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Previous Article | Next Article 
Molecular and Cellular Biology, March 2000, p. 1713-1722, Vol. 20, No. 5
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Inhibition of c-Jun N-Terminal Kinase 2 Expression
Suppresses Growth and Induces Apoptosis of Human Tumor Cells in a
p53-Dependent Manner
Olga
Potapova,1
Myriam
Gorospe,1
Ryan H.
Dougherty,1
Nicholas M.
Dean,2
William A.
Gaarde,2 and
Nikki J.
Holbrook1,*
Cell Stress and Aging Section, Laboratory of
Biological Chemistry, National Institute on Aging, National Institutes
of Health, Baltimore, Maryland 21224,1 and
Isis Pharmaceuticals, Inc., Carlsbad, California
920082
Received 7 July 1999/Returned for modification 11 August
1999/Accepted 10 November 1999
 |
ABSTRACT |
c-Jun N-terminal kinase (JNK) plays a critical role in coordinating
the cellular response to stress and has been implicated in regulating
cell growth and transformation. To investigate the growth-regulatory
functions of JNK1 and JNK2, we used specific antisense oligonucleotides
(AS) to inhibit their expression. A survey of several human tumor cell
lines revealed that JNKAS treatment markedly inhibited the growth of
cells with mutant p53 status but not that of cells with normal p53
function. To further examine the influence of p53 on cell sensitivity
to JNKAS treatment, we compared the responsiveness of RKO, MCF-7, and
HCT116 cells with normal p53 function to that of RKO E6, MCF-7 E6, and
HCT116 p53
/, which were rendered p53 deficient by
different methods. Inhibition of JNK2 (and to a lesser extent JNK1)
expression dramatically reduced the growth of p53-deficient cells but
not that of their normal counterparts. JNK2AS-induced growth inhibition
was correlated with significant apoptosis. JNK2AS treatment induced the
expression of the cyclin-dependent kinase inhibitor
p21Cip1/Waf1 in parental MCF-7, RKO, and HCT116
cells but not in the p53-deficient derivatives. That
p21Cip1/Waf1 expression contributes to the
survival of JNK2AS-treated cells was supported by additional
experiments demonstrating that p21Cip1/Waf1
deficiency in HCT116 cells also results in heightened sensitivity to
JNKAS treatment. Our results indicate that perturbation of JNK2
expression adversely affects the growth of otherwise nonstressed cells.
p53 and its downstream effector p21Cip1/Waf1
are important in counteracting these detrimental effects and promoting
cell survival.
| |
INTRODUCTION |
The c-Jun N-terminal kinase (JNK)
signal transduction pathway, culminating in the phosphorylation of one
or more JNK proteins, is known to play an important role in
coordinating the cellular response to stress (25, 34). The
JNK family includes three genes, JNK1, JNK2, and
JNK3, each of which can produce 46- and 54-kDa isoforms
(25). JNK1 and JNK2 are ubiquitously
expressed, while JNK3 is largely restricted to brain, heart
and testis (25, 28, 35). Although some differences in the
substrate specificities and activities of various JNK isoforms have
been reported (5, 9, 13, 20, 26, 44), their functional
distinctions remain unclear. Among the major targets of JNK
phosphorylation are the transcription factor c-Jun (12, 22,
29) and the tumor suppressor protein p53 (24, 32).
Numerous studies have implicated both JNK activation and c-Jun
phosphorylation in the induction of apoptosis following stress
(27). However, an opposing function of the JNK pathway has
also been suggested by other studies, including two recent reports
which demonstrate that JNK-mediated phosphorylation of c-Jun confers
protection to cells exposed to UVC irradiation or tumor necrosis factor
alpha (3, 42).
In addition to playing a role during stress, there is also evidence to
support a role for the JNK pathway in regulating cell growth. While the
basal activity of JNK is generally low in cells maintained under normal
growth conditions, JNK can be activated by growth factors such as
epidermal growth factor and platelet-derived growth factor via
mechanisms that appear to rely on phosphoinositide 3-kinase (2, 4,
30, 31, 33). It has long been appreciated that c-Jun promotes
proliferation (1), and both cells lacking c-Jun and cells
expressing its nonphosphorylatable dominant negative counterpart,
c-Jun(Ser63A,Ser73A), display well-defined growth defects
(3, 42). Another study has provided evidence suggesting that
c-Jun controls cell cycle progression in a p53-dependent manner
(41). The JNK pathway has also been implicated in the transformation of pre-B cells by Brc-Abl and in the
transformation of fibroblasts by the Met oncogene (36,
37). In addition, both epidermal growth factor-dependent
proliferation and anchorage-independent growth of A549 cells can be
prevented by either stable expression of c-Jun(Ser63A,Ser73A) or
addition of JNK antisense oligonucleotides (JNKAS) (4, 5).
