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Molecular and Cellular Biology, April 2000, p. 2818-2826, Vol. 20, No. 8
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
The DNA Binding Protein BTEB Mediates Acetaldehyde-Induced,
Jun N-Terminal Kinase-Dependent 
I(I) Collagen Gene
Expression in Rat Hepatic Stellate Cells
Anping
Chen and
Bernard H.
Davis*
Gastroenterology Section, Department of
Medicine, University of Chicago Medical Center, Chicago, Illinois
60637
Received 1 November 1999/Returned for modification 22 December
1999/Accepted 24 January 2000
 |
ABSTRACT |
Alcohol-induced cirrhosis results partially from the excessive
production of collagen matrix proteins, which, predominantly 
I(I)
collagen, are produced and secreted by activated hepatic stellate cells
(HSC). The accumulation of I(I) collagen in HSC during
cirrhosis is largely due to an increase in I(I) collagen gene
expression. Acetaldehyde, the major active metabolite of alcohol, is
known to stimulate I(I) collagen production in HSC. However, the
mechanisms responsible for it remain unknown. The aim of this study was
to elucidate the mechanisms by which I(I) collagen gene expression
is induced by acetaldehyde in rat HSC. In the present study, the
acetaldehyde response element was located in a distal GC box,
previously described as the UV response element, in the promoter
of the I(I) collagen gene (
1484 to 1476). The GC box was
predominantly bound by the DNA binding transcription factor BTEB (basic
transcription element binding protein), expression of which was
acetaldehyde and UV inducible. Blocking BTEB protein expression
significantly reduced the steady-state levels of the acetaldehyde-induced I(I) collagen mRNA, suggesting that BTEB is
required for this gene expression. Further studies found that acetaldehyde activated Jun N-terminal kinase (JNK) 1 and 2 and activator protein 1 (AP-1) transactivating activity. Inhibition of JNK
activation resulted in the reduction of the acetaldehyde-induced BTEB
protein abundance and I(I) collagen mRNA levels, indicating that the
expression of both genes is JNK dependent in HSC. Taken together, these
studies demonstrate that BTEB mediates acetaldehyde-induced, JNK-dependent I(I) collagen gene expression in HSC.
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INTRODUCTION |
The sinusoidal hepatic stellate
cells (HSC) are the major effectors during hepatic fibrogenesis and
cirrhosis. During the early stages of hepatic injury associated with
cirrhosis, the normally quiescent, vitamin A-storing HSC transform
into actively proliferating, collagen-producing myofibroblast-like
cells (34). Alcohol is one of the principal causes of
cirrhosis. While the major clinical problem of alcohol-induced hepatic
fibrogenesis has been the subject of numerous studies, the precise
molecular mechanism(s) which leads to the increase in I(I) collagen
in HSC remains incompletely understood (2, 6, 24, 26, 35, 36). It was demonstrated that acetaldehyde, but not ethanol, induced the increase in the I(I) collagen gene expression (up to
2.5-fold) measured by Northern blots in cultured 3T3 fibroblasts (2). Further studies indicated that acetaldehyde increased the I(I) collagen gene transcription in cultured HSC demonstrated by
transcription run-on assays (4). These previous observations clearly indicated that acetaldehyde induced the I(I) collagen gene
expression by transcription. However, their results did not exclude the
possibility of other mechanisms being involved, such as
posttranscriptional regulation. Stefanovic et al. identified a novel
RNA-protein interaction targeted to the C-rich sequence in the I(I)
collagen mRNA untranslated region (UTR), which might play an
important role in increasing I(I) collagen mRNA stability in
activated HSC (32). This result suggested that the increase in the I(I) collagen gene expression in activated HSC may involve both transcriptional and posttranscriptional mechanisms. As
acetaldehyde is the major initial and active metabolite of alcohol,
most studies have used it in lieu of alcohol (2, 6, 24, 26, 35, 36). It has been recognized that acetaldehyde is at least
partially responsible for causing the increase in I(I) collagen gene
expression in alcohol-induced fibrogenesis (2, 6, 24, 26, 35, 36). Acetaldehyde is associated with the production of acetate, adduct formation, lipid peroxidation, and changes in the redox state of
cells, all of which may play contributory roles in the development of
hepatic fibrogenesis by an as yet incompletely understood mechanism
(2, 6, 24, 26, 35, 36).
Eukaryotic cells respond to and integrate the extracellular stimuli
through specific signal transduction pathways. Three of them are
simplified as follows: (i) Raf
MEK1,2extracellular signal regulated kinase 1 and 2 (ERK1,2); (ii) MEKK1SEK1c-Jun
N-terminal kinase 1 and 2 (JNK1,2)/SAPK; (iii) MEKK1SEK1p38
(34). In each of the cascades, an upstream kinase
phosphorylates and activates an immediate downstream
substrate kinase. Extracellular signals are, thereby, transduced
through the cytoplasmic cascades to their nuclear target genes and
regulate their expression in cells. JNK was identified as a kinase that
bound and phosphorylated the proto-oncogene c-Jun on Ser-63 and Ser-73
within its NH2-terminal activation domain (13).
The transcription factor activator protein 1 (AP-1) consists of either
Jun-Jun homodimers or Fos-Jun heterodimeric complexes. AP-1 binds to
the palindromic TPA-response element (TRE) sequence
TGA(C/G)TCA in the promoter regions of many genes, including
c-jun, and regulates gene expression (37). AP-1
DNA binding and transcriptional activities are generally correlated with an increase in the abundance of the AP-1 complex as well as with
changes in the phosphorylation of the c-Jun protein (28, 31). AP-1 has been described as a major modulator of cell growth, differentiation, and apoptosis (12, 17, 28). It was found that acetaldehyde increased the steady state levels of c-fos
and c-jun mRNA transcripts in HSC (5). In
addition, inhibitors of protein kinase (PKC) activity blocked the
stimulatory effects of acetaldehyde on the increases in fos
and jun mRNA, as well as on the induction of I(I)
collagen gene expression in HSC (5).
