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Previous Article | Next Article 
Mol Cell Biol, January 1998, p. 525-535, Vol. 18, No. 1
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Constitutive Activation of the Aromatic
Hydrocarbon Receptor
Ching-Yi
Chang and
Alvaro
Puga*
Center for Environmental Genetics and
Department of Environmental Health, University of Cincinnati
Medical Center, Cincinnati, Ohio 45267-0056
Received 29 September 1997/Accepted 22 October 1997
 |
ABSTRACT |
The ligand-activated aromatic hydrocarbon receptor (AHR) dimerizes
with the AHR nuclear translocator (ARNT) to form a functional complex
that transactivates expression of the cytochrome P-450 CYP1A1 gene and other genes in the dioxin-inducible
[Ah] gene battery. Previous work from this laboratory has
shown that the activity of the CYP1A1 enzyme negatively regulates this
process. To study the relationship between CYP1A1 activity and Ah
receptor activation we used CYP1A1-deficient mouse hepatoma
c37 cells and CYP1A1- and AHR-deficient African green
monkey kidney CV-1 cells. Using gel mobility shift and luciferase
reporter gene expression assays, we found that c37 cells
that had not been exposed to exogenous Ah receptor ligands already
contained transcriptionally active AHR-ARNT complexes, a finding that
we also observed in wild-type Hepa-1 cells treated with Ellipticine, a
CYP1A1 inhibitor. In CV-1 cells, transient expression of AHR and ARNT
leads to high levels of AHR-ARNT-dependent luciferase gene expression
even in the absence of an agonist. Using a green fluorescent
protein-tagged AHR, we showed that elevated reporter gene expression
correlates with constitutive nuclear localization of the AHR.
Transcriptional activation of the luciferase reporter gene observed in
CV-1 cells is significantly decreased by (i) expression of a functional
CYP1A1 enzyme, (ii) competition with chimeric or truncated AHR proteins containing the AHR ligand-binding domain, and (iii) treatment with the
AHR antagonist 
-naphthoflavone. These results suggest that a CYP1A1
substrate, which accumulates in cells lacking CYP1A1 enzymatic
activity, is an AHR ligand responsible for endogenous activation of the
Ah receptor.
| |
INTRODUCTION |
Polycyclic aromatic hydrocarbons,
halogenated aromatic hydrocarbons, and other, structurally related
planar organochlorinated compounds elicit many adverse biological
effects, including immunosuppression, teratogenesis, tumor promotion,
hormonal disregulation, and cardiovascular disease (4, 8, 14, 46,
51). All of these seemingly unrelated biological effects are
believed to be mediated by the sustained activation of the aromatic
hydrocarbon receptor (AHR) and the subsequent perturbation of cellular
homeostasis. AHR is a ligand-dependent basic helix-loop-helix (bHLH)
transcription factor belonging to the bHLH/PAS gene family (5,
12). AHR and other genes in this family are expressed very early
in embryogenesis (1, 2, 25, 49) and appear to be involved in
important developmental functions such as neurogenesis (13,
42), tracheal morphogenesis (28, 73), regulation of
circadian rhythm (29, 35, 58), and response to hypoxia
(68).
Among the genes identified in the bHLH/PAS family, AHR appears to be
the only member that requires ligand binding for activation. Ligand
activation allows the cytosolic AHR to translocate into the
nucleus and to dimerize with the AHR nuclear translocator (ARNT)
(59), another member of the bHLH/PAS gene family.
Heterodimeric AHR-ARNT complexes function as transcriptional activators
by binding to consensus sequences termed AhRE (also known as DRE or
XRE) in the regulatory domains of numerous genes (15, 32,
47). Genes transcriptionally regulated by AHR-ARNT complexes
encode several foreign chemical-metabolizing enzymes including, the
cytochrome P-450 enzymes CYP1A1, CYP1A2, and CYP1B1 (61,
64), NAD(P)H-menadione oxidoreductase
(NMO1), UDP glucuronosyltransferase
(UGT1A6), glutathione transferase (GSTA1), and
a tumor-specific aldehyde dehydrogenase (ALDH3c,
Ahd4) (44). In addition, transcription of
plasminogen activator inhibitor II, interleukin-1
(65),
and protooncogenes c-jun and jun D can also be
activated by the AHR-ARNT complex (26, 55).
Furthermore, due to competition with dimerization partners, a
ligand-activated AHR may be involved in down-regulation of ARNT-ARNT
homodimer-dependent transcriptional responses (66), or, conversely, AHR-ARNT-dependent transactivation may be inhibited by
activation of the hypoxia response (22). Thus, it appears that AHR plays an important role not only in the regulation of xenobiotic metabolism but also in the maintenance of homeostatic functions.
Autoregulation of endogenous substrates by metabolizing enzymes is an
important mechanism to maintain homeostasis in biological systems
(43). Among the cytochrome P-450 enzymes induced by the
AHR-ARNT complex, the clearest example is the transcriptional activation of the Cyp1a1 gene. In variant mouse hepatoma
cell lines lacking functional CYP1A1 enzyme activity, transcription rates of Cyp1a1 and of several other genes in the
[Ah] gene battery are remarkably elevated, such that mRNA
levels in the untreated variant cell lines are comparable to those in
2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD)-treated wild-type
Hepa-1 cells (21, 24, 56, 57, 60, 67). Stable expression of
murine CYP1A1 or human CYP1A2 cDNAs in these cell lines represses
deregulated CYP1A1 mRNA levels and restores TCDD inducibility (56,
57). It has been suggested that an endogenous CYP1A1 substrate is
somehow involved in transcriptional regulation of the [Ah]
gene battery. It has been proposed that this putative substrate could
be an endogenous AHR ligand that is rendered inactive by metabolism or,
alternatively, that metabolism could convert the substrate into a
repressor of AHR-dependent transcription. In the present study, we have
examined these two alternative hypotheses. The results suggest
that a putative endogenous CYP1A1 substrate up-regulates gene
transcription through activation of the AHR-ARNT complex. This
putative endogenous CYPA1 substrate functions as an AHR
activator and thus may represent an endogenous ligand for the AHR.
