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Vol. 14, Issue 7, 3041-3054, July 2003
B–dependent Activation of Cyclooxygenase-2 by Rho GTPases: Effects on Tumor Growth and Therapeutic Consequences
Department of Molecular and Cellular Biology of Cancer, Instituto de Investigaciones Biomédicas, Consejo Superior de Investigaciones Cientificas, Madrid, Spain
Submitted August 28, 2002;
Revised March 6, 2003;
Accepted March 6, 2003
Monitoring Editor: Richard Assoian
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ABSTRACT |
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 TOP ABSTRACT INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONACKNOWLEDGMENTSREFERENCES |
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B (NF-B), but not Stat3, a transcription factor required
for RhoA-induced tumorigenesis. With respect to RhoA, this effect is dependent
on ROCK, but not PKN. Treatment of RhoA-, Rac1-, and Cdc42-transformed
epithelial cells with Sulindac and NS-398, two well-characterized nonsteroid
antiinflammatory drugs (NSAIDs), results in growth inhibition as determined by
cell proliferation assays. Accordingly, tumor growth of RhoA-expressing
epithelial cells in syngeneic mice is strongly inhibited by NS-398 treatment.
The effect of NSAIDs over RhoA-induced tumor growth is not exclusively
dependent on COX-2 because DNA-binding of NF-B is also abolished upon
NSAIDs treatment, resulting in complete loss of COX-2 expression. Finally,
treatment of RhoA-transformed cells with Bay11-7083, a specific NF-B
inhibitor, leads to inhibition of cell proliferation. We suggest that
treatment of human tumors that overexpress Rho GTPases with NSAIDs and drugs
that target NF-B could constitute a valid antitumoral strategy. |
INTRODUCTION |
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TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONACKNOWLEDGMENTSREFERENCES |
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;
Bar-Sagi and Hall, 2000; Aznar
and Lacal,
2001a,b,
2003;
Ridley, 2001;
Schmitz et al. 2002).
Rho proteins regulate transcription via several transcription factors that
include SRF, NF-B, E2F, Stat3, Stat5a, Pax6, FHL-2, Estrogen Receptor
/
, ELK, PEA3, ATF2, MEF2A, Max, and CHOP/GADD153
(Aznar and Lacal, 2001b).
When overexpressed, Rho GTPases are tumorigeneic and transform murine
fibroblast to promote in vivo tumor growth and distant lung metastasis in
syngeneic mice (Perona et al.,
1993; van Leeuwen et
al., 1995; del Peso
et al., 1997). As well, they mediate many aspects of the
oncogenicity of several oncogenes such as Ras, Met, EGFR, and IGFR (Qiu et
al.,
1995a,b;
Nur-E-Kamal et al.,
1999; Boerner et al.,
2000; Sachdev et al.,
2001). Overexpression or deregulation of the GTPase or some
element of the Rho pathway has been reported for human breast, colon, head and
neck squamous carcinomas; and testicular germ, ovarian, leukemias,
osteosarcomas, gastric, thyroid papillary, prostate, and hepatocellular
cancer, among others (reviewed in Aznar and
Lacal, 2003).
The role of transcription in promoting the tumoral and metastatic phenotype
of Rho GTPases is acquiring increased attention. We have recently described
that activation of Stat3 is involved in transformation of human fibroblasts by
oncogenic RhoA (Benitah et al., 2003). Furthermore, we have
identified Stat5a as an essential component of RhoA-induced epithelial to
mesenchymal transition and cell motility (Aznar et al., 2002).
Transcription of cyclin D1 and the protooncogene c-myc takes place by
a Rho-dependent mechanism that permits G1 entry
(Danen et al., 2000;
Chiariello et al.,
2001; Welsh et al.,
2001). Finally, an indirect role for both nuclear factor-B
(NF-B) in RhoGEF-mediated tumorigenesis, and for FHL2 in Rho-dependent
tumor progression of prostate cancer, has been proposed
(Whitehead et al.,
1999; Muller et al.,
2002). With respect to the metastatic phenotype, transcription and
expression of the uPAR gene is dependent on RhoA upon integrin
signaling, and SRF is regulated by changes in actin dynamics to promote
transcription of vinculin and actin, both necessary for the cytoskeletal
changes essential to motility and invasion
(Sotiropoulos et al.,
1999; Muller et al.,
2000,
2002;
Psichari et al.,
2002). However, little is known on the target genes regulated by
these transcription factors that allow proper tumor progression in the context
of Rho GTPases.
Herein, we demonstrate that Rho GTPases induce cyclooxygenase-2 (COX-2)
expression in epithelial cells by a NF-B–dependent mechanism.
COX-1 and COX-2 catalyze the synthesis of prostaglandins
(Gupta and Dubois, 2001).
Whereas COX-1 is constitutively expressed in most tissues and maintains
housekeeping prostaglandin synthesis, COX-2 is inducible upon proinflammatory
cytokines, growth factors, and oncogenes
(Dubois, 2001;
Gupta and Dubois, 2001).
Accordingly, tumor cells that express COX-2 secrete proangiogenic factors
stimulating tube formation and endothelial migration, contributing to the
vascularization and growth of the tumor
(Tsujii et al., 1998;
Cao and Prescott, 2002). COX-2
is tumorigenic because its overexpression in the mammary glands itself causes
malignant growth and metastasis in transgenic mice
(Liu et al., 2001).
