(Received for publication, May 29, 1996, and in revised form, November 5, 1996)
From the Laboratory for Molecular Oncology, Center for Human Genetics, University of Leuven and the Flanders Interuniversity Institute for Biotechnology, Herestraat 49, B-3000 Leuven, Belgium
The proximal promoter region of the
neuroendocrine-specific human prohormone convertase 1 (PC1)
gene contains two distinct cAMP response elements (CRE-1 and CRE-2).
Both elements are essential in directing the cAMP-mediated hormonal
regulation of PC1 gene transcription. In this study, we
have demonstrated that CRE-1 binds several trans-acting
factors. In electrophoretic mobility shift assay experiments with
nuclear extracts prepared from neuroendocrine AtT-20 and -TC3 cells
and non-neuroendocrine COS-1 cells, three specific protein-DNA
complexes (I-III) were detected. Complexes II and III were shown to
contain CREB-1 and ATF-1, respectively. The most slowly migrating
complex I was only detected with the neuroendocrine cell lines and
appeared to comprise a c-Jun-containing heterodimer. In addition, CRE-2
was shown to bind a protein that was only detected in nuclear extracts
derived from the neuroendocrine cell lines. Antibody supershift
experiments indicated that both the c-Jun-interacting protein in CRE-1
complex I and the CRE-2-interacting protein are distinct from known
members of the basic domain, leucine zipper family of transcription
factors. UV cross-linking experiments demonstrated that these potential
novel proteins are ~100 and 60 kDa in size, respectively.
Site-specific mutagenesis experiments demonstrated that the formation
of both CRE-1 and CRE-2 complexes is correlated with the
transcriptional activity of the proximal PC1 promoter as
has been shown in transient transfections with wild-type and mutant
promoter constructs. In addition, it was shown that both CREB-1 and
ATF-1 transactivate the human PC1 promoter in transient
transfection experiments.
A variety of regulatory peptides and proteins are generated from inactive precursors by endoproteolytic processing. This endoproteolytic cleavage, generally at sites consisting of paired basic amino acid residues, is a common post-translational modification of membrane and secretory proteins on the exocytotic transport route. Such proteins include precursors of peptide hormones, neuropeptides, growth factors, coagulation factors, serum albumin, cell-surface receptors, adhesion molecules, and viral glycoproteins. All these proteins play important roles in a large variety of different biological processes, and their function depends on proteolytic cleavage of their respective precursor molecules (for reviews, see Refs. 1 and 2). In mammals, seven prohormone- and proprotein-processing enzymes, responsible for this cleavage, have been molecularly characterized.
The mammalian prototype of this enzyme family is furin (3, 4), which is involved in the cleavage of precursor molecules within the constitutive secretory pathway. The structure and expression of the FUR gene, encoding furin, have been analyzed in detail (5). It has been shown that the FUR gene is expressed in a wide variety of tissues and cell lines. Recently, we have shown that FUR gene transcription is regulated by multiple promoter regions (6). In addition to furin, the very recently cloned member of the prohormone convertase (PC)1 enzyme family, LPC (7), described as PC7 in Ref. 8, also exhibits rather a ubiquitous expression pattern and is capable of processing substrates within the constitutive secretory pathway.
In contrast to this, PC1 (9, 10), also described as PC3 (11), and PC2 (9, 12) are neuroendocrine-specific (13) and have been shown to be involved in the tissue-specific processing of prohormones and neuropeptide precursors, e.g. proglucagon, proinsulin, prosomatostatin, proenkephalin, and pro-opiomelanocortin, within the regulated secretory pathway (14-20). In addition, it has been demonstrated that the cell type-specific processing of the multifunctional precursor protein pro-opiomelanocortin by PC1 and PC2 is down-regulated in antisense transfection experiments in pituitary corticotroph-derived AtT-20 cells (21).
Very recently, a novel plurihormonal syndrome, comprising impaired glucose tolerance, early-onset obesity, hypogonadism, and hypoadrenalism, was found to be caused by a primary defect in prohormone processing. The complete failure of processing of a normal proinsulin molecule and a defect in pro-opiomelanocortin processing at the PC1 cleavage sites strongly suggested aberrant PC1 activity (22).