(This research was submitted by C.-Y. Chang in partial fulfillment of
the requirements for the degree of Doctor of Philosophy from the
University of Cincinnati.)
| |
MATERIALS AND METHODS |
Cell lines, transfections, and growth conditions.
The mouse
Hepa-1 hepatoma cell line (3), its variants c37
(24, 33), CX4, CH3.3, and CPr (56, 57), and
African green monkey adult kidney CV-1 cells (31) were
cultured in -minimum essential medium (Gibco BRL) supplemented with
5% fetal bovine serum and 1% antibiotic-antimycotic (Gibco BRL) in a
humidified 5% CO2 atmosphere. Derivations and pertinent
phenotypes of these cell lines are shown in Table
1. Duplicate or triplicate transient transfection experiments were performed by using standard calcium phosphate techniques (23) on cells grown either in
25-cm2 tissue culture flasks or on 12-well plates. In all
experiments, to control for variations in transfection efficiency,
cells were also cotransfected with plasmid pCMVgal (ClonTech). To
express AHR and ARNT, pcDNAI/B6AHR and pcDNAIneo/mARNT (see below) were included in all transfections with CV-1 cells. CV-1 cells express detectable levels of immunoreactive ARNT protein, but inclusion of
pcDNAIneo/mARNT in the transfection causes a large increase of
AHR-ARNT-dependent luciferase reporter expression. Since Hepa-1 cells
already express endogenous AHR and ARNT, expression plasmids for these
two proteins were not included in transfections with these cells unless
otherwise specified. Twelve to 16 h after transfection, cells were
washed three times with phosphate-buffered saline (PBS) and changed to
fresh medium. TCDD (10 nM), control vehicle (dimethyl sulfoxide
[DMSO]), or, in some experiments, -naphthoflavone (ANF) (1 µM)
were added to the cells 8 h later. Luciferase and
-galactosidase activities were measured 14 to 16 h after
treatment, according to the manufacturer's instructions (Promega).
Cells grown in 25-cm2 flasks were transfected and washed
with PBS as described above. Three to 4 h later, cells were
trypsinized and seeded into 12-well or 24-well plates. After the cells
had adhered to the plates, medium containing appropriate chemicals was
added, and luciferase and -galactosidase activities were measured 14 to 16 h after treatment. For experiments using the alkaline
phosphatase reporter construct pGREII-oct-AF, fresh medium containing
the appropriate chemicals was added to the cells 48 h after
transfection, and alkaline phosphatase secreted into the medium was
measured for the interval between 48 and 64 h after transfection.
Alkaline phosphatase activity was assayed by a colorimetric method,
with p-nitrophenyl phosphate as a substrate and measurement
of the increase of absorbance at 405 nm as described previously
(70), and was normalized to the cotransfected
-galactosidase activity. Alternatively, alkaline phosphatase
activity was measured with a chemiluminescent assay system from Tropix,
Inc., according to the manufacturer's specifications. All experiments
were repeated a minimum of three independent times, and the results
shown are averages ± standard deviations (SD).
A wild-type Hepa-1 cell line with a stably integrated pAhRDtkLuc3
reporter gene was generated by cotransfecting pAhRDtkLuc3 (see below)
and pIND (Invitrogen), a plasmid conferring resistance to G418, into
wild-type Hepa-1 cells. G418-resistant colonies were analyzed for
luciferase expression in the presence or absence of TCDD treatment.
Colonies that showed TCDD inducibility were chosen as reporter cell
lines for analysis of AHR-ARNT-dependent gene activation. Medium
containing 10 or 100 nM Ellipticine (Sigma), DMSO vehicle control, or
10 nM TCDD was added to semiconfluent cells, and luciferase activity
was assayed 12 h after treatment and normalized to the amount of
total protein in the cell lysate, as measured by the Bradford assay
(Bio-Rad).
Plasmid constructs.
The Ah receptor expression plasmids
pcDNAI/B6AHR and pcDNAI/D2AHR were cloned into the
BamHI and XbaI sites of the pcDNAI/Amp vector (Invitrogen) with reverse transcription (RT)-PCR-amplified cDNA
fragments from lymphocytes of C57BL/6J and DBA/2 mice, respectively. The amplified product contained 2,638 bases, beginning 39 nucleotides upstream from the ATG codon and ending 181 nucleotides past the termination codon in the Ahrb-1 allele, as
previously described (7). Amino acid changes in the
expression plasmids were generated by standard recombinant DNA
techniques with the appropriate cDNA fragments obtained by RT-PCR from
lymphocytes of DBA/2 mice (7). Unique restriction sites in
the AHR cDNA were used to generate chimeric constructs pR, pNMR, pNM,
pPNMR, pP, pVPNM, pVP, and pV by gradually replacing corresponding DNA
fragments in pcDNAI/B6AHR with DNA fragments from pcDNAI/D2AHR.
Relevant polymorphisms (7) in these constructs were
confirmed by DNA sequencing, and expression of the encoded AHR proteins
was verified by coupled in vitro transcription-translation. Complete
details of the construction of these chimeric plasmids are available
upon request. Reporter construct p1646P1Luc2 was generated by
subcloning the Cyp1a1 5'-regulatory sequences from 
1646 to
+57 (20, 21) into the pGL2 basic vector (Promega). Complementary oligonucleotides encoding one copy of the AhRE sequence 5' TCGAACTCACGCAACT 3' (26) were annealed and
ligated into the MluI site of the pGL2 promoter vector
(Promega) to generate the pAhRESV40Luc2 reporter construct. pAhRDtkLuc2
was constructed by ligation of the mouse Cyp1a1 AhRD
enhancer (coordinates 1100 to 896), containing three different AhRE
motifs (20, 45), into a modified pGL2 basic vector that
contains the herpes simplex virus type 1 thymidine kinase
(tk) minimum promoter from 79 to +53 (39), from
which the SP1-binding site was removed. pAhRDtkLuc3 and pAhRDSV40Luc3
were similarly constructed by cloning the AhRD sequences next to the
tk or simian virus 40 (SV40) minimum promoter, respectively,
in the pGL3 basic vector. The mouse ARNT expression plasmid
pcDNAIneo/mARNT was generously provided by O. Hankinson (54). The chimeric construct 
DBD/DR83-593, containing the
AHR ligand-binding region (amino acids 83 to 593) fused to the
glucocorticoid receptor DNA-binding and transactivation domains, and
the alkaline phosphatase reporter pGREII-oct-AF were gifts from L. Poellinger and M. Whitelaw (70, 71). Plasmid pAhP1S,
expressing full-length mouse CYP1A1, has been described previously
(57). pAhP1short is a derivative of pAhP1S containing an
insertion of 3 stop codons in the three frames at amino acid 429 which
thus codes for a truncated, nonfunctional form of the CYP1A1 protein.
