun31-57
were expressed alone or with MEKK in 293 cells. Cells were harvested
24 h posttransfection, and whole-cell extracts were analyzed by
SDS-polyacrylamide gel electrophoresis and immunoblotting using anti-HA
antibody.
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With phosphorylation not involved, an alternative explanation for the
protective function of exogenously expressed c-Jun would
be that the
protein titrates out activated JNK. If the escape
from apoptosis caused
by c-Jun expression was simply due to sequestration
of JNK, the
deletion mutant c-Jun
31-57, which lacks the
docking site for the kinase, would be expected
not to rescue PC12 cells
from
MEKK1-induced apoptosis. However,
expression of this
domain-less mutant, along with
MEKK1, prevented
cell death as
effectively as wild-type c-Jun (Fig.
3C). In addition,
prominent
neurite outgrowth was induced (Fig.
3D). In fact, the
deletion mutant
lacking the
domain caused differentiation more
efficiently than
wild-type c-Jun (Fig.
3B). Consistently, the
deletion mutant is a
more potent inducer of AP-1 reporter activity
than c-Jun
wt
(data not shown) (
2). The gain-of-function characteristics
of c-Jun
31-57 are surprising in light of the fact that
this mutant, lacking
the main JNK docking site, was not expected to be
N-terminally
phosphorylated. Interestingly, however, at least under the
experimental
conditions employed, the mutant appeared to be efficiently
phosphorylated
when cotransfected with
MEKK, as judged by SDS-gel
mobility (Fig.
3E). The reason for this effect and the question of how
c-Jun
can be phosphorylated in the absence of a JNK docking site await
experimental clarification. These results indicate that JNK binding
is
not required for the phosphorylation, antiapoptotis, and
differentiation
activities of c-Jun in undifferentiated PC12
cells.
c-Jun can antagonize MEKK-induced cell death independently of DNA
binding and dimerization.
To further investigate the importance of
the distinct functional domains of c-Jun for the antiapoptotic effect,
we tested whether the deletion mutants c-JunbZIP and
c-Jun1-223NLS, which lack transactivation and bZIP
domains, respectively, could prevent MEKK1-induced death of
undifferentiated PC12 cells. The N-terminally truncated mutant,
c-JunbZIP, acts as a dominant interfering mutant of c-Jun,
presumably by sequestering endogenous AP-1 components or by occupying
the AP-1 DNA-binding site. In contrast to the effect of
dominant-negative c-Jun in differentiated PC12 cells, where it
suppresses MEKK1-induced apoptosis (21, 37), the
expression of c-JunbZIP did not have this effect in
undifferentiated PC12 cells (Fig. 4B). This illustrates
further that AP-1 activation does not play a positive role in
mediating apoptosis in the undifferentiated cells.
c-Jun1-223NLS, which includes the transactivation
and JNK-binding domains fused to a simian virus 40 nuclear localization
signal in order to ensure correct localization in the nucleus, was
equally inefficient in preventing apoptosis (Fig. 4B) and in inducing
differentiation (Fig. 4C). These results imply that the general
integrity of c-Jun is required for its ability to antagonize
MEKK1-mediated death and to induce differentiation. However, some
lesions, such as removal of the phosphorylation sites that impair
transcriptional functions and the ability of c-Jun to initiate neuronal
differentiation, do not affect the protective function observed in
undifferentiated PC12 cells. Furthermore, the failure of
c-Jun1-223NLS, which contains all the known
transcriptional activation domains of c-Jun, to rescue cells from
apoptosis indicates that the underlying mechanism is unlikely to result
from "squelching," the competition for transcription coactivators.