While most of the effects of JNK described above have been attributed
to its phosphorylated state, it has recently become apparent that
nonphosphorylated JNK (which lacks kinase activity) also contributes to
the regulation of its substrates. In contrast to activated JNK,
which serves to stabilize and enhance the transcriptional activity of
its substrates, nonphosphorylated JNK appears to lead to ubiquitination
and degradation of its substrates (14-16). Thus, both
inactive and active JNK are likely to play a role in regulating a
variety of cell processes including growth, apoptosis, and transformation.
To investigate the role of JNK in regulating tumor cell growth, we have
used highly specific JNKAS to inhibit the expression of JNK1
and JNK2 (4, 5, 43). A preliminary survey of
several different cell lines revealed that JNKAS treatment had little or no effect on the growth of most of the cell lines examined, but
three cell lines displayed marked growth inhibition in response to such
treatments (Table 1). Interestingly, the
growth-inhibitory response to JNKAS treatment appeared to correlate
with the p53 status of the cell, in that suppression of growth occurred
only in cells harboring mutations in p53 (6; O. Potapova, M. Gorospe, F. Bost, N. M. Dean, R. McKay, S. A. Kim, D. Mercola, and N. J. Holbrook, submitted for publication;
our unpublished observations). The present study was designed to
further investigate the possibility that p53 directly influences the
response of tumor cells to JNKAS treatment. To this end, we have used
derivatives of MCF-7 and RKO cells, in which p53 function was abrogated
through expression of the viral E6 oncoprotein (38), and
HCT116 p53/ cells, where the p53 gene was
disrupted through homologous recombination (8). We
demonstrate that loss of p53 function in these cells results in growth
inhibition and apoptosis following JNKAS treatment and provide
additional evidence indicating that the inability to elevate
p21Cip1/Waf1 levels contributes to the enhanced
sensitivity of p53-deficient cells to JNKAS. Our findings support an
important role for the JNK pathway in maintenance of normal tumor cell
growth in the absence of p53 function and suggest the utility of
strategies aimed at eliminating JNK for the treatment of tumors
harboring mutant p53.
| |
MATERIALS AND METHODS |
Cells and reagents.
Human breast carcinoma MCF-7 neo and
MCF-7 E6 cells, a gift from A. J. Fornace, were cultured in RPMI
1640 (Life Technologies, Bethesda, Md.). Human colorectal carcinoma RKO
neo and RKO E6 cells, a gift from M. Kastan, were cultured in minimal
essential medium (Life Technologies, Bethesda, Md.). HCT116 and their
p21/ and p53/ derivatives (8,
41), a gift from B. Vogelstein, were grown in McCoy's 5A medium
(Biofluids, Rockville, Md.). The media were supplemented with 10%
fetal calf serum (HyClone Laboratories, Logan, Utah), nonessential
amino acids, and antibiotics.
Oligonucleotide synthesis, treatment, and confocal
microscopy.
The oligonucleotides used in this study were
synthesized at Isis Pharmaceuticals, Inc. (Carlsbad, Calif.). The
sequences of the oligonucleotides used are as follows: JNK1AS
(ISIS12539), 5'-CTC TCT GTA GGC CCG CTT GG-3'; JNK2AS (ISIS 12560),
5'-GTC CGG GCC AGG CCA AAG TC-3'; JNK1Scr (ISIS14321), 5'-CTT TCC GTT GGA CCC CTG GG-3'; and JNK2Scr (ISIS14319), 5'-GTG CGC GCG AGC CCG AAA
TC-3' (4). All oligonucleotides were
2'-O-methoxyethyl chimers containing five
2'-O-methoxyethyl-phosphodiester residues flanking a
2'-deoxynucleotide-phosphorothioate region (43). Cells were
treated with 0.3 µM oligonucleotides in the presence of 10 µg of
Lipofectin reagent (Life Technologies, Bethesda, Md.) per ml as
described previously (11). To determine the efficiency of
the oligonucleotide transfection into MCF-7 and RKO cells, a
fluorescein isothiocyanate (FITC)-labeled phosphorothioate control oligonucleotide, ISIS13193 (5'-TCC CGC CTG TGA CAT GCA TT-3'), was
used. At the indicated times following lipofection with the FITC-labeled oligonucleotide, the cells were fixed in 3.7%
formaldehyde and images were taken using a Carl Zeiss LSM 410 confocal
microscope (488-nm laser wavelength; ×40/1.3 magnification; pinhole
size, 20 nm).
