(Received for publication, August 27, 1996, and in revised form, April 1, 1997)
From the Department of Biochemistry, Queen's University, Kingston, Ontario K7L 3N6, Canada
To induce oxidative stress, HepG2 cells were exposed to a compound known as gramoxone. This compound undergoes a one-electron reduction to form a stable free radical which is capable of generating reactive oxygen species. We demonstrated that exposure of HepG2 cells to gramoxone (0.1 µM) resulted in a 2-fold decrease in apoA-I mRNA with no significant change in apoB and apoE mRNA levels. To examine if increased rates of mRNA degradation were responsible for the reduction in apoA-I mRNA levels, mRNA half-lives were measured in the presence of actinomycin D with and without gramoxone treatment. These studies revealed a 4-fold increase in the rate of apoA-I mRNA degradation in cells exposed to gramoxone. In similarly treated cells, nuclear run-off assays indicated that the transcription rate of the apoA-I gene was also increased 2-fold. Consistent with nuclear run-off assays, transient transfection experiments using a series of pGL2-derived luciferase reporter plasmids containing the human apoAI proximal promoter demonstrated that gramoxone treatment increased apoA-I promoter activity 2-fold. We have identified a potential "antioxidant response element" (ARE) in the apoA-I promoter region that may be responsible for the increase in apoA-I transcriptional activity by gramoxone. Gel mobility shift assays with an ARE oligonucleotide revealed increased levels of a specific protein-DNA complex that formed with nuclear extracts from gramoxone-treated cells. UV cross-linking experiments with the ARE and nuclear extracts from either untreated or gramoxone-treated cells detected proteins of approximately 100 and 115 kDa. When a single copy of the ARE was inserted upstream of the SV40 promoter in a luciferase reporter plasmid, a significant 2-fold induction in luciferase activity was observed in HepG2 cells in the presence of gramoxone. In contrast, a plasmid containing a mutant apoAI-ARE did not confer responsiveness to gramoxone. Furthermore, pGL2 (apoAI-250 mutant ARE), in which point mutations eliminated the ARE in the apoAI promoter, showed no increase in luciferase activity in response to gramoxone. Taken together, the data suggest that gramoxone affects apoA-I mRNA levels by both transcriptional and post-transcriptional mechanisms.
Epidemiological studies have demonstrated that lowering low density lipoprotein-cholesterol (LDL-C)1 or raising high density lipoprotein-cholesterol (HDL-C) reduces cardiovascular risk (1). However, among myocardial infarction survivors, greater than one-half have normal lipid levels, suggesting that factors other than lipoprotein profiles contribute to the disease process (2). One such factor appears likely to be the oxidation of LDL (3-5). Oxidized LDL has been implicated in the formation of foam cells and thus may play an important role in the etiology of atherosclerosis (6, 7). In contrast, oxidized HDL is not avidly taken up by macrophages, does not lead to foam cell formation (8), and may actually inhibit endothelial cell-mediated LDL modification (8, 9). HDL is also capable of protecting against LDL peroxidation in vitro (8, 10, 11). Recently, the antioxidative activity of HDL has been demonstrated in vivo (12). These properties suggest another protective role for HDL (in addition to its involvement in "reverse cholesterol transport") in reducing atherosclerotic risk.
Reduced levels of plasma HDL are observed in cigarette smokers (13, 14). However, the mechanisms responsible for the decrease are not known. During cigarette smoking, the oxidation of polycyclic aromatic hydrocarbons produces free radicals (15). The presence of quinone and hydroquinone complexes in the particulate phase of cigarette smoke can result in generation of reactive species such as superoxides and hydrogen peroxide. If a metal catalyst is present, hydroxyl radicals will also form. Consequently, the smoker has a higher free radical burden and a lower HDL level than the nonsmoker and it has been suggested that this may contribute to the smoker's higher risk of developing atherosclerosis (16).
