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Previous Article | Next Article 
Molecular and Cellular Biology, November 2000, p. 8571-8579, Vol. 20, No. 22
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Cyclooxygenase 2 Promotes Cell Survival by
Stimulation of Dynein Light Chain Expression and Inhibition of
Neuronal Nitric Oxide Synthase Activity
Yu-Wen E.
Chang,1,
Rolf
Jakobi,2
Ann
McGinty,1,3
Marco
Foschi,1,4
Michael J.
Dunn,1 and
Andrey
Sorokin1,*
Department of Medicine and Cardiovascular
Research Center1 and Department of
Pharmacology and Toxicology,2 Medical College of
Wisconsin, Milwaukee, Wisconsin 53226; Department of Surgery,
The Queen's University of Belfast, Institute of Clinical Science,
The Royal Group of Hospitals, Belfast, Northern Ireland, United
Kingdom3; and Department of Internal
Medicine, University of Florence, Florence 50134, Italy4
Received 1 January 2000/Returned for modification 29 February
2000/Accepted 22 August 2000
 |
ABSTRACT |
Cyclooxygenase 2 (COX-2) inhibits nerve growth factor (NGF)
withdrawal apoptosis in differentiated PC12 cells. The inhibition of
apoptosis by COX-2 was concomitant with prevention of caspase 3 activation. To understand how COX-2 prevents apoptosis, we used cDNA
expression arrays to determine whether COX-2 regulates differential expression of apoptosis-related genes. The expression of dynein light
chain (DLC) (also known as protein inhibitor of neuronal nitric oxide
synthase [PIN]) was significantly stimulated in PC12 cells
overexpressing COX-2. The COX-2-dependent stimulation of DLC expression
was, at least in part, mediated by prostaglandin E2.
Overexpression of DLC also inhibited NGF withdrawal apoptosis in
differentiated PC12 cells. Stimulation of DLC expression resulted in an
increased association of DLC/PIN with neuronal nitric oxide synthase
(nNOS), thereby reducing nNOS activity. Furthermore, nNOS expression
and activity were significantly increased in differentiated PC12 cells
after NGF withdrawal. This increased nNOS activity as well as increased
nNOS dimer after NGF withdrawal were inhibited by COX-2 or DLC/PIN
overexpression. An nNOS inhibitor or a membrane-permeable superoxide
dismutase (SOD) mimetic protected differentiated PC12 cells from NGF
withdrawal apoptosis. In contrast, NO donors induced apoptosis in
differentiated PC12 cells and potentiated apoptosis induced by NGF
withdrawal. The protective effects of COX-2 on apoptosis induced by NGF
withdrawal were also overcome by NO donors. These findings suggest that
COX-2 promotes cell survival by a mechanism linking increased
expression of prosurvival genes coupled to inhibition of NO- and
superoxide-mediated apoptosis.
| |
INTRODUCTION |
Prostaglandins have been shown to
mediate inflammatory responses as well as to regulate a number of
signal transduction pathways that modulate cellular adhesion, growth,
and differentiation. Cyclooxygenase (COX) is the key enzyme in the
production of prostaglandins. The isoform COX-1 is constitutively
expressed in most tissues, whereas the expression of isoform COX-2 is
induced by growth factors, tumor promoters, cytokines (10,
47), and vasoactive peptides such as endothelin 1 (27). In addition to involvement in the inflammatory
responses, COX-2 and its products, especially prostaglandin E2 (PGE2), have been reported to be important
in inhibition of apoptosis (46, 55). Apoptosis, or
programmed cell death, is a normal physiological process which occurs
during embryonic development as well as in maintenance of tissue
homeostasis. Inappropriate induction of apoptosis has been associated
with organ injury, whereas a failure to undergo apoptosis may cause
abnormal cell overgrowth and malignancy (20).
Previous studies in rat intestinal epithelial cells have shown that
COX-2 overexpression leads to a number of effects that could be
associated with tumorigenesis: increased adhesion to extracellular
matrix proteins, inhibition of butyrate-induced apoptosis, decreased
expression of both E-cadherin and transforming growth factor 
2
receptor, and stimulation of Bcl-2 protein expression (55).
The model systems involving coculture of endothelial cells with colon
carcinoma cells showed that COX-2-expressing cells produce high level
of angiogenic factors, which stimulate endothelial tube formation in
the coculture model (56). Indeed, the level of COX-2 protein
has been reported to increase dramatically in human colorectal
adenocarcinomas (11), in colorectal tumors (33,
44), in adenomas taken from APC mutant mice
(39), and in intestinal tumors from carcinogen-treated rats
(9). High levels of constitutive COX-2 expression are also
detected in the human colon cancer cell line HCA-7. Treatment of HCA-7
cells with SC-58125, a highly selective COX-2 inhibitor, results in
inhibition of growth and increase of apoptotic cells, which is reversed
by PGE2 stimulation (46). In addition,
overexpression of COX-2 in RAW 264.7 macrophages inhibits apoptosis
(57). Inhibition of COX-2 activity by SC-58236 or
downregulation of COX-2 protein by antisense expression in medullary
interstitial cells causes apoptosis (18). Therefore, these
data suggest that COX-2 may function as a survival factor and protect
cells from apoptosis. To further explore the mechanisms of
antiapoptotic effects of COX-2, we established a PC12 pheochromocytoma
cell line stably transfected with a rat COX-2 cDNA or vector alone
under the control of an
isopropyl--D-thiogalactopyranoside (IPTG)-inducible
promoter (lacSwitch promoter) (37). PC12 cells have been
commonly used as a cell culture model for studies of neuronal
development and functions. In particular, PC12 cells are also a
convenient alternative to cultured neurons for studying the trophic and
differentiative actions of nerve growth factor (NGF) since PC12 cells
can be induced by NGF to differentiate to acquire many characteristics
of mature sympathetic neurons, including extended long branching
neurites (52). Moreover, differentiated PC12 cells undergo
pronounced and well-characterized apoptosis upon NGF withdrawal that
resembles apoptosis in cultured sympathetic neurons (59). We
have demonstrated that COX-2 overexpression inhibits the apoptosis by
NGF withdrawal of differentiated PC12 cells (37).
