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INTRODUCTION |
Arachidonic acid metabolites, particularly prostaglandins,
participate in both normal growth responses and in aberrant growth, including carcinogenesis (1-3). The committed step in the conversion of free arachidonic acid to prostaglandins is catalyzed by
cyclooxygenase (COX),1 also
termed prostaglandin H synthase (4). There are two isoforms of
cyclooxygenase; the type 1 (COX-1) isoform is present under resting
conditions in many cells, and presumably makes prostaglandins for
physiological functions. The type 2 (COX-2) is not normally present
under basal conditions, or present in very low amounts, but is rapidly
induced by cytokines, growth factors, and tumor promoters to result in
prostaglandin synthesis associated with inflammation and carcinogenesis
(5-8).
Insight into the molecular events controlling COX-2 expression preceded
its discovery. Early studies of the regulation of inducible COX
activity identified time-dependent modulation of transcriptional and post-transcriptional phases of the COX biosynthetic pathway (9). Since the molecular cloning and characterization of COX-2,
extensive studies identified transcriptional regulation of COX-2
(10-13). COX-2 also may be regulated at the post-transcriptional level
since the 3'-untranslated region (3'-UTR) of its mRNA contains multiple copies of adelylate- and uridylate-rich (AU-rich) elements (AREs) composed of the sequence 5'-AUUUA-3'. This element, which is
present within the 3'-UTRs of many proto-oncogene and cytokine mRNAs, confers post-transcriptional control of expression by acting as a mRNA instability determinant (14-16) or as a translation
inhibitory element (17-20). Many proteins bind to these AU-rich
sequences in vitro (21-35), yet the exact role these
potential trans-acting factors play in post-transcriptional
regulation of ARE-containing mRNAs remains to be determined.
To further understand the molecular mechanisms that control the
expression of the COX-2 protein, we examined the ability of the
ARE-containing 3'-UTR of the COX-2 message to mediate
post-transcriptional regulation of expression. The results presented
here demonstrate that the 3'-UTR of COX-2 can influence mRNA
stability along with controlling translation efficiency. Analysis of
the sequences within the 3'-UTR identified a conserved 116-nucleotide
AU-rich element responsible for rapid mRNA turnover and
translational inhibition. Using RNA gel shift assays and label transfer
analysis, we identified cytoplasmic proteins with apparent molecular
masses ranging from 90 to 35 kDa that bound specifically to the COX-2 ARE.
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EXPERIMENTAL PROCEDURES |
Cell Culture and DNA Transfections--
WI38, a human lung
fibroblast cell line, was maintained in Eagle's basal medium,
supplemented with 10% fetal bovine serum. Cells were grown to 70-80%
confluence in normal medium, then growth-arrested by incubation in
Eagle's basal medium containing 0.5% fetal bovine serum for 48 h. Subsequent serum stimulation was initiated by the addition of fetal
bovine serum to 20%. COS7 and HeLa cells were passed in Dulbecco's
modified Eagle's medium containing 10% fetal bovine serum. RNA
half-life experiments were initiated by adding ActD (5 µg/ml) or Dex
(1 µM) to the growth medium.
Stable transfections of COS7 cells were accomplished by plating cells
at a density of 1 × 105 cells per 60-mm culture dish
18-20 h prior to transfection. Five µg of luciferase+3'UTR reporter
cDNAs contained in the pcDNA3.1/Zeo expression vector
(Invitrogen) were transfected using LipofectAMINE (Life Technologies,
Inc.) following the vendor's instructions. Stably transfected cells
were selected in normal growth medium containing 400 µg/ml zeocin
(Invitrogen) for 2-3 weeks. Several hundred zeocin-resistant colonies
were pooled and subsequently used in the indicated experiments.
Transient transfections of COS7 cells with full-length COX-2 or
COX-2
3'-UTR expression plasmids were carried out similarly except 1 µg of expression plasmid was co-transfected with 0.5 µg of the
pSV-
-Gal (Promega) plasmid using 5 µl of LipofectAMINE (Life
Technologies, Inc.) in 6-well tissue culture plates. The transfection
medium was replaced after 6 h with normal growth medium and the
cells were incubated for 24 h before analysis. Transient
transfections of lacZ+3'UTR reporter cDNA constructs
contained in the pcDNAI/Amp expression vector (Invitrogen) were
done identically except transfections were carried out in 12-well
tissue culture plates and all reagents were scaled accordingly.
Plasmid Construction--
The full-length human COX-2 cDNA
contained in the vector pBlueScript II (KS+) (Stratagene) was inserted
into the EcoRI site of the expression vector pcDNA3.
Deletion of the 3'-UTR of COX-2 was accomplished by standard PCR
techniques using primers to amplify the 5'-UTR and coding region of
COX-2. The PCR amplified product (COX-23'-UTR) was subcloned into
the vector pCRII by T/A cloning (Invitrogen) and then inserted into the
BamHI and XhoI sites of pcDNA3.
-Gal reporter expression constructs illustrated in Fig. 4 were
created as follows. The p-Gal 3'-UTR expression construct containing the lacZ cDNA without a 3'-UTR was created by
PCR amplification of the -Gal coding region from pSV--Gal; the
5'-end of the product was flanked by a HindIII site and the
3'-end contained a BamHI site adjacent to the stop codon.