Plasmid pcDNAI/B6AhR-GFP, encoding a fusion protein of the AHR and the
green fluorescent protein (GFP) from Aequorea victoria, was
generated as follows: GFP coding sequences were excised from pAlpha+GFP
(Maxigene) and cloned into the EcoNI site at the 3' end of
the B6AHR coding sequences in pcDNAI/B6AHR, interposing between the two
coding sequences a (Gly-Ala)5 linker, as described for the
glucocorticoid receptor-GFP fusion protein (27).
pAHR
495-805 was derived from pcDNAI/B6AHR by deleting the C-terminal
311 amino acids; this plasmid encodes an AHR protein which is capable
of ligand binding and dimerization with ARNT but lacks transactivation
activity.
In vitro transcription-translation.
One microgram each of
pcDNAI/B6AHR-GFP and pcDNAIneo/mARNT were used in a 50-µl in vitro
transcription-translation reaction with the TNT-coupled
reticulocyte lysate system from Promega, according the
manufacturer's directions. Reaction mixtures were incubated at 30°C
for 2 h, and translated proteins were kept at 20°C until use.
Gel mobility shift assays.
Cells were grown on 15-cm plates
to subconfluence and treated with DMSO vehicle or 10 nM TCDD for 1 h. Nuclear extracts were prepared as described previously (6,
9) and kept at 70°C until use. For gel mobility shift assays,
20 µg of nuclear protein extract was mixed with 1 µg of
poly(dI-dC)-poly(dI-dC) in binding buffer containing 0.12 M KCl, 1 mM
EDTA, 1 mM dithiothreitol, 10% glycerol, and 20 mM HEPES (pH 7.8) for
15 min at room temperature. One-tenth of a nanogram of
32P-labeled probe was added to the reaction mix and
incubated for an additional 15 min at room temperature. Bromophenol
blue was added before the reaction mixture was loaded onto a 4%
nondenaturing polyacrylamide gel. The gel was run at 200 V for 2 h
and visualized by autoradiagraphy. Quantitation of bound probe was done
with the ImageQuaNT algorithm of the Storm 860 PhosphorImager
(Molecular Dynamics). The mXRE-1 probe was generated as described
previously (59), with [32P]dCTP as the labeled
precursor.
For experiments using in vitro-translated proteins, 5 µl of the
pcDNAI/B6AHR-GFP and 5 µl of the pcDNAIneo/mARNT translation reaction
mixtures were combined and incubated with 0.1% DMSO or 100 nM TCDD at
30°C for 1 h. Reaction mixtures were used for gel mobility shift
assays according to the protocols described above.
Western blots.
Nuclear and cytosolic extracts from Hepa-1,
c37, and CX4 cells were analyzed for the presence of Ah
receptor as described previously (53), by using a specific
anti-AHR antibody, a generous gift of R. Pollenz. Chemiluminescent
images were quantitated by Scan Analysis software (Biosoft). For
Western blot analysis of CYP1A1 expression, CV-1 cells were harvested
in 1× PBS 40 h after transfection, pelleted by centrifugation,
and washed once with PBS. Cell pellets were resuspended in buffer A (10 mM Tris-HCl, 1 mM EDTA, 2 mM dithiothreitol [pH 7.5]) and homogenized
with a Wheaton tissue grinder. Cell homogenates were spun down at
600 × g to clear out the nuclear pellet and then
subjected to centrifugation at 105,000 × g for 1 h to collect the microsomal fraction. Microsomal pellets were dissolved
in sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis
buffer (62.5 mM Tris-HCl [pH 6.8], 2% SDS, 2% 2-mercaptoethanol,
10% glycerol). Twenty micrograms of the microsome-enriched fractions
were separated by SDS-12% polyacrylamide gel electrophoresis and
transferred to a polyvinylidene difluoride membrane for Western
blotting. The membrane was incubated with BLOTTO (5% fat-free milk
powder in TTBS [150 mM NaCl, 50 mM Tris, 0.2% Tween 20 {pH
7.5}]) for 2.5 h at room temperature and then incubated with
primary antibody P450c (rabbit anti-mouse CYP1A1; a gift from S. Kimura) diluted 1:5,000 in BLOTTO for 2 h at room temperature. The
blot was washed 4 times with TTBS+ (300 mM NaCl, 50 mM Tris, 0.5%
Tween 20 [pH 7.5]) and incubated with a 1:5,000 dilution of
horseradish peroxidase-conjugated goat anti-rabbit secondary antibody
for 1 h. The blot was washed and developed with the Amersham ECL
detection system.
Fluorescence microscopy.
Hepa-1 or CV-1 cells were seeded
onto coverslips and cotransfected with pcDNAI/B6AhR-GFP and
pcDNAIneo/mARNT. Approximately 48 h after transfection, cells were
treated with DMSO vehicle or 10 nM TCDD for 2 h. The coverslips
were washed 3 times with PBS and fixed in 2% paraformaldehyde-PBS for
30 min at room temperature. After fixing, the coverslips were washed 3 times in PBS, mounted on microscope slides with 80% glycerol-PBS, and
sealed with rubber cement. A Leitz Laborlux S microscope equipped with
3
-Ploemopak incident fluorescent light was used to visualize
cellular localization of the expressed GFP proteins with an excitation
wavelength of 450 to 490 nm and an emission wavelength of 515 nm.
Approximately 40 to 50 highly fluorescent cells were observed per
coverslip of transfected cells. Transfection experiments were repeated
3 or 4 times; shown in Fig. 5c are typical representatives of each cell
line and treatment.
| |
RESULTS |
CYP1A1 autoregulates its own transcription through an AHR-ARNT
complex.