In this study, we determined whether oxidative stress could affect the synthesis of apoA-I, the major protein constituent of HDL. To induce oxidative stress, the human hepatoma cell line, HepG2, was exposed to gramoxone (also called paraquat and methyl viologen). This compound is a quaternary dipyridyl that is not metabolized but undergoes a one-electron reduction to form a stable free radical (17, 18). Redox cycling of the free radical decreases the levels of reducing equivalents in the cell and it is the critical biomedical event in gramoxone toxicity (19). Gramoxone has no other known mechanism of cytotoxicity (20).
The present study demonstrates that exposure of HepG2 cells to
gramoxone resulted in a 2-fold reduction of apoA-I mRNA, with no
significant effect on apoB and apoE mRNA levels. The observed 2-fold decrease in apoA-I mRNA levels appears to be the result of a
4-fold increase in apoA-I mRNA degradation rate combined with a
2-fold increase in the rate of transcription of the apoA-I gene. The
apoA-I gene promoter contains a sequence match with the 5-flanking
region of the rat glutathione S-transferase (GST) Ya subunit
(21) and the NADP(H) quinone reductase genes (22). The match involves
the motif, 5
-puGTGACNNNGC-3
(where pu is a purine and N is any
nucleotide), corresponding to a putative antioxidant response element
(ARE) (21, 22). One copy of the element with one mismatched nucleotide
is present in the apoA-I promoter between nucleotides
142 and
132
relative to the transcription start site of the gene. Transient
transfection studies demonstrate that the putative ARE is necessary for
gramoxone-mediated induction of human apoA-I gene expression. By
performing gel mobility shift experiments, we found that exposure of
HepG2 cells to gramoxone resulted in increased binding of nuclear
proteins to the ARE. UV cross-linking experiments identified two
polypeptides of approximately 100 and 115 kDa. Taken together, the data
suggest that the mechanism(s) by which gramoxone affects apoA-I
mRNA levels occur(s) at both transcriptional and
post-transcriptional levels.
Complementary pairs of oligonucleotides were
synthesized using the Beckman Oligo 1000 DNA Synthesizer according to
the manufacturer's instructions. The following oligonucleotides (and
their complementary strands) were prepared: apoAI-ARE,
5-CAGCCCCAGGGACAGAGCTG-3
; mutated ARE,
5
-CAGCCCCATTTGAGTGTATG-3
; GST-ARE, 5
-CTAATGGTGACAAAGCAG-3
; xenobiotic response element (XRE), 5
-AGTGCTGTCACGCTAG-3
.
The human hepatoma cell line, HepG2, was obtained from the American Type Culture Collection (Rockville, MD). Cells were grown in T75 flasks containing 20 ml of Eagle's minimal essential medium supplemented with 10% fetal bovine serum as described previously (23). Freshly confluent monolayers were washed twice with minimal essential medium and then incubated with fresh medium for 0-8 h in the absence or presence of gramoxone, dissolved in phosphate-buffered saline, ranging from 0.1 µM to 10 µM. In some experiments, gramoxone and cycloheximide were added to cells to give final concentrations of 0.1 µM and 10 µg/ml, respectively. Where noted, HepG2 cells were also treated with or without gramoxone and in the presence of actinomycin D (1 µg/ml), for various time periods as described in the figure legends. Cell viability was routinely monitored by trypan blue exclusion and lactate dehydrogenase leakage as described previously (24). In all experiments the number of dead cells never exceeded 5% of the total number of cells.
RNA Isolation and DetectionTotal cellular RNA was isolated using the acid guanidinium thiocyanate-phenol-chloroform extraction method described by Chomczynski and Sacchi (25). RNA detection and quantitation were determined by slot blot analyses. For slot blots, multiple RNA samples (0.5-5.0 µg) from cells cultured under a variety of conditions were denatured with formaldehyde and applied to wells of a slot blot apparatus (Bio-Rad) onto Zeta-Probe GT membranes. Blots were prehybridized and hybridized with nick-translated apoA-I, apoB, and apoE cDNA probes as described (26). Detection of catalase mRNA levels was essentially under the same conditions as described for apolipoprotein mRNAs (26). The catalase cDNA probe was obtained from the American Type Tissue Culture Collection (ATCC). All results were normalized using densitometric analyses of slot blots probed with radiolabeled oligo(dT) to correct for loading variations.