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FIG. 4.
c-Jun dimerization and DNA binding are not necessary for
rescue from MEKK-induced apoptosis. (A) Morphology of cells
expressing c-Jun mutants and MEKK. PC12 cells were injected with
expression vectors for MEKK together with c-Junwt or
various c-Jun mutants as indicated. A plasmid coding for nuclear
-galactosidase was coexpressed to mark the injected cells. After
40 h, the cells were fixed, stained with anti--galactosidase and TRITC-phalloidin, and examined by
confocal microscopy. MUT14 (K268I C269D) and MUT22-23 (L294P L308A) are
defective in DNA binding and dimerization, respectively. MUT12 (K254I
A255D) binds DNA poorly as a homodimer but well as a heterodimer with
Fos. MUT17 (K288I A289D) forms slightly more stable homodimers than
wild-type c-Jun. All mutants have been described previously
(2). (B and C) Quantification of cell survival and neurite
outgrowth was performed as for Fig. 1. The data are means ± standard errors of two or three separate experiments. Statistically
significant differences from MEKK-expressing cells are indicated as
follows: *, P < 0.05; **, P < 0.01; ***, P < 0.001. (D) Transcriptional
activation of collagenase reporter by MEKK and c-Jun mutants. PC12
cells were transfected with AP-1-responsive collagenase luciferase
(col-LUC) and a control reporter (Renilla luciferase vector
driven by the human ubiquitin promoter) together with expression
vectors for MEKK and c-Jun mutants, as indicated. The cells were
harvested after 36 h for a dual luciferase assay. The firefly
luciferase activity was normalized against the Renilla
luciferase readings from the cotransfected internal control reporter.
The data are representative of three independent experiments done in
duplicate (means ± standard errors). (E) Morphology of cells
expressing c-Jun and c-Fos. PC12 cells were injected with expression
vectors for c-Jun, c-Fos, or both, as indicated. A plasmid coding for
nuclear -galactosidase was coexpressed to mark the injected cells.
After 40 h, the cells were fixed and stained with
anti--galactosidase and TRITC-phalloidin and examined by confocal
microscopy. (F) Quantification of neurite outgrowth was performed as
for Fig. 1. The data are the means ± standard errors of two or
three separate experiments.
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The results described above indicate that c-Jun's ability to
antagonize MEKK1-induced apoptosis in PC12 cells relies on an
unconventional mechanism. To investigate whether other aspects
of c-Jun
function that are essential for its activity as a transcription
factor
are required for the antiapoptotic effect, we analyzed
a panel of
previously characterized c-Jun mutants in which dimerization
and/or DNA
binding functions are impaired (
2). c-Jun
MUT14
homodimers and even heterodimers of this mutant with wild-type
c-Fos
cannot bind to DNA due to two amino acid substitutions in
the basic
domain. When we tested its transactivation potential
in PC12 cells, we
observed that unlike c-Jun
wt, c-Jun
MUT14 does
not enhance MEKK-induced AP-1 responsive promoter activity
(Fig.
4D).
Consistently, c-Jun
MUT14 cannot drive PC12 cells towards
neuronal differentiation (Fig.
4C). However, the same mutant still
causes significant suppression
of
MEKK1-induced apoptosis (Fig.
4B).
Thus, DNA binding and
12-
O-tetradecanoyl-phorbol-13-acetate-responsive-element-dependent
transactivation are not required for the rescue effect.
c-Jun
MUT12 carries a less severe mutation in the
DNA-binding domain, which
causes a significant decrease of c-Jun's
ability to bind DNA as
a homodimer. This mutant can, however, bind to
AP-1 sites well
when dimerized with c-Fos (D. Bohmann, unpublished
data). Moreover,
it can potentiate the MEKK1-induced reporter activity
in PC12
cells (Fig.
4D). Interestingly, in the microinjection assay,
c-Jun
MUT12 behaves in all respects like the wild-type
protein: it not only
blocks apoptosis but also efficiently induces
neuronal differentiation.
This result suggests that c-Jun acts as a
heterodimer when it
activates the neuronal differentiation. Consistent
with this idea,
coexpression of c-Jun and c-Fos results in more
efficient neuronal
differentiation than the expression of either c-Jun
or c-Fos alone
(Fig.