The fragment was subsequently cloned into the HindIII and
BamHI sites of pcDNAI/Amp. The 3'-UTR of COX-2 was
amplified by PCR from full-length COX-2 cDNA contained in
pBlueScript II (KS+) using a forward primer to place a BamHI site at the 5'-end of the 3'-UTR and the M13 reverse primer used for
the 3'-end. The product was digested with BamHI and
XhoI and subcloned into pBlueScript (KS+). The full-length
3'-UTR was inserted into the BamHI and XhoI sites
of p-Gal3'-UTR to create p-Gal+3'UTR. The p-Gal234 and
p-Gal892 constructs were made by digesting p-Gal+3'UTR with
SphI to remove 216 bp or partial digestion with HindIII to remove 874 bp, respectively. Complete plasmids
containing the 3'-UTR deletions were purified by agarose gel
electrophoresis and religated. The plasmid p-Gal+3'UTR was digested
with HindIII and ScaI to generate a 3469-bp
lacZ+ARE fragment that was agarose gel-purified and inserted
into the HindIII and EcoRV sites of pcDNAI/Amp to create p-Gal+ARE. The construct p-GalARE was made by digesting p-Gal+3'UTR with XhoI and partial
digestion with ScaI. The remaining 3'-UTR fragment (1392 bp)
was inserted into the filled-in BamHI site and the
XhoI site of p-Gal3'-UTR.
Luciferase reporter expression constructs illustrated in Fig. 2 were
prepared in the vector pcDNA3.1/Zeo(+) containing the luciferase
cDNA from pGL3-Basic (Promega) cloned into the HindIII and XbaI sites to yield pLuc3'-UTR. Addition of the COX-2
3'-UTR was accomplished by PCR amplifying the COX-2 3'-UTR using
XbaI-tailed primers and inserting it adjacent to the
luciferase coding region to yield pLuc+3'UTR. The constructs pLuc+ARE
and pLucARE were prepared similarly as the p-Gal+ARE and
p-GalARE, respectively. All DNA constructs were analyzed by
restriction mapping and DNA sequencing. Plasmid DNAs were purified by
two rounds of cesium chloride density gradient centrifugation (36).
In Vitro Transcription--
The plasmid pBlueScript II (KS+)
containing the 5'-end region of the COX-2 cDNA (bases 11-424; (8))
was linearized with XbaI; transcription from the T3 promoter
yielded a 508-nucleotide antisense riboprobe. A 383-bp region of the
neomycin resistance gene from pcDNA3 was cloned into pLitmus-29
(New England Biolabs) and a 381-bp region of the luciferase cDNA
from pGL3-Basic was cloned into pBlueScript II (KS+); transcription
from the T7 promoter on linearized plasmids yielded riboprobes of 495 and 425 nucleotides in length, respectively. Linearized plasmids used
to generate riboprobes for human c-myc and GAPDH were
purchased from Ambion. In vitro transcription reactions
incorporating [
-32P]UTP (50 µCi) were performed
using T7 or T3 RNA polymerase (Ambion) according to the manufacturer's
instructions. Template DNA was removed by incubating the reaction with
2 units of RNase-free DNase I (Ambion) for 15 min at 37 °C.
Purification of radiolabeled riboprobe was accomplished using Elutip-R
purification columns (Schleicher & Schuell) or TE Midi Select-D G-25
spin columns (5 Prime-3 Prime, Inc.) and quantitated by scintillation
counting. The specific activity was typically
106-107 cpm/µg of RNA.
mRNA Analysis--
Total RNA was isolated using TRIzol
reagent (Life Technologies, Inc.) and chloroform extraction according
to the vendor's RNA isolation protocol for use in RNase protection
assay or reverse transcriptase-PCR (RT-PCR). RNase protection assay was
done according to the RPA II kit (Ambion) with the following
modifications (37). Total RNA samples (5 µg) were incubated at
37 °C in 1× NEBuffer 2 buffer (10 mM Tris-HCl (pH 7.9),
10 mM MgCl2, 50 mM NaCl, 1 mM dithiothreitol) (New England Biolabs) containing 2 units
of RNase free-DNase I for 15 min. 32P-Labeled antisense
riboprobe was added and both the sample RNA and probe were
co-precipitated in ethanol. The RNA/riboprobe pellet was dissolved in
hybridization buffer and incubated overnight at 45 °C. Subsequent
RNase A and T1 digestions were done and the protected riboprobe
fragments were separated on a 5% denaturing polyacrylamide gel. The
protected riboprobes yielded fragments of 413, 383, 316, and 250 nucleotides for COX-2, neo, GAPDH, and c-myc mRNAs,
respectively. Quantitation of the relative mRNA levels was
accomplished by PhosphorImager analysis using the STORM 860 system
(Molecular Dynamics).
RT-PCR analysis of mRNA was accomplished as follows. One µg of
total RNA served as template for single strand cDNA synthesis in a
reaction using oligo(dT) primers and SuperScript reverse transcriptase
(Life Technologies, Inc.) under conditions indicated by the
manufacturer. The sequences for the following PCR primers used were:
luciferase sense, 5'-ACGGATTACCAGGGATTTCAGTC-3' and luciferase
antisense, 5'-AGGCTCCTCAGAAACAGCTCTTC-3'; -actin sense, 5'-GAAAATCTGGCACCACACCTTC-3' and -actin antisense,
5'-GCTCATTGCCAATGGTGATGAC-3'; GAPDH sense
5'-CCACCCATGGCAAATTCCATGGCA-3' and GAPDH antisense 5'-TCTAGACGGCAGGTCAGGTCCACC-3'. PCR of cDNA samples was
performed as described previously (8) with samples amplified for 30 cycles of denaturation at 94 °C for 45 s, annealing at 55 °C
for 1 min, and extension at 72 °C for 1 min. The amplified PCR
products for luciferase had a size of 367 bp. PCR reactions from COS7
cell cDNA containing -actin and GAPDH primers yielded products
of sizes similar to reactions using human cDNA (514 and 600 bp,
respectively). PCR products were analyzed by 1.8% agarose gel
electrophoresis containing ethidium bromide and quantitated digitally
using 1D Image Analysis Software (Kodak).