The aim of this study was to determine a possible downstream
mediator(s) of COX-2 in antiapoptotic signaling. The cDNA probes generated from PC12 cells overexpressing COX-2 (PCXII cells) or mock-transfected cells (PC-MT cells) were used for expression array
screening using the Atlas human cDNA expression array (Clontech). The
screening showed an enhanced expression of the cytoplasmic dynein light
chain (DLC) (also known as protein inhibitor of neuronal nitric oxide
synthase [PIN]) gene. DLC protein expression was elevated not only in
PCXII cells but also in PC12 or human mesangial cells infected with
adenovirus encoding COX-2. Furthermore, PC12 cells overexpressing DLC
(PC-DLC cells) were more resistant than parental (PC-Off) cells to
apoptosis induced by NGF withdrawal. Coimmunoprecipitation assays
showed increased association of DLC protein with neuronal nitric oxide
synthase (nNOS) in PCXII or PC-DLC cells, which decreased nNOS
activity. We also observed that nNOS expression and activity were
further elevated in differentiated PC12 cells after NGF withdrawal.
However, this increased nNOS activity was inhibited by COX-2 or DLC
overexpression. An nNOS inhibitor as well as a membrane-permeable
superoxide dismutase (SOD) mimetic prevented differentiated PC12 cell
death induced by NGF withdrawal. NO donors induced apoptosis in
differentiated PC-MT cells and reversed the protective effects of COX-2
on apoptosis induced by NGF withdrawal, partially due to activation of
caspase 3. Taken together, our results provide a new molecular
mechanism underlying the protective role of COX-2 in differentiated
PC12 cell death in response to NGF withdrawal.
| |
MATERIALS AND METHODS |
Cell culture.
The PCXII and PC-MT cell lines were
constructed using the lacSwitch expression system (Stratagene) as
described previously (37). Both PC12 cell lines were
cultured in Dulbecco modified Eagle medium supplemented with 10%
heat-inactivated horse serum, 5% fetal bovine serum, 2 mM glutamine,
penicillin (100 U/ml), streptomycin (100 U/ml), Geneticin (G418; 0.8 mg/ml; Gibco-BRL), and hygromycin B (0.08 mg/ml; Gibco-BRL) in culture
plates coated with rat tail collagen (Becton Dickson).
Human mesangial cells were provided by Jean-Daniel Sraer and cultured
as described elsewhere (49). For PGE2 treatment,
human mesangial cells were serum starved for 48 h in RPMI medium
containing 0.1% fetal bovine serum, and PC12 cells were serum starved
for 17 h in F-12K medium containing 1% horse serum. Cells were
then treated with PGE2 for 6 h.
Hybridization of cDNA expression array.
PCXII or PC-MT cells
were grown in regular serum medium in the presence of IPTG (2.5 mM) for
17 h on collagen-coated culture plates. mRNA was isolated from two
100-mm-diameter plates of each cell line, using a QuickPrep Micro mRNA
purification kit (Amersham Pharmacia Biotech). 32P-labeled
cDNA probes were prepared and hybridized to the Atlas human cDNA
expression array (Clontech) as instructed by the manufacturer. Membranes were exposed to Kodak BioMax MS X-ray film with a BioMax MS
intensifying screen at 
70°C for 24 h.
Cloning of cytoplasmic DLC cDNA.
Total RNA was isolated from
IPTG-stimulated PCXII cells by using TRIzol reagent (Gibco-BRL). The
rat DLC cDNA was amplified by reverse transcription-PCR (Amersham
Pharmacia Biotech) using primers corresponding to the rat DLC gene
(GenBank accession no. R47168). The 5' primer
(5'-ACTGACATATGTGCGACCGGAAGGCGG-3') contained an
NdeI site, and the 3' primer
(5'-TCAGTAGGATCCTTAACCAGATTTGAACAGAAG-3') contained a
BamHI site. The amplified DLC cDNA was subcloned into the
NdeI-BamHI sites of pKoz/M-Flag, a plasmid
containing a Kozak sequence and an N-terminal Flag tag (R. Jakobi,
unpublished data), and sequenced to confirm the identity.
Establishment of PC-DLC cells.