At last, several human tumors including colon, breast, pancreas, lung, and
squamous cell carcinoma of the head and neck display high levels of COX-2
protein (Tegeder et al.,
2001).
COX-2 has acquired great interest as a potential target for the prevention
and treatment of several human cancers. Nonsteroidal anti-inflammatory drugs
(NSAIDs) that inhibit COX-2 are potent antitumoral and antimetastatic agents
in vivo against several tumor models
(Tegeder et al.,
2001). However, these drugs display COX-2 independent effects that
mainly affect activator protein-1, mitogen-activated protein kinase, and
NF-B (Tegeder et al.,
2001). Consequently, the promiscuity of NSAIDs has led to the
development of new COX-2 inhibitors, termed Coxibs (celecoxib and rofecoxib)
with very selective COX-2 inhibitory capacity, albeit, their specificity has
been recently challenged (Jones et
al., 1999; Tegeder et
al., 2001).
Herein, we provide evidence that indicates that treatment of Rho-bearing
tumors with NSAIDs and drugs that target NF-B may constitute a valid
cancer therapy.
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MATERIALS AND METHODS |
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TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONACKNOWLEDGMENTSREFERENCES |
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Plasmids
PCDNAIIIB plasmid (Invitrogen) and derived expression vectors encoding for
constitutively activated RhoA (QL), Rac1 (QL), and Cdc42Hs (QL) proteins and
their wild-type versions have been described previously
(Aznar et al., 2001).
The HIV-Luc reporter that contains NF-B-responsive elements has been
described (Aznar et al.,
2001). PRCCMV-p65 and pRCCMV-IB A32/36S, wild-type and
dominant negative pCEFL-Stat3 constructs, have been described previously
(Aznar et al., 2001).
COX-2-Luc reporter vector containing the promoter sequence spanning from
nucleotide -1778 to +107 of human COX-2 gene was kindly provided by Dr.
Muñoz Salas (Diaz-Cazorla et
al., 1999). Wild-type and dominant negative (deltaF3)
pRCCMV-FLAG-PKN constructs were kindly provided by Dr. Ono (Biosignal Research
Center and Graduate School of Science and Technology, Kobe University, Japan).
Wild-type and dominant negative (KD-IA) pCAG-myc-ROCK constructs were a kind
gift of Dr. Narumiya (Department of Pharmacology, Kyoto University, Faculty of
Medicine, Kyoto, Japan).
Gene Expression Analysis
Cells (2 x 105) were transfected with the indicated
plasmids. Forty-eight hours after transfection protein extracts were prepared
by lysis with the commercially available Reporter lysis buffer (Promega,
Madison, WI). Protein (0.5–2 µg) was assayed for luciferase activity
by using a commercial kit as described by the manufacturer (Promega).
Transfection efficiencies were corrected by detection of the expressed
proteins by Western immunoblotting and with a constitutive RSV5-CAT reporter
vector as indicated previously (Aznar
et al., 2001).
Western Blot Assays and Antibodies
For protein expression assays, cells were transfected with the
corresponding plasmids and incubated in DMEM 0.5% fetal bovine serum or 10%
fetal bovine serum where indicated for the next 48 h. Preparation of the
samples was carried out as described previously (Benitah et al.,
2003). After transfer of proteins to Immobilon-P polyvinylidene difluoride
membrane (Millipore, Bedford, MA), the blots were incubated with the
corresponding antibodies, and immunocomplexes were visualized by enhanced
chemiluminescence detection (Amersham Biosciences, Piscataway, NJ) by using
either an anti-rabbit and anti-mouse antibody conjugated to peroxidase (Santa
Cruz Biotechnology, Santa Cruz, CA). -COX-2 and -Cdc42
monoclonal antibodies were purchased to BD Biosciences (San Jose, CA).
-COX1, -p65, and -RhoA were purchased to Santa Cruz
Biotechnology. Anti-Rac1 was purchased to Upstate Biotechnology (Lake Placid,
NY). Anti-Stat3 and anti-phosphoStat3 (Tyr 705) were purchased to Cell
Signaling Technology (Beverly, MA). Mouse monoclonal anti-phospho-p44/42
mitogen-activated protein kinase (Thr202/Tyr204) and phospho-MEK1 were
purchased from New England Biolabs (Beverly, MA). Anti-FLAG and anti-myc
antibodies to detect the expression of PKN and ROCK were purchased from Santa
Cruz Biotechnology.
Electrophoretic Mobility Shift Assays (EMSAs)
For EMSA assays, cells were either transfected with the corresponding
plasmids or indicated treatments and incubated in appropriate medium for
24–36 h. Nuclear extracts were obtained as described previously (Benitah
et al., 2003). Briefly, 2 µg of nuclear protein was incubated with
0.1 ng of B probe (5000 cpm) or with unlabeled probe and subjected to
electrophoresis (80 V, 45 min) on a nondenaturing 4% acrylamide/bisacrylamide
gel (29:1) (Bio-Rad, Hercules, CA). For gel supershift analysis, the nuclear
extract was incubated for 10 min (room temperature) with anti-p65 or anti-p50
(Santa Cruz Biotechnology) in ice before addition of the labeled probe. For
nonspecific competition, Stat3-binding element hSIE from the c-fos
promoter was used.