Analysis of mRNA and protein expression.
Total RNA was
isolated using Stat-60 solution (Tel-Test, Friendswood, Tex.). RNA
samples (20 µg) were denatured, size separated by electrophoresis in
1.2% agarose-formaldehyde gels, and transferred onto GeneScreen Plus
membranes (DuPont NEN Research Products, Boston, Mass.). For the
detection of JNK1 and JNK2 mRNAs, the respective
cDNAs were excised from 3xHA-JNK1-SR
3 and 1xHA-JNK2-SR3 and
labeled with [-32P]dATP using a random primer labeling
kit (Boehringer Mannheim, Indianapolis, Ind.). Expression of
p21Cip1/Waf1 was detected by hybridization with
an 46-base oligonucleotide specific for human
p21Cip1/Waf1 (Integrated DNA Technologies,
Coralville, Iowa). Variations in loading and transfer among samples
were monitored by hybridizing to a 29-base oligonucleotide
complementary to 18S RNA (Clontech, Palo Alto, Calif.). Hybridization
and washes were performed by the Church and Gilbert method
(10), and radioactive signals were quantified by using a
PhosphorImager (Molecular Dynamics, Sunnyvale, Calif.).
For Western analysis, total protein was extracted using whole-cell
extract buffer (5) and the protein concentration was quantified by the Bradford assay. Protein samples (25 to 50 µg) were
separated in by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (12% polyacrylamide) and transferred onto
polyvinylidene difluoride membranes (Millipore, Bedford, Mass.). JNK
proteins were identified using C-571 anti-JNK primary antibodies (Santa Cruz Biotechnology, Santa Cruz, Calif.), and reactive bands were visualized using the enhanced chemiluminescence detection system (NEN
Life Science Products, Boston, Mass.).
In vitro JNK activity assay.
Cells were irradiated with UVC
at 40 J/m2 24 h following the lipofection; 30 min
later they were washed with cold phosphate-buffered saline and
suspended in whole-cell extract (WCE) buffer (5). The JNK
assay was performed with a fusion protein containing glutathione S-transferase (GST) linked to the 1-222 fragment of human
c-Jun (GST-cJun) as substrate, as described previously (22).
Briefly, 50-µg portions of cell lysates were incubated for 3 h
at 4°C with 10 µg of GST-cJun bound to glutathione-Sepharose 4B
(Pharmacia Biotech, Uppsala, Sweden). After being washed three times in
WCE buffer (5) and once in kinase reaction buffer (20 mM
HEPES [pH 7.7], 20 mM MgCl2, 20 mM -glycerophosphate,
20 mM p-nitrophenyl phosphate, 0.1 mM sodium vanadate, 2 mM
dithiothreitol), the beads were incubated for 30 min at 30°C with 30 µl of kinase reaction buffer containing 20 µM ATP and 5 µCi of
[
-32P]ATP. The reaction was stopped by the addition of
Laemmli sample buffer, and samples were boiled for 5 min and resolved
by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (12%
polyacrylamide). The [32P]GST-cJun was quantified with a PhosphorImager.
Cell viability assays.
Cells were seeded in 96-well cluster
plates at a density of 15 × 103 cells/well and
transfected with AS oligonucleotides as described above. At the
designated times, viable cell mass was measured by detection of
3-(4,5-dimethylthiazol - 2 - yl) - 5 - (3 - carboxymethoxyphenyl) - 2 - (4 - sulfophenyl) - 2H - tetrazolium,
inner salt (MTS) dye reduction at 490 nm as described in the
manufacturer's protocol (Promega, Madison, Wis.). All viability assays
were carried out in triplicate.
Apoptosis detection and flow cytometry analysis.
Apoptosis
was assessed using a cell death detection enzyme-linked immunosorbent
assay (ELISA) (Boehringer Mannheim, Indianapolis, Ind.) as specified by
the manufacturer. Oligonucleosomal fragments, released from the nuclei
after internucleosomal degradation of genomic DNA, were detected in
cytoplasmic fractions of 2,000 cells. For cell cycle analysis, cells
were collected 24 h following treatment, fixed in 70% ethanol,
and stained with 1 µg of propidium iodide (Cellular DNA flow
cytometric analysis kit; Boehringer Mannheim) per ml. The DNA content
was analyzed on FACScalibur flow cytometer (Becton Dickinson, San Jose,
Calif.). The percentages of cells in various phases of the cell cycle
were determined using Becton Dickinson ModFitLT software.
| |
RESULTS |
Specific inhibition of JNK expression by JNKAS.