We have previously reported that serum, via ERK and JNK pathways,
stimulated and up-regulated I(I) collagen gene expression in
cultured HSC through different regions of the 5'-upstream promoter sequence (UPS) of the gene (7, 8, 11). While the
ERK-stimulatory signal was mapped to the most proximal NF-1 and SP-1
binding domains of the 5' UPS of the gene, a distal GC box (1484 to
1476) in the 5' UPS of the gene played a central role in receiving
extracellular signals through the JNK pathway (8). A recent
study also reported that fibronectin and inflammatory cytokines, such
as interleukin 1 (IL-1) and tumor necrosis factor alpha
(TNF-), activated JNK, ERK, and AP-1 in rat HSC (29).
4-Hydroxy-2,3-nonenal (HNE), an aldehydic product of lipid
peroxidation, was found to interact directly with JNK in human HSC
(27). Our recent studies also demonstrated that JNK and AP-1
activation were required for the UV-induced increase in I(I)
collagen gene expression in HSC (8). The UV response element
was located in the distal GC box of the 5' promoter of the I(I)
collagen gene, and the GC box was bound by a DNA binding protein,
termed BTEB (basic transcription element binding protein)
(8).
The present studies were designed to localize the acetaldehyde response
element in the 5' UPS of the I(I) collagen gene and to elucidate the
mechanisms by which acetaldehyde induces I(I) collagen gene
expression in rat HSC.
In the present report, the acetaldehyde response element was located in
the distal GC box (1484 to 1476) in the 5' UPS of the I(I)
collagen gene. The same region was previously described as the UV
response element (8). The GC box binding protein BTEB was
acetaldehyde inducible. Blocking BTEB protein production resulted
in a significant reduction in acetaldehyde-induced I(I) collagen
gene expression. Additional experiments indicated that acetaldehyde
activated JNK1,2 and that the acetaldehyde-induced I(I)
collagen gene transcription was JNK dependent. Inhibition of JNK by
curcumin, a JNK inhibitor at low doses, significantly reduced the
acetaldehyde-induced BTEB protein abundance as well as the
steady-state levels of endogenous I(I) collagen mRNA in HSC. Taken together, activation of JNK by acetaldehyde results in the
expression of BTEB and I(I) collagen genes in HSC. These results
indicate that the GC box binding protein BTEB mediates the
acetaldehyde-induced I(I) collagen gene expression in HSC via a
JNK-dependent pathway. Our results suggest a complex model wherein JNK
and AP-1 activations induced by acetaldehyde are intimately linked to stimulate the production of the recently described
transcription factor BTEB. BTEB plays an as yet unappreciated
role in coordinating the HSC response to extracellular stimulations and
bringing about an increase in I(I) collagen gene expression.
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MATERIALS AND METHODS |
Stellate cell isolation and culture.
HSC were isolated from
male Sprague-Dawley rats as previously described (7, 8, 11).
Cells were used for culture in tissue culture flasks precoated with
type I collagen and maintained in Dulbecco's modified Eagle medium
(DMEM) supplemented with 10% fetal bovine serum and 10% newborn calf
serum (10/10 medium). Experiments were carried out with cells between
passages 2 and 6. In most experiments, cells were serum starved for
48 h in DMEM with 0.4% fetal bovine serum (0.4% medium) before
incubation in 0.4% medium with or without acetaldehyde (100 µM) for
an additional 36 h. Acetaldehyde was replenished every 12 h
in cultured cells in sealed flasks to minimize the effects of
evaporation. The acetaldehyde concentration (100 µM) used in this
study is in the lower range compared to prior acetaldehyde studies (150 to 200 µM) in HSC (2, 6, 24, 26, 35, 36). We considered
that the lower dose of acetaldehyde in cell culture should be closer to
the pathophysiological concentration found in the in vivo setting
(39) if the dose could induce enough stimulation and effects
for detection. In some experiments, curcumin (15 µM), a JNK inhibitor
at low doses from Sigma, in the 0.4% medium was added to cells
3 h before the addition of acetaldehyde. Chemical inhibitors
of acetaldehyde dehydrogenase were not used because previous
experiments showed that they induced some degree of cytotoxicity (data
not shown).
Suppression of BTEB expression.
BTEB translation was blocked
by use of antisense oligonucleotides (38). In general, 60 to
80% confluent serum-starved HSC were incubated in DMEM with 0.4%
serum and with the indicated concentrations of antisense or sense BTEB
oligonucleotides for 3 h before the addition of acetaldehyde (100 µM). The medium was replaced next day with fresh DMEM containing
acetaldehyde and antisense or sense BTEB oligonucleotides. The total
treatment lasted for 48 h. The sequence coding for the first 7 amino acids (21 nucleotides) of BTEB cDNA was used as sense or
antisense BTEB oligonucleotides (16).
Phosphorothionate-modified oligonucleotides were synthesized by Life
Technologies (Grand Island, N.Y.).
The sequence of the antisense BTEB oligonucleotide was 5'-ATG TCC GCG
GCC GCC TAC ATG-3', and that of the sense BTEB oligonucleotide was
5'-CAT GTA GGC GGC CGC GGA CAT-3'.
The optimal concentration of antisense BTEB oligonucleotides to block
BTEB translation was determined by Western blotting
using a polyclonal
anti-BTEB serum produced by Research Genetics
(Huntsville, Ala.).
Transfection and CAT assay.