Nuclear Run-off Transcription Assay and Preparation of Nuclear ExtractsNuclei were prepared according to the procedure of Bartalena and co-workers (27). An in vitro nuclear run-off transcription assay was carried out as described (27) with minor modifications (24). Procedures for nuclear run-off transcription assays and preparation of nuclear extracts from HepG2 cells have been described in detail previously (28).
Bandshift AssaysFor bandshift assays, nuclear extracts
(1.0 µg) were incubated with 100 µg of poly(dI-dC) in binding
buffer containing 5 mM dithiothreitol and 5 µM ZnCl2, on ice for 30 min. Then 2 fmol (10,000 cpm) of 5-end labeled synthetic oligonucleotides corresponding to either the apoAI-ARE or GST-ARE were added to the reaction mixtures
and incubated on ice for another 30 min. Procedures for bandshift
assays have been described in detail previously (28). Competition
assays were performed by adding the unlabeled competitor DNA 15 min
prior to the addition of either labeled apoAI-ARE or GST-ARE as
indicated in the figure legends.
Ultraviolet (UV) cross-linking experiments were carried out as described by Wu et al. (29) with minor modifications. Briefly, the binding reactions were first carried out as described above for bandshift assays, except that the reaction was scaled up 25-fold. The binding reactions were irradiated on ice for 30 min with a 254-nm wavelength ultraviolet source (Stratalinker). Equal amounts of 2 × SDS sample buffer were added to the irradiated reactions. The samples were then heated at 90 °C for 10 min and electrophoresed on a 8% polyacrylamide/SDS denaturing gel by the method of Laemmli (30). The gel was dried and autoradiographed.
Preparation of Luciferase ConstructsTwo
GeneLightTM vectors (Promega, Life Technologies) were used:
pGL2-Basic (pGL2-B) and pGL2-Promoter (pGL2-P). A 491-base pair DNA
fragment of the human apoA-I promoter between nucleotides 491 to +1
was generated by polymerase chain reaction amplification described in
detail previously (28). The sequence of this DNA fragment was confirmed
by DNA sequencing. The fragment was inserted into the XhoI
site of the pGL2-Basic vector, upstream of the luciferase gene. This
plasmid is hereafter referred to as pGL2(apoAI-491)luc. Plasmid
pGL2(apoAI-250)luc was constructed by releasing a DNA fragment (
491
to
251 of the apoA-I promoter) from pGL2(apoAI-491)luc using
SmaI. The vector was gel purified and re-ligated.
Plasmid pGL2(apoAI-250 mutant ARE)luc was prepared by a polymerase
chain reaction-based protocol as described by Morrison and Desrosiers
(31). To generate this mutated ARE plasmid, two sets of primers were
used. One set of primers, designated GL and LUC, was hybridized to
specific regions of the plasmid pGL2. The other set of primers which
contained the mutagenic ARE residues were named primers FOR and REV.
The primers GL (5-TGTATCTTATGGTACTGTAACTG-3
) and REV
(5
-GATCATACACTCAAATGGGGCTGGG-3
) were complementary to the noncoding
strand of DNA while primers FOR (5
-CCCATTTGAGTGTATGATCCTTGAAC-3
) and
LUC (5
-GGCGTCTTCCATTTTACC-3
) were complementary to the coding strand
of DNA. The plasmid pGL2(apoAI-250)luc was used as the polymerase chain
reaction template. Amplification was carried out as described
previously (28). The DNA fragment generated was then digested with
SmaI and HindIII and the resulting DNA fragment
was purified from an agarose gel. The purified DNA fragment was cloned
into the SmaI and HindIII sites of the pGL2-Basic
(Promega Inc.) and used to transform competent Escherichia
coli cells. DNA was prepared from individual clones by the
alkaline lysis miniprep procedure and the entire DNA insert including
the area of mutagenesis was sequenced using the sequenase version 2.0 system (U. S. Biochemical Corp.).