PC12 cells were obtained from
the American Type Tissue Collection (Manassas, Va.) and grown in F-12K
medium supplemented with 15% heat-inactivated horse serum and 2.5%
fetal bovine serum in rat tail collagen-coated culture plates. The
retroviral gene delivery and expression system RevTet-Off (Clontech)
was used to establish PC12 cells expressing the rat DLC cDNA. The
vector pRevTet-Off encodes the tetracycline transcriptional activator,
which binds to the tetracycline response element and activates
transcription in the absence of tetracycline or doxycycline. Addition
of either antibiotic at 10 µg/ml inhibits expression of DLC. pRevTRE
is a response vector in which DLC cDNA was cloned with a Kozak sequence and an N-terminal Flag tag downstream of the tetracycline response element. To create the parental cell line PC-Off, the packaging cell
line (Phoenix Eco) (23) was transfected with the regulator vector (pRevTet-Off), and the resulting virus-containing supernatant was used to infect PC12 cells. Stable PC12 cell populations expressing the transcriptional activator were selected in the presence of G418
(0.75 mg/ml; Gibco-BRL) and served as parental cells as well as control
cells for establishing stable cells expressing DLC (PC-DLC cells).
Phoenix Eco cells were then transfected with pRevTRE, which contained
DLC cDNA, and the supernatant was used to infect PC-Off cells. Stable
cell populations (PC-DLC cells) were selected in the presence of
hygromycin B (0.3 mg/ml).
Induction of differentiated PC12 cells.
PC12 cells were
differentiated for 7 to 9 days in medium containing 1% horse serum and
50 ng of NGF (Becton Dickson) per ml. To obtain the maximal expression
of COX-2, IPTG (2.5 mM) was added into the differentiation medium for
PC-MT or PCXII cells.
Adenovirus COX-2 gene transfer.
The recombinant adenovirus
vector AdCOX-2, expressing COX-2, was constructed from
replication-deficient adenovirus type 5 (Ad5) with deletions in the E1
and E3 genes, Addl327, and a plasmid containing Ad5
sequences from 22 to 5790 with a deletion of the E1 region from bp 342 to 3523, a polycloning site under control of the cytomegalovirus
promoter, the COX-2 cDNA, and the simian virus 40 polyadenylation
signal. Human mesangial or PC12 cells were incubated with AdCOX-2 or an
Ad5-based -galactosidase expression vector (AdLacZ) (at a
multiplicity of infection [MOI] of 25 for human mesangial cells or
MOI 50 for PC12 cells) for 1 h, followed by addition of complete
medium. At 24 h after infection, cells were lysed and subjected to
Western blot analysis or stained for 5-bromo-4-chloro-3-indolyl--D-galactopyranoside (X-Gal)
as described previously (15).
Immunoprecipitation; Western and Northern blot analyses.
Cells were washed and lysed in lysis buffer as described previously
(15). The cleared cell lysates (200 µg) were incubated with nNOS antibody (R20; 4 µg; Santa Cruz Biotechnology) overnight at
4°C, followed by incubation with protein A-Sepharose (Amersham Pharmacia Biotech) for 1 h. The immunoprecipitates were washed three times with 1 ml of lysis buffer and boiled in Laemmli buffer for
5 min at 95°C.
Immunoprecipitates or cell lysates (30 to 40 µg) were separated by
sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE)
and transferred to nitrocellulose membranes (Micron Separation Inc.),
and immunodetection was carried out as described previously
(15). nNOS monoclonal antibody for Western blotting was from
Transduction Laboratories, and antibodies for COX-2 (N20) and caspase 3 (H227) were from Santa Cruz.
For Northern blot analysis, total RNA was isolated from PCXII or PC-MT
cells by using TRIzol reagent (Gibco-BRL). RNA samples (10 µg) were
then separated by electrophoresis on 1.2% agarose gels containing
formamide and transferred to a Hybond-N+ nylon membrane (Amersham
Pharmacia Biotech). The membrane was hybridized with
32P-labeled full-length rat COX-2 cDNA, full-length DLC
cDNA, or glyceraldehyde 3-phosphate dehydrogenase (GAPDH) cDNA in
ExpressHyb solution (Clontech).
Apoptosis.
Differentiated PC12 cells were induced for
apoptosis by NGF withdrawal as described previously (59).
NGF withdrawal was carried out by washing the cells once with NGF-free
medium followed by incubation in NGF-free medium containing rabbit
neutralizing antibody to 2.5s NGF (Sigma) at a 1:500 dilution for
17 h. The NO donor 2-2'-(hydroxynitrosohydrazino)bisethanamine
(DETA-NONOate; 200 µM; Cayman) or
S-nitro-N-acetylpenicillamine (SNAP; 200 µM; Cayman) or the nNOS inhibitor
N5-(1-imino-3-buteny)-L-orthine
(L-VNIO; 10 µM; gift from Owen Griffith, Medical College
of Wisconsin) (2) or manganese III
4,4',4",4'"(21H,2H-porphine-5,10,15,20-tetrayl)tetrakis (benzoic acid;
better known as manganese TBAT; 200 µM; Alexis) was added to the
cells as indicated. Cells washed once in NGF-free medium and then
incubated in NGF-containing medium were used as controls for apoptotic
cells. Cells were fixed with a mixture of acetone and methanol (1:1
ratio) for 20 min at 20°C, and the nuclei were stained with Hoechst
33258 (25 µg/ml; Sigma) for 15 min at room temperature and observed
under fluorescence microscopy using a 4',6-diamidino-2-phenylindole
(DAPI) filter. Fragmented or condensed nuclei were scored as apoptotic.