Sixty- to eighty-percent
confluent HSC were transfected using the Lipofectamine reagent (Life
Technologies). Cell extraction, quantitation, and a chloramphenicol
acetyltransferase (CAT) assay were performed as previously described
(8). Transfection efficiency was determined by
cotransfection of a 
-galactosidase reporter, pSV- gal (Promega).
The level of -galactosidase activity was measured by a
chemiluminescence assay kit (Tropix, Bedford, Mass.) according to the
manufacturer's instructions.
Plasmid construction.
The dominant-negative JNK expression
plasmid (dn-JNK) was a gift from R. J. Davis (University of
Massachusetts). The dominant-negative Jun expression plasmid (dn-Jun)
was kindly provided by John Kokondis (University of Chicago). To make
dn-Jun, the cDNA fragment coding for the N-terminal portion of Jun,
including the phosphorylation sites Ser-63 and Ser-73, was deleted. The
AP-1 reporter plasmid, 3x-TRE-CAT, contains three AP-1 binding sites
(TRE) upstream of a CAT reporter gene, and the empty control plasmid,
pBL-CAT, has no AP-1 binding sites. Both plasmids were kindly provided
by E. Fuchs (University of Chicago). The colCAT reporter plasmid
p1.7/1.6 contains 1.7 kb of the 5' promoter region of the rat I(I)
collagen gene, 1.6 kb of the first exon, and part of the first intron
linked to a CAT reporter plasmid vector. Plasmid p1.7(GC box mut.)/1.6 was derived from plasmid p1.7/1.6 by overlap extension of site-directed mutagenesis (8). The site (1494 to 1468) was mutated
from 5'-GGTTTGGAGGAGGCGGGACTCCTTGC-3'
to 5'-GGTTTGGAGGAAATAAGACTCCTTGC-3'. The GC box of interest is underlined. Plasmid p1.7/1.6 (del.
516-786) was created by digestion of p1.7/1.6 with BstB1 and
Afl2. After the digestion, the DNA fragment generated was
blunted by mung bean nuclease and ligated by T4 DNA ligase
(both from NEB BioLab, Beverly, Mass.). The deleted DNA fragment from
+516 to +786 contains a putative AP-1 binding motif
(5'-TGATTCAT-3') at positions +557 to +564.
EMSA.
Nuclear protein extracts were prepared and
electrophoretic mobility shift assays (EMSA) were performed as
previously described (8). Briefly, 5 µg of nuclear
proteins was incubated for 20 min at room temperature (RT) with 0.1 ng
of [32P]-labeled double-stranded GC-box oligonucleotides
(5'-TTGGAGGCGGGACTCCTTG-3') from 1489 to 1470 of the 5'
UPS of the rat I(I) collagen gene, synthesized by GIBCO, Life
Technologies (Grand Island, N.Y.). Oligonucleotide-protein complexes
were separated by electrophoresis on a 6% nondenaturing polyacrylamide
gel in 0.5× Tris-borate-EDTA (TBE) buffer. In competition assays, up
to a 50-fold excess of unlabeled GC-box oligonucleotides were
preincubated with nuclear proteins for 10 min at RT before addition of
the [32P]-labeled double-stranded GC-box
oligonucleotides. Supershift assays began with incubation of nuclear
extracts with the radiolabeled oligonucleotides. Then 2 µl of
anti-BTEB serum or normal rabbit serum (NRS) was added to the mixture
and incubated for an additional 20 min at RT. The integrity of the
extracts was tested in a gel shift assay with a
[32P]-labeled SP-1 consensus probe
(5'-ATTCGATCGGGGCGGGGCGAGC-3'), resulting in distinct SP-1
shifts from all extracts (data not shown).
RNA isolation and RPA.
Total RNAs were isolated by the
TRI-Reagent (Sigma) following the protocol provided by the
manufacturer. The first exon (1 to 206) of the rat I(I) collagen
gene was subcloned in pGEM-3Zf(+) (Promega) (8). The
T7 promoter in the plasmid was used to generate a
single-stranded antisense RNA probe. The template for rat cyclophilin was obtained from Ambion and yields a 103-bp protected fragment. The
antisense RNA probes were synthesized and labeled by in vitro Transcription Kits MAXIscript (Ambion). The synthesized probes were gel
purified. RNase protection assays (RPA) were carried out with RPA II
(Ambion) following the protocol provided by the manufacturer. The dried
gels were exposed to a phosphorimaging system (Phosphor Image SI;
Molecular Dynamics, Sunnyvale, Calif.). The radioactivities in each
band were measured by computer-aided densitometry of the phosphorimage
using IPLab Gel (Signal Analytics Corp.) as described previously
(8). Cyclophilin was used as an internal control to
normalize the loading of RNA in each sample.
Western blot analysis.
Using standard techniques, sodium
dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) with a
10% resolving gel was used to separate nuclear proteins (20 µg/lane). The separated proteins were electroblotted and detected by
using either the anti-ACTIVE JNK polyclonal antibody (pAb) (Promega),
an anti-total JNK antibody (Santa Cruz Biotechnology, Inc., Santa Cruz,
Calif.), or a polyclonal anti-BTEB antibody produced by Research
Genetics and horseradish peroxidase-conjugated goat anti-rabbit
immunoglobulin G (IgG; Santa Cruz Biotechnology). Protein bands were
visualized by utilizing a chemiluminescence reagent (Kirkegaard & Perry
Laboratories, Gaithersburg, Md.). The anti-ACTIVE JNK pAb
preferentially recognizes the dual phosphorylated active forms of
JNK1,2.
| |
RESULTS AND DISCUSSION |
The distal GC box is the acetaldehyde response element.
To
localize the acetaldehyde response element in the 5' promoter region of
the rat I(I) collagen gene, rat HSC were transfected with a collagen
CAT reporter plasmid (p1.7/1.6) as a surrogate of the I(I) collagen
gene and treated with or without acetaldehyde (Fig.