We used electrophoretic mobility shift assays to
determine whether activated AHR-ARNT complexes were present in
unstimulated CYP1A1-deficient cells. Nuclear protein extracts from
wild-type Hepa-1, CYP1A1-deficient c37 cells, and CX4 cells,
a c37 stable transfectant line that expresses a
plasmid-encoded wild-type CYP1A1 enzyme, were analyzed with a
32P-labeled AhRE probe. Control nuclear extracts from
Hepa-1 cells showed high TCDD-dependent recruitment of AhRE-binding
complexes to the nucleus, whereas c37 extracts showed
greatly reduced levels of these complexes. Expression of CYP1A1 in CX4
cells restored a wild-type-like phenotype, with extensive TCDD-induced
nuclear translocation (Fig. 1A).
Quantitation of several such gel shift experiments showed that CYP1A1
deficiency in c37 cells resulted in two separate effects. On
the one hand, AHR-ARNT nuclear activation in untreated cells was
fivefold higher than that observed in control Hepa-1 cells (Fig. 1B).
On the other hand, TCDD-induced activation was reduced to one-third of
the level observed in TCDD-treated Hepa-1 cells. As a result, overall
TCDD-dependent induction, approximately 40-fold in Hepa-1 cells, was
reduced to only 3-fold in c37 cells. CX4 cells partly
restored the wild-type phenotype, with significantly lower uninduced
and higher TCDD-induced levels of AHR-ARNT complexes. Western blot
analysis of nuclear and cytosolic extracts from these cell lines (Fig.
1C) indicated that the amount of AHR in c37 cells was
extremely low compared to Hepa-1 and CX4 cells. Results from three
Western blots were quantitated, showing that c37 cells had only 3% of the AHR levels found in Hepa-1 cells and that CX4 cells had
an almost complete restoration of the wild-type phenotype (Table
2); however, compared to Hepa-1 and CX4,
a significantly larger proportion of the AHR in untreated
c37 cells was localized to the nucleus (Table 2).
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FIG. 1.
Detection of active AHR-ARNT complexes and of AHR in
wild-type and variant mouse hepatoma cell lines. (A) Electrophoretic
mobility shift assays. Hepa-1, c37, and CX4 cells were grown
to subconfluence and treated with 10 nM TCDD (T) or with DMSO vehicle
(C) for 1 h. Nuclear extracts were prepared, and gel mobility
shift assays were performed as described in Materials and Methods. The
arrow indicates the shifted AHR-ARNT complex. (B) Quantitation of
mobility shift data. Three separate gel shift assays were quantitated
by PhosphorImaging. The ordinate represents the ratio of probe bound by
each of the nuclear extracts tested to probe bound by the untreated
Hepa-1 nuclear extract and thus is a measure of changes relative to
constitutive levels in wild-type cells. Indicated in the abscissa is
the fold induction by TCDD for each cell line tested. (C) Western blot
analysis of AHR. Cytosolic (C) and nuclear (N) extracts from Hepa-1,
c37, and CX4 cells were separated in 7.5% acrylamide gels,
transferred to polyvinylidene difluoride and analyzed for the presence
of AHR with an AHR-specific antibody. For Hepa-1 and CX4, 20 µg of
cytosolic or nuclear extract was used; for c37, 20, 40, and
60 µg of each extract was used, as indicated over the lanes.
c37-60* is a 20-fold longer exposure of the lane denoted by
c37-60. (D) Transient transfection assays. Hepa-1 (wild
type), c37 (Hepa-1 derivative lacking CYP1A1 enzymatic
activity), CX4 and CH3.3 (c37 stable transfectants
expressing mouse CYP1A1 and human CYP1A2, respectively), and CPr
(c37 stable transfectant carrying enhancerless mouse CYP1A1
cDNA) were transiently transfected with pAhRDtkLuc3 and pCMVgal and
treated with 10 nM TCDD or DMSO vehicle 14 to 16 h after
transfection. Luciferase and -galactosidase assays were performed as
described in Materials and Methods. The ordinate represents the ratio
of normalized luciferase activity to activity in untreated Hepa-1
cells. Fold induction by TCDD is the ratio of luciferase activity in
TCDD-treated to untreated samples in the same transfection group.
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We also measured the expression of pAhRDtkLuc3, a luciferase reporter
plasmid driven by the AhRD enhancer (20, 45), in transient
transfection assays in CYP1A1-deficient and wild-type Hepa-1 cells
(cell lines and phenotypes are shown in Table 1). In addition to
Hepa-1, c37, and CX4 cells, we also tested CH3.3 cells,
derived from c37, which overexpress a plasmid encoding the
human CYP1A2 enzyme, and CPr cells, also a c37 variant,
which are stably transfected with a plasmid containing mouse CYP1A1 cDNA fused to an enhancerless SV40 promoter. CPr cells were used as a
control, since absence of the AhRD enhancer prevents these cells from
expressing detectable levels of CYP1A1 enzyme (56, 57). In
good agreement with the gel shift data, basal luciferase expression in
untreated CYP1A1-deficient cells was significantly higher than in
wild-type Hepa-1 cells (Fig. 1D), and expression levels in TCDD-treated
cells were within a twofold range for all cell lines regardless of
CYP1A1 functional status. As a consequence, treatment with TCDD caused
only a 5-fold induction in c37 and CPr, whereas similar
treatment in wild-type Hepa-1 cells caused a 50-fold induction; hence,
we surmise that TCDD treatment in these CYP1A1-deficient cell lines
results in low induction values because these cells already have
elevated constitutive levels of luciferase expression. In contrast, CX4
and CH3.3, the two c37 variants expressing CYP1A1 and CYP1A2
enzymes, respectively, showed significantly lower basal luciferase
activity, resulting in an elevation to 13- and 9-fold induction,
respectively, by TCDD (Fig. 1D). To test whether inhibition of CYP1A1
enzymatic activity in wild-type Hepa-1 cells would also increase basal
levels of AHR-ARNT-dependent gene expression, we used Ellipticine, a suicide inhibitor of CYP1A1 activity (34) that, at the low
doses used in our experiments, is not a mouse AHR agonist
(17). Treatment with 10 or 100 nM Ellipticine significantly
induced AHR-ARNT-driven luciferase gene expression, to levels
approaching those observed in TCDD-treated cells (Table
3). These results suggest that activation of AHR-ARNT complexes can take place as a result of the interaction between AHR and a CYP1A1 substrate. Both wild-type and c37
cell lines have little CYP1B1 expression, which is detectable only by
RT-PCR (10a); hence, the possible role of this putative
compound as a CYP1B1 substrate remains to be elucidated.