4E).
Next, we investigated whether dimerization and the integrity of the
leucine zipper are important for protection from death.
Two point
mutations within the leucine zipper of c-Jun
MUT22-23
abolish its ability to homodimerize or heterodimerize with other
AP-1 proteins (
2,
24). Like c-Jun
MUT14, this
form of c-Jun could rescue PC12 cells from apoptosis but
had completely
lost the ability to stimulate neurite formation
(Fig.
4C) and AP-1
transcriptional activity (Fig.
4D). c-Jun
MUT17, which has a
mildly enhancing effect on homodimerization but
not on
heterodimerization with Fos (
2,
28), was also tested.
This
mutation did not, however, affect the activity of c-Jun in
the
differentiation or survival assay. From all the data together,
it
appears that the antiapoptotic function of c-Jun described
here is not
mediated by the conventional AP-1 activity of the
protein, which
involves dimerization, DNA binding, and transcriptional
activation of
target genes. Rather, in this context, c-Jun acts
in a manner
independent of its DNA-binding capacity, possibly
by interacting with
other
proteins.
ATF-2 mediates MEKK-induced apoptosis in undifferentiated PC12
cells.
The results described above indicate that, in contrast to
its previously described role in neuronally differentiated cells, where
c-Jun mediates cell death in response to MEKK activity, it protects
undifferentiated cells from such a fate. This raises the question of
which effector, if not c-Jun, mediates the apoptotic response to MEKK
activation in the undifferentiated state. A potential candidate is the
bZIP protein ATF-2. This transcription factor is phosphorylated and
activated by JNK and thus can mediate MEKK responses (8,
32). Phosphorylated ATF-2 has been detected in rat brain neurons
and PC12 cells upon apoptosis-inducing insults, such as hypoxia or
okadaic acid treatment (33). We tested a potential role of
ATF-2 phosphorylation in death and differentiation of PC12 cells by the
microinjection assay. ATF-2 derivatives, in which the JNK
phosphorylation sites had been mutated, were introduced into PC12 cells
(Fig. 5). After 48 h the numbers of cells
which survived or differentiated were counted. When constitutively active ATF-2 (ATF-2ED) was expressed in PC12 cells, a
decrease in surviving cells (Fig. 5A), and increased apoptosis (Fig.
5C) were observed. In comparison, expression of ATF-2WT
caused a moderate decrease in cell survival, whereas
ATF-2AA, which cannot be phosphorylated by JNK, failed to
induce cell death. Unlike c-JunAsp, none of the ATF-2
derivatives could induce PC12 cell differentiation. Thus, ATF-2
phosphorylation by JNK in response to MEKK signaling triggers apoptosis
of PC12 cells in their undifferentiated state. To investigate whether
ATF-2 might represent the death-inducing principle that is antagonized
by c-Jun, we coexpressed ATF-2ED along with c-Jun
derivatives in undifferentiated PC12 cells. Indeed,
c-JunAsp could partially counteract ATF-2-induced cell
death and push the cells along the alternative path of neuronal
differentiation.
View larger version (24K):
[in this window]
[in a new window]
|
FIG. 5.
Activated ATF-2 induces cell death in PC12 cells. (A and
B) PC12 cells were injected with plasmids encoding ATF-2WT,
ATF-2AA, or ATF-2ED alone or in the presence of
c-JunAsp or MUT22-23, as indicated. Nuclear
-galactosidase was coexpressed to mark the injected cells. (C and D)
PC12 cells were transfected with 0.5 µg of the expression vectors for
c-JunAsp or ATF-2ED per 3-cm dish in the
presence of increasing amounts of ATF-2ED or
c-JunAsp vectors (0, 0.1, 0.5, and 2.5 µg), respectively.