In previous experiments, we have cloned and sequenced the genomic DNA
encompassing the 5-flanking region of the human PC1 gene,
identified the transcription start sites, and localized transcriptional
control elements (23). It was shown that neuroendocrine-specific human
PC1 gene expression and its hormonal regulation are directed by the proximal promoter region. Several positive regulatory elements were identified within 224 bp of the proximal promoter region. This was
found using AtT-20 cells and
-TC3 pancreatic insulinoma cells
transfected with fusion genes containing the 5
-flanking region of the
human PC1 gene linked to luciferase as reporter. Two
structurally related cis-acting DNA elements located at
283 bp (CRE-1) and
263 bp (CRE-2) were found to specifically
mediate cAMP-regulated expression of human PC1 promoter
activity. CRE-1 matches the palindromic consensus CRE (TGACGTCA (24)),
whereas CRE-2 is different (TGACGTGT).
A number of nuclear proteins specifically bind to the CRE and CRE-like
sequences (25), and these are all members of the bZIP superfamily of
transcription factors. They are characterized by the presence of a
basic domain required for DNA binding and an adjacent leucine zipper
domain, which facilitates dimerization between family members (26). To
identify the trans-acting factors involved in the
hormone-mediated, transcriptional regulation of the human
PC1 gene, we analyzed the nuclear proteins interacting with
the CRE-1 and CRE-2 motifs of the proximal PC1 promoter. Our
findings demonstrate that in addition to ATF-1 and CREB-1, a novel
c-Jun-containing heterodimer binds to the CRE-1 site. Both ATF-1 and
CREB-1 were shown to enhance PC1 promoter activity in
transient transfection experiments. In addition, CRE-2 was found to
specifically interact with a novel protein present in nuclear extracts
derived from the neuroendocrine cell lines AtT-20 and -TC3. No
binding of CRE-2 was observed using nuclear extracts from the control
non-neuroendocrine COS-1 cells.
AtT-20
pituitary corticotroph cells (ATCC CRL1795), -TC3 insulinoma cells
(27), COS-1 kidney fibroblasts (ATCC CRL1650), and F9 teratocarcinoma
cells (ATCC CRL1720) were cultured according to the suppliers'
protocols. The wild-type and mutant CRE-1- and CRE-2-containing
PC1 promoter-luciferase reporter constructs have been
described previously (23). An expression vector encoding the catalytic
subunit of protein kinase A was kindly provided by Dr. R. A. Maurer.
Expression vectors for ATF-1, CREB-1, and c-Jun were kindly provided by
Drs. W. Schmid, G. Schütz, and B. Burgering, respectively. DNAs
were purified using anion-exchange chromatography (Nucleobond AX,
Machery Nagel, Durnen, Germany). Unless otherwise indicated, cells were
propagated in the prescribed media supplemented with 10% fetal calf
serum. Cells were transfected using cationic liposomes (Lipofectamine,
Life Technologies, Inc.) according to the manufacturer's protocol. For
each experiment, luciferase activity was determined in duplicate wells.
The results are expressed as the mean of three individual transfection
experiments. Cells were harvested at 24 h after the start of
transfection, and luciferase reporter enzyme activity driven by the
various human PC1 promoter fragments was determined with the
luciferase assay system (Promega) using a Monolight 2010 luminometer
(Analytical Luminescence Laboratory).
Nuclear
extracts were prepared according to Schreiber et al. (28).
Protein concentrations in nuclear extracts were 5-10 mg/ml, as
determined by the BCA protein assay (Pierce). Complementary oligonucleotides corresponding to the human PC1 gene
5-flanking DNA sequence
293 to
267 bp, relative to the translation
start site (CRE-1,
5
-CAGGTAGATC
AGAGATGGC-3
), and sequence
265 to
239 bp (CRE-2,
5
-TTCGTCGATT
AAACACTCA-3
) were obtained
from Pharmacia Biotech Inc. A double-stranded oligonucleotide containing a prototypic AP-1 site (underlined;
5
-CGCTTGA
GCCGGAA-3
) was obtained from Promega.