To verify
that the lipofection procedure used here resulted in
high-efficiency oligonucleotide uptake in MCF-7 and RKO cells, the
control FITC-labeled phosphorothioate oligonucleotide ISIS13193 was used. Shown in Fig. 1 is green
fluorescence, visualized 24 h after lipofection with 0.4 µM
ISIS13193. Virtually 100% of cells showed uptake of the transfected
oligonucleotide. Similar results were obtained at the 12- and 48-h time
points and over an extended dose-response range (0.1 to 0.5 µM
oligonucleotide). Mock-lipofected cells did not excite any fluorescent
signal (data not shown). No differences in the efficiency of
oligonucleotide uptake were seen between p53-deficient (E6-expressing)
and p53-proficient (expressing a neo-containing vector control) cells.
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FIG. 1.
MCF-7 and RKO cells display high-efficiency uptake of
oligonucleotides delivered via transfection with Lipofectin reagent.
Cells were treated with 0.3 µM 3' FITC-labeled control
oligonucleotide as described in Materials and Methods. Twenty-four
hours later, they were fixed and examined for fluorescence with a
confocal microscope. Images were obtained at a magnification of ×800.
(Left) Confocal fluorescent images of transfected cells. (Right)
Confocal transparent images of the same fields. Virtually all cells
show uptake of the oligonucleotides, irrespective of p53 status.
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Next, we investigated the effect of JNK1AS and JNK2AS on JNK
expression in MCF-7 and RKO cells. Cells were treated either with 0.3 µM JNK1AS or JNK2AS individually or with JNK1AS and JNK2AS in
combination (0.15 µM each). Scrambled-sequence oligonucleotides (JNK1Scr and JNK2Scr) were used at the same concentrations and served
as controls. Both AS treatments led to >95% reduction in the
corresponding mRNA levels (Fig. 2A),
while neither mock lipofection nor treatment with scrambled
oligonucleotides had any effect on JNK1 or JNK2
mRNA expression.
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FIG. 2.
JNKAS treatment effectively inhibits JNK
expression in MCF-7 and RKO cells regardless of p53 status. (A) Total
RNA was extracted from cells 24 h following treatment with 0.3 µM JNK1AS, JNK2AS, or control oligonucleotides (JNKScr). RNA samples
were analyzed by Northern analysis using cDNA probes specific for
JNK1 and JNK2 mRNAs. (B) Whole-cell lysates were
examined by Western analysis for JNK expression 24 h following
treatment with JNKAS oligonucleotides. (C) Total Jun kinase activity
was determined 30 min following exposure to UVC (40 J/m2)
by an in vitro kinase assay using GST-cJun(1-222) as a substrate. At
24 h prior to UVC treatment, cells were transfected with
combinations of JNK1AS plus JNK2AS (0.15 µM each) or JNK1Scr plus
JNK2Scr (0.15 µM each) (labeled JNKAS and JNKScr, respectively).
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Western analysis of JNK protein expression revealed a corresponding
reduction in the level of JNK protein in JNKAS-treated cells (Fig. 2B).
Since differential splicing of both JNK1 and JNK2
mRNAs results in the production of 46- and 54-kDa isoforms and since
there is significant cross-reactivity between the available JNK1 and
JNK2 antibodies, we cannot distinguish with certainty between the JNK1
and JNK2 isoforms. However, based on our observations and those of
others, it appears that the slower-migrating proteins (p54JNK) are composed primarily of JNK2 isoforms
whereas the faster-migrating forms (p46JNK)
contain mostly JNK1 (25). Hence, JNK1AS was more effective in eliminating the p46JNK isoform while JNK2AS
was more effective in eliminating the p54JNK
form (Fig. 2B).
An immunocomplex kinase assay was used to examine basal and
UVC-induced JNK activity in mock-, JNKAS- and JNKScr-treated
cells (Fig. 2C). No significant JNK activity was detectable in any of the treatment groups of either wild-type or p53-deficient MCF-7 and RKO
cells in the absence of stress. Consistent with the reduction in JNK
protein levels, UVC-induced JNK activation was markedly reduced in both
wild-type and p53-deficient MCF-7 and RKO cells treated with a
combination of JNK1AS and JNK2AS (Fig. 2C, JNKAS). Neither mock
lipofection nor treatment with scrambled oligonucleotides affected the
JNK kinase activity.
Taken together, the experiments described above demonstrate that, using
JNKAS, we can effectively achieve a significant reduction in
JNK expression and therefore directly investigate the roles of JNK1 and JNK2 in regulating the growth of p53-proficient and p53-deficient MCF-7 and RKO cells.
Growth inhibition by JNKAS is dependent on p53 status.