To visualize oligonucleosomal fragmentation, DNA was extracted from
control or apoptotic cells with phenol-chloroform-isoamyl alcohol as
described previously (50) and analyzed on a 2% agarose gel.
nNOS activity assay.
nNOS activity was measured using the
conversion of [3H]arginine to
[3H]citrulline by a modification (21) of the
method described by Kiedrowski et al. (28). PC12 cells were
cultured at a density of 200,000 cells per well on collagen-coated
six-well plates with or without NGF treatment, and so nNOS activity was
measured within the linear range. Cells were preincubated with
[3H]arginine (3 µCi) for 5 min at 37°C. After removal
of [3H]arginine, cells were washed and then scraped in 1 ml of 0.3 mM HClO4, the lysate was centrifuged, and the
supernatant was neutralized with K2CO3. An
aliquot of the supernatant was counted for 3H to assess
[3H]arginine uptake. A second aliquot of the supernatant
was placed onto columns containing Dowex AG 50W-X8 cation-exchange
resin (sodium form; Bio-Rad). The flowthrough and eluate following the addition of 2 ml of water were combined, and counts per minute was
determined. Studies using [14C]citrulline and
[3H]arginine standards demonstrate that the columns
retain over 98% of added arginine and less than 7% of added
citrulline. Each treatment was measured in triplicate, and each
experiment was repeated three times; means ± standard deviations
(SD) are reported.
| |
RESULTS |
Inhibition of caspase 3 activation by COX-2 overexpression.
Our previous studies have shown that overexpression of COX-2 in
differentiated PC12 cells results in inhibition of programmed cell
death induced by NGF withdrawal compared to mock-transfected cells
(37). Caspase 3 has been implicated as an indicator of apoptosis since it was discovered as a key protease in the execution phase of apoptosis (53). The activated caspase 3 comprises a 17-kDa large subunit containing the active site and a small subunit of
approximately 10 kDa (53). In PC-MT cells, activation of caspase 3 was detected as early as 3 h after NGF withdrawal and reached maximal levels at 6 h, as shown by the presence of the p17
caspase 3 cleavage product (Fig. 1). The
activation of caspase 3 was transient since the p17 cleavage product
disappeared between 6 and 17 h of apoptosis (Fig. 1). Little
activation of caspase 3 was observed in PCXII cells (Fig. 1),
indicating that COX-2 either acts at the level of pro-caspase 3 or
disrupts the upstream signal that leads to activation of caspase 3 activity.
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FIG. 1.
COX-2 overexpression suppressed activation of caspase 3 after NGF withdrawal. PC-MT and PCXII cells were differentiated by NGF
for 7 days in the presence of IPTG (2.5 mM), followed by NGF withdrawal
for 0, 3, 6, 17, and 24 h. Cell lysates (40 µg) were separated
by SDS-8 to 15% PAGE, and activation of caspase 3 was analyzed by
Western blotting using caspase 3 antibody.
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COX-2 overexpression stimulates the expression of DLC/PIN.
To
identify the differential expression of genes involved in antiapoptotic
effects mediated by COX-2, Atlas human cDNA expression arrays
(Clontech) were screened with 32P-labeled cDNA generated
from mRNA from PC-MT or PCXII cells. Under the high-stringency
conditions used, only six genes were found to be expressed
differentially between PC-MT and PCXII cells. A difference of more than
threefold was considered significant. Signals were normalized to
signals from housekeeping genes (data not shown). Expression of
cytoplasmic DLC displayed the most change and was sixfold greater in
PCXII cells than in PC-MT cells. DLC has been shown to be important for
cellular viability (8, 16); hence, we evaluated the
correlation between stimulation of DLC expression by COX-2 and
COX-2-dependent antiapoptotic effects in differentiated PC12 cells. DLC
was initially identified as a component of microtubule-associated motor
complex with a molecular mass of 8 kDa (30), which is also
known as PIN (25). To confirm the results of cDNA expression
array screening, RNA and cell lysates from PC-MT and PCXII cells were
analyzed by Northern and Western blot analyses, respectively. The
levels of DLC mRNA as well as DLC protein were significantly higher in
PCXII cells than in PC-MT cells (Fig. 2).
Furthermore, pretreatment of PCXII cells with the nonselective COX
inhibitor indomethacin blocked the stimulation of DLC expression
without affecting COX-2 expression (Fig. 2B). Thus, stimulation of DLC
expression requires the enzymatic activity of COX-2.
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FIG. 2.
COX-2 overexpression in PC12 cells stimulated DLC
expression. (A) Northern blot analysis of RNA from PC-MT and PCXII
cells untreated or treated with IPTG for 17 h. Equal loading of
RNA samples (10 µg) was confirmed by reprobing with GAPDH cDNA.
Arrows indicate the positions of COX-2 and DLC. (B) Western blot
analysis of cell lysates from PC-MT and PCXII cells untreated or
treated with IPTG for 17 h. For indomethacin treatment, PC-MT and
PCXII cells were pretreated with 10 µM indomethacin for 24 h and
then incubated with or without IPTG for an additional 17 h. Cell
lysates (30 µg) were resolved by SDS-8 to 20% PAGE, transferred
onto a nitrocellulose membrane (0.22-µm pore size), and analyzed by
Western blotting using COX-2 or DLC antibody. The densitometric values
of the signals are normalized such that the zero time point is defined
as 1.
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Next, the construct AdCOX-2 was used to transfect PC12 cells and human
mesangial cells to determine whether transient expression of COX-2 also
stimulates DLC expression. Mesangial cells, a prominent cell type in
the glomerulus, are involved in the regulation of glomerular
hemodynamics and glomerulonephritis (7, 26). The transgenic
adenovirus construct AdLacZ was used to determine the MOI in order to
obtain 100% transfection efficiency (Fig.
3A). COX-2 expression in
AdCOX-2-transfected cells was confirmed by Western blotting (Fig. 3A).