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TABLE 3.
Induction of AHR-ARNT-dependent reporter gene expression
by Ellipticine in Hepa-1 cells stably transfected with pAhRDtkLuc3
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Expression of AHR in CV-1 cells results in a dose-dependent
increase in reporter gene expression in the absence of exogenous
ligand.
It has been reported that transient transfection of a
plasmid encoding AHR into CV-1 cells, which lack endogenous AHR
expression (16), results in high levels of reporter gene
expression in the absence of an exogenous AHR ligand and that addition
of an exogenous ligand such as TCDD causes only a two- to threefold induction (16, 30, 37, 38). These findings, which were attributed to nonphysiological conditions resulting from overexpression of transfected plasmids, resemble our results in CYP1A1-deficient hepatoma cells; however, since CV-1 cells lack CYP1A1 activity, these
results might be explained equally well by the accumulation of an
endogenous CYP1A substrate capable of activating the formation of
AHR-ARNT complexes.
To test this possibility, we determined the effect of transfecting CV-1
cells with decreasing amounts of the expression plasmid pcDNAI/B6AHR.
In the absence of TCDD treatment, decreasing amounts of this plasmid
led to a dose-dependent decrease in luciferase expression, yet TCDD
treatment caused less than a 2.5-fold induction, regardless of
the amount of pcDNAI/B6AHR used in the transfection (Fig.
2A). By comparison, transfection of
increasing amounts of pcDNAI/B6AHR into Hepa-1 cells, which
express AHR endogenously, did not lead to significant changes in basal
reporter gene expression levels, regardless of plasmid dose, and led
only to a minor reduction in TCDD-induced levels at the higher plasmid
doses (Fig. 2B). Since Hepa-1 cells express AHR endogenously,
we cannot rule out experimentally the formal possibility that
overexpression did not take place in the Hepa-1 cell line. We feel,
however, that this possibility is rather unlikely, since other
expression plasmids (e.g. -galactosidase reporters) controlled by
the same cytomegalovirus promoter used for AHR expression show clear
dose-dependent expression effects.
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FIG. 2.
AHR dose-dependent reporter gene expression in CV-1 (A)
and Hepa-1 (B) cells. Transient transfections contained fixed amounts
of pAhRDSV40Luc3 reporter gene, pCMVgal, and
pcDNAIneo/mARNT, and increasing amounts of pcDNAI/B6AHR, as shown on
the abscissa. Twenty-four hours after transfection, cells were treated
with DMSO vehicle control or 10 nM TCDD. Luciferase and
-galactosidase activities were measured 14 to 16 h after
treatment. The ordinate represents luciferase activity normalized to
-galactosidase activity.
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To rule out the possibility that the results observed were due to
unknown peculiarities of one or another promoter-enhancer combination
in the reporter constructs, we tested several such combinations. The
combinations tested contained either the 1646 to +57 regulatory
region of the mouse Cyp1a1 gene, the AhRD enhancer region
fused to either an SV40 or a tk minimal promoter, or one copy of the AhRE motif fused to the SV40 minimal promoter. Similar patterns of AHR-dependent gene expression were observed regardless of
the reporter constructs used. Basal (vehicle-treated) activities were
always higher in CV-1 cells than in Hepa-1 cells transfected in
parallel, and, depending on the particular enhancer-promoter combination used, TCDD treatment induced luciferase expression to a
much higher extent in Hepa-1 cells than in CV-1 cells (Fig. 3), ruling out promoter-enhancer
variations as the explanation for the results.
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FIG. 3.
Effects of different promoter-enhancer combinations on
TCDD induction of reporter gene expression in Hepa-1 and CV-1 cells.
The different DNA sequence motifs used to construct the reporter
plasmids shown are described in detail in Materials and Methods. Fold
induction by TCDD is the ratio of the relative luciferase activities in
TCDD-treated versus DMSO-treated samples.
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CYP1A1 regulates activation of AHR-ARNT transcriptional
complexes.
Since CV-1 cells do not have detectable CYP1A1 activity
(26), a likely explanation for the results described above
is that, as in c37 cells, an endogenous CYP1A1 substrate
that accumulates in CV-1 cells due to the lack of CYP1A1 enzyme
activity is also a putative AHR ligand. To test this hypothesis,
we determined the effect of a coexpressing pAhP1S, an expression
plasmid encoding full-length CYP1A1 cDNA, on basal AHR-dependent
reporter expression. The experimental design was to examine whether the
presence of a functional CYP1A1 enzyme would suppress the high
constitutive levels of reporter gene expression. In addition to
the control plasmid pCMVgal, five additional plasmids were
simultaneously transfected into the cells: (i)
pcDNAI/B6AHR and pcDNAIneo/mARNT, needed to activate CYP1A1
expression from pAhP1S, since expression of this plasmid is
controlled by the AhRD enhancer element (56); (ii)
DBD/DR83-593, a chimeric plasmid carrying the glucocorticoid receptor DNA-binding and transactivation domains fused to the AHR
ligand-binding domain (70). This chimeric AHR, when
activated by AHR ligands, transactivates genes containing
glucocorticoid response elements (GREs) and thus serves as a sensor of
changes in levels of putative AHR ligand (CYP1A substrate) resulting
from CYP1A1 enzymatic activity); and (iii) pGREII-oct-AF, a
GRE-containing reporter construct that responds to activation of the
chimeric AHR by expressing secreted alkaline phosphatase
(71).
If our hypothesis was correct, we would expect that increased doses of
pAhP1S would lead to higher CYP1A1 activity and to decreased levels of
the putative ligand. The overall effect would be detected as a
dose-dependent decrease in alkaline phosphatase activity. This
prediction was indeed correct. Expression of CYP1A1 caused a
dose-dependent decrease in alkaline phosphatase expression (Fig.