Anchorage-independent Growth in Soft Agar
Cells (3 x 103; MDCK or RhoAQL stable clones) in 60-mm
dishes were trypsinized and resuspended in fresh medium. Anchorage-independent
growth assay was performed as described previously by plating 5000 cells/60-mm
dish (Aznar et al.,
2001). After 3 wk of incubation the medium was absorbed, 500 µl
of 0.005% crystal violet was added and incubated for 1 h at 37°C. Plates
were then washed once with 1x phosphate-buffered saline and visualized
under a microscope.
Cell Cytometry and Cell Proliferation Assays
For cell proliferation assays, 1500 cells were seeded in 24-well dishes and
24 h later the indicated drugs were added to fresh medium. At the indicated
time points, cells were washed, fixed on 1% glutaraldehyde (500 µl) for 30
min, and washed three times with 1x phosphate-buffered saline. Once all
time points were collected, 500 µl of 0.1% crystal violet was added to
cells for 30 min and then washed as described above. To obtain the
incorporated crystal violet 500 µl of 10% acetic acid was added for 10 min
and was later collected and read at a wavelength of 595 nm. For cell cytometry
analysis, 2 x 105 cells were plated on 60-mm dishes and were
treated with sulindac or NS-398 for the indicated time. For FACSSCAN analysis,
the protocol was followed as described previously
(Embade et al.,
2000). Adhered cells were trypsinized and the cell membrane was
permeabilized with 70% ethanol, spun, and resuspended in propidium iodide.
In Vivo Tumorigenic Assay and NSAIDs Treatment
Cells (2 x 106) were trypsinized and resuspended in 100
µl of fresh DMEM medium. Cells were injected subcutaneously in the limb and
tumor growth was monitored twice a week for 90 d. Tumor volume was determined
using the following equation: V = (Dxd2)/2. When tumors had reached
a volume of 0.1 cm3, 3 mg/kg NS-398 was injected intraperitoneally
three times a week during 9 wk. Tumor volume was measured at 2-d intervals
during the treatment.
Prostaglandin E2 (PGE2) Quantification
Cells (5000) were plated on 24-well dishes and 24 h later they were treated
with Bay11-7083 (10 µM) at the indicated time intervals (6, 8, 12, and 24
h) to collect all the supernatants at the same time of analysis. The amount of
PGE2 was measured using the commercial kit PGE2 EIA
kit-monoclonal (Cayman Chemical) as described by the manufacturer. Medium (50
µl) was collected and mixed in a PGE2 monoclonal antibody-coated
96-well dish and incubated overnight for 18 h at 4°C. The wells were then
washed five times and incubated with Ellman's reagent in the dark for 90 min
at room temperature. The assay was read at a single wavelength of 405 nm.
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RESULTS |
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TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONACKNOWLEDGMENTSREFERENCES |
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B transcriptional activation. Thus, we sought to verify whether
Rac1QL regulates COX-2 levels in MDCK cells by stable expression. In this
sense, we generated MDCK stable transfectants of pcDNAIIIb or its derived
vector encoding for Rac1QL, and verified the level of COX-2 expression. We
were able to select six independent Rac1QL-expressing clones that exhibited
increased levels of Rac1QL and that induced high COX-2 expression of which
three representative ones are shown (Figure
1D). Additionally, we generated MDCK stable transfectants of
vectors encoding for RhoA and Cdc42QL, and tested for the level of COX-2
expression for three independent clones of each GTPase. Two representative
RhoAQL clones SP7.3, SP7.4, and a mass culture (SP7.29) that express different
amounts of oncogenic RhoA, exhibit differential expression of COX-2 with
respect to MDCK control cells, SP7.0. The same effect was observed with two
independent Cdc42-expressing clones, SP7.18 and SP7.17, and a mass culture
(SP7.20). Thus, RhoA, Rac1, and Cdc42 (QL) induce high levels of COX-2 also in
MDCK cells.
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In addition, we verified that this effect was specific to COX-2 and not the constitutively expressed isoform COX-1 (Figure 1E). SP7.0 (MDCK-pcDNAIIIb control) and cells that express high levels of each GTPase, SP7.29 (RhoAQL), SP7.9 (Rac1QL), and SP7.18 (Cdc42QL) were used to verify COX-1 expression. As seen in Figure 1E the levels of COX-1 remain unchanged upon Rho GTPases expression in MDCK cells. The same results were obtained with all RhoAQL-, Rac1QL-, and Cdc42QL-expressing clones and mass cultures with identical results (our unpublished data). As well, no change in COX-1 expression was observed upon transient expression of RhoAQL, Rac1QL, or Cdc42QL in NIH3T3 cells compared with empty vector transfected cells (Figure 1E).
As shown in Figure 1B, HT29
human colorectal carcinoma cells show high endogenous level of COX-2 compared
with other cell systems. We next verified whether Rho GTPases are involved in
the expression of COX-2 in the human colorectal cancer-derived cell line HT29.
To that end, we attempted to generate HT29 stable transfectants that express
either dominant negative Rac1 (N17), Cdc42 (N17), RhoA (N19), or control empty
vector (pcDNAIIIb). As observed in Figure
1F, expression of Cdc42N17 induced a drastic reduction of COX-2
expression, whereas Rac1N17 expression had no effect on COX-2 levels. The same
result was obtained with transient expression of Cdc42N17 in HT29 cells,
although due to a transfection efficiency of 
35%, we did not observed a
full inhibition of COX-2 expression (our unpublished data). Although HT29
cells can transiently express high levels of dominant negative RhoA (N19), we
were not able to obtain viable clones that expressed dominant negative RhoA
(N19) in a stable manner. Thus, we expressed RhoA in transient transfection
experiments. RhoAN19 did not affect the expression of COX-2 in HT29 cells
(Figure 1F). As controls of
dominant negative activity for each GTPase, we verified that expression of
RhoAN19, Rac1N17 and Cdc42N17 in HT29 cells inhibited the activation of
NF-B activity by Ost, Vav1, and Dbl, respectively, as described
previously (Montaner et al. (1998)) (our unpublished data).