Growth
of untreated and JNKAS-treated cells was monitored using an MTS dye
reduction assay. JNKAS treatment had little to no effect on the growth
of wild-type (neo) MCF-7 and RKO cells (Fig.
3). A small transient reduction in the
growth of JNK2AS-treated MCF-7 cells was apparent at 24 to 48 h
following lipofection, but the viable cell mass did not differ from
that of control cultures by 72 h posttreatment. No significant
effect on growth was observed in wild-type RKO cells with any
treatment. In contrast, p53-deficient derivatives (E6) of both MCF-7
and RKO cells displayed a marked reduction in cell viability following
treatment with JNKAS; the growth-inhibitory effect was greater for
JNK2AS than for JNK1AS. Growth suppression by JNK2AS was most
pronounced in p53-deficient RKO cells, where viability was reduced
>70% by 48 h following treatment with the oligonucleotide.
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FIG. 3.
Effect of JNKAS treatment on the viability of
p53-proficient and p53-deficient MCF-7 and RKO cells. Cells were seeded
in 96-well cluster plates and treated with 0.3 µM oligonucleotides in
Lipofectin reagent (JNKScr designates treatment with 0.15 µM JNK1Scr
plus 0.15 µM JNK2Scr). Cell viability was assessed at the indicated
times by measuring MTS dye in a colorimetric assay as described in
Materials and Methods.
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Inhibition of JNK2 expression results in apoptosis of p53-deficient
cells.
To determine the cause of the decline in growth of
JNKAS-treated cell populations, we first examined whether DNA synthesis was altered after application of JNKAS. We observed no differences in
bromodeoxyuridine (BrdU) incorporation relative to the number of viable
cells among any of the treatment groups (data not shown); therefore,
the reduction in growth of p53-deficient cells could not be explained
by an inhibition of DNA replication. Next we tested the possibility
that the decrease in cell number reflected selective death in
JNKAS-treated cultures. Shown in Fig. 4
is the morphology of parental and p53-deficient MCF-7 and RKO cells with or without JNKAS treatment. The p53-deficient (E6) lines treated
with JNK2AS revealed features consistent with apoptosis, including cell
rounding, membrane blebbing, and detachment from the tissue culture
dish (Fig. 4). These effects were also evident to some degree in
JNK1AS-treated cultures but were completely absent in p53-deficient
cells subjected to either mock treatment or treatment with scrambled
oligonucleotides. They were also absent in p53-proficient (neo) cells
regardless of treatment.
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FIG. 4.
Morphological appearance of JNK2AS-treated MCF-7 and RKO
cells with normal (neo) or deficient (E6) p53 function. Cells treated
with 0.3 µM of the indicated oligonucleotides were examined by
optical microscopy 24 h after lipofection. Cultures that were
subjected to either mock lipofection or treatment with scrambled
oligonucleotides (the same as described in the legend to Fig. 3) had
morphologies similar to those seen in untreated control cultures. The
density of JNKAS-treated E6-expressing MCF-7 and RKO cells is lower
than that of the neo-expressing counterparts. JNK2AS-treated
p53-deficient (E6-expressing) cells exhibit membrane blebbing and an
increase in the number of rounded and/or detached cells.
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Biochemical evidence of apoptosis in the p53-deficient cells was
obtained using an ELISA for detection of cytoplasmic histone-associated DNA fragments (Fig. 5). Both
E6-expressing MCF-7 and RKO lines exhibited significant induction of
apoptosis 24 h following JNK2AS treatment. In this assay, we also
observed some evidence of DNA degradation in JNK2AS-treated RKO neo
cells as well as in RKO E6 cells treated with JNK1AS, but
quantitatively it was not nearly as great as that seen in
JNK2AS-treated RKO E6 cells.
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FIG. 5.
Biochemical evidence of DNA degradation in p53-deficient
cells treated with JNKAS. Apoptosis of p53-proficient (neo) and
p53-deficient (E6) MCF-7 and RKO cells was assessed 24 h after
treatment with 0.3 µM JNKAS or control oligonucleotides using an
ELISA that measures nucleosomal degradation. JNKScr depicts results for
treatments with equal amounts of JNK1Scr plus JNK2Scr (0.15 µM each).
Results are expressed as relative absorption (OD) at 405 nm.
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Consistent with the biochemical analysis, fluorescence-activated cell
sorter (FACS) analysis of RKO E6 cells as early as 24 h after
treatment revealed the presence of a sub-G1 cell population in cultures treated with JNK2AS alone or with JNK1AS and JNK2AS in
combination (Fig. 6). No
sub-G1 peak was evident in RKO E6 cells subjected to any of
the control treatments or in the RKO neo cells regardless of treatment.