1). Plasmid p1.7/1.6 contains 1.7 kb of
the 5' UPS of the I(I) collagen gene and 1.6 kb of the intact first
exon and part of the first intron. It was found that acetaldehyde
caused an increase of approximately threefold in CAT activity in cells
transfected with plasmid p1.7/1.6 (Fig. 1). The 1.7-kb promoter region
contains numerous potential response elements, such as transforming
growth factor activation element (TAE), NF-1, SP-1, and a distal GC box (7, 8, 11). In order to locate the major acetaldehyde response element, several plasmids with site-directed mutagenesis in
the promoter region or a DNA fragment deletion in the first intron were
generated. It was found that plasmids containing site-directed mutations within sites of TAE, NF-1, or SP-1 did not change the acetaldehyde stimulatory patterns in transfected HSC (data not shown),
which suggested that these sites were not required for acetaldehyde
stimulation of I(I) collagen gene transcription. Since previous
study demonstrated that acetaldehyde increased the steady state levels
of c-fos and c-jun mRNA transcripts in HSC
(5), it is important to determine whether AP-1 is directly involved in acetaldehyde-induced I(I) collagen gene transcription. Plasmid p1.7/1.6(del. 516-786) contains a full-length 5' promoter region of 1.7 kb and a DNA fragment deletion from +516 to +786 in the
first intron. The deleted DNA fragment contains a putative AP-1 binding
motif at the site of +557 to +564. Transfections with this plasmid
showed a similar stimulation by acetaldehyde (Fig. 1). This observation
suggested that the putative AP-1 binding motif might not be required in
the acetaldehyde induction of I(I) collagen gene transcription in
rat HSC. The AP-1 motif present in the first intron of the I(I)
collagen gene has been suggested to promote stimulatory activity in
human and avian fibroblasts (1, 23). However, the role of
the first intron in I(I) collagen gene transcription has been
somewhat controversial. When Houglum et al. examined the response to
CCl4 stimulation in transgenic animals, they found that
much of the first intron, including the putative AP-1 binding motif,
was not required for the induction of the I(I) collagen transgene
(14). Our previous study had also found that the AP-1
binding motif in the first intron was not required for the UV-induced
I(I) collagen gene transcription in cultured HSC (8). Our
experiments have previously located the UV response element in the
distal GC box in the 5' promoter region of the I(I) collagen gene.
Plasmid p1.7 (GC box mut)/1.6 is a mutant containing a site-directed
mutagenized distal GC box in the 5' promoter region of the gene. HSC
transfected with this plasmid completely lost the stimulatory response
to acetaldehyde (Fig. 1). This result indicated that the GC box in the
5' promoter region of the I(I) collagen gene was the acetaldehyde
response element, which is required for the acetaldehyde induction of
the I(I) collagen gene transcription in rat HSC.
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FIG. 1.
The distal GC box is required for acetaldehyde-induced
I(I) collagen gene transcription. Serum-starved HSC were transfected
with 2 µg of one of the collagen CAT reporter plasmids [wild-type
plasmid p1.7/1.6, p1.7/1.6(del. 516-786), which contains a deletion of
a fragment containing a putative AP-1 binding motif in the first
intron, or p1.7 (GC box mut.)/1.6, which contains a site-directed
mutation in the distal GC box] as detailed in Materials and Methods.
After transfection and recovery, cells were left untreated or treated
with acetaldehyde for an additional 36 hr. CAT assays were performed as
described in Materials and Methods. The transfection efficiency was
normalized by -galactosidase activity as described in Materials and
Methods. Values presented here reflect the means ± standard
deviations (n = 6). *, P < 0.05
compared with the control (No Acetal.).
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Acetaldehyde induces BTEB protein production and DNA binding
activity.
Further studies were focused on the protein which binds
to the GC box in the 5' UPS of the I(I) collagen gene. Our previous study had demonstrated that BTEB bound to the distal GC box in the
I(I) collagen gene promoter in HSC (8). Protein extracts from serum-starved HSC treated with acetaldehyde were analyzed for the
32-kDa BTEB protein expression by Western blotting using a polyclonal
anti-BTEB serum (Fig. 2A). It was
found that acetaldehyde induced BTEB protein production in
serum-starved HSC (Fig. 2A, lanes 1 to 5). BTEB was also found to be UV
inducible (Fig. 2A, lanes 6 and 7). The presence of the faint BTEB band
prior to the exposure to either acetaldehyde or UV irradiation is not
surprising because HSC were culture activated before serum starvation.
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FIG. 2.
Acetaldehyde induces BTEB protein abundance and enhances
BTEB DNA binding activity. Sixty-eight-percent confluent HSC were
preincubated in DMEM with 0.4% serum for 48 h before the
acetaldehyde treatment (100 µM) for the indicated times (hours).
Nuclear protein extracts were prepared as described in Materials and
Methods. A whole-cell extract from HSC treated with UV irradiation (10 J/m2) as previously described (8) was used to
study whether BTEB is UV inducible. (A) Twenty micrograms of nuclear
extract proteins or 30 µg of whole-cell extracts of each sample were
analyzed by Western blotting using a polyclonal anti-BTEB serum. A
representative Western blot assay is shown here (repeated three times
with similar results). (B) Ten micrograms of nuclear extract proteins
from HSC exposed to acetaldehyde for the indicated times were analyzed
by EMSA. [32P]-labeled double-stranded oligonucleotides
containing a GC box identical to the sequence in the 5' promoter of the
I(I) collagen gene were used as a probe (see Materials and Methods).