Double-stranded oligonucleotides were radiolabeled using
[
-32P]ATP (6000 Ci/mmol; DuPont NEN) and T4
polynucleotide kinase (Boehringer Mannheim). In mutant oligonucleotides
CRE-1mut and CRE-2mut, the central AC
dinucleotide core (boldface) was converted into TG. Gel shift assays
were performed as follows. Prior to the addition of radiolabeled DNA
probes, nuclear proteins (10 µg) were incubated for 10 min in
reaction buffer containing 20 mM Hepes (pH 7.9), 50 mM KCl, 6.25 mM MgCl2, 0.5 mM EDTA, 10% glycerol, 0.5 mM dithiothreitol,
20 µg/ml each poly(dI-dC) and poly(dI/C) as nonspecific competitors,
and a 0.2 mM concentration of the protease inhibitor
phenylmethylsulfonyl fluoride. Subsequently, radiolabeled DNA probes
were added, and incubation was continued for 20 min. For competition
and antibody supershift experiments, binding mixtures were incubated
with unlabeled double-stranded oligonucleotides or monospecific
antibodies for 10 min prior to the addition of the radiolabeled
oligonucleotides. All monospecific antibodies were obtained from Santa
Cruz Biotechnology (Santa Cruz, CA). Protein-DNA complexes were
analyzed on 4% nondenaturing polyacrylamide gels at 4 °C in
0.5 × Tris borate/EDTA and visualized by autoradiography.
Probes for UV cross-linking were prepared
according to a published protocol (29). Briefly, the above-mentioned
CRE-1 and CRE-2 oligonucleotides were labeled with
[-32P]dCTP (DuPont NEN) on the antisense strand by
primer extension reaction using Klenow enzyme (Boehringer Mannheim).
The reaction was carried out in the presence of bromodeoxy-UTP
(Sigma). This bromodeoxyuridine substitution had no
effect on the gel shift patterns (data not shown). AtT-20 nuclear
extracts were incubated with the bromodeoxyuridine-substituted CRE-1
and CRE-2 probes in standard EMSA reaction mixtures and analyzed on
EMSA gels as described above. Subsequently, the gel was exposed to UV
light for 15 min at 4 °C in a UV Stratalinker 1800 (Stratagene), and the various cross-linked protein-DNA complexes were visualized by
autoradiography of the wet gel for 2 h at 4 °C. Gel slices containing the cross-linked complexes were excised from the gel, boiled
in SDS sample buffer, resolved on a 10% SDS-polyacrylamide gel, and
visualized by autoradiography. Colored Rainbow Markers (Amersham Corp.)
were used as protein molecular mass markers.
Previous studies in our laboratory (23) have
demonstrated the presence of two functional CREs located within the
proximal promoter region of the human PC1 gene. These
elements, CRE-1 (TGACGTCA) and CRE-2 (TGACGTGT), have both been
demonstrated to mediate the hormonal regulation of PC1 gene
expression. Using site-specific mutagenesis, it was demonstrated that
both CREs differentially contributed to the cAMP-mediated regulation of
transcription. Although the palindromic consensus CRE-1 was
demonstrated to be the most important element, site-specific
mutagenesis of the CRE-2 sequence also clearly down-regulated the cAMP
inducibility of PC1 gene transcription. In addition, cell
type-specific effects were observed in neuroendocrine AtT-20 and
-TC3 cells versus non-neuroendocrine COS-1 cells.
To identify the trans-acting factors involved in the
hormonal regulation of human PC1 gene transcription, we
performed EMSA experiments with both CRE-1- and CRE-2-containing
probes. As shown in Fig. 1 (lanes 1 and
4), in EMSAs using the CRE-1 probe, nuclear extracts derived
from the neuroendocrine cell lines AtT-20 and -TC3, respectively,
gave rise to three retarded protein-DNA complexes (complexes I-III),
whereas nuclear extracts prepared from the non-neuroendocrine COS-1
cells gave rise to only two complexes (Fig. 1, lane 2).