4A) and a concomitant increase in TCDD
inducibility (Fig. 4B). In contrast, expression of pAhP1short, a
control plasmid encoding a truncated form of CYP1A1 lacking enzymatic
activity, had no effect on basal or TCDD-induced reporter gene
expression (Fig. 4A and B). A Western blot with antibodies against
mouse CYP1A1 verified that pAhP1S, but not pAhP1short, expressed
increasing amounts of full-length CYP1A1 in the transfected cells in a
dose-dependent manner (Fig. 4C).
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FIG. 4.
Inhibition by CYP1A1 of constitutive activation of
AHR-ARNT complexes. CV-1 cells were cotransfected with the
chimeric AHR construct DBD/DR83-593, its reporter gene
pGREII-oct-AF, the pCMVgal control plasmid, and increasing amounts
of pAhP1S or pAhP1short. To activate transcription of CYP1A1 from
pAhP1S (encoding a functional enzyme) and pAhP1short (encoding a
truncated, nonfunctional enzyme), we also cotransfected fixed amounts
of pcDNAI/B6AHR and pcDNAIneo/mARNT in all experiments. (A) Medium was
changed 40 h after transfection, and alkaline phosphatase (AP) and
-galactosidase activities were measured 14 to 16 h later.
Relative AP activity is expressed as the ratio of AP to
-galactosidase activity. The doses, in micrograms, of plasmid per
106 cells of pAhP1S or pAhP1short are indicated on the
abscissa. (B) Fold induction by TCDD, measured as the ratio of the
relative AP activities in TCDD-treated versus DMSO-treated samples, is
plotted as a function of plasmid dose. (C) Western blot analysis of
CYP1A1 expressed in the transfected cells. Doses of pAhP1S or
pAhP1short (in micrograms of plasmid per 106 cells) are
indicated over the corresponding lanes. 0 and T, control and
TCDD-treated untransfected CV-1 cells and Hepa-1 cells, respectively.
Five micrograms of TCDD-treated Hepa-1 microsomal protein extract and
20 µg of all other microsomal extracts were separated by
electrophoresis in 12% polyacrylamide gels.
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|
Transfected AHR is targeted to the nucleus of CV-1 cells.
The
transient transfection data discussed above suggests that the AHR may
be constitutively activated in CV-1 cells and, therefore, that it may
be targeted to the nucleus even in the absence of an exogenous ligand.
To visualize the cellular localization of the transfected AHR in CV-1
cells and to compare it with its localization in control Hepa-1 cells,
we made use of a plasmid expressing a GFP-tagged AHR protein. GFP, the
green fluorescent protein from A. victoria, is an
autofluorescent protein that can be directly observed by fluorescence
microscopy at 450 to 490 nm and 515 nm as excitation and emission
wavelengths, respectively. GFP fusion chimeras have been used
extensively to visualize protein trafficking in cells (see reference
27 and references therein). Gel shift and transient
transfection assays were used to verify that the functional
characteristics of AHR were maintained by the AHR-GFP fusion protein.
Indeed, AHR-GFP showed ligand-dependent dimerization with ARNT and DNA
binding (Fig. 5a), as
well as activation of luciferase expression in a transient transfection
assay (Fig. 5b). In the absence of TCDD treatment, Hepa-1
cells transiently transfected with pcDNAI/B6AHR-GFP showed
cytosolic localization of the vast majority of the chimeric AHR-GFP
protein (Fig. 5c, upper left panel), whereas after TCDD treatment the
majority of AHR-GFP was found in the nucleus (Fig. 5c, lower left
panel). In contrast, CV-1 cells transfected with the same plasmid
showed similar patterns of localization in untreated and TCDD-treated cells, with the majority of the AHR-GFP protein expressed in untreated cells already localized to the nucleus (Fig. 5c, right two panels), thus suggesting the constitutive presence of an AHR ligand or activator
in these cells.
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FIG. 5.
Cellular localization of transfected AHR in CV-1 and
Hepa-1 cells. (a) Gel mobility shift assays using in vitro-translated
B6AHR-GFP and mARNT. Translated proteins were incubated with 0.1% DMSO
() or 100 nM TCDD (+) for 1 h at 30°C before the gel shift
reaction. Nuclear extracts from DMSO-treated (C) and TCDD-treated (T)
Hepa-1 cells were also included in the gel shift assays as controls.
(b) Reporter gene pAhRDtkLuc3 expression in CV-1 cells transiently
transfected with pcDNAI/B6AHR-GFP or pAlpha+GFP. Control plasmid
pCMVgal and the mARNT expression plasmid pcDNAIneo/mARNT were also
included in the transfection. (c) Subcellular localization of the
AHR-GFP fusion protein. Hepa-1 and CV-1 cells grown on coverslips were
cotransfected with pcDNAIneo/mARNT and pcDNAI/B6AHR-GFP and treated
with either DMSO vehicle control (C) or 10 nM TCDD (T) for 2 h.
Cells were fixed with 2% paraformaldehyde, and the expressed fusion
proteins were visualized by fluorescence microscopy at 450 to 490 nm
and 515 nm as excitation and emission wavelengths, respectively. Five
representative cells from each transfection are shown for each cell
line and treatment.
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|
Inhibition of transactivation by wild-type AHR with chimeric and
truncated AHR proteins.
The previous results support the view that
an endogenous CYP1A1 substrate possibly also functions as an AHR
ligand. If this is the case, chimeric and truncated AHR containing the
ligand-binding domain should compete with wild-type AHR for this
putative endogenous ligand. To test this hypothesis, CV-1 cells were
cotransfected with a fixed amount of pcDNAI/B6AHR and with increasing
amounts of the chimeric DBD/DR83-593 used in previous experiments
along with the two reporter plasmids pAhRDSV40Luc3 and pGREII-oct-AF. Competition for ligand between wild-type and chimeric AHR in these experiments was monitored by the changes in expression of the two
reporter genes. As the dose of DBD/DR83-593 increased, expression of
its corresponding reporter gene pGREII-oct-AF also increased, while
expression of the reporter in pAhRDSV40Luc3, responsive to wild-type AHR, concomitantly decreased (Fig.