The level of DLC protein in AdLacZ-transfected cells was the same as
that in nontransfected cells and was significantly increased in
AdCOX-2-transfected cells (Fig. 3A). Treatment of PC12 and human
mesangial cells with PGE2 increased DLC expression (Fig.
3B). In PC12 cells, DLC expression started to be increased at a
PGE2 concentration of 1 nM and was evident at
PGE2 concentrations of 5 to 25 nM (data not shown). These
results suggest that stimulation of DLC expression in PC12 cells and in
human mesangial cells by COX-2 overexpression is, at least in part,
mediated by the COX-2 product, PGE2.
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FIG. 3.
Stimulation of DLC expression by transient expression of
COX-2 using adenovirus gene delivery as well as by PGE2
treatment. (A) Human glomerular mesangial and PC12 cells were mock
infected or infected with AdLacZ or AdCOX-2. As assessed by X-Gal
staining, AdLacZ infected ~100% of cells. Cell lysates (40 µg)
were analyzed by Western blotting using anti-COX-2 or anti-DLC/PIN
antibody. (B) Human mesangial cells were treated with increasing
concentrations of PGE2, and control cells were treated with
vehicle (dimethyl sulfoxide) for 6 h. Cell lysates (20 µg) from
human mesangial and PC12 cells were separated by SDS-4 to 20% PAGE
and analyzed by Western blotting using DLC/PIN antibody. Experiments
were repeated three times with similar results.
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Overexpression of DLC inhibits apoptosis in differentiated PC12
cells induced by NGF withdrawal.
In Drosophila
melanogaster, a total loss-of-function DLC mutant results in
degeneration during embryogenesis, and dying cells showed morphological
changes characteristic of apoptosis (8). These data
suggested that DLC plays a role in the inhibition of apoptosis. We
established the PC-DLC cell line (see Materials and Methods) to examine
whether DLC is involved in inhibition of apoptosis induced by NGF
withdrawal. The expression of DLC in PC12 cells was characterized by
Western blot analysis (Fig. 4A). The
level of DLC can be downregulated by addition of doxycycline or
tetracycline, but basal levels may still exist (Fig. 4A, lanes 3 and
4). Therefore, the parental (PC-Off) cells were used for comparison
with PC-DLC cells in the following experiments. As analyzed by Hoechst
staining, approximately 30% of differentiated PC-Off cells were
apoptotic at 17 h after NGF withdrawal, whereas only a few
apoptotic PC-DLC cells were observed (Fig. 4B). Fragmentation of
genomic DNA was observed at 17 h after NGF withdrawal in PC-Off cells but was not observed in PC-DLC cells (Fig. 4C). In PC-Off cells,
the earliest appearance of active caspase 3 as determined by the
cleavage product p17 was detected 2 h after NGF withdrawal; the
level of p17 was maximal at 6 h and then decreased at 19 h (Fig. 4D). In contrast, very little caspase 3 p17 was detected in
PC-DLC cells throughout the time course. Therefore, DLC overexpression also blocked apoptosis by NGF withdrawal in PC12 cells, indicating that
inhibition of apoptosis by COX-2 is, at least in part, mediated by
DLC/PIN.
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FIG. 4.
Effects of DLC overexpression on differentiated PC12
cell apoptosis induced by NGF withdrawal. (A) Western blot
analysis of PC12 cells stably expressing DLC. Lanes 1 and 2, PC-Off
(parental) cells treated without (lane 1) or with (lane 2) doxycycline
(10 µg/ml) for 48 h; lanes 3 and 4, PC-DLC cells stimulated
without (lane 3) or with (lane 4) doxycycline (10 µg/ml) for 48 h. (B) Prevention of PC12 cell apoptosis induced by NGF
withdrawal by DLC overexpression as determined by Hoechst staining.
PC-Off and PC-DLC cells were differentiated by NGF for 7 days, followed
by treatment with or without NGF withdrawal for 17 h. Data shown
are the averages of three independent experiments, and error limits are
within 3%. (C) Prevention of PC12 cell apoptosis induced by
NGF withdrawal by DLC overexpression as determined by DNA
fragmentation. Soluble cytoplasmic DNA from differentiated PC-Off or
PC-DLC cells with (+) or without () NGF withdrawal for 17 h was
analyzed by agarose gel electrophoresis. Some undegraded RNA was also
strongly stained with ethidium bromide at the bottom of the gel. (D)
Inhibition of caspase 3 activation induced by NGF withdrawal by DLC
overexpression. Differentiated PC-Off or PC-DLC cells were incubated
with or without anti-NGF antibody. At indicated time points, cells
lysates (40 µg) were analyzed by Western blotting for caspase
3.
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Association of DLC with nNOS results in reduction of nNOS
activity.
DLC interacts with nNOS, resulting in inhibition of nNOS
activity (25). PC12 cells were differentiated by NGF for 7 days to fully induce nNOS expression (40, 45). Although
equal amounts of nNOS were immunoprecipitated with nNOS antibody from
all differentiated PC12 cell lines, more DLC was coimmunoprecipitated
with nNOS from PCXII or PC-DLC cells than from PC-MT or PC-Off cells,
respectively (Fig. 5A). These data were
consistent with a previous report that the complex of DLC and nNOS is
detected in rat cerebellum extracts by coimmunoprecipitation
(25). nNOS activity was then examined in all cell lines with
or without NGF stimulation for 7 days. Very little nNOS activity as
well as nNOS protein was detected in all cell lines without NGF
treatment (Fig. 5B), consistent with previous studies
(40, 45). After NGF treatment for 7 days, the expression of
nNOS in all cell lines was induced to similar extents, while nNOS
activity was significantly increased only in PC-MT or PC-Off cells, not
in PCXII or PC-DLC cells (Fig. 5B). Neither endothelial nor inducible
NOS protein was detected in these lysates by Western blotting using a
specific antibody (data not shown), consistent with the report from
Sheehy et al. (45). These results suggest that the
stimulation of DLC expression led to an increase of association with
nNOS and thus decreased nNOS activity in differentiated PC12 cells.