Northern blot analysis was carried out according to Sheng et
al. (38) with the following modifications. Total RNA (20 µg) was
extracted at the indicated time points and separated on 1.2% denaturing formaldehyde-agarose gels. The RNA was transferred to nylon
membranes (Schleicher & Schuell) and fixed to the membrane by UV
cross-linking. Membranes were prehybridized in NorthernMax prehybridization-hybridization buffer (Ambion) and then hybridized for
16 h with 1 × 106 cpm/ml of a
32P-labeled antisense riboprobe specific for luciferase at
65 °C. Blots were then washed twice for 15 min at room temperature
with 2 × SSC, 0.1% SDS and 3 times at 65 °C with 0.1 × SSC, 0.1% SDS for 15 min prior to autoradiography and PhosphorImaging.
18 S rRNA signals were used as controls for RNA loading and integrity. Luciferase mRNA levels were quantitated by PhosphorImager analysis and normalized to signals for 18 S rRNA.
Protein Analysis--
COS7 cells transfected with COX-2
expression constructs were lysed in 250 µl of cell lysis buffer (39)
and protein expression was determined by Western blot analysis after
separation of 25 µg of cell lysate on 10% SDS-PAGE. Protein content
was determined using a BCA protein assay with bovine serum albumin as
standard (Pierce). Detection of COX-2 protein was accomplished using a mouse monoclonal antibody against human COX-2 as described (39). Control -Gal protein expression was detected on the same blot using
a monoclonal antibody against -galactosidase according to
manufacturer's instructions (Promega). The blots were developed by the
enhanced chemiluminescence system (ECL, Amersham Pharmacia Biotech) and
exposed to Bio-Max MR film (Kodak); quantitation of the relative COX-2
and control -Gal protein levels was accomplished by digital analysis
using 1D Image Analysis Software (Kodak).
Cells transfected with -Gal expression constructs were lysed in 150 µl of 1× reporter lysis buffer (Promega) and chemiluminescent detection of enzymatic activity was used to quantitate -Gal protein expression. Aliquots (0.5 µl) of cell extract were assayed for -Gal activity using Galacto-Light (Tropix) and control luciferase activity using the Luciferase Assay System (Promega). -Gal activity was normalized to luciferase activity and all results reported are the
averages of three independent experiments done in triplicate.
Analysis of Protein-RNA Interactions--
The p-Gal+3'UTR
plasmid was digested with BamHI and ScaI to
release the 116-bp COX-2 ARE sequence, which was cloned into the
BamHI and EcoRV sites of pBlueScript (KS+).
Complementary oligonucleotides containing the GM-CSF AU-rich element
(15) were annealed and cloned into the BamHI site of
pBlueScript (KS+). pTRI-CAT (Ambion) was used to create a control CAT
RNA. In vitro transcription reactions incorporating
[-32P]UTP (50 µCi) were performed using T7 or T3 RNA
polymerase as indicated above to yield sense RNAs for COX-2 and GM-CSF
AREs of sizes 188 and 151 nucleotides, respectively; the control CAT RNA is 213 nucleotides in size. Unlabeled competitor RNAs were made
using the Ribomax kit (Promega). Cytoplasmic cell lysates were prepared
as indicated (22) with the following modifications. COS7 and HeLa cells
were grown in p150 tissue culture dishes until confluent, and washed
twice with phosphate-buffered saline before 4 ml of lysis buffer (25 mM Tris-HCl (pH 7.5), 0.5% Nonidet P-40) was added and the
cells frozen at 
70 °C. Thawed cells were scraped from the plate,
vortexed briefly (15 s), and centrifuged at 14,000 × g
for 10 min. The supernatant was assayed for protein concentration using
a BCA protein assay with bovine serum albumin as standard and used
immediately or snap frozen at 70 °C. For native gel mobility shift
assay, 5 µg of COS7 cytoplasmic lysate was incubated with 1 × 104 cpm of RNA in binding buffer (20 mM HEPES
(pH 7.5), 3 mM MgCl2, 40 mM KCl, 1 mM dithiothreitol, 5% glycerol) in a total volume of 20 µl. The mixture was then incubated for 15 min at room temperature, heparin was added to a final concentration of 5 mg/ml and incubation continued for 20 min at room temperature. Samples were electrophoresed in 4% polyacrylamide gels (60:1 acrylamide/bisacrylamide) in 0.5 × TBE (Tris borate-EDTA) buffer containing 5% glycerol, dried, and
exposed overnight with Kodak Bio-Max MS film and an intensifying screen. For competition experiments, unlabeled amounts of the stated
RNAs were added to labeled COX-2 ARE prior to the addition of 1 µg of
lysate. For UV cross-linking experiments, 10 µg of lysate from COS7
or HeLa cells were incubated with 1 × 105 cpm of
labeled RNAs in a 40-µl reaction as described above. Where indicated,
cytoplasmic lysates were digested with proteinase K (50 µg/ml) for 15 min at 37 °C prior to the addition of RNA. Reaction mixtures were
UV-irradiated in 96-well trays in a Stratalinker 2400 (Stratagene) for
5 min and then incubated with 10 µg of RNase A and 5 units of RNase
T1 (Ambion) for 30 min at 37 °C. Laemmli buffer containing
dithiothreitol was added and the samples were boiled for 3 min and
electrophoresed in 10% denaturing SDS-PAGE with prestained or
low-range molecular size markers (Bio-Rad). The 32P-labeled
proteins were visualized by autoradiography.