A series of pGL2-P vectors containing apoAI-ARE, GST-ARE, and mutated
ARE were also constructed. pGL2-P was digested with the restriction
enzymes KpnI and NheI. The restriction digest was
electrophoresed and the digested plasmid was gel purified. Synthetic
oligomers corresponding to the putative ARE from the apoA-I promoter
(apoAI-ARE), the consensus GST-ARE, and mutated ARE were inserted
individually into the KpnI and NheI of the
linearized pGL2-P vectors. All synthetic oligomers contained a
5-KpnI and a 3
-NheI site to facilitate
unidirectional cloning into the pGL2-P vector. The sequence of all
pGL2-P constructs was confirmed by DNA sequencing.
The human hepatoma cell line, HepG2, was maintained as monolayers on 100-mm plates in minimal essential medium supplemented with 10% fetal bovine serum. Transient DNA transfections were performed by the calcium phosphate precipitation procedure described by Gorman and co-workers (32) and detailed previously (28). The cells were then cultured in the absence or presence of gramoxone (0.1 µM) ranging from 0 to 8 h.
Transfected HepG2 cells were harvested by washing three times in
phosphate-buffered saline and assayed for luciferase activity as
described in the Luciferase Assay Kit Technical Manual (Promega, Inc.)
(33). This assay has also been described in detail previously (28). In
all transfections, 5 µg of an internal control plasmid (pSGLacZ)
containing the E. coli Lac Z gene under the control of the
SV40 early promoter and enhancer, was included to correct for
differences in transfection and harvesting efficiency. Transfected cells were harvested as described (28) and
-galactosidase activities in the cell lysates determined (28). The pGL2-promoter vector which
contains a SV40 promoter is used as a reference for both transfection
and luciferase assays. All luciferase activities are reported as
mean ± S.E. Significance of group differences was determined by
Student's t test, using two-tailed p values.
The effects of gramoxone on levels of apolipoprotein mRNAs were examined by slot blot analysis using the level of total poly(A)+ RNA determined by oligo(dT) hybridization to control for variation in RNA loading. Exposure of HepG2 cells to gramoxone at concentrations of 0.1, 1.0, or 10.0 µM for 8 h resulted in a 2-fold reduction in apoA-I mRNA levels. However, there were no significant changes in the levels of apoB and apoE mRNA at any of the above concentrations of drug tested. At a concentration of >10 µM, gramoxone decreased cell viability significantly (data not shown). Therefore, in all further experiments, the drug was used at 0.1 µM.
Analysis of Gramoxone Temporal Response ProfilesTime course
studies of the effect of gramoxone on apoA-I mRNA levels in HepG2
cells were performed to determine whether or not the decline in steady
state levels of apoA-I mRNA could be seen earlier than 8 h.
After 2 h of exposure to gramoxone, apoA-I mRNA levels
decreased to 50% of control values and this decrease was maintained
for the duration of the remaining 6 h (Fig. 1). No
significant differences in apoB and apoE mRNA levels were observed when HepG2 cells were cultured in the presence of gramoxone over the
8-h period. To ensure that the cells were under oxidative stress, the
levels of catalase mRNA were also determined. Exposure of HepG2
cells to gramoxone resulted in a 4- and 10-fold increase in steady
state levels of catalase mRNA at 6 and 8 h, respectively. This
induction could be suppressed by simultaneously exposing the cells to
1% (v/v) dimethyl sulfoxide, a free radical scavenger (data not
shown).
Analysis of the Effect of Gramoxone on Transcription of the ApoA-I Gene and Half-life of ApoA-I mRNA
The 2-fold decrease in
apoA-I mRNA levels could be the result of either a decrease in
rates of transcription or an increased degradation of the apoA-I
mRNA. Therefore, we measured the transcription rate of the apoA-I
gene using isolated nuclei from HepG2 cells cultured in the presence of
gramoxone for 0-8 h. Nuclear run-off assays indicated that the
rate of transcription of apoA-I gene increased approximately 2-fold
between 4 and 8 h after gramoxone treatment (Fig.