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FIG. 5.
Association of DLC with nNOS in differentiated PC12
cells reduced nNOS activity. (A) PC-MT, PCXII, PC-Off, and PC-DLC cells
were treated with NGF for 7 days; IPTG was added to PC12-MT and PCXII
cells. Cell lysates (200 µg) were immunoprecipitated with nNOS
antibody. Lysates (40 µg) and immunoprecipitates were analyzed by
Western blotting using nNOS (top) or DLC (bottom) antibody. (B) nNOS
activity was assayed in PC-MT, PCXII, PC-Off, and PC-DLC cells treated
with or without NGF for 7 d; IPTG was added to PC-MT and PCXII
cells. The activity of nNOS is presented as the percentage of
conversion of [3H]arginine to
[3H]citrulline. Values are means ± SD of three
independent experiments. In the parallel experiments, cell lysates were
analyzed for nNOS expression by Western blotting using nNOS antibody.
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NGF withdrawal further increases nNOS expression and activity.
Although nNOS expression and activity were stimulated by NGF, we found
that nNOS activity was further increased in both PC-MT and PC-Off cells
after NGF withdrawal (Fig. 6). The nNOS
activity in PCXII or PC-DLC cells remained unchanged after NGF
withdrawal. Western blot analysis showed that nNOS protein was also
significantly increased in all PC12 cell lines as early as 3 h
after NGF withdrawal and up to two- to threefold at 6 h (Fig. 6).
The levels of nNOS then declined at 17 h after NGF withdrawal
(data not shown). In PCXII and PC-DLC cells, nNOS protein was increased
after NGF withdrawal but the activity remained unchanged, possibly due
to association of DLC with nNOS. Dimerization of nNOS (~320 kDa) is
essential for its activity and can be analyzed by low-temperature
SDS-PAGE in the presence of tetrahydrobiopterin and arginine
(31). nNOS dimerization was increased two- to threefold in
PC-MT and PC-Off cells at 6 h after induction of apoptosis
compared to differentiated cells. Dimerization was not detected in
PCXII or PC-DLC cells either at the differentiated stage or after NGF
withdrawal (Fig. 6C). These results suggest that nNOS activity plays an
important role in apoptosis in differentiated PC12 cells
induced by NGF withdrawal and that overexpression of either COX-2 or
DLC could prevent this increased nNOS activity.
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FIG. 6.
NGF withdrawal from differentiated PC12 cells further
stimulated nNOS expression and activity, and nNOS activity was
inhibited by COX-2 or DLC overexpression. (A and B) PC-MT, PCXII,
PC-Off, and PC-DLC cells were treated with NGF for 7 days; IPTG was
added to PC-MT and PCXII cells. At 0, 3, and 5 h after NGF
withdrawal, nNOS expression was analyzed by Western blotting, and
activity was measured as described in Materials and Methods. Values are
means ± SD of three experiments. (C) Cell lysates from
differentiated PC-MT, PCXII, PC-Off, or PC-DLC cells incubated with (+)
or without () anti-NGF antibody for 6 h were analyzed for nNOS
dimerization by SDS-PAGE under low-temperature conditions as described
previously (31), followed by Western blot analysis
using nNOS antibody. The dimer/monomer ratio was determined by
densitometrically scanning of both nNOS bands on autoradiogram.
|
|
NO donors induce apoptosis, while NOS inhibitor or SOD
mimetic manganese TBAT prevents apoptosis.
L-VNIO has been recently shown to be a potent and selective
inhibitor for nNOS (2). Treatment with 10 µM
L-VNIO prevented apoptosis in PC-MT cells and had
no effect on PCXII cells (Fig. 7A).
Similar results have been obtained using a nonselective NOS inhibitor,
NG-nitro-L-arginine methyl ester
(L-NAME; 10 µM) (data not shown). The protection from
apoptosis by L-VNIO could be overcome by the NOS
substrate L-arginine (100 µM) but not
D-arginine, suggesting that L-VNIO is a
stereospecific inhibitor of nNOS. A membrane-permeable scavenger of
superoxide and peroxynitrite, manganese TBAT (14, 51), also
increased survival of PC-MT cells after NGF withdrawal (Fig. 7A),
suggesting that an intracellular increase in superoxide was required to
induce cell death. In contrast, NO donors DETA-NONOate and SNAP caused
differentiated PC-MT cells to undergo apoptosis but to a lesser
extent compared to NGF withdrawal, while NO donors had no effect on
PCXII cells (Fig. 7B). Furthermore, NO donors potentiated the
apoptosis in PC-MT cells induced by NGF withdrawal and also
reversed the protective effects of COX-2 on apoptosis. The
depleted NO donors had no effect on apoptosis. Caspase 3 was also activated in differentiated PC-MT cells by both DETA-NONOate and
SNAP but to a lesser extent compared to NGF withdrawal. DETA-NONOate but not SNAP further increased the activated caspase 3 in
differentiated PC-MT cells after NGF withdrawal (Fig. 7C). Both NO
donors had no effect on caspase 3 activation in differentiated PCXII
cells, but DETA-NONOate potentiated caspase 3 activation in the same cells after NGF withdrawal (Fig. 7C). These results suggested that NO
is necessary but not sufficient to induce differentiated PC12 cell
apoptosis. Superoxide or possibly peroxynitrite (a strong oxidant formed by the reaction of NO and superoxide) may also play an
important role in induction of apoptosis in differentiated PC12
cells by NGF withdrawal.