Preparation of Polysomes--
Confluent cultures of COS7 cells
grown in p150 tissue culture dishes were washed twice with
phosphate-buffered saline at 4 °C. Cells were removed from dishes by
scraping and pelleted at 200 × g for 10 min at
4 °C. Polysomes were isolated as described previously (40) with the
following modifications. Crude cytoplasmic lysates were prepared by
adding 2 ml of Buffer A (10 mM Tris-HCl (pH 7.5), 1 mM KCl, 1.5 mM MgCl2, 2 mM dithiothreitol) containing 0.5% Nonidet P-40 per p150
dish of cells and centrifuged (12,000 × g) at 4 °C
for 10 min. The supernatant was layered on a sucrose cushion composed
of Buffer A containing 30% sucrose and centrifuged 36,000 rpm for 135 min at 4 °C in a Beckman SW55Ti rotor. The postribosomal supernatant
(S130 fraction) was separated from the sucrose cushion and the polysome
pellets were resuspended in Buffer A. The cytoplasmic lysate, S130
fraction, and polysome fraction was assayed for protein concentration
using a BCA protein assay with bovine serum albumin as standard and
used immediately or snap frozen at 70 °C.
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RESULTS |
The AU-rich 3'-UTR of COX-2 Influences mRNA Stability--
The
expression of COX-2 has been demonstrated to occur through
transcriptional activation that is induced by cytokines, growth factors, and tumor promoters (5-8). Yet, growing experimental evidence
has demonstrated that COX-2 expression is also regulated on a
post-transcriptional level (38, 41-43). To determine if the AU-rich
3'-UTR of COX-2 mediates post-transcriptional regulation by changing
mRNA stability, we measured COX-2 mRNA half-life
(t[ifrax,1/2]) values in serum-stimulated human lung
fibroblasts that also were treated with actinomycin D (ActD). Total RNA
was isolated at various times after ActD treatment, and the stability
of COX-2 mRNA was examined by RNase protection analysis. As shown
in Fig. 1A, the level of COX-2
mRNA decayed significantly during the initial 2 h after ActD
treatment; however, at later time points (>120 min) COX-2 mRNA
stabilization was observed. This may have resulted from the ability of
ActD to interfere with degradation (20, 44-46). Using the observed
initial decay values, we determined the half-life of the COX-2 mRNA
to be approximately 90 min (Fig. 1B). This rate is greater
than the inducible proto-oncogene of c-myc
(t1/2 = 27 min), but is similar to the half-lives of
the induced cytokine mRNAs of interleukin-6 (t1/2 = 67 min), interleukin-8
(t1/2 = 44 min), and granulocyte
macrophage-colony stimulating factor (GM-CSF;
t1/2 = 61 min) (Fig. 1B and data not
shown). The ability of the COX-2 mRNA to be rapidly degraded in the
absence of ActD treatment was demonstrated using the glucocorticoid Dex
(Fig. 1). In serum-stimulated fibroblasts rapid decay of COX-2 mRNA
occurred following the addition of Dex (t1/2 = 39 min), whereas Dex did not influence the turnover of c-myc
(t1/2 > 240 min). The ability of Dex to influence
COX-2 mRNA stability was also seen in phorbol ester-stimulated HeLa
cells. However, transcription was necessary for Dex-mediated mRNA
turnover since the addition of ActD attenuated COX-2 mRNA
degradation.2 These findings
agree with other results that show a rapid turnover of COX-2 mRNA
and that glucocorticoids increase the rate of degradation (47-49).
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Fig. 1.
COX-2 mRNA destabilization in
serum-stimulated human lung fibroblasts. Growth-arrested human
lung fibroblasts (WI38) were induced for 4 h with 20% fetal
bovine serum. ActD or Dex then was added to 5 µg/ml or 1 µM, respectively, and total cellular RNA was prepared at
the indicated time points. A, equal amounts of RNA (5 µg)
were analyzed by RNase protection of 32P-labeled riboprobes
specific for COX-2, c-myc, and the GAPDH internal standard.
The protected mRNA for c-myc was detected as a doublet
of equal intensities. B, summary of mRNA half-life data
obtained from serum-stimulated human lung fibroblasts treated with ActD
and Dex. RNase protection analysis was used to analyze mRNA for
COX-2 (filled symbols) and c-myc (open
symbols) under conditions of ActD (circles) or Dex
(triangles). The radioactive signals were quantitated using
a STORM PhosphorImager with relative amounts of each mRNA
normalized to the internal standard GAPDH and initial decay curves were
plotted versus time. The data presented are representative
of three experiments.
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Within the COX-2 mRNA there are multiple copies of the AU-rich
sequence element, AUUUA, in the 1455-nucleotide 3'-UTR (8). To
determine if the AU-rich 3'-UTR of COX-2 mediates rapid degradation, we
examined the decay of chimeric luciferase cDNA constructs
containing the 3'-UTR of COX-2. Expression constructs containing
luciferase with the full-length COX-2 3'-UTR, a highly conserved
AU-rich region of the 3'-UTR (48), or with the AU-rich region deleted from the full-length 3'-UTR were stably transfected in COS7 cells to
examine luciferase mRNA decay. ActD was added at the given times to
pooled colonies of zeocin-resistant cells and the mRNA half-life
was measured by RT-PCR and Northern blot analysis. The results shown in
Fig. 2B demonstrate that both
the full-length 3'-UTR (Luc+3'UTR) and conserved AU-rich region of the
3'-UTR (Luc+ARE) confer instability on the reporter luciferase mRNA
with half-lives of 30 and 29 min, respectively. Deletion of this
AU-rich region within the 3'-UTR (LucARE) or complete removal of the 3'-UTR (Luc3'UTR) resulted in a stable mRNA, no decay was
detected. Similar results were detected by Northern analysis of
ActD-treated cells with the presence of the COX-2 ARE mediating rapid
luciferase mRNA decay (t1/2 = 49 min) whereas no
decay was seen with the control luciferase mRNA or if cells were
treated for 4 h with the protein synthesis inhibitor cycloheximide (Fig. 2C). COS7 cells similarly stably transfected with an
expression construct containing c-myc showed rapid turnover
of c-myc mRNA (t1/2 = 55 min)
comparable to previously reported findings (50) (data not shown). Taken
together, these findings demonstrate that the AU-rich 3'-UTR of COX-2
can regulate COX-2 expression by increasing the rate of degradation and
that this effect is mediated by a highly conserved AU-rich element (ARE) contained at the proximal end of the 3'-UTR (Fig. 5).