The number of apoptotic cells in JNK2AS-treated RKO E6 cultures further
increased with time, and by 48 h posttreatment had reached 14%
(data not shown). Taken together, these experiments indicate that
JNK2AS treatment results in apoptosis of p53-deficient MCF-7 and RKO
cells, thus largely accounting for the growth-suppressive effects
described above (Fig. 3).
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FIG. 6.
FACS analysis of mock-transfected and JNKAS-treated RKO
cells. RKO neo and RKO E6-expressing cells were treated with either
JNK1AS, JNK2AS, or a combination of control scrambled oligonucleotides
(JNKScr). They were harvested 24 h following the lipofection, and
2 × 106 cells were subjected to DNA content analysis
by FACS. The percentage of total cells contained in the
sub-G1 peak of JNK2AS and JNK1AS- plus JNK2AS-treated RKO
E6 cell cultures is indicated in the figure (arrow). For all other
treatments of E6-expressing RKO and RKO neo cells, the
sub-G1 fraction was 1.5% or less.
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Effects of JNKAS treatment on HCT116 p53/
cells.
Although expression of the E6 oncoprotein is a
well-recognized way to inhibit p53 function, it remained possible that
our findings with RKO E6 and MCF-7 E6 cells could reflect other
function(s) of E6 protein. To address this possibility, we used another
model of p53 deficiency, HCT116 human colorectal carcinoma cells
rendered p53-null by a somatic knockout procedure (8).
Consistent with our observations with E6-expressing RKO and MCF-7
cells, HCT116 p53/ cells displayed significantly
greater sensitivity (P < 0.003 by Student's
t test) to JNK2AS treatment than did parental HCT116 cells
with normal p53 status (Fig. 7).
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FIG. 7.
Inhibition of JNK expression in HCT116 cells
results in growth suppression in a p53-dependent manner. Viable cell
mass was measured at 24 h, 48 h (shown here), and 72 h
following treatment with JNKAS and control oligonucleotides as
described in Materials and Methods. Growth inhibition following JNK2AS
treatment is p53 dependent: *, statistically significant difference
between the number of viable cells in JNK2AS-treated cultures of
parental HCT116 cells and HCT116 p53/ cells
(P < 0.003, Student's t test).
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Induction of p21Cip1/Waf1 in p53-proficient
and p53-deficient cells following JNKAS treatment.
Our finding
that inhibition of JNK expression, especially
JNK2, resulted in preferential apoptosis of p53-deficient
cells suggests that cells with intact p53 signaling possess a
protective mechanism that is unavailable to their p53-deficient
counterparts. We have previously shown that the ability of cells to
elevate expression of the cyclin-dependent kinase inhibitor
p21Cip1/Waf1 following exposure to cellular
stress leads to enhanced survival (18, 19). Given that p53
is an important regulator of p21Cip1/Waf1
expression during stress and that perturbations in JNK
expression could constitute a stress to growing cells, we examined
p21Cip1/Waf1 mRNA levels in JNKAS-treated cells.
Treatment with JNKAS (especially with JNK2AS) resulted in induction of
p21Cip1/Waf1 mRNA in parental MCF-7, RKO, and
HCT116 cells. In contrast, no elevation in
p21Cip1/Waf1 mRNA was evident in p53-deficient
MCF-7 E6, RKO E6, and HCT116 p53/ cells (Fig.
8A). That the increase in
p21Cip1/Waf1 mRNA results in increased
p21Cip1/Waf1 protein expression is shown in Fig.
8B, where p21Cip1/Waf1 protein levels were
examined 24 h following JNK2AS treatment. All three p53-proficient
cell lines showed an increase in
p21Cip1/Waf1 protein expression, but this
p21Cip1/Waf1 induction was not seen in the
p53-deficient derivatives.
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FIG. 8.
JNK2AS treatment results in induction of
p21Cip1/Waf1 expression in cells with normal p53
function (neo-transfected MCF-7 and RKO, and HCT166 cells) but not in
p53-deficient cells (E6-expressing MCF-7 and RKO, and HCT116
p53/ cells). (A) Total RNA was extracted from cells
24 h following treatment with 0.3 µM antisense (AS) or control
(Scr) oligonucleotides. RNA samples were analyzed by Northern analysis
using an oligonucleotide probe specific for human
p21Cip1/Waf1. Following analysis of
p21Cip1/Waf1 expression, Northern blots were
stripped and reprobed with an oligonucleotide complementary to 18S rRNA
to verify equal loading and transfer of RNA samples. (B)
p21Cip1/Waf1 expression was examined by Western
blot analyses 24 h following treatment with 0.3 µM JNK2AS or
JNKScr oligonucleotides (as described in the legend to Fig. 3).