The lower arrow indicates the oligonucleotide-BTEB complex. Ten- to
50-fold excesses of the unlabeled double-stranded oligonucleotides were
used in the competition assays. Two microliters of the anti-BTEB serum
(-BTEB) or NRS was used in the supershift assays. Incubation with
the anti-BTEB serum caused a supershift band, as indicated by the upper
arrow, and a significant reduction in the oligo-BTEB complex band. A
representative gel is shown here.
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EMSA was used to study BTEB DNA binding activity in HSC after the
acetaldehyde treatment with indicated time courses (Fig.
2B). EMSA was
performed with a probe of [
32P]-labeled double-stranded
oligonucleotides which was identical
to the distal GC box sequence in
the 5' UPS of the
I(I) collagen
gene. After exposure of HSC to
acetaldehyde for 8 h, a prominent
gel shift band appeared,
indicated by the lower arrow on the right
(Fig.
2B, lanes 2 to 4).
Excess unlabeled oligonucleotides abolished
the shift band (Fig.
2B,
lanes 5 and 6), indicating that the binding
protein of the shift band
was GC-box specific. Incubation with
the polyclonal anti-BTEB serum
generated a supershift band, indicated
by the upper arrow on the right,
and significantly reduced the
abundance of the lower shift band (Fig.
2B, lane 8). In contrast,
an equal amount of preimmune NRS had no
effect on the GC-box gel
shift band (Fig.
2B, lane 7). Taken
together, these results demonstrated
that BTEB protein production
and BTEB GC-box binding activity
were acetaldehyde inducible in
HSC.
It has been known that a GC-box DNA motif in a gene promoter region
could be bound by several different DNA binding proteins,
such as SP-1
and BTEB (
16,
21). A very recent study described
another
novel GC-box binding protein, Zf9, which is increased
during HSC
activation (
30). We have previously shown that the
BTEB
mobility shift completely differed from that of SP-1, which
clearly
indicated that SP-1 did not bind to the distal GC box
in the 5' UPS of
the
I(I) collagen gene (
8). The molecular
weight of Zf9
was 42 kDa, while that of BTEB was 32 kDa (
16,
21,
30). The
amino acid sequence of Zf9 is considerably different
from that of BTEB
(
16,
21,
30). Our results do not suggest
the direct binding
of Zf9 to this GC box in the rat
I(I) collagen
gene. We, however,
cannot exclude a possible contribution of the
novel GC box binding
protein Zf9 in acetaldehyde-induced
I(I)
collagen gene expression in
HSC. The study by Imataka et al. suggested
that flanking nucleotides,
copy numbers, and the position of a
GC box sequence in the promoter
region of a gene, might play key
roles in determining which protein
would bind to the GC-box and
its effects on gene transcription
(
16). Our observations suggest
that BTEB is likely to be an
unappreciated important protein binding
to the distal GC box in the 5'
UPS of the
I(I) collagen gene
and, in turn, regulating the gene
expression in HSC (see
below).
BTEB mediates acetaldehyde-induced I(I) collagen gene
expression.
Antisense c-jun oligonucleotides have been
successfully used to specifically block c-Jun protein translation in
order to study the role of AP-1 activation in cell differentiation
(9, 38). Antisense BTEB oligonucleotides were used to block
BTEB protein production to determine the role of BTEB in the
acetaldehyde-induced I(I) collagen gene expression in HSC (Fig.
3). To determine the optimal
concentration of antisense BTEB oligonucleotides to block BTEB protein
translation, HSC were treated with acetaldehyde plus various
concentrations of either antisense or sense c-jun
oligonucleotides as a control. Western blots indicated that BTEB
protein abundance was markedly reduced by antisense BTEB
oligonucleotides at 50 µg/ml (Fig. 3A). As expected, the same
concentration of sense BTEB oligonucleotides had no effect on BTEB
protein abundance (Fig. 3A). Compared to serum-starved control HSC,
which were not exposed to any treatments, antisense BTEB
oligonucleotides at 50 µg/ml blocked most of the acetaldehyde-induced
BTEB protein production (data not shown). The effectiveness of the BTEB
antisense oligonucleotides at 50 µg/ml in blocking
acetaldehyde-induced I(I) collagen gene expression was confirmed in
HSC transfected with the I(I) collagen reporter P1.7/1.6 (Fig. 3B).
It was found that BTEB antisense oligonucleotides at this dose
abolished the acetaldehyde-induced increase in CAT activities in HSC
transfected with the I(I) collagen reporter plasmid P1.7/1.6. The
role of BTEB in acetaldehyde-induced I(I) collagen gene expression
was studied by RPA (Fig. 3C). The total RNA was obtained from
serum-starved HSC treated with acetaldehyde plus antisense or sense
BTEB oligonucleotides at 50 µg/ml. The result of this experiment
demonstrated that the steady-state levels of endogenous I(I)
collagen mRNA were significantly reduced by anti-BTEB
oligonucleotides (~77%) (Fig. 3C and D). In contrast, sense BTEB
oligonucleotides at the same concentration had no detectable effect on
the steady-state levels of endogenous I(I) collagen mRNA (Fig.
3C and D). Since antisense BTEB oligonucleotides at 50 µg/ml did not
completely block BTEB protein production, it is not surprising that the
antisense BTEB oligonucleotides could not completely abolish the
acetaldehyde-induced increase in I(I) collagen mRNA (Fig. 3C and
D). Taken together, these studies demonstrated that BTEB, as a
regulator, mediated the acetaldehyde-induced I(I) collagen gene
transcription in HSC.
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FIG. 3.