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Fig. 2.
The COX-2 3'-UTR mediates rapid mRNA
decay. A, various deletions of the 1455-nucleotide
COX-2 3'-UTR (open bars) were fused to the reporter gene
luciferase (shaded bars) to create expression construct
containing the luciferase cDNA fused to the full-length COX-2
3'-UTR (Luc+3'UTR), the putative COX-2 AU-rich element
(Luc+ARE), the AU-rich element deleted from the full-length
3'-UTR (LucARE), or luciferase without a 3'-UTR
(Luc3'UTR). The filled circles represent
AU-rich sequences, AUUUA, contained within the 3'-UTR;
circles adjacent to one another indicate multiple repeat
elements. B, pooled colonies of COS7 cells stably
transfected with the indicated expression constructs were treated for
various times with ActD (5 µg/ml). Total RNA (1 µg) was used to
prepare cDNA by reverse transcription using oligo(dT) primers
followed by PCR using primers specific for luciferase and the internal
controls of -actin or GAPDH as indicated. PCR products were resolved
by electrophoresis on a 1.8% agarose gel containing ethidium bromide.
The 90-min -actin product from cells expressing the Luc+ARE mRNA
was omitted from this experiment. C, COS7 cells stably
expressing Luc+ARE or Luc3'UTR mRNAs were treated for various
times with ActD (5 µg/ml) or for 4 h with cycloheximide (10 µg/ml). Total RNA (20 µg) was resolved by denaturing
formaldehyde-agarose gel electrophoresis and analyzed by Northern
blotting with a 32P-labeled luciferase antisense riboprobe.
The ethidium bromide-stained 18 S ribosomal RNA is shown
below each respective autoradiogram. The results presented
in B are representative of three experiments; the data shown
in C are representative of duplicate experiments.
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The 3'-UTR of the COX-2 mRNA Inhibits Protein
Translation--
Previous work demonstrated the ability of AU-rich
elements from various cytokine mRNAs to confer translational
control (17, 18, 51, 52). To determine if the 3'-UTR of COX-2 also
functions at a post-transcriptional level to inhibit translation, we
transfected COS7 cells transiently with cDNA expression constructs
encoding either full-length COX-2 or COX-2 with the 3'-UTR removed, and protein expression was measured. We found a 2-3-fold increase in the
amount of COX-2 protein when the 3'-UTR was absent (Fig. 3A; COX-23'UTR). Co-transfection of a
vector encoding the -Gal protein was used to ensure that this effect
was not owing to differences in transfection efficiency. The ability of
the 3'-UTR to decrease COX-2 protein levels under these experimental
conditions resulted from inhibition of translation since, in parallel
transfections, the steady-state COX-2 mRNA levels showed similar
amounts of full-length COX-2 and COX-23'UTR mRNAs (Fig.
3B). These results suggest that the COX-2 3'-UTR acts to
primarily attenuate protein expression through translational inhibition
when abnormally high mRNA levels are present during transient
transfections and that this inhibition may directly influence rapid
mRNA decay occurring through a co-translational mechanism (53).
Similar findings were also seen in transfections of NIH3T3, Chinese
hamster ovary, and HeLa cells (data not shown), demonstrating that this
regulation is conserved among different cell types.
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Fig. 3.
The COX-2 3'-UTR attenuates the expression of
COX-2 protein. COS7 cells were transiently transfected with the
expression vector pcDNA3, or with cDNAs for full-length COX-2
(COX-2) or COX-2 with the 3'-UTR deleted (COX-23'UTR). Transfection
efficiency was controlled by either co-transfection of the pSV--Gal
expression vector encoding the -Gal protein or expression of the
neomycin resistance mRNA (neo) contained on the
pcDNA3 vector. COX-2 protein expression (A) was
determined by SDS-PAGE and Western blot analysis of 25 µg of cell
lysate using a monoclonal antibody specific for human COX-2 and ECL
detection. -Galactosidase protein expression was detected on the
same blot using a monoclonal antibody specific for -Gal.
Steady-state COX-2 mRNA levels (B) were detected by
RNase protection as described in the legend to Fig. 1. The detection of
control lacZ mRNA in this experiment shows similar
results (not shown). The mobility of undigested riboprobes is shown in
lane 1 and the substitution of yeast RNA demonstrates total
digestion of unprotected riboprobes (lane 2). The yield of
expressed mRNA in transiently transfected COS7 cells is
approximately 10-fold greater than in stably transfected cells such as
in Fig. 2 (data not shown).