2).
To determine if the rate of apoA-I mRNA degradation also changed in
response to gramoxone treatment, the turnover of apoA-I mRNA was
determined in the presence of actinomycin D (1 µg/ml) with and
without gramoxone. The half-lives obtained for apoA-I mRNAs
following the addition of actinomycin D in the absence or presence of
gramoxone were approximately 12.5 ± 1.5 and 3.0 ± 0.4 h, respectively (Fig. 3). Thus, there was a 4-fold
increase in the rate of degradation of apoA-I mRNA when HepG2 cells
were subjected to oxidative stress.
Transient Transfection Studies
To further investigate the
increase in transcription detected by nuclear run-off assays, transient
transfection experiments were carried out using a series of
pGL2-derived luciferase reporter plasmids. As shown in Fig.
4, both pGL2(apoAI-491)luc and pGL2(apoAI-250)luc constructs showed a significant 2-fold induction of luciferase activity
in HepG2 cells cultured in the presence of gramoxone for 8 h. We
hypothesized that the 2-fold increase in apoA-I promoter activity could
involve a potential ARE detected by sequence comparison with the GST Ya
subunit and NADP(H) quinone reductase genes. To test this hypothesis,
we constructed the pGL2(apoAI-250 mutant ARE) in which the entire ARE
consensus sequence was replaced (G T, C
A, T
G, A
C).
Results from these studies demonstrated that pGL2(apoAI-250 mutant
ARE) showed no increase in luciferase activity in response to gramoxone
treatment. To confirm that the ARE was able to confer responsiveness to
gramoxone, transient transfection experiments were carried out using a
series of pGL2-P/luc constructs. The control vector pGL2-P/luc
demonstrated no change in luciferase activity in response to gramoxone
treatment. Plasmids with one copy of the ARE derived from the apoA-I or
GST promoters pGL2(apoAI-ARE)/luc and pGL2(GST-ARE)/luc inserted
upstream of the SV40 promoter, displayed a 4-fold increase in
luciferase expression relative to the control vector. This suggests
that the ARE may enhance the basal rate of transcription of the
reporter gene. Furthermore, the luciferase activity of
pGL2(apoAI-ARE)/luc and pGL2(GST-ARE)/luc was increased by an
additional 2-fold in the presence of gramoxone. However, a plasmid
containing one copy of the mutant apoAI-ARE, pGL2P(apoAI-mutant
ARE)/luc, had a basal rate of expression similar to the control vector
and displayed no responsiveness to gramoxone.
Protein-DNA Interaction at the ARE of the Human ApoA-I Proximal Promoter
Mobility shift experiments were performed to further
examine the mechanism by which the ARE confers responsiveness to
gramoxone. A double-stranded oligonucleotide (apoAI-ARE), corresponding
to the apoA-I promoter between nucleotides 149 and
130, was
end-labeled with 32P and analyzed for its ability to bind
to nuclear proteins isolated from HepG2 cells cultured in the presence
and absence of gramoxone. As shown in Fig.
5A, a retardation complex was detected with
extracts prepared from control HepG2 cells. After 1 h of gramoxone
treatment, the levels of this complex increased 2-fold. This induction
was not blocked by inhibiting protein synthesis with cycloheximide (data not shown). In nuclear extracts from gramoxone-treated HepG2 cells, binding to the labeled apoAI-ARE was efficiently blocked by
competition with 50-100-fold molar excess of unlabeled apoAI-ARE and
to a lesser extent with unlabeled GST-ARE. No competition was observed
with up to 100-fold molar excess of the XRE or a mutant ARE
oligomer.