Inhibition of BTEB by antisense BTEB
oligonucleotides significantly reduces acetaldehyde-induced I(I)
collagen mRNA levels. Serum-starved HSC were treated with or
without acetaldehyde (100 µM) plus sense or antisense BTEB
oligonucleotides at the indicated concentrations for 48 h. The
medium was replaced once with fresh DMEM containing acetaldehyde and
antisense or sense BTEB oligonucleotides. (A) To determine the optimal
concentration of antisense BTEB oligonucleotides, whole-cell protein
extracts (30 µg) were analyzed by Western blotting using a polyclonal
anti-BTEB serum. (B) Compared to the BTEB sense oligonucleotides, the
effectiveness of the BTEB antisense oligonucleotides at 50 µg/ml in
blocking acetaldehyde-induced I(I) collagen gene expression was
confirmed in HSC transfected with the I(I) collagen reporter
P1.7/1.6 by CAT assays. Values presented here reflect the means ± standard deviations (n = 6). (C) A representative
I(I) collagen RPA gel is shown. Ten micrograms of total RNA from HSC
treated with or without acetaldehyde (100 µM) plus sense or antisense
BTEB oligonucleotides at 50 µg/ml were used. Upper arrow, I(I)
collagen mRNA; lower arrow, cyclophilin mRNA, as a control. (D)
Quantitation of I(I) collagen mRNA in an RPA (Fig. 3B) by
computer-aided phosphorimaging densitometry. Loading variation was
normalized by cyclophilin mRNA. Representative gels are shown.
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Acetaldehyde activates JNK and AP-1 in HSC.
Additional studies
were focused on signal transduction pathways to determine how the
acetaldehyde signal was transduced to stimulate the activation of the
I(I) collagen gene promoter in HSC. It has been shown that
fibronectin and inflammatory cytokines, such as TNF- and IL-1,
activated JNK and AP-1 in rat HSC (29). HNE, an aldehydic
product of lipid peroxidation, was found to interact directly with JNK
in human HSC (27). We have recently observed that exposure
of HSC to UV irradiation induced JNK activation and AP-1 gene
transactivity as well as an increase in I(I) collagen gene
expression (8). The UV response element, as well as the acetaldehyde response element, were located in the same distal GC box
in the 5' promoter of the I(I) collagen gene (8). It was,
therefore, decided to determine whether acetaldehyde activated JNK in
rat HSC. Whole-cell extracts were prepared from serum-starved HSC
treated with acetaldehyde for Western blot analyses utilizing an
anti-ACTIVE JNK antibody, which preferentially recognizes the dual
phosphorylated active forms of JNK1,2 (Fig.
4). This study clearly indicated that
acetaldehyde rapidly activated JNK1,2 within 15 min and reached its
peak within 3 h (Fig. 4).
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FIG. 4.
Acetaldehyde induces rapid JNK activation.
Whole-cell extracts were prepared from serum-starved HSC exposed to
acetaldehyde (100 µM) for the indicated times. A whole-cell extract
from HSC treated with UV irradiation (10 J/m2) was used as
a positive control for active forms of JNK as previously described
(8). Twenty micrograms of proteins of each sample was used
for Western blot analysis. Active forms of JNK were probed with a
polyclonal antibody specific to the dual phosphorylated and
activated JNK1 and JNK2 (Promega), as indicated by the
arrows on the right of the gel. A representative gel is shown here.
|
|
JNK is a major kinase for c-Jun/AP-1 activation. AP-1 activation is
generally correlated with changes in the phosphorylation
of c-Jun
protein (
28,
31). AP-1 consists of either Jun-Jun
homodimers
or Fos-Jun heterodimeric complexes, which bind to TRE
sites found in
the promoter regions of many genes and regulate
the expression of these
genes (
18-20). To study the role of acetaldehyde
in the
induction of AP-1 gene transcriptional activity, HSC were
transfected
with either an AP-1 reporter plasmid, 3x-TRE-CAT,
which has three AP-1
binding sites (TRE) linked to a CAT reporter
gene, or with a control
empty plasmid, pBL-CAT, which has no AP-1
binding site upstream of the
CAT gene (Fig.
5). This study
demonstrated
that acetaldehyde significantly increased CAT activities
in cells
transfected with 3x-TRE-CAT and that there was no stimulation,
as expected, in HSC transfected with the empty vector pBL-CAT.
This
result suggested that acetaldehyde induced AP-1 activation
in HSC. To
explore the role of JNK in AP-1 activation induced
by acetaldehyde, HSC
were cotransfected with 3x-TRE-CAT and either
a dominant-negative JNK
expression plasmid (dn-JNK) or an empty
plasmid, pMNC (Fig.
5). The
results indicated that CAT activities
induced by acetaldehyde in cells
transfected with 3x-TRE-CAT was
completely blocked by cotransfected
dn-JNK plasmid, suggesting
that the activation of JNK was required for
the AP-1 activation
induced by acetaldehyde (Fig.
5). Taken together,
these studies
demonstrate that acetaldehyde activates JNK and AP-1 in
HSC. These
results are in basic agreement with previous findings that
acetaldehyde
increased the steady-state levels of c-
fos and
c-
jun mRNA transcripts
in HSC (
5). It is
known that activated AP-1 could bind to the
TRE in the promoter of the
c-
jun gene, which would result in the
up-regulation of the
c-
jun gene expression (
18-20).
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|
FIG. 5.
Acetaldehyde induces AP-1 activation via a JNK-dependent
pathway. Sixty- to eighty-percent confluent HSC were transfected with
either an AP-1 reporter plasmid, 3x-TRE-CAT, or an empty control
plasmid, pBL-CAT. The AP-1 reporter plasmid 3x-TRE-CAT contains three
AP-1 binding sites upstream of a CAT reporter gene. In cotransfection
experiments, HSC were cotransfected with 3x-TRE-CAT and a
dominant-negative JNK expression plasmid (dn-JNK) or an empty control
plasmid, pMNC. After recovery, the transfected cells were treated with
or without acetaldehyde (100 µM) for an additional 36 h in DMEM
containing 0.4% fetal bovine serum. Transfection efficiency was
normalized by measurement of -galactosidase activity (see Materials
and Methods). Values are expressed as means ± standard deviations
(n = 6). *, P < 0.05 compared with
the control (No Acetal).
|
|
Acetaldehyde stimulates I(I) collagen gene promoter activation
via a JNK-dependent pathway.