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To determine if the AU-rich region that mediates rapid degradation
could also confer translational inhibition, we used 3'-UTR deletion
constructs fused to the reporter cDNA for lacZ to
examine protein and mRNA levels in transiently transfected COS7
cells (Fig. 4). In agreement with the
results shown in Fig. 3, the level of -Gal protein expression was
decreased approximately 2-fold when the full-length COX-2 3'-UTR
(labeled +3'UTR) was present compared with the 3'UTR construct. This
inhibition was detected with successive deletions of the distal 6 AUUUA
elements (constructs 234, 892, and +ARE), whereas internal
deletion of the proximal 6 elements (construct ARE) restored
translational efficiency to that seen in the absence of the 3'-UTR. In
the same experiment, the steady-state lacZ mRNA levels
from each construct were approximately the same and mRNA half-life
in transiently transfected cells was not influenced by the presence of
any region of the COX-2 3'-UTR (Fig. 4 and data not shown). Expression
of COX-2 or luciferase protein from constructs containing analogous
3'-UTR deletions yielded protein levels similar to the analogous
-Gal constructs (data not shown). We conclude that the proximal
116-nucleotide ARE of the COX-2 3'-UTR regulates translational
efficiency (Fig. 5).
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Fig. 4.
The COX-2 AU-rich element inhibits protein
expression. Various deletions of the 1455-nucleotide COX-2 3'-UTR
(open bars) were fused to the reporter gene lacZ
(shaded bars) similar to those described in the legend to
Fig. 2. The designation for each deletion construct defines the region
of 3'-UTR removed as indicated in the illustrated construct. The
-Gal reporter constructs were transiently transfected in COS7 cells
along with vectors expressing luciferase enzyme (pGL2-Control) or CAT
mRNA (pcDNAI/Amp-CAT) to control for transfection efficiency.
-Gal protein expression was determined by assaying for -Gal
enzymatic activity and values were normalized for luciferase enzymatic
activity. Steady-state lacZ mRNA levels were normalized
to CAT mRNA expression and detected by RNase protection assay. All
percentages listed are based on expression of -Gal protein or
lacZ mRNA from the construct containing no 3'-UTR
(3'UTR). These results are the averages of three independent
experiments done in triplicate; the standard deviation within each set
was less than 5% except for the ARE construct that was 9.5%.
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Fig. 5.
The COX-2 AU-rich element. The
representation of the COX-2 mRNA is not to scale and is described
in the legend to Fig. 2. The 116-nucleotide sequence of the COX-2 ARE
in uppercase letters contains six AU-rich sequence motifs
(AUUUA). The COX-2 termination codon is shown in
lowercase letters.
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Identification of Cytoplasmic Proteins that Specifically Interact
with the COX-2 AU-rich Element--
Various cytoplasmic proteins bind
specifically to the AREs of mRNAs that are controlled on a
post-transcriptional level. Therefore, we sought to determine if these
or other unidentified proteins recognize the ARE region of the COX-2
mRNA. To investigate this we incubated COS7 cytoplasmic lysates
with in vitro transcribed, 32P-labeled RNAs of
similar lengths composed of the COX-2 ARE or a positive control AU-rich
region from the GM-CSF mRNA 3'-UTR known to confer mRNA
instability and translational inhibition (15, 17). A region of the CAT
mRNA of similar length was used as a negative control. Protein
binding was analyzed by a shift in the electrophoretic mobility of the
labeled RNA during electrophoresis. We detected discrete protein-RNA
complexes with COX-2 and GM-CSF elements, but no binding to the control
CAT RNA (Fig. 6A). High level
binding of the COX-2 ARE by factors present in the cell lysates was
observed with nearly all of the RNA being bound. This binding was
saturated at approximately 1 µg of cytoplasmic protein (data not
shown). A protein-RNA complex of similar mobility was detected for the
COX-2 element using a cytoplasmic lysate from HeLa cells (data not
shown). Complex formation with the GM-CSF element was less dramatic
(Fig. 7A). The two unbound RNA
species seen with the GM-CSF element did not result from differences in size of the labeled RNA since only one RNA species was detected by
denaturing PAGE (data not shown). This suggests the GM-CSF element is
able to form different RNA conformations and that the protein binding
preferred the RNA species of slower mobility. Cytoplasmic protein
binding to the COX-2 ARE generated a broad range of complexes.
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Fig. 6.
Detection of protein complexes that
specifically bind to the COX-2 AU-rich element. A,
32P radiolabeled in vitro transcribed RNAs
containing control CAT RNA, the COX-2 ARE, or GM-CSF ARE were incubated
with cytoplasmic lysate (5 µg) from COS7 cells at room temperature
prior to addition of heparin and electrophoresis on native low-ionic
strength polyacrylamide gels. Detection of protein-RNA complexes bound
to the COX-2 ARE are shown by the bracket with the
arrow indicating the mobility of the major discrete species.
Unbound RNAs are shown on the left; the resulting two bands
seen with the GM-CSF element is presumably due to different GM-CSF RNA
conformations. B, the specificity of COX-2 ARE binding was
determined by adding increasing amounts of unlabeled nonspecific
competitor CAT RNA or specific COX-2 ARE RNA to 32P
radiolabeled COX-2 ARE prior to the addition of 1 µg of COS7 lysate.
The arrow on the right indicates the position of
the main band-shifted complex. The results presented are representative
of experiments done in triplicate.
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Fig. 7.
Identification of cytoplasmic proteins
interacting with the COX-2 AU-rich element. A,
cytoplasmic lysates from COS7 or HeLa cells were incubated with
radiolabeled RNAs as shown in Fig. 6 and described under
"Experimental Procedures." The bound protein was cross-linked to
32P-labeled RNA by UV light irradiation and then treated
with RNases A and T1 to remove the exogenous unbound RNA. The
cross-linked products were resolved by electrophoresis on SDS-PAGE.