6B), suggesting that the chimeric Ah
receptor in DBD/DR83-593 and wild-type AHR compete for a common
activator.
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FIG. 6.
Competition of wild-type and chimeric or truncated AHR
proteins for endogenous ligand. CV-1 cells were cotransfected with
reporter constructs pAhRDSV40Luc3, pGREII-oct-AF, pCMVgal, a fixed
amount of pcDNAI/B6AHR, and increasing amounts of DBD/DR83-593, as
indicated on the abscissa (in micrograms per 106 cells).
Secreted alkaline phosphatase (AP) activity (A) and luciferase activity
(B) were assayed from the medium and cell lysate, respectively, of the
same transfected cells and normalized to -galactosidase activity.
(C) Increasing amounts (in micrograms per 106 cells) of
pAHR495-805 expressing a truncated AHR were cotransfected into CV-1
cells with pcDNAI/B6AHR, pcDNAIneo/mARNT, pCMVgal, and the reporter
plasmid pAhRDtkLuc3. Luciferase and -galactosidase activities were
measured and calculated as described above.
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|
To test the hypothesis further we used a truncated AHR, encoded by
pAHR495-805, as a competitor. This AHR mutant contains only the
N-terminal 494 amino acids, including the bHLH and the ligand-binding
domains but not the transactivating domain. Cotransfection of
increasing amounts of this plasmid also caused a dose-dependent decrease of luciferase expression (Fig. 6C). This truncated AHR could
also function as a dominant negative mutant preventing wild-type AHR
from interacting with ARNT (10, 16), and it could be argued that its effect on luciferase expression was solely due to
sequestration of ARNT. This is unlikely, however, because the chimeric
AHR, DBD/DR83-593, also blocks wild-type AHR function and yet does not dimerize with ARNT. It is more likely that activity of the truncated AHR is the result of additive dominant negative and ligand
competition effects. Chimeric and truncated AHR have in common the
ligand-binding domain, and both require ligand for activation,
suggesting that this domain is responsible for their effect in blocking
wild-type AHR function. Trivial explanations for these results, such as
depletion of common elements of the transcription machinery, are
possible, although unlikely, since expression of
-galactosidase, which shares the same elements and is used as
a normalization factor, is unaffected by the increased doses of
competitor plasmid. These results, therefore, are in better agreement
with the conclusion that elevated, constitutive AHR-ARNT-dependent gene expression in CV-1 cells is due to activation of AHR, most likely by an endogenous CYP1A1 substrate that is also an
AHR ligand. We cannot rule out, however, the possibility that other
mechanisms might also be involved.
High- and low-ligand-affinity AHR variants show different
affinities for the endogenous ligand.
ANF inhibits
AHR-ARNT-dependent gene expression by acting as an AHR antagonist
that blocks the binding of xenobiotic Ah receptor ligands (18, 40,
41, 72). In preliminary experiments using expression plasmids of
the two AHR ligand affinity variants encoded by the
Ahrb-1 and Ahrd alleles
(48, 50), we observed that ANF blocked reporter plasmid expression directed by the low-affinity Ahrd
allele to a greater extent than that of the high-affinity
Ahrb-1 allele (data not shown). Five-amino-acid
differences have been found between these two alleles (7),
of which an A375V change is responsible for the high-versus
low-affinity polymorphism (11, 52). If this ligand affinity
polymorphism were also true for the putative endogenous ligand, we
would expect that the observed differences in the ability of ANF to
block Ahrb-1- and
Ahrd-directed reporter expression would also
depend on the presence of Ala or Val at position 375. To test this
hypothesis, we constructed chimeric combinations of the two Ah receptor
proteins by replacing corresponding DNA fragments in the pcDNAI/B6AHR
and pcDNAI/D2AHR plasmids, which encode the AHRB-1 and AHRD proteins,
respectively. We used these constructs, as well as the parental
plasmids, for transient transfection experiments and determined the
effect of ANF treatment on luciferase expression. In agreement
with our preliminary observations, ANF treatment blocked the
low-affinity AHR, encoded by pcDNAI/D2AHR, three to four times
more efficiently (20 to 30%, compared to 70 to 80% of control values)
than the high-affinity AHR, encoded by pcDNAI/B6AHR (Fig.
7). In addition, experiments with the
chimeric combinations of the two Ah receptor proteins demonstrated that
the presence of Val at position 375 resulted in extensive inhibition by
ANF (Fig. 7), thus confirming our hypothesis that the same amino acid
change responsible for the differences in ligand-binding affinities
(11, 52) was responsible for the differences in
ANF-dependent inhibition. The fact that a point mutation known to
affect ligand affinity is the main determinant for ANF competition is
compelling evidence that the effect of ANF is due to competition with
an endogenous ligand present in CV-1 cells.
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FIG. 7.
Differential antagonism by ANF of transactivation by
high- and low-affinity AHR variants. CV-1 cells were transfected with
pAhRDtkLuc3, pCMVgal, pcNDAIneo/mARNT, and different pcDNAI/AHR
chimeric constructs. The positions of amino acid differences between
Ahrb-1 and Ahrd alleles,
encoded by plasmids pcDNAI/B6AHR and pcDNAI/D2AHR, respectively, are
shown at the top of the diagram on the left. Amino acids are
represented by their one-letter codes. The star denotes the termination
codon. Amino acid differences between Ahrb-1-
and Ahrd-encoded proteins are shown in black
lettering on an open square (Ahrb-1 allele) or
white lettering on a filled circle (Ahrd
allele). All chimeric constructs were generated by replacing segments
from the cloned AHRB-1 cDNA with the corresponding regions from the
cloned AHRD cDNA. Transfected CV-1 cells were treated with DMSO vehicle
control or with 1 µM ANF (a dose predetermined in preliminary
experiments) at 24 h after transfection. Luciferase and
-galactosidase activities were measured 14 to 16 h after
treatment. The ordinate represents the ratio of luciferase activity in
ANF-treated cells to that in control cells.
|
|
| |
DISCUSSION |
The data presented in this study show that constitutive activation
of AHR-ARNT transcriptional complexes is regulated by the level of
CYP1A enzymatic activity. In the absence of CYP1A enzymes, Hepa-1
variant c37, lacking CYP1A1 activity, and AHR- and
CYP1A1-negative CV-1 cell lines show constitutive levels of
AHR-ARNT-dependent gene expression approaching 20 to 80% of those
found following treatment of Hepa-1 cells with TCDD, the most potent
AHR ligand. In addition, inhibition of CYP1A1 enzymatic activity in
wild-type Hepa-1 cells also leads to activation of AHR-ARNT in the
absence of exogenous ligand. In both c37 and CV-1 cell
lines, introduction of a CYP1A1 expression plasmid down-regulates the
high levels of AHR-ARNT activation. These results suggest that an
endogenous CYP1A1 substrate is responsible for the constitutive
activation of AHR-ARNT-dependent gene expression.