Nuclear -galactosidase was coexpressed. The cells were fixed after
48 h, stained with anti--galactosidase and TRITC-phalloidin,
and examined by confocal microscopy. Quantification of cell survival
and neurite outgrowth was performed as for Fig. 1. For panel C, cells
undergoing apoptosis were identified and quantitated by measuring
nuclear fragmentation with Hoechst staining. The data are the mean
vs ± standard errors of two separate experiments. Statistically
significant differences relative to values for
ATF-2ED-expressing cells are indicated with an asterisk
(P < 0.05).
|
|
To corroborate these results with an alternative experimental approach,
we used transient transfection to express different
amounts of
cJun
Asp and ATF-2
ED in undifferentiated PC12
cells (Fig.
5C and D). This titration
experiment shows a
dosage-dependent effect of ATF-2 in the induction
of apoptosis and of
c-Jun in antiapoptosis and the induction of
neuronal differentiation.
These results indicate that the balance
between ATF-2 and c-Jun is
important in determining the PC12 cell
responses. The suppression of
the ATF-2
ED-induced apoptosis could also be observed when
the nondimerizing
c-Jun mutant MUT22-23 was employed. However, this
c-Jun mutant
could not trigger the differentiation program. Evidently,
c-Jun
can suppress the ATF-2-mediated apoptosis with same
characteristics
as when it antagonizes
MEKK.
| |
DISCUSSION |
The biological program that is initiated upon exposure of
undifferentiated PC12 cells to NGF encompasses the cessation of proliferation, the suppression of apoptosis, and the triggering of
neuronal differentiation. We have previously demonstrated that c-Jun
can mediate the differentiation effects of NGF (21). Here we show that a further aspect of the NGF response, namely, survival, is
supported by c-Jun (Fig. 6). In its
capacity as a differentiation factor, c-Jun seems to work like a
conventional AP-1 transcription factor, since functional DNA-binding,
dimerization, and transactivation domains are all necessary for neurite
formation. In addition, phosphorylation of the MAPK target residues, as
induced by NGF treatment (21), enhances the
differentiation response as well as transcriptional activation of an
AP-1 reporter, whereas a dominant interfering mutant inhibits both of
these functions.
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|
FIG. 6.
Multiple functions of c-Jun in the control of apoptosis
and neuronal differentiation. c-Jun prevents undifferentiated PC12
cells from undergoing MEKK1- and ATF-2-mediated apoptosis and promotes
their neuronal differentiation. The first function does not require
dimerization, DNA binding, or MAPK phosphorylation, whereas the latter
appears to be a conventional AP-1 effect stimulated by ERK. Once
differentiated, PC12 cells react to AP-1 activation through the JNK
pathway by initiating apoptosis.
|
|
It is worth noting that obliteration of the JNK-docking site by removal
of the domain generates a gain-of-function mutant for neuronal
differentiation. Interestingly, the deletion, as found in v-Jun,
also increases the transforming potential of the protein
(3). Perhaps in cell transformation, a process in which c-Jun has been found to cooperate with oncogenic Ras (13,
22), and in NGF-dependent differentiation of PC12 cells, which
is also thought to be mediated by Ras, c-Jun acts in a comparable manner.
In its second guise, c-Jun acts antiapoptotically and interferes with
MEKK-induced cell death when PC12 cells are not yet neuronally
differentiated. For this effect, several canonical functions of c-Jun
as an AP-1 transcription factor are not essential. A physical
interaction with other leucine zipper proteins and with JNK and even a
direct contact to DNA appear not to be required for c-Jun to help
undifferentiated PC12 cells survive MEKK1 activation. Furthermore,
dominant-negative forms of the protein cannot suppress the
antiapoptotic function of c-Jun. This novel activity of c-Jun is shared
by its close relatives JunD and JunB. In a paper on a similar topic,
Le-Nicolescu and colleagues reported that activation of JNK in a PC12
cell line in which MEKK1 can be inducibly expressed from a stably
transfected vector causes apoptosis irrespective of the differentiation
state (19), i.e., they did not observe the protective
function of c-Jun described here. This may be due to the modified PC12
line used in this study. The basal levels of JNK activity present in
these cells before induction might create a milieu resembling in some
respect that of differentiated cells, where c-Jun activation leads to
cell death. As the study presented here used de novo introduction of
Jun and MEKK proteins in naïve PC12 cells, this situation was avoided.