Distinct proteins or protein complexes from COS7 or HeLa cells are
detected to bind to the COX-2 ARE. No radiolabeled proteins were seen
when UV light irradiation was omitted or when the lysate was pretreated
with proteinase K. B, distribution of ARE-binding proteins
from crude cytoplasmic lysate, S130, and polysomes isolated from COS7
cells and cross-linked to COX-2 and GM-CSF AREs. Molecular weight
protein standards (kDa) are listed on the right.
Electrophoresis of the gel shown in B, was carried out
approximately 1.5 times longer than A. The results presented
in A are representative of five experiments; the data shown
in B are representative of duplicate experiments.
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The specificity of the protein binding to the COX-2 ARE was assessed by
adding increasing concentrations of unlabeled competitor CAT RNA or
COX-2 ARE to the radiolabeled COX-2 ARE prior to the addition of the
COS7 lysate (Fig. 6B). We found that complex formation was
progressively inhibited by increasing amounts of unlabeled COX-2 ARE
(right panel) but that at least 20-fold more of the CAT RNA
was required to achieve a similar inhibition (left panel). Competition of COX-2 ARE binding was also detected using unlabeled GM-CSF element, although approximately 2-fold more competitor GM-CSF
RNA was needed to inhibit binding compared with unlabeled COX-2 ARE as
a competitor (data not shown).
The number of proteins involved in forming stable complexes with the
COX-2 ARE was assessed by cross-linking radioactive labeled RNA to the
RNA-binding proteins through UV light irradiation. Cytoplasmic lysates
from COS7 or HeLa cells were incubated with radiolabeled COX-2 ARE,
irradiated with UV light, and treated with RNases A and T1 to remove
the exogenous unprotected RNA prior to electrophoresis on SDS-PAGE. As
shown in Fig. 7A, several distinct proteins or protein
complexes with molecular masses ranging from 90 to 35 kDa cross-linked
to the COX-2 ARE. No label was transferred to protein when UV light
irradiation was omitted or when the lysate was pretreated with
proteinase K. No proteins containing transferred label were detected
using the control CAT RNA (data not shown). The similar sizes of bound
proteins seen with cytoplasmic extracts from COS7 and HeLa cells
suggest that these ARE-binding proteins are conserved between these
cell types.
Previous findings have demonstrated proto-oncogene and cytokine
mRNA decay is influenced by cytosolic factors that associate with
polysomes or remain unassociated (40, 54). To further characterize the
factors identified to bind the COX-2 ARE from cytoplasmic lysates, we
performed UV light cross-linking of radiolabeled ARE to proteins
contained in polysomes and S130 postribosomal supernatants from COS7
cells. As shown in Fig. 7B, polypeptides with masses ranging
from 90 to 35 kDa contained within the crude cytoplasmic lysate were
detected to bind the COX-2 ARE. However, after centrifugation though a
sucrose pad to isolate polysomes from the S130 postribosomal
supernatant fraction, differential localization of ARE-binding proteins
was observed. The protein doublet of 90/88 kDa was localized to the
S130 fraction and the 35-kDa polypeptide was primarily polysome
associated. The factors with masses of 66 and 64 kDa appeared to
primarily bind only in the crude lysate with approximately 30%
detected in the S130 and <10% in the polysome fractions. Nearly
identical results were detected with the GM-CSF ARE, thus we conclude
that several cytoplasmic proteins that bound to the COX-2 ARE are
likely to be the same as those described in Jurkat cells and human
peripheral blood leukocytes that bind to the GM-CSF element and
consensus AU-rich RNA sequences (22, 24, 40).
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DISCUSSION |
The molecular mechanisms controlling the expression of COX-2 are
not completely understood but is important because this is a crucial
component of inflammation and a rate-limiting step in colon
carcinogenesis. In this report we demonstrate that a major regulatory
point of COX-2 gene expression occurs at the post-transcriptional level. This control is mediated by the 3'-UTR of the COX-2 mRNA through a conserved AU-rich sequence element contained within the
3'-UTR; the context of these AUUUA motifs within the 3'-UTR strongly
implicates the involvement of this region in rapid decay of mRNA
(16). We showed that cytoplasmic proteins specifically bind to the
COX-2 ARE and we postulate that this interaction regulates the
stability of COX-2 mRNA. Thus, the levels of COX-2 protein are
determined by post-transcriptional regulation as well as by transcriptional mechanisms. This level of complexity is consistent with
the requirement for tight control of the enzymatic action of COX-2,
which has pathogenic effects if its expression is unregulated.