These COS-1 complexes exhibited the same mobility as complexes II and
III detected with the AtT-20 and
-TC3 nuclear extracts. Of interest
is the difference in relative abundance of complex I versus
complexes II and III when the AtT-20 extracts are compared with the
-TC3 extracts. In
-TC3 cells, the more slowly migrating complex I
was the most abundant one, whereas in AtT-20 cells, complex I was as
abundant as complexes II and III. As can be seen in Fig. 1 (lane
5), the CRE-2 probe gave rise to the formation of only a single
retarded complex. Moreover, the mobilities of the CRE-1 complexes are
clearly different from the mobility of the complex observed when the
CRE-2 motif is used as a probe. Characterization of the CRE-2 complex
is presented below.
To determine whether all three EMSA complexes observed with the
PC1 CRE-1 sequence represent specific interactions of
nuclear proteins with this probe, we tested several competitor
oligonucleotides. As can be seen in Fig. 2A,
in AtT-20 and COS-1 cells, the addition of increasing molar
concentrations of unlabeled wild-type CRE-1 competes for formation of
the retarded complexes. Moreover, no difference in competition profile
are observed when complexes I-III are compared. We next investigated
whether CRE-2 was capable to cross-compete for binding of nuclear
proteins to the CRE-1 probe. As depicted in Fig. 2B, using
AtT-20 nuclear extract, no effect on the formation of complexes I-III
is observed when CRE-2 is included as specific competitor. Only with a
high, 1000-fold molar excess (Fig. 2B, lane 5)
was partial competition observed. However, this is nonspecific since a
similar effect is seen on the aspecific complexes. To determine whether
the observed effects of the site-directed mutagenesis on PC1
gene expression (23) could be correlated with the pattern of CRE-1
binding activities, we tested double-stranded oligonucleotides carrying
the same CRE-1 mutations in competition experiments. It was found that
the CRE-1mut oligonucleotide, in which the central AC
dinucleotide is mutated into a TG pair, was not able to compete for
binding of nuclear proteins to CRE-1 using AtT-20 nuclear extracts
(Fig. 2C, lanes 1-3). This was also observed
using COS-1 nuclear extracts (Fig. 2C, lanes
4-6). This is in agreement with our findings that when CRE-1mut was used as a labeled probe in EMSAs with these
nuclear extracts, no retarded complexes were observed (data not shown). The results from these experiments fit well with the observed drastic
drop in cAMP inducibility of PC1 promoter activity when the
sequence of the PC1 CRE-1 site is converted into
CRE-1mut (23). Altogether, the results of the CRE-1 EMSAs
underscore the specificity of complexes I-III and suggest that the
proteins present in these complexes could represent
trans-acting factors conferring cAMP-mediated regulation of
PC1 promoter activity.
Identification of the PC1 CRE-1 Complexes in EMSA Antibody Supershift Experiments
cAMP has been shown to be involved in the
transcriptional regulation, through cAMP-dependent protein
kinase A, of a wide array of genes with diverse functions and patterns
of expression. Studies on the regulatory regions of such genes have
revealed a conserved motif, called the CRE. There exists an extensive
family of proteins that are able to interact with consensus CRE and
related sequences (reviewed in Refs. 25, 30, and 31). The members of
this transcription factor superfamily all contain leucine zipper
dimerization domains and have significant sequence similarity within
both their basic DNA-binding and leucine zipper domains (bZIP). To more
completely characterize the proteins that bind to the PC1
CRE-1 element, we performed antibody supershift experiments. Since
several homo- and heterodimers of the bZIP superfamily are capable of
interacting with palindromic CREs, we tested antibodies specific to the
individual members of the bZIP superfamily: ATF-1, ATF-2 (also
described as CREB-2, CRE-BP2, and ATF-4), ATF-3, CREB-1, CREM
(AMP
esponse
lement
odulator; all isoforms), C/EBP (all isoforms), AP-1
(c-Jun), and Fos (all isoforms). All antibodies tested were reported
not to interfere with DNA binding of their respective target protein, and therefore, all produced supershifts in control experiments. As has
been shown above (Fig. 1) in EMSAs with nuclear extracts of AtT-20,
-TC3, and COS-1 cells, two equally migrating, retarded complexes
(complexes II and III) were detected with the PC1 CRE-1 probe. To investigate the nature of these complexes in more detail, supershift experiments were performed with the COS-1 nuclear extract. This was done since complex I, which might interfere with the visibility of supershifted complexes, is absent in this cell line. As
shown in Fig. 3A, the results of the antibody
supershift experiments