In contrast, when mobility shift assays were carried out using the GST-ARE as a probe, similar levels of binding activity were observed using nuclear extracts isolated from control and gramoxone-treated HepG2 cells (Fig. 5B). Binding to the labeled GST-ARE probe was also effectively inhibited by competition with 50-100-fold molar excess of unlabeled GST-ARE. However, unlabeled apoAI-ARE was not able to block the formation of the protein-DNA complex efficiently. Both negative control oligomers (XRE and mutant ARE) showed no competition in the binding activity (Fig. 5B).
Identification of the Trans-acting Factor by UV Cross-linking ExperimentsUV cross-linking studies indicated binding of two
polypeptides of apparent molecular masses of approximately 115 and 100 kDa to the apoAI-ARE in both untreated and gramoxone-treated nuclear extracts (Fig. 6A), with the 100-kDa species
being the predominant one bound in both extracts. Densitometry
demonstrated that gramoxone treatment increased in labeling of the 115- and 100-kDa proteins by approximately 71 and approximately 105%,
respectively. Neither polypeptide was detected when binding reactions
were supplemented with a 100-fold molar excess of unlabeled apoAI-ARE
(Fig. 6B).
UV cross-linking experiments were also carried out by using labeled GST-ARE as a probe to determine whether or not the proteins with similar apparent molecular masses were bound. As shown in Fig. 6C, four polypeptides of approximately 21, 28, 57, and 98 kDa were labeled using gramoxone-treated nuclear extracts and a GST-ARE. Similar results were also observed when control nuclear extracts were utilized (data not shown). Densitometric analyses indicated that the 57-kDa protein was the predominant species bound, followed by the 21-, 98-, and 28-kDa protein bands. Binding of these four polypeptides to the labeled GST-ARE probe was efficiently blocked by competition with a 100-fold molar excess of unlabeled GST-ARE.
It has been reported that hyperoxic conditions increase steady state mRNA levels of catalase, Cu/Zn-superoxide dismutase, and glutathione peroxidase in human endothelial cells (34, 35). In HepG2 cells, we found that oxidative stress induced by treatment with gramoxone resulted in a 10-fold increase in steady state levels of catalase mRNA and a 2-fold increase in levels of Cu/Zn-superoxide dismutase mRNA (data not shown). Consistent with the proposed mechanism of action of gramoxone, this response was eliminated by the addition of the free radical scavenger, Me2SO (34). In contrast, gramoxone treatment decreased the steady state levels of apoA-I mRNA 2-fold without affecting the levels of mRNAs for other major apolipoproteins such as apoB and apoE. This down-regulation of apoAI mRNA in response to oxidant treatment suggests that decreased apoA-I synthesis may contribute to the observed reduction in plasma HDL seen in cigarette smokers (13-16).
Our studies demonstrate for the first time that oxidative stress may act by selectively decreasing hepatic apoA-I mRNA levels. Although the molecular mechanisms by which gramoxone modulates apoA-I are not completely understood, we have provided evidence that the 2-fold reduction in apoA-I mRNA level results from a combination of a 4-fold increase in apoA-I mRNA degradation and a 2-fold increase in apoA-I gene transcription. This apparently paradoxical effect on mRNA synthesis and stability is not without precedent. For instance, apoA-I gene transcription decreases during chronic hyperthyroidism while the hepatic abundance of apoA-I increases 3-fold by a mechanism that involves stabilization and/or more efficient processing of the nuclear apoA-I mRNA precursors (36, 37). This observation has prompted the suggestion that apoA-I gene transcription may be subject to feedback regulation and that degradation of nuclear apoA-I RNA could have a positive effect on apoA-I gene transcription (36, 37). While the suggestion remains a hypothesis, the data presented here are also consistent with the possibility that the increase in transcription is a compensatory response to the decrease in apoA-I mRNA levels. In addition to the perturbations of thyroid hormone status, dietary cholesterol and saturated fat can also affect apoA-I gene expression at both transcriptional and post-transcriptional levels (38-42).