Many observations demonstrate that proto-oncogene and cytokine
mRNAs are rapidly degraded and that this is mediated by AU-rich elements. Here we show that the inducible COX-2 gene encodes
a transcript that can be degraded, and that the ARE-containing 3'-UTR of COX-2 mediates this destabilization. It is unclear why the serum-induced COX-2 message is not completely degraded in the presence
of the transcriptional inhibitor ActD. One possibility is that the
transcriptional inhibitor ActD may have inhibited a component of the
rapid degradation pathway, which has been described (20, 46). The
effects of ActD may work through a mechanism to influence mRNA
stability indirectly by allowing the accumulation of sequence-specific
RNA-binding proteins in the cytoplasm. These proteins conceivably could
bind the COX-2 ARE and protect it from degradation (20, 44-46) as
demonstrated with the ARE-binding protein HuR (33, 34). Along these
same lines, alterations in ARE binding by ActD may directly inhibit
mRNA translation since ARE-dependent mRNA turnover
is proposed to be coupled to translation (53, 55-57). We also
demonstrate the anti-inflammatory glucocorticoid dexamethasone causes
rapid degradation of the COX-2 mRNA (Fig. 1). This effect may
simply reside in the ability of Dex to inhibit serum-induced COX-2
transcription (58), thereby allowing degradation to ensue. Others have
found that glucocorticoids regulate COX-2 expression on a
post-transcriptional level. The effects elicited by Dex presumably
occur through the induction or repression of factors required for COX-2
mRNA turnover (48, 49). However, this appears to be independent of
the COX-2 ARE since expression of reporter genes containing the COX-2
3'-UTR and ARE binding activity are not altered by the presence of
Dex.2
The ability of AU-rich sequences in interferon-, GM-CSF, and tumor
necrosis factor mRNAs to confer translational control similar to
the COX-2 ARE has been shown in Xenopus oocytes, rabbit reticulocyte lysate extracts, and transfected RAW 264.7 cells (17, 18,
51, 52). In these studies the mRNA levels of the respective genes
were virtually unaffected, demonstrating that the AU-rich sequences act
solely as translation inhibitory elements in these experimental
systems. Although we cannot specifically account for the observed
differences in mRNA decay detected in stably and transiently
transfected cells, one possible explanation may reside in an inability
of the cells to degrade abnormally high levels of 3'-UTR containing
mRNA when transiently transfected because the ARE-binding proteins
are present in limiting amounts. Findings illustrating this effect
include sequestration of the ARE-binding protein AUF1 by the heat shock
protein hsp70, which results in stabilization of ARE-containing
mRNAs (59). These studies also demonstrate the physical interaction
of ARE-binding proteins with translation initiation factors. Thus,
sequestration of ARE-binding factors bound to the eIF4G and
poly(A)-binding proteins may be responsible for the observed inhibition
of translation initiation seen here and this inhibition may directly
influence ARE-dependent mRNA decay that is coupled to
ongoing translation (53, 55, 60). With regard to this, polysome profile
studies have demonstrated the ability of AREs to block mRNA
translation by inhibiting polysome association (19, 56).
Several groups have detected polypeptides that specifically interact
with AREs from rapidly degraded mRNAs. These regulatory trans-acting factors include several cytoplasmic
mRNA-binding proteins proposed to be involved with the
destabilization (27, 61-64), stabilization (21, 22, 29), or mRNA
processing and nucleocytoplasmic transport (23, 24, 65). While a number of RNA-binding proteins that recognize AU-rich elements have been reported, the mechanism by which these factors mediate mRNA
degradation or translational inhibition is unknown. Insight into the
molecular events involved in post-transcriptional control has been
facilitated through the identification of these proteins. Several
ARE-binding proteins have been identified and show a wide variety of
activities ranging from pre-mRNA processing, developmental control,
and metabolic catalysis (24-29, 31). More importantly, the AUBF, HuR,
TTP, and AUF1 ARE-binding proteins have been shown to directly effect ARE-mediated mRNA decay (32-34, 40, 59). Investigation into the
role these proteins play in post-transcriptional control of COX-2 is
currently in progress.
A number of observations suggest that genetic alterations of AU-rich
sequences play a role in neoplastic transformation of cells. When
AU-rich elements are removed from the proto-oncogenes c-fos
and c-myc there is a correlation with increased oncogenicity (66, 67) and mast cells show enhanced tumorgenicity when transfected interleukin-3 lacking the normal ARE-containing 3'-UTR is overexpressed (68). These observations are consistent with our finding of increased
levels of COX-2 protein in cells transfected with a 3'-UTR deletion
construct (Fig. 3). Additionally, a variety of human tumor cells show
enhanced mRNA stability of ARE-containing cytokine genes (69) and a
reporter gene containing the 3'-UTR of GM-CSF is stable in mouse
monocytic tumor cells (70). This suggests that AU-rich sequences may
not function properly in tumor cells because of alterations in
ARE-binding regulatory proteins. These findings, taken together,
suggest that post-transcriptional regulation mediated by AU-rich
sequences is vital for maintaining normal cellular growth and the
removal or defective recognition of these elements results in enhanced tumorgenicity.
The molecular events leading to the overexpression of the COX-2 protein
in colon cancer are not totally understood. Kutchera et al.
(71) demonstrated constitutive activation of the COX-2 promoter in
colon cancer cell lines, suggesting that the increased levels of COX-2
mRNA seen in colorectal adenomas, adenocarcinomas (71, 72), and
colon cancer cell lines (71) occurs at the transcriptional level. Yet,
it is interesting to note that concomitant expression of COX-2 protein
was not detected in all adenomas or adenocarcinomas (73, 74) and
increased levels of COX-2 protein was not seen in all colon cancer cell
lines shown to overexpress COX-2 mRNA (75).2 This
apparent discrepancy between COX-2 mRNA and protein expression appears to be limited to the earlier stages of adenoma-carcinoma development (73) and COX-2 protein expression is enhanced with increasing size of small intestinal and colonic polyps in mice (76).
These findings, with the results presented here, suggest that loss of
post-transcriptional regulation of COX-2 may be a crucial step in colon
carcinogenesis and complements the genetic evidence to showing that
induction of COX-2 protein is a rate-limiting step for adenoma
formation (3, 76). These events could result from a lack of COX-2
3'-UTR recognition by a trans-acting regulatory factor and
not a deletion or modification of the COX-2 ARE since the COX-2 3'-UTR
was normal in a number of colon cancer tissues and cell lines (77). We
propose that this loss of regulation occurs through mutation of the
proteins that specifically interact with the COX-2 ARE. This results in
unregulated expression of COX-2 protein and presumably other
ARE-containing early-response genes that are detected in the later
stages of adenoma development.
§,
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ABSTRACT
INTRODUCTION