View larger version (35K):
[in this window]
[in a new window]
|
FIG. 7.
Effects of NO donors, nNOS inhibitor, or manganese TBAT
on apoptosis in differentiated PC12 cells. (A) Differentiated
PC-MT and PCXII cells were treated with or without nNOS inhibitor as
indicated in the presence of NGF (25 ng/ml) for 24 h or anti-NGF
antibody for 17 h. Nuclei were stained with Hoechst 33528. Cells
containing condensed or fragmented nuclei were scored as apoptotic. (B)
Differentiated PC-MT and PCXII cells were treated with or without NO
donor as indicated in the presence of NGF (25 ng/ml) for 24 h or
anti-NGF antibody (1:1,000 dilution) for 17 h. For depletion, the
NO donors were incubated at room temperature in serum-free medium for 4 days to completely liberate NO. Values are means ± SD of four
experiments. (C) Differentiated PC-MT or PCXII cells, treated with or
without NO donor (200 µM DETA-NONOate [Deta] or SNAP) in the
presence of NGF (25 ng/ml) or anti-NGF antibody (1:500 dilution) for
6 h. Cell lysates (40 µg) were separated by SDS-8 to 15% PAGE,
and activation of caspase 3 was analyzed by Western blotting using
caspase 3 antibody.
|
|
| |
DISCUSSION |
The significance of the antiapoptotic properties of COX-2 have
been emphasized because of the contribution of COX-2 to the progression
of various proliferative diseases. The enhancement of glomerular COX-2
mRNA level has been shown in animal models of proliferative
glomerulonephritis (5, 22). The progression of proliferative
glomerulonephritis is accompanied by intensive proliferation of
glomerular mesangial cells, which is usually attenuated by programmed
cell death (apoptosis). The constitutive expression of COX-2
has been identified in a majority of colon cancer specimens (11,
33, 58). Overexpression of COX-2 in intestinal epithelial cells
leads to inhibition of apoptosis and correlates with induction
of Bcl-2 expression (55). Our previous data showed that
induction of apoptosis in differentiated PC12 cells by NGF
withdrawal was blocked by overexpression of COX-2 and that this
inhibitory effect was concomitant with inhibition of caspase 3 activation (37). Therefore, it appears that stimulation of
COX-2 expression interferes with a program of self-regulated destruction of undesirable cells and thus can contribute to
uncontrolled cell growth. Although the capacity of COX-2 to prevent
apoptosis is documented in a number of systems, the mechanism
of antiapoptotic effect of COX-2 overexpression remains unknown. The
data presented here provide evidence for the molecular mechanisms of
the antiapoptotic effect of COX-2. The results suggest a crucial role
of COX-2 in regulation of nNOS activity in the prevention of
apoptosis, which we postulate is dependent on upregulation of
DLC expression.
In this study, we demonstrated that COX-2 overexpression resulted in a
significant induction of DLC expression. This stimulation of DLC
expression by COX-2 required the enzymatic activity of COX-2, as
indomethacin inhibited and PGE2 stimulated DLC
expression. Previously, overexpression of COX-2 in rat intestinal
epithelial cells has been shown to induce Bcl-2 expression
(55). However, Bcl-2 protein was not detectable in our
system with or without COX-2 overexpression, suggesting that the
induction of Bcl-2 is cell specific (Y.-W. E. Chang et al.,
unpublished data). DLC has been identified as a component of cellular
motor complex with a molecular mass of 8 kDa (4, 30).
Partial loss-of-function mutations of DLC in Drosophila lead
to morphogenetic defects in bristle and wing development, female
sterility, and disruption of sensory axon trajectories, while
total loss-of-function mutations induces apoptosis and
embryonic lethality (8). The mRNA levels of DLC are
rapidly induced by global ischemia in pyrimidal neurons of the
hippocampal CA3 region and granule cells of the dentate gyrus, which
are shown to be resistant to ischemic damage (16). A new
member of Bcl-2 family, Bim, has been demonstrated to provoke apoptosis (38), and the association of Bim with DLC
causes sequestration of Bim to the microtubule-associated dynein motor
complex, thereby presumably delaying the access of Bim to antiapoptotic
Bcl-2 family members in cells exposed to a death stimulus
(43). Therefore, these studies suggest that DLC/PIN
plays an important role in regulation of apoptosis. Here, we
showed that overexpression of DLC significantly inhibited
apoptosis as well as activation of caspase 3 in differentiated
PC12 cells induced by NGF withdrawal. Therefore, our data provide
direct evidence that DLC can be an antiapoptotic protein and function
as a downstream mediator of COX-2 in antiapoptotic signaling.