The nonconventional mechanism by which c-Jun, JunB, and JunD bring
about the rescue function remains a matter of speculation at this
point. Our experiments identify the AP-1 family member ATF-2 as an
agonist of cell death in undifferentiated PC12 cells. A dominant
activated form of ATF-2 can mimic the effect of deliberate JNK
activation and induce apoptosis. As in the case of MEKK1-induced cell
death, this effect can be suppressed by coexpression of c-Jun. Interestingly, c-Jun appears to counteract ATF-2-and MEKK1-mediated death by the same unconventional mechanism that does not require dimerization or DNA binding. This makes a simple model where c-Jun would modulate ATF-2 function by direct contact unlikely. An indirect effect, such as competition for cofactors, may be an alternative explanation, even though the inability of the isolated transactivation region to inhibit apoptosis appears to argue against a classical squelching mechanism. We speculate that balance between ATF-2 and Jun
activities in the differentiation-competent PC12 cells will be an
important factor in the decision between the alternative fates of
neuronal differentiation and death.
Our experiments implicate Jun proteins in the control of two opposing
programs in neuronal cells as they can either cause cell
differentiation and survival or initiate programmed cell death. Studies
in primary neurons suffering axotomy yielded related results. Herdegen
and colleagues described two alternative neuronal fates after axon
transection, regeneration, or apoptosis (10). Interestingly, it was found that elevated c-Jun levels and c-Jun phosphorylation are involved in both of these responses. This indicates
that the mechanism described here is not a peculiarity of the PC12 cell
system but reflects a physiological regulatory phenomenon in the brain.
Neuronal differentiation and apoptosis are phenomena of major medical
significance, and it is of central interest to control the underlying
regulatory events by pharmacological intervention, for example, after
brain injury or stroke or during neurodegenerative diseases. The
finding that c-Jun can be an effector of several apparently opposing
functions (death, survival, and differentiation) may sound
disheartening at first, as it suggests that interference with c-Jun
function may be have effects too pleiotropic to be therapeutically
useful. However, if the survival function of c-Jun is mediated by a
mechanism distinct from the apoptotic effect, selective interference
with one or the other phenomenon may be possible and beneficial.
| |
ACKNOWLEDGMENTS |
We thank P. Angel, R. J. Davis, S. Gutkind, M. Treier, M. Yaniv, C. Weiss, and J. Woodgett for expression plasmids. J. Westermarck, C. Weiss, and C. Ovitt are acknowledged for helpful
comments on the manuscript.
S.L. is supported by fellowships from the Academy of Finland, The
Finnish Cancer Society, and The Helsinki Biocentrum.
| |
FOOTNOTES |
*
Corresponding author. Mailing address for Sirpa
Leppä: Molecular and Cancer Biology Program, Biomedicum Helsinki,
P.O. Box 63 (Haartmaninkatu 8), FIN-00014 Helsingin Yliopisto, Finland. Phone: 358 9 19125606. Fax: 358 9 19125554. E-mail:
sirpa.leppa{at}helsinki.fi. Present address for Dirk Bohmann:
Center for Cancer Biology, Aab Institute of Biomedical Sciences,
University of Rochester School of Medicine and Dentistry, 601 Elmwood
Ave., Box 633, Rochester, NY 14642. Phone: (716) 273-1446. Fax:
(716) 273-1450. E-mail: Dirk _Bohmann{at}urmc.rochester.edu.
| |
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Molecular and Cellular Biology, July 2001, p. 4369-4378, Vol. 21, No. 13
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.13.4369-4378.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Top
Abstract
Introduction