Because HT29 have a high level of endogenous COX-2 expression, we next investigated whether Rho GTPases were able to regulate COX-2 expression in another human colorectal cancer-derived cell line such as DLD-1, with low levels of expression of Rho GTPases and which completely lacks endogenous COX-2 expression. As shown in Figure 1G, RhoA efficiently induced the expression of COX-2 in DLD1 cells when expressed ectopically. In contrast, Cdc42 (Figure 1G), and Rac1 (our unpublished data) failed to do so. Thus, these results suggest that Rho GTPases can modulate COX-2 expression in human colon cancer. However, each GTPase analyzed in our work seems to have differential contribution or mechanisms to effect regulation of COX-2.
Rho-A-, Rac1-, and Cdc42-induced Expression of COX-2 Is Dependent on
the NF-B Transcription Factor
Analysis of the promoter of human COX-2 revealed several putative binding
sites for transcription factors whose activity is modulated by Rho GTPases.
These include NF-B, SRF, C/EBP, AP-1, c-Myc, and STATs. To
quantify the extent of transcription of the cox-2 gene under Rho
signaling a reporter vector termed COX2-Luc containing the cox-2
promoter region spanning from bases -1772 to +106 was generated
(Diaz-Cazorla et al.,
1999). Transient transfection of 0.5 µg of COX2-Luc into 7.0
(MDCK-pcDNAIIIB), 7.3 (MDCK-RhoAQL), 7.9 (MDCK-Rac1QL), and 7.18
(MDCK-Cdc42QL) clones was carried out and 48 h posttransfection luciferase
activity was measured. All three RhoA, Rac1, and Cdc42 (QL) induced
transcription of the cox-2 promoter compared with empty vector
transfected cells (Figure
2A).
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It has been reported that NF-B regulates COX-2 expression under a
variety of circumstances such as inflammation, hypoxia, bacterial infections,
or colorectal cancers (Crofford et
al., 1997; Schmedtje
et al., 1997; Lim
et al., 2001). Thus, we verified whether this
transcription factor played any role in the induction of COX-2 by Rho GTPases.
First, we transiently expressed dominant positive IB that
carries serine residues 32 and 35 mutated to alanine
(IBA32/A36), whose expression leads to a
very efficient inhibition of NF-B, and verified COX-2 levels under Rho
signaling in MDCK cells (Karin et
al., 2002). The induction of COX-2 by ectopic expression of
both RhoAQL and Cdc42QL was drastically inhibited by
IBA32/A36
(Figure 2B). The same result
was obtained with two independent stable clones for RhoAQL (SP7.3 and SP7.29)
and Cdc42QL (SP7.17 and SP7.18) (our unpublished data). As well,
Rac1-dependent induction of COX-2 relies on the NF-B pathway, because
ectopic expression of dominant positive IB in SP7.7 cells
inhibited COX-2 expression (Figure
2C). These results were also obtained with another clone, SP7.9
(our unpublished data). As expected, inhibition of Rho GTPases-induced COX-2
expression by IBA32/A36 was at the level
of transcription because it abrogated COX2-Luc transcription when expressed in
stable clones of each GTPase (Figure
2D). As a control of dominant positive
IBA32/A36 activity, we verified that its
expression led to inhibition of NF-B activity and DNA-binding induced
by Rho GTPases (Figure 2E; our
unpublished data).
To further test whether NF-B is involved in the induction of COX-2
by Rho GTPases, we next expressed the p65 subunit of NF-B together with
RhoAQL and Cdc42QL or control vector in MDCK cells. As seen in
Figure 2F, transient
coexpression of p65 with either RhoAQL or Cdc42QL in MDCK cells potentiated
COX-2 expression. The same effect was observed when p65 was transiently
transfected into two Rac1QL-expressing clones, SP7.7 and SP7.9, whereas
overexpression of NF-B alone in MDCK cells did not cause a significant
elevation of COX-2 expression (Figure
2G; our unpublished data). Expression of p65 in RhoA, Rac1, or
Cdc42QL stable clones led to an increase in cox-2 promoter activity
by more than threefold compared with their respective controls
(Figure 2H). Accordingly,
coexpression of p65 increased NF-B transcriptional activity induced by
all three GTPases (Figure 2I).
Thus, NF-B mediates the induction of COX-2 by oncogenic RhoA, Rac1, and
Cdc42 at the transcriptional level.
Induction of COX-2 by RhoGTPases Is Not via Stat3
Activation of Stat3 by members of the family of RhoGTPases, such as RhoA
and Rac has been described previously
(Simon et al., 2000;
Aznar et al., 2001;
Faruqi et al., 2001).
Furthermore, Stat3 is necessary for RhoA-induced anchorage independent growth
(Aznar et al., 2001).
Because the cox-2 promoter contains putative Stat-binding elements,
we sought to verify whether Stat3 might act downstream of Rho GTPases to
induce COX-2 expression.