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Finally, to more directly examine the influence of
p21Cip1/Waf1 on cell survival following JNKAS
treatment, we used HCT116 colorectal carcinoma cells in which the
p21Cip1/Waf1 genes were disrupted by homologous
recombination (41). Wild-type HCT116 cells (+/+) and HCT116
cells in which one (+/
) or both (/)
p21Cip1/Waf1 alleles were disrupted were
examined for apoptosis by flow cytometry following treatment with
antisense oligonucleotides (Fig. 9). No
significant apoptosis was evident in p21+/+ cells,
regardless of treatment (1.5% in control populations versus 3% in
JNKAS-treated cultures). p21/ cells exhibited higher
basal apoptosis than did the p21+/+ parental cell lines (4 and 1.5%, respectively), perhaps reflecting the importance of
p21Cip1/Waf1 for normal cell homeostasis.
Neither mock lipofection nor treatment with JNKScr or JNK1AS
altered this level. However, treatment of the p21/
cells with JNK2AS resulted in a substantial increase in the
sub-G1 population within 24 h after treatment (Fig.
9). An intermediate level of apoptosis was observed following JNK2AS
treatment of cells containing one functional
p21Cip1/Waf1 allele (+/), suggesting that the
relative level of p21 expression might be important in
determining the outcome. These results further support the hypothesis
that p21 contributes to the survival of cells following JNKAS
treatment.
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FIG. 9.
HCT116 human colorectal carcinoma cells lacking
p21Cip1/Waf1 expression display enhanced
sensitivity to JNK2AS treatment. Parental HCT116 cells with normal
p21Cip1/Waf1 expression (p21 +/+) and derivative
lines in which one (p21 +/) or both (p21 /)
p21Cip1/Waf1 alleles have been disrupted through
homologous recombination were examined by FACS analysis for apoptotic
cells 24 h following treatment with JNK1AS or JNK2AS
oligonucleotides.
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| |
DISCUSSION |
Over the past several years, the functional role of the JNK
pathway has been extensively investigated. The vast majority of studies
have relied on overexpression of mutant forms (dominant negative or
constitutively active) of various upstream signaling components to
modulate JNK kinase activity. Although informative, this approach can
produce confounding results for several reasons. First, most upstream
JNK regulators are also implicated in other signaling pathways (p38,
ERK, and others), and thus alterations in these pathways can contribute
to the effects observed. Second, considerable redundancy exists in the
upstream components (e.g., both MEKK4 and MEKK7 phosphorylate and
activate JNK), and therefore interference with the activity of one
component often leads to only partial inhibition of JNK activation.
Finally, the approaches described above do not alter JNK protein levels
and therefore do not allow the investigation of the importance of
changes in basal JNK activity or other potential functions of the
protein unrelated to kinase activity. This is particularly important
given that, in the absence of stress, nonphosphorylated JNK has
recently been implicated in down-regulating the expression of its
substrates, targeting them to degradation (14-17). While
the recent generation of JNK1, JNK2, and
JNK3 knockout mice provides the opportunity to address the
roles of specific JNK isoforms in normal mouse cells and tissues, such
model systems are not currently available for human cells, and they do
not address the importance of JNK in regulating tumor cell growth. The
AS strategy used here avoids many of the drawbacks noted above and
offers several distinct advantages. It produces significant and
isoform-specific inhibition of basal JNK mRNA and protein
expression in human cells without perturbing other components of the
pathway. The availability of AS oligonucleotides highly specific for
JNK1 and JNK2 allows investigation into
differential roles of these genes. Using this strategy, we have
investigated growth-regulatory functions of JNK1 and JNK2 in otherwise
unstressed cells and have provided evidence suggesting that JNK2 is
required for growth and homeostasis of tumor cells lacking p53
function, since elimination of JNK2 expression in p53-deficient cells results in their apoptosis (Fig. 4 to 6). This role
appears not to be shared by JNK1. However, we have shown that the JNK1
protein has a longer half-life than JNK2 protein (Potapova et al.,
submitted), and therefore it remains possible that the more efficient
elimination of JNK2 accounts for its greater inhibitory effects.