Previous studies have found that
acetaldehyde increased I(I) collagen accumulation in activated HSC
(2, 6, 24, 26, 35, 36). Our previous studies discovered that
UV irradiation activated JNK and AP-1 gene transactivity and stimulated
I(I) collagen gene expression in HSC via a JNK-dependent pathway
(8). Since the intact distal GC box is required for UV as
well as acetaldehyde stimulation of I(I) collagen gene expression in
HSC, it was hypothesized that acetaldehyde may be JNK dependent in
stimulating I(I) collagen gene expression in HSC. To explore this
hypothesis, HSC were cotransfected with plasmid p1.7/1.6 and dn-JNK or
dn-Jun and then treated with acetaldehyde (Fig.
6). It was found that dn-JNK or dn-Jun
completely blocked the acetaldehyde-induced increase in CAT activities
in cells transfected with p1.7/1.6. In contrast, the control plasmid pMNC had no effect (Fig. 6). These studies demonstrate that
acetaldehyde induces I(I) collagen gene promoter activation in HSC
by a JNK- and c-Jun-dependent mechanism.
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FIG. 6.
Acetaldehyde induces I(I) collagen gene promoter
activation by a JNK-dependent mechanism. Serum-starved HSC were
cotransfected with the wild-type collagen CAT reporter plasmid p1.7/1.6
and either a dominant-negative JNK expression plasmid (dn-JNK), a
dominant-negative c-Jun expression plasmid (dn-Jun), or an empty
control plasmid, pMNC. After transfection and recovery, cells were
treated with or without acetaldehyde for an additional 36 h as
described for Fig. 1 and in Materials and Methods. Cotransfected
-galactosidase activity was used for normalization of
transfection efficiency (n ± 6). *,
P < 0.05 compared with the control (No Acetal.).
|
|
JNK activation is required for the endogenous I(I) collagen gene
expression induced by acetaldehyde.
To further evaluate the
effects of acetaldehyde-induced JNK activation on endogenous BTEB
production and endogenous I(I) collagen gene expression in HSC, JNK
activation was specifically inhibited by curcumin. Curcumin, a dietary
pigment responsible for the yellow color of curry, was reported to be a
JNK inhibitor at a low dose in many cell lines (10, 15, 22,
33). Determination of the optimal concentration of curcumin in
HSC by Western blot analyses found that curcumin at 10 to 20 µM
inhibited JNK activation but not ERK activation (data not shown). To
confirm that curcumin at this dose blocks JNK activation, further trial
experiments were conducted in UV-irradiated HSC transfected with
an AP-1 reporter plasmid. The results demonstrated that curcumin at 15 µM completely blocked UV-induced AP-1 activation in HSC (data not
shown). These observations confirmed the previous observations in
other cell lines (11, 15, 22, 33). Our further studies
demonstrated that acetaldehyde specifically induced an increase in the
phosphorylated JNK (the active forms of JNK), and that there is no
significant change in the total JNK proteins detected by an antibody to
JNK1,2 (Fig. 7A). Furthermore, curcumin
at 15 µM inhibited JNK activation and subsequently reduced BTEB
protein abundance induced by acetaldehyde in HSC (Fig. 7A). As
expected, curcumin at 15 µM had no effect on the protein abundance of
total JNK1,2. Without acetaldehyde or any other treatments, curcumin at
15 µM did not change the basic level of BTEB protein abundance in HSC
(data not shown). Additional studies found that acetaldehyde increased
the steady-state levels of I(I) collagen mRNA (>2.8-fold) and
that inhibition of JNK activation by curcumin at 15 µM resulted in a
significant reduction in the endogenous steady state levels of I(I)
collagen mRNA (>85%) (Fig. 7B and C). However, curcumin itself at
15 µM had no effect on the endogenous steady-state levels of I(I)
collagen mRNA in HSC without any other treatments (data not shown).
These studies provided direct evidence that JNK activation is required for acetaldehyde-induced I(I) collagen gene expression in HSC. In
addition, these studies also support our previous observations in this
report that BTEB mediates acetaldehyde-induced JNK activation and
acetaldehyde-induced I(I) collagen gene expression in HSC. Furthermore, this result also explains why the BTEB antisense oligonucleotides had no detectable effects on the basal CAT activities in the transfected HSC incubated in DMEM with 0.4% serum without acetaldehyde treatment (Fig. 3B). The explanation is that because BTEB
protein production requires JNK activation (Fig. 7A) and there is a
negligible amount of JNK activator in DMEM with 0.4% serum, the
BTEB antisense oligonucleotides cannot play any role in
blocking the basal expression of the I(I) collagen gene. It was
found that basal expression of the gene requires only the 220 bp in the
5' promoter region of the I(I) collagen gene, which does not contain
the BTEB-binding GC box (3, 25). A future project is to
dissect the promoter of the BTEB gene and study the effects of
overexpression of the BTEB gene in HSC on I(I) collagen gene
expression in the absence of acetaldehyde. The results of these studies
will contribute to our understanding of the significance of
acetaldehyde-induced JNK/AP-1 activation and BTEB production in
mediating acetaldehyde stimulation and the increase in I(I) collagen
gene expression in HSC.
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FIG. 7.