To that end, we expressed wild-type Stat3 (wt) or a dominant negative Stat3 with a mutated transactivation domain (Stat3D), in RhoAQL-, Rac1QL-, and Cdc42QL-expressing clones SP7.29, SP7.9, and SP7.17 (Figure 3). RhoA QL, Rac1 QL, and Cdc42QL efficiently induced tyrosine-705 phosphorylation of Stat3 in MDCK cells; however, no change in the level of COX-2 was observed upon transfection of either Stat3wt or Stat3D compared with vector control transfected cells. Thus, although the COX-2 promoter contains Statresponsive elements, and Stat3 is activated by Rho GTPases in MDCK epithelial cells, there is no functional relationship between Stat3 and COX-2 under Rho GTPases signaling.
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ROCK, but Not PKN, Is Necessary for RhoA-induced COX-2 Expression via
NF-B
RhoA signaling is dependent on a large number of effector proteins that
physically interact with RhoA and transmit the signal within the cell. Among
the most studied of these are the families of ROCK and PKN
(Van Aelst and D'Souza-Schorey,
1997). These families of effectors mediate most of the
cytoskeletal changes induced by RhoA and have been implicated in some of the
developmental processes that lead to growth and metastasis of human tumors by
RhoA. Thus, we next studied the possible role of ROCK and PKN in RhoA-induced
expression of COX-2. To that end, we expressed either ROCKwt or dominant
negative ROCKdn in RhoAQL-expressing cells or MDCK parental cells, and
measured the protein level of COX-2. Although expression of ROCKwt synergized
with RhoA to induce expression of COX-2, ROCKdn greatly impaired COX-2
expression (Figure 4A). This
effect was specific to RhoA signaling because overexpression of ROCKwt or
ROCKdn in parental MDCK cells had no effect over COX-2 expression
(Figure 4A). No effect of ROCK
on COX-2 expression was observed in MDCK parental cells
(Figure 4A). Inhibition of
COX-2 expression was also observed when RhoAQL-expressing cells were treated
with Y-27632, a specific inhibitor of ROCK kinases
(Figure 4B).
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As shown above, expression of COX-2 induced by RhoA is at the
transcriptional level via the NF-B pathway. Thus, we next verified
whether ROCK was involved in this process. The COX2-Luc reporter vector was
transfected in MDCK-RhoAQL cells together with control vector, ROCKwt, or
ROCKdn and transcription of the COX-2 promoter was measured. As well,
MDCK-RhoAQL cells transfected with the COX2-Luc reporter were treated with
Y-27632 (10 µM) for 24 h. Although expression of ROCKwt resulted in a
moderate increase in transcription of the COX-2 proximal promoter region,
expression ROCKdn or treatment with Y-27632 inhibited such transcription
(Figure 4C). The same type of
experiment was carried out with the NF-B–responsive reporter
vector HIV-luc, to verify whether ROCK had any effect over NF-B
activity. Surprisingly, expression of ROCKwt or ROCKdn, or treatment with
Y-27632 had the same effect over NF-B activity than COX-2 promoter
transcription.
The same experiments as described above were carried out with respect to PKN. However, expression of PKNwt of PKNdn in RhoAQL-transformed cells had no effect over COX-2 expression (Figure 4E). As well, no changes in the transcription of the COX-2 promoter were observed between MDCK cells transfected with RhoAQL or cotransfected with RhoAQL and PKNwt or PKNdn (Figure 4F). Expression of FLAG-tagged PKN and myc-tagged ROCK constructs were verified using anti-FLAG and anti-myc antibodies, respectively (Figure 4, A and E).
Thus, ROCK, but not PKN, affects RhoA-mediated COX-2 expression at the
transcriptional level via modulation of the activity of NF-B. To our
knowledge, this is the first evidence for a relationship between NF-B
and ROCK kinases.
Nonsteroidal NSAIDs Inhibit Both Proliferation and Tumor Growth of
RhoAQL Epithelial Cells
Given the implication of COX-2 and Rho GTPases overexpression in
tumorigenesis and metastasis of human tumors, the above-mentioned results
suggest that COX-2 might play a role in RhoA-mediated tumorigenesis. First, we
analyzed the tumorigenic potential of stable MDCK-RhoAQL transfectants. Four
different RhoAQL expressing clones were plated on soft agar to determine their
capacity to grow under anchorage-independent conditions compared with
MDCK-pcDNAIIIb (negative control) and MDCK-K-RasV12 cells (positive control).
Although MDCK-pcDNAIIIb cells do not grow under these conditions, all
MDCK-RhoAQL clones displayed anchorage-independent growth. Both the growth
rate and size of RhoAQL clones in all cases was lower and smaller,
respectively, compared with MDCK-K-RasV12 clones. Representative pictures of
RhoAQL and K-RasV12 clones are shown in
Figure 5A. Accordingly, four
mice were injected with 2 x 106 MDCK-RhoAQL (SP7.3 and
SP7.29) cells and tumor growth was monitored weekly up to 90 d after
injection. As controls, MDCK-pcDNAIIIb and MDCK-KrasV12 cells were injected in
the same conditions. Although control MDCK-pcDNAIIIb cells did not induce any
detectable tumor, K-RasV12 cells developed tumors in 100% of injected mice
approximately 10 to 15 d after injection. Both MDCK-RhoAQL clones (SP7.3 and
SP7.29) induced tumor growth in three of four animals (75%). However, both the
tumor volume and growth rate of RhoAQL clones were significantly lower than
that displayed by K-RasV12 cells because RhoAQL tumors reached a size similar
to K-RasV12 tumors 30 d after injection, with tumor volumes ranging 1
cm3 after 2 mo of inoculation. Representative pictures of
MDCK-RhoAQL induced tumors are shown in
Figure 5B.