DLC binds to nNOS, resulting in destabilization of nNOS dimer and
thereby inhibiting nNOS activity (25). In PCXII or PC-DLC cells, DLC associated with nNOS, thus preventing the increase of nNOS
activity in response to NGF treatment. Moreover, NOS activity in
differentiated PC-MT and PC-Off cells was found to be rapidly stimulated further after NGF withdrawal and as a result of increased nNOS expression. However, nNOS activity remained unchanged in PCXII
PC-DLC cells after NGF withdrawal due to association of DLC with nNOS.
Our results suggested that increased nNOS activity is important for
differentiated PC12 cell apoptosis induced by NGF withdrawal.
In agreement with this hypothesis, we demonstrated that NOS inhibitors
reduced PC12 cell apoptosis, NO donors increased apoptosis of PC12 cells, and NO donors reversed the protective effects of COX-2 on apoptosis. Further evidence was provided by increasing activation of caspase 3 by NO donors. However, our data show
that NO is required but not sufficient enough to induce apoptosis. nNOS has been shown to produce NO and superoxide in vitro (41, 42). We found that superoxide and peroxynitrite played a significant role in induction of apoptosis, as shown by treatment with manganese TBAT, a membrane-permeable SOD mimetic (14, 51), protecting differentiated PC12 cells from
apoptosis induced by NGF withdrawal. Thus, NO and superoxide
are required for apoptosis in differentiated PC12 cells induced
by NGF withdrawal.
Motor neuron apoptosis induced by trophic factor
withdrawal involves both increased NO production after induction of
nNOS expression and augmented intracellular production of superoxide, in which NO reacts with superoxide to produce peroxynitrite
(13). Peroxynitrite, a stronger and more toxic oxidant than
NO and superoxide, has been shown to stimulate apoptosis of
PC12 cells (12, 48, 54). Therefore, we concluded that NGF
withdrawal from differentiated PC12 cells increases peroxynitrite,
which contributes to apoptosis of PC12 cells.
NO, a potentially oxidant radical, can function as either a pro- or an
antiapoptotic agent (29). NO is physiologically produced by
NOS in various cellular types including endothelial cells and neurons,
and it acts as a pleiotropic messenger molecule regulating blood flow
and cellular signaling (29). However, many studies suggested
that NO is associated with several neuropathological processes and
triggers apoptosis in different cell types (29, 35).
Induction of ischemia causes activation of nNOS, resulting in excess
production of NO (32, 36) and allowing it to react with
superoxide to form peroxynitrite, which is associated with cell death
(36). Addition of NO donors induces apoptosis in macrophages (1), astrocytes (24), cerebellar
granule cells (34), PC12 cells (19), and human
neuroblastoma cells (6). Recently, DLC has been implicated
to function as an endogenous regulator of nNOS by showing association
with nNOS in vivo (25). In addition, its expression level is
nearly parallel with that of nNOS in different brain regions
(17). Furthermore, DLC levels rapidly increase in brain
regions that are resistant to ischemic damage, suggesting that
induction of DLC expression following global ischemia counteracts the
rise of nNOS activity, thereby protecting neurons from excess
NO-induced damage (16). Also, DLC functions as an
antiapoptosis factor contributing to resistance to kainic
acid-induced apoptosis in the rat hippocampus (3). Our present study showed that stimulation of DLC expression could inhibit programmed cell death by preventing the increase of nNOS activity. Therefore, an increase of DLC expression may be used as an
endogenous mechanism to counteract the elevation of nNOS activity and
protect neurons from excess NO-induced damage.
In summary, the model for the mechanism by which COX-2 inhibits
apoptosis by NGF withdrawal in PC12 cells is that DLC functions as a downstream mediator of COX-2 (Fig.
8). COX-2 stimulates DLC expression and
leads to increased association of DLC with nNOS. This prevents
elevation of nNOS activity, thereby inhibiting apoptosis of PC12 cells. The data presented here provide initial evidence for a mechanism linking COX-2 with regulation of nNOS and inhibition of
apoptosis.
View larger version (12K):
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[in a new window]
|
FIG. 8.
Model for regulation of apoptosis by COX-2.
Removal of NGF from differentiated PC12 cells elevates nNOS expression
and activity, thereby leading to production of excess NO and
superoxide, which contributes to cell death by producing peroxynitrite.
Stimulation of COX-2 expression by agonists is concomitant with
increased production of PGE2. PGE2 is released
from the cells and can stimulate the prostaglandin (PG) receptors on
PC12 cells, leading to an increase in DLC expression. Stimulation of
DLC expression results in an increase in association of DLC with nNOS,
causing inactivation of nNOS and thus reducing production of NO and
superoxide. This may prevent PC12 cells apoptosis induced by
NGF withdrawal.
|
|
| |
ACKNOWLEDGMENTS |
We thank Cecilia J. Hillard (Medical College of Wisconsin) for
her help with the nNOS activity assay, Owen Griffith (Medical College
of Wisconsin) for his generous gift of L-VNIO, and Samie R. Jaffrey (John Hopkins University) for his generous gift of DLC (PIN)
polyclonal antibody. We are grateful to Bradley Miller for excellent
technical assistance.
This work was supported by National Institutes of Health research
grants DK 41684 to A.S., HL 22563 to M.J.D., and ACS-IRG 170 to R.J.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Medicine and Cardiovascular Research Center, Medical College of
Wisconsin, 8701 Watertown Plank Road, Milwaukee, WI 53226. Phone: (414)
456-4438. Fax: (414) 456-6515. E-mail: sorokin{at}mcw.edu.
Present address: Molecular Biology Resources, Inc., Milwaukee,
WI 53218.
| |
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Abstract
Introduction