Autoregulatory transcriptional derepression has been shown to take
place for Cyp1a1 and other genes of the [Ah]
battery (57). The present results extend this observation
and show that derepression of these genes is due to endogenous
activation of the AHR-ARNT transcriptional complex. The experiments
represented in Fig. 1 indicate that in the absence of CYP1A1 activity,
a greater proportion of the Ah receptor in untreated c37
cells is activated and hence translocated to the nucleus. Activated
nuclear Ah receptor undergoes proteolytic degradation at a much higher
rate than the cytosolic form (19, 53), which suggests that
the low levels of AHR found in c37 cells are possibly due to
resetting of steady-state levels resulting from constitutive nuclear
translocation and subsequent degradation. Overexpression of CYP1A1 or
CYP1A2 restores partially, but not completely, TCDD inducibility in
CYP1A1-deficient cell lines, suggesting that CYP1A activity is not the
only factor that controls constitutive AHR-ARNT activation. CV-1 cells,
which do not express AHR, show a much higher degree of derepression
than c37 cells; this suggests that other downstream genes
regulated by AHR are also silent in this cell line and that these genes may also contribute to the autoregulatory mechanism. Alternatively, the
balance between the rates of endogenous ligand synthesis and metabolism
may be widely different in different cell lines, leading to different
constitutive levels of AHR-ARNT activation. These two alternatives are
not mutually exclusive.
Several lines of evidence presented in this article are consistent with
the conclusion that this putative CYP1A1 substrate is also an
endogenous Ah receptor ligand. First, its presence stimulates
AHR-ARNT-dependent transactivation of reporter genes. Second, it
promotes the DNA-binding activity of AHR-ARNT complexes. Third, it
induces AHR nuclear translocation. Fourth, it requires the
ligand-binding domain of AHR for its activity. Last, its effect is
antagonized by ANF and shows functional characteristics for polymorphic
AHR proteins similar to exogenous ligands. Formal proof that the
compound involved is in fact a ligand of AHR must await purification
and structural analysis.
Figure 8 summarizes our current
working hypothesis on the regulation of AHR-ARNT-dependent gene
expression. The endogenous CYP1A1 substrate activates AHR in the
absence of exogenous ligands, but the substrate is to some degree
transformed into an inactive product by the functional CYP1A1
enzyme. Thus, in cells expressing CYP1A1, the substrate is maintained
at a low concentration and AHR is relatively inactive. In cell lines
lacking CYP1A1 activity, the substrate accumulates and AHR is
constantly activated and able to dimerize with ARNT and to
transactivate target genes.
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FIG. 8.
Schematic representation of the current working
hypothesis. CYP1A1 enzymatic activity converts the endogenous
CYP1A1 substrate (S) to an inactive product (P). Substrate-bound AHR
dimerizes with ARNT, and the AHR-ARNT complex transactivates
Cyp1a1 and other target genes.
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|
Nuclear localization of AHR has been reported for HeLa cells in the
absence of an exogenous ligand (63). Similar results have
been observed in the developing mouse embryo (1). Recently, stable transfection of AHR expression plasmids into receptorless cells
has revealed that this protein plays an important role in the control
of cell cycle progression and that no exogenous ligands are needed for
this function (36, 69), further suggesting the existence of
an endogenous AHR ligand. Other members of the bHLH/PAS gene family are
believed to participate in early embryonic development, a stage in
which cells continuously face decision checkpoints for proliferation,
differentiation, or apoptosis. Activation of AHR by an endogenous
ligand might be a critical event at any of these decision checkpoints.
TCDD and other exogenous ligands may derail normal homeostasis by
perturbing the balance in signal transduction pathways relevant to
these decisions. In fact, TCDD is a powerful teratogen (8,
62).
| |
ACKNOWLEDGMENTS |
We are grateful to O. Hankinson (University of California, Los
Angeles) for providing pcDNAIneo/mARNT and for originally supplying the
c37 cell line. We thank M. L. Whitelaw and L. Poellinger (Karolinska Institute, Stockholm, Sweden) for the
DBD/DR83-593 and pGREII-oct-AF plasmids, S. Kimura (NCI) for the
anti-CYP1A1 antibody, R. S. Pollenz (University of South Carolina)
for the anti-AHR antibody, G. L. Hager (NCI) for suggesting the
use of a (Gly-Ala)5 linker on the AHR-GFP fusion protein,
S. Wert (Children's Hospital Research Foundation, Cincinnati, Ohio)
for help and advice with fluorescence microscopy, and S. Eltom and C. Jefcoate (University of Wisconsin) for communicating their results
before publication. We also thank M. Carty, M. J. Carvan, T. P. Dalton, and D. W. Nebert for critical reading of the manuscript
and for many suggestions throughout the course of this work.
This work was supported by grants NIEHS ES06273 and NIEHS P30 ES06096
and by a predoctoral fellowship to C.-Y.C. from the Pharmaceutical
Research and Manufacturers of America Foundation.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Center for
Environmental Genetics and Department of Environmental Health,
University of Cincinnati Medical Center, P.O. Box 670056, Cincinnati,
OH 45267-0056. Phone: (513) 558-0916. Fax: (513) 558-0925. E-mail: Alvaro.Puga{at}UC.EDU.
| |
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Abstract
Introduction