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We next verified whether RhoAQL clones were susceptible to growth
inhibition upon treatment with two NSAIDs, sulindac and NS-398. MDCK,
MDCK-K-RasV12, and MDCK-RhoAQL (SP7.29) cells were treated with increasing
amounts of Sulindac or NS-398, and cell viability was measured at 24-h
intervals up to 4 d (Figure 5, C and
D). A slight, nonsignificant decrease in cell growth was observed
on MDCK-pcDNAIIIb cells upon treatment with both NSAIDs. However, in keeping
with previous publications (Taylor et
al., 2000), K-RasV12-expressing cells were significantly more
sensitive to sulindac and NS-398. RhoAQL-expressing cells were also highly
sensitive to sulindac and NS-398 treatment as early as 24 h upon treatment.
Inhibition of proliferation was observed at concentrations of 50 µM for
NS-398 and 100 µM for sulindac, with strong inhibition at 100 and 200
µM, respectively (Figure 5, C and
D). However, maximal inhibition was achieved at concentrations of
150 and 400 µM for NS-398 and sulindac, respectively. Inhibition of cell
proliferation with both NSAIDS was also observed upon treatment of MDCK-Rac1QL
and MDCK-Cdc42QL cells at the same concentrations as those used for
RhoAQL.
The growth inhibitory action of both drugs over RhoAQL-expressing cells versus control MDCK cells was due to strong induction of apoptosis rather than a cell cycle arrest as determined by flow cytometry. MDCK and RhoAQL cells were treated with sulindac (400 µM) and NS-398 (150 µM) for 120 h and analysis of propidium iodide incorporation by flow cytometry was carried out at 24-h intervals. Figure 5E shows a representative histogram at 96 h of NS-398 treatment of MDCK and MDCK-RhoAQL cells. Although control MDCK cells exhibited a residual 13.79% of apoptosis at 96 h of treatment with NS-398, >45% of RhoAQL cells were undergoing apoptosis. Although a higher toxicity was observed with sulindac in MDCK control cells, a strong induction of apoptosis was observed in RhoAQL expressing clones upon sulindac treatment (our unpublished data).
In addition, the capacity of NS-398 to inhibit RhoAQL-induced tumor growth in vivo was studied. To this end, 12 mice were injected with MDCK-RhoAQL (SP7.29) cells and when tumors had reached a mean volume of 0.05–0.1 cm3 (approximately 1 mo after inoculation), mice were treated intraperitoneally with either NS-398 (3 mg/kg, 3 times a week during 4 wk) or vehicle, and tumor growth was compared between both populations. As observed in Figure 6A, a strong tumor growth inhibition was obtained in NS-398–treated mice that was statistically significant after 1 wk of treatment (p < 0.05). A slight decrease in tumor volume was observed at this time, yet tumor size was maintained all throughout the time of treatment after this first week. A representative picture of a treated and a nontreated mouse is depicted in Figure 6B. Therefore, NS-398 is a very efficient antitumoral agent against tumors that arise as a consequence of RhoAQL overexpression.
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Overexpression of members of the family of Rho GTPases in diverse human tumors has been described. Moreover, in several tumoral models, Rho GTPases have been found to be essential either for tumor growth or metastasis. Thus, we next evaluated whether inhibition of Rho GTPases in human colorectal carcinoma-derived cell line HT29, which overexpress both Cdc42 and RhoA, would have any effect over their capacity to promote tumor growth in vivo. As mentioned above, we could not obtain viable stable RhoAN19-HT29 clones; however, we established two HT29-Cdc42N17 clones (SP1.19 and SP1.21), which have completely lost expression of COX-2 (Figure 1F). Both HT29-Cdc42N17 stable cell lines showed an approximate 50% reduction with respect to vector transfected HT29 cells in their capability to grow under anchorage independent conditions in soft agar (Figure 6C). Furthermore, both SP1.19 and SP1.21 clones were injected each in four nude mice and tumor growth was monitored at 3-d intervals compared with control vector transfected HT29 cells (SP1.7). Tumor growth of HT29-Cdc42N17 cells (clones SP1.19) was significantly delayed compared with that of parental HT29 cells (SP1.7), with statistical significance (p <0.05) (Figure 6D). Thus, Cdc42 is an important signaling component that contributes to tumor growth of HT29 human colorectal carcinoma cells.
NF-B Activity Is Affected by Both Sulindac and NS-398
Treatment in RhoAQL-expressing Cells and Is Necessary for Cell
Proliferation
Several works have shown that different NSAIDs elicit their
antiinflammatory and antitumoral effects by COX-2–independent mechanisms
(Tegeder et al.,
2001). In fact, sulindac and NS-398 have been shown to affect
NF-B activity as well as other proteins in different cell types that
would account for some of their specific effects
(Yamamoto et al.,
1999; Shao et al.,
2000; Mack et al.,
2001). This is of particular interest in our system where both
proteins, COX-2 and NF-B, are directly connected. Thus we sought to
determine the effect of sulindac and NS-398 treatment on NF-B activity
under RhoAQL signaling. To that end, two RhoAQL expressing clones, SP7.3 and
SP7.29, were treated with sulindac (400 µM) or NS-398 (150 µM) for 72 h,
and DNA-binding of NF-B studied using a B consensus element. As
shown in Figure 7A, NF-B
DNA-binding was significantly impaired upon treatment with both drugs.