Inhibition of JNK by curcumin reduced BTEB protein
abundance and decreased the endogenous I(I) collagen mRNA
levels. Serum-starved HSC were pretreated with (Acetal.+ curcumin) or
without (Acetal.) curcumin at 15 µM for 3 h before being treated
with acetaldehyde for 24 h. Cells treated with 0.2% ethyl alcohol
(EtOH) only were used as a control (No Acetal.), as curcumin was
dissolved in EtOH. Each treatment was performed in triplicate. (A)
Nuclear proteins (20 µg/sample) were used for Western blot analyses
and detected by anti-ACTIVE JNK pAb, a polyclonal antibody specific to
the dual phosphorylated and activated JNK1,2, by anti-BTEB, or by
anti-JNK1,2 total proteins as a control for the normalization of
loading. (B) Total RNA from the cells (10 µg/lane) was analyzed for
the endogenous I(I) collagen mRNA by RPA. Cyclophilin was used
as an internal control to normalize the loading of the total RNA in
each lane. (C) The radioactivity in each band in panel B was quantified
and normalized by computer-aided phosphorimaging densitometry.
Representative gels are shown.
|
|
The increase in
I(I) collagen production in activated HSC results
from stimulation by extracellular stimuli during hepatic
injury. It is,
therefore, of interest to identify the involved
signal transduction
pathways and to determine the required components
in the induction of
I(I) collagen gene expression in HSC. Previous
studies have
demonstrated that the ERK and JNK cascades were involved
in the
induction of
I(I) collagen gene expression during the
activation of
HSC (
5-7). It was discovered in the present study
that
acetaldehyde-induced
I(I) collagen gene expression occurs
via a
JNK-dependent pathway. The acetaldehyde response element
was located in
the distal GC box (
1484 to
1476) in the 5' UPS
of the
I(I)
collagen gene. The GC box, also previously described
as the UV
response element, was exclusively required for the induction
by
acetaldehyde of
I(I) collagen gene promoter activation in
HSC.
In addition, the GC box was bound predominantly by the DNA
binding
protein, BTEB, which was acetaldehyde inducible as well.
BTEB was
required for acetaldehyde-induced
I(I) collagen gene
expression in
HSC. Taken together, these results support the contention
that
acetaldehyde induces BTEB expression, which then binds to
the GC box in
the 5' UPS of
I(I) collagen gene and up-regulates
the gene
expression in HSC during alcohol-induced hepatic fibrogenesis.
At this
time, it remains unclear how acetaldehyde-induced JNK
and AP-1
activations are involved in regulating BTEB and
I(I)
collagen gene
expression in HSC. It was not suggested from our
results that the
putative AP-1 binding motif in the first intron
of the gene was a
cis-acting factor and was required for the
acetaldehyde
stimulation in HSC. There is little information available
concerning
BTEB gene regulation and expression. At least two potential
AP-1
binding sites could be found in the 5' promoter region of the
BTEB
gene (
16).
Based on the present and prior observations, a model is proposed to
explain how acetaldehyde induces
I(I) collagen gene expression
in
HSC (Fig.
8). In this model, treatment of
HSC with acetaldehyde
rapidly activates JNK1,2, which, in turn,
phosphorylates c-Jun
and enhances AP-1 transactivating ability. The
activated AP-1
subsequently binds to the potential AP-1 binding sites
in the
promoter of the BTEB gene and stimulates BTEB gene expression.
The acetaldehyde-induced BTEB, in turn, binds to the distal GC
box in
the 5' UPS of the
I(I) collagen gene and stimulates the
expression
of this gene in HSC.
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|
FIG. 8.
Schema of acetaldehyde-induced I(I) collagen gene
expression in HSC. Exposure of HSC to acetaldehyde rapidly activates
JNK1,2, though it remains unclear how JNKs are activated. Activated
JNKs phosphorylate and activate c-Jun/AP-1, which, in turn,
up-regulates BTEB gene expression by binding to the putative AP-1
binding sites in the promoter of BTEB gene. The acetaldehyde-induced
BTEB acts as a mediator, binding to the distal GC box in the promoter
and stimulating I(I) collagen gene expression in HSC.
|
|
In summary, the present studies demonstrated that a
cis-acting acetaldehyde response element was located in the
distal GC
box in the 5' UPS of the
I(I) collagen gene. The GC box
was bound
by the DNA binding transcription factor BTEB, whose abundance
and DNA binding activity were acetaldehyde inducible in HSC. Inhibition
of BTEB protein expression by antisense BTEB oligonucleotides
indicated
the requirement of this protein in the acetaldehyde
induction of
I(I) collagen gene expression. Further experiments
found that
acetaldehyde stimulated
I(I) collagen gene expression
via a JNK- and
AP-1-dependent pathway. This study identified a
previously
unappreciated link between the ubiquitous JNK, AP-1,
BTEB, and the GC
box. The relationship among them suggested in
this report may not be
unique to the
I(I) collagen gene but may
involve other genes as
well. These studies have practical importance
for the understanding of
the mechanisms of alcohol-induced cirrhosis
because acetaldehyde is the
chief metabolite of ethanol with major
pathobiological significance
during hepatic
fibrogenesis.
| |
ACKNOWLEDGMENTS |
We thank J. J. Vande Vusse for technical assistance and D. Rowe, D. Breault, and R. Davis for plasmids used in transfection.
This work was supported by National Institute of Health grants DK
02022, DK40223, DK 42086, DK 07074-18, and DK 47995-01A2 and by the
Liver Research Fund, University of Chicago.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Gastroenterology
Section, Department of Medicine, University of Chicago Medical Center, MC 4076, 5841 S. Maryland Ave., Chicago, IL 60637. Phone: (773) 702-1467. Fax: (773) 834-1288. E-mail:
bhdavis{at}medicine.bsd.uchicago.edu.
| |
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Molecular and Cellular Biology, April 2000, p. 2818-2826, Vol. 20, No. 8
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