The ability of JNK to bind to and phosphorylate p53 was reported
several years ago (24, 32). More recently, several reports have appeared indicating that JNK plays opposing roles in regulating the stability of the p53 protein under normal growth conditions and
during stress (15, 16). Finally, it was recently shown that
p53 transcription is subject to repression by activated c-Jun, a major
known substrate of JNK (39). Taken together, these
observations suggest important links between the activities of JNK and
p53. Our study demonstrating that JNK2AS treatment leads to growth inhibition and apoptosis of RKO, MCF-7, and HCT116 human tumor cells in
a p53-dependent manner provides evidence for yet another link between
these stress-regulated pathways. The greater sensitivity of
p53-deficient tumor cells to JNK2AS treatment is not restricted to
these cell types, since we have observed that other human tumor cell
lines with null or mutant p53 status display greater growth inhibition
and cytotoxicity following JNKAS treatment than do cells with normal
p53 function (Table 1) (6; Potapova et al., submitted). Whether reintroduction of wild-type p53 into tumor cells
with mutant or null p53 status can alter their response to JNKAS
treatment remains to be investigated.
p53 can act in two opposing directions to influence the sensitivity of
a cell to stressful conditions: it can promote apoptosis in response to
certain cytotoxic agents (e.g., hydrogen peroxide) while conferring
protection against the cytotoxic effects of others (e.g., UVC
irradiation and tumor necrosis factor alpha) (7, 8, 21, 40).
The factors contributing to these seemingly disparate functions of p53
are far from clear, but recent studies have provided strong evidence
that the protective influence of p53 is mediated largely through its
ability to up-regulate p21Cip1/Waf1 expression
(18, 19). Consistent with this view, we observed that MCF-7,
RKO, and HCT116 cells with normal p53 function responded to the JNK2AS
treatment with induction of p21Cip1/Waf1 while
the p53-deficient derivatives did not (Fig. 8). Although JNK1AS
treatment resulted in induction of
p21Cip1/Waf1 expression (Fig. 8A), this effect
was less pronounced than that seen in JNK2AS-treated cells, and
p21Cip1/Waf1 protein levels were induced
to a much lesser extent (data not shown). These results, taken together
with the absence of marked growth suppression following JNK1AS
treatment (Fig. 3 and 7), suggest that JNK2 may have a specific
function(s) which is not shared by JNK1. That the
p21Cip1/Waf1 expression might be important in
contributing to the survival of JNK2AS-treated cells was supported by
additional studies with HCT116 cells in which targeted disruption of
the p21Cip1/Waf1 gene was likewise associated
with enhanced apoptosis following JNK2AS treatment (Fig. 9).
Based on these observations, we propose the following model. Tumor
cells require JNK2 for normal growth, and the depletion of JNK2 in
cells with normal p53 function by the JNK2AS treatment perturbs normal
homeostasis, triggering a stress response. This results in the
induction of p21Cip1/Waf1, which promotes
survival. The lack of p53 in the E6-expressing and p53/
cells prevents the induction of p21Cip1/Waf1,
depriving the cells of this important protective factor and therefore
leading to growth suppression and apoptosis. It is not clear, however,
how the death program is initiated or which of the mediators of this
response are important. It is also important to note that not all
p53-deficient cells undergo apoptosis in response to JNK2AS treatment.
T98G glioblastoma cells, for example, do not die but, rather, undergo
arrest in the S and G2 phases of the cell cycle (Potapova
et al., submitted). However, unlike p53-deficient cells used in this
study, T98G cells show marked induction of
p21Cip1/Waf1 expression following JNK2AS
treatment, more so in fact than do parental MCF-7, RKO, and HCT116
cells. It is likely that the high levels of
p21Cip1/Waf1 contribute to the cell cycle
arrest, since the importance of p21Cip1/Waf1 in
mediating G2 arrest has recently been established
(8). The mechanisms leading to this p53-independent
induction of p21Cip1/Waf1 remain to be clarified.
In summary, there is accumulating evidence suggesting that the JNK
pathway plays an important role in regulating the growth of tumor cells
and may in fact contribute to cellular transformation (4-6; Potapova et al., submitted). The current
findings reported here support this view and further suggest that JNK
(JNK2 in particular) is important for growth of human tumor cells
lacking functional p53. It may be possible to exploit this preferential
sensitivity of p53-deficient cells to JNK2AS treatment for the design
of therapeutic approaches for the management of tumors harboring p53
mutations (23).
| |
ACKNOWLEDGMENTS |
We are grateful to A. J. Fornace, Jr., M. Kastan, and B. Vogelstein for cells provided for this study; to M. Karin for the gift
of plasmid reagents; to R. Roberson for technical assistance; and to
J. Chrest and C. Morris for help with flow cytometry analysis.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Laboratory of
Biological Chemistry, GRC, NIA, 5600 Nathan Shock Dr., Box 12, Baltimore, MD 21224. Phone: (410) 558-8446. Fax: (410) 558-8386. E-mail: nikki_holbrook{at}nih.gov.
| |
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Abstract
Introduction