Accordingly, the level of nuclear p65 subunit was verified to be lower in
treated versus untreated cells. Whole cell lysates were obtained under the
same conditions and the total level of cellular p65 was determined to remain
constant (Figure 7A). Thus,
inhibition of NF-B by sulindac and NS-398 is not due to reduced
NF-B synthesis but rather to a specific inhibition of its nuclear
migration and DNA-binding activity.
|
Expression of COX-2 by RhoAQL is dependent on NF-B. Therefore, we
hypothesized that inhibition of NF-B upon sulindac and NS-398 treatment
would lead to a reduction in the level of expressed COX-2. Whole cell extracts
were obtained from SP7.3 and SP7.29 cells treated during 24 h with 400 µM
sulindac or 150 µM NS-398, and COX-2 expression was determined by Western
immunoblotting (Figure 7B).
Interestingly, the level of COX-2 was significantly reduced in
sulindac-treated cells and complete loss of expression was observed upon
NS-398 treatment. This effect was not due to a general loss of expression of
cellular proteins because the level of endogenous p65 was unaffected upon
treatment with both drugs. A similar effect was observed with 50 µM NS-398,
although the effect was not as drastic (our unpublished data). Thus, both
sulindac and NS-398 affect both COX-2 and NF-B activities.
Last, we verified whether treatment of MDCK-pcDNAIIB and MDCK-RhoAQL cells
with a specific inhibitor of NF-B, termed Bay11-7083, would confirm
these results. As shown in Figure
7C, treatment of RhoAQL-expressing cells with Bay11-7083 resulted
in inhibition of both COX-2 expression and NF-B DNA-binding. We next
verified if exposure of MDCK-RhoAQL cells to Bay11-7083 would lead to
inhibition of cell proliferation. MDCK-pcDNAIIIb and MDCK-RhoAQL cells were
treated with Bay11-7083 (10 µM) during 96 h, and cell viability was
measured at 24-h intervals (Figure
7D). Although treatment of MDCK cells with Bay11-7083 produced an
inhibition of cell proliferation, this inhibition was drastically increased in
MDCK-RhoAQL cells. Thus, inhibition of NF-B with Bay11-708 drastically
interferes with cell proliferation driven by oncogenic RhoA, in keeping with
the results shown above on a similar effect induced by the COX-2 inhibitors
sulindac and NS-398.
To discriminate the effects on NF-B from those of COX-2, we next
analyzed the possible inhibitory effect of Bay11-7083 directly on COX-2
activity at early stages of treatment
(Figure 7E). For this, we
measured synthesis of PGE2 in both MDCK control cells (transfected
with the empty vector) and in RhoAQL transformed cells. Bay11-7083 had no
significant effect on COX-2 activity up to 8 h of treatment, whereas a partial
inhibition of PGE2 production could be observed at 12 h of
treatment. This effect was due to inhibition of COX-2 expression rather than a
direct inhibition over its enzymatic activity
(Figure 7F). As well, as a
positive control we treated MDCK-RhoAQL cells with NS-398 (100 µM) for 8 h
in the same experiment and verified that there was a much more efficient
inhibition of COX-2 enzymatic activity. Thus, NF-B activity is
necessary for cell proliferation induced by RhoA.
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DISCUSSION |
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TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONACKNOWLEDGMENTSREFERENCES |
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;
Sahai and Marshall, 2002).
Many works have delineated the downstream effectors to RhoA, Rac1, and Cdc42
that contribute to the tumoral phenotype. On the other hand, there is a
significant lack of knowledge about the physiological target genes whose
expression is modulated under persistent Rho signaling contributing to tumor
development and metastasis. In this sense, cyclin D1, c-Myc, p21 (Cip1), and
p27 (Kip1) are among the few known targets that might enable aberrant growth
stimulated by Rho GTPases (Pruitt and Der,
2001).
In this work, we identify COX-2 as a target gene that is transcriptionally
regulated by Rho GTPases in several cell lines of murine, canine, and human
origin. Activation of COX-2 by Rho GTPases may be cell specific, as many other
Rho-dependent signaling pathways (reviewed in
Aznar and Lacal, 2001b). Thus,
overexpression of COX-2 in human colon cancer HT29 cells is completely
dependent on Cdc42, because stable expression of dominant negative Cdc42N17
led to complete loss of COX-2 expression. However, although transient
expression of oncogenic RhoAQL or Rac1QL in HT29 results in an increase in
COX-2 expression, inhibition of endogenous Rac1 or RhoA through expression of
their dominant negative inhibitory mutants did not affect COX-2 expression in
the cell line. However, DLD1 cells that express low levels of Rho GTPases and
completely lack endogenous COX-2 expression, express COX-2 upon RhoA, but not
Rac1 and Cdc42 overexpression. These results suggest that Rho GTPases might be
involved in the expression of COX-2 in a cell type- and tumor-specific
manner.
Some works had previously suggested that Rho GTPases might trigger
transcription of the cox-2 promoter, with reporter assays and
chemical inhibitor experiments (Slice et al.,
1999,
2000;
Hahn et al., 2002).