In addition to the proposed autoregulation of apoA-I transcription described above, apoA-I gene expression could be directly responsive to oxidative stress since the apoA-I promoter does contain a potential ARE, although the sequence differs by one nucleotide from the putative ARE (21, 22). Bandshift assays demonstrate that both untreated and gramoxone-treated HepG2 nuclear extracts contain factors that bind specifically to the ARE and these factors can be induced by gramoxone treatment. The increase in protein-DNA complex formation was apparent within 1 h of gramoxone exposure and was not blocked by inhibiting protein synthesis, suggesting that the increased binding activity was attributable to modification of a pre-existing factor. UV cross-linking experiments identified two proteins with apparent molecular masses of approximately 100 and 115 kDa (Fig. 6A). Although present in control HepG2 nuclear extracts, gramoxone treatment resulted in an increase in binding of both proteins. Our data differ from a report by Nguyen and Pickett (43) which indicates that proteins UV cross-linked to the GST-ARE have apparent molecular masses of approximately 28 and 45 kDa and that the DNA binding activity of these proteins are not increased by t-butylhydroquinone treatment in HepG2 cells. To examine this discrepancy, we carried out UV cross-linking experiments using labeled GST-ARE as a probe together with either control or gramoxone-treated nuclear extracts. Our results demonstrated four polypeptides (apparent molecular masses of 21, 28, 57, and 98 kDa) were cross-linked to the GST-ARE after UV irradiation (Fig. 6C). In contrast to apoAI-ARE UV cross-linked proteins, the DNA binding activity of these proteins was not increased by gramoxone treatment in HepG2 cells (data not shown). The 28- and 57-kDa proteins may correspond to the two species described by Pickett and co-workers (43). However, at present it is not clear why these investigators do not also observe the 21- and 98-kDa polypeptides. Although the 98-kDa protein cross-linked to the GST-ARE has a very similar size to the smaller and more predominant species cross-linked to the apoAI-ARE, the lack of inducibility of the 98-kDa protein by gramoxone treatment suggests that these two proteins are different. This suggestion is supported by competition bandshift experiments which also indicate differences in the protein binding to these two elements (Fig. 5, A and B).
Transient transfection experiments using pGL2-P-derived luciferase
reporter plasmids confirmed a functional role for the ARE in apoA-I
gene transcription in response to gramoxone. Constructs which contain
nucleotides 491 to +1 and
250 to +1 upstream from the transcription
start site (+1) of the human apoA-I gene show a significant 2-fold
increase in luciferase activity in the presence or gramoxone (Fig. 4).
The involvement of the ARE in gramoxone-mediated induction of apoA-I
gene expression was demonstrated by using the pGL2(apoAI-250 mutant
ARE) in which the consensus ARE was eliminated by multiple point
mutations. Results from these studies indicated that this plasmid had
lost gramoxone inducibility. In addition, we also examined whether or
not the ARE could function independently as a regulatory element using
a heterologous promoter. These studies demonstrated that the plasmids
pGL2P(apoAI-ARE)/luc and pGL2P(GST-ARE)/luc, where one copy of either
the apoAI-ARE or the GST-ARE was inserted upstream of the SV40
promoter, conferred gramoxone inducibility. However, a plasmid
containing one copy of the mutated apoAI-ARE pGL2P(apoAI-mutated
ARE)/luc displayed no response to gramoxone treatment. These data
indicated that the ARE located in the apoA-I promoter region can
function independently as a bona fide regulatory element that is
responsive to oxidative stress.
In summary, we have identified gramoxone-inducible nuclear proteins which bind specifically to the ARE region of the human apoA-I gene. These protein-DNA interactions appear likely to be involved in the mechanism by which oxidant or antioxidant-inducible trans-acting nuclear factors modulate apoA-I gene transcription. Taken together, our data demonstrate that gramoxone affects hepatic apoA-I mRNA abundance by both transcriptional and post-transcriptional mechanisms.
We thank Sandra Caine for excellent secretarial skills and express our appreciation to Dr. R. G. Deeley for critical comments.