Slice et al. (2000)
have shown that RhoA and Rac1 but not Cdc42 induce transcriptional activation
of a reporter vector that contains the cox-2 promoter region spanning
from -963 to +50 in NIH3T3 fibroblasts. Herein, we provide evidence that
either wild-type or constitutively active forms of Cdc42 stimulate expression
of endogenous COX-2 via the NF-B pathway to a similar extent to that
found for RhoA and Rac1. This discrepancy might be due to differences in the
selected promoter region used for the reporter vector, because it lacked all
putative B elements present in the endogenous cox-2 promoter.
Interestingly, in the same work it was determined that the elements located in
the cox-2 promoter between -80 and -40 were critical for Rac- and
Rho-induced transcription of the reporter vector. In addition, a CRE/ATF
element was shown to be essential for transcriptional stimulation of the
reporter by Rac1, but not for RhoA. In our work, we have observed that
inhibition of NF-B leads to complete loss of COX-2 expression.
Although, this does not exclude the possibility that other cis-acting
elements might be relevant for the physiological expression of COX-2 under Rho
signaling. Interestingly, although Stat3 is involved in Rho-mediated anchorage
independent growth, and the cox-2 promoter contains at least two STAT
putative binding elements, we have not observed any effect of Stat3 signaling
over Rho GTPases-induced expression of COX-2.
In terms of the molecular mechanism involved, we have identified ROCK as
one of the RhoA effector proteins involved in the expression of COX-2. The
role of ROCK in Rho-mediated tumorigenesis has been extensively studied.
However, besides their profound effects over cell cytoarchitecture and
motility, both of which have been related to its capability to promote tumor
invasion, little is known as to whether this family of kinases regulates
transcriptional pathways that promote tumor growth. Herein, we demonstrate
that ROCK is necessary for RhoA-induced expression of COX-2 at the
transcriptional level and that ROCK modulates the transcriptional activity of
NF-B.
In keeping with the possible functional relationship between Rho GTPases
and COX-2, there are many similarities between the expression profiles of both
proteins in human tumors. For instance, both proteins are up-regulated and
necessary for aberrant epidermal growth factor receptor signaling and tumor
growth induced by the receptor. The same holds true for tumor growth induced
by oncogenic Ras, activation of c-Myc by growth factors, or signaling from the
PI3K/Akt pathway (Taylor et al.,
2000; Sheng et al.,
2001a,b;
Murga et al., 2002;
Pai et al., 2002).
Furthermore, overexpression of COX-2 and members of the family of Rho GTPases
has been detected in same human tumors such as breast, colon, pancreas, and
head and neck squamous carcinomas.
The relationship between the NF-B/COX-2 pathway and Rho proteins in
neoplastic transformation might provide an additional way to treat tumors
where Rho proteins are implicated. Several inhibitors of Rho signaling are
available that exhibit antitumoral and antimetastatic activities (Aznar and
Lacal, 2001b,
2003). In identifying the
ROCK/NF-B/COX-2 pathway as a physiological Rho target, new antitumoral
approaches can be made with respect to tumors where Rho GTPases are an issue.
MDCK cells transformed with RhoA, which are tumorigenic as determined by
anchorage-independent growth and in vivo tumor growth studies, are susceptible
to efficient inhibition of proliferation by sulindac and NS-398. Thus, NSAIDs
inhibit cell proliferation, induce apoptosis, and prevent tumor growth of
cells transformed with Rho proteins with little effects over parental
untransformed cells. The differences between MDCK and MDCK-RhoAQL cells upon
NSAIDs treatment are probably due to the differential activities of signaling
pathways, including COX-2 and NF-B. Indeed, the inhibitory effects of
both NSAIDs over Rho-transformants cannot be solely related to COX-2
inhibition, because both drugs have been reported to affect several other
pathways (Tegeder et al.,
2001). These pathways regulated by Rho would presumably set the
different behavior of the parental cells versus RhoA-transformed cells upon
drug exposure. Of particular interest is the inhibitory action of sulindac and
NS-398 over NF-B activation. More importantly, COX-2 expression is
completely inhibited upon 24 h of NS-398 treatment of the cells. Thus, given
that the half-life of COX-2 ranges from 3.5 to 8 h, the antitumoral effect of
both NSAIDs over RhoAQL transformed cells might take place via inhibition of
the preexisting COX-2 at early stages of treatment and to sustained
NF-B inhibition during early and late stages of the treatment. This
idea is further strengthened by the fact that BAY11-7083, an inhibitor of
NF-B, drastically blocks proliferation of RhoAQL transformed cells with
no direct effect on COX-2 enzymatic activity upon early stages of treatment.
In addition, these observations suggest that treatment of tumors induced by
Rho GTPases with conventional NSAIDs might be equally valid with respect to
treatment with yet to be synthesized specific COX-2 inhibitors.
Last, we have provided evidence that inhibition of endogenously
overexpressed Cdc42 in HT29 cells leads to a significant delay of tumor growth
in vivo, further potentiating the knowledge of an important role of Rho
GTPases in human cancer. Thus, overall, these results suggest that inhibition
of Rho GTPases signaling via COX-2, NF-B, or ROCK may constitute a
plausible strategy to inhibit tumor growth and open a new alley for the
development of a novel antitumoral strategy against human tumors where Rho
GTPases play an important role.
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ACKNOWLEDGMENTS |
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TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONACKNOWLEDGMENTSREFERENCES |
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Footnotes |
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Present address: Departamento de Bioquímica, Universidad de Las
Palmas de Gran Canaria, Islas Canarias, Spain 28029.
Corresponding author. E-mail address:
jclacal{at}iib.uam.es.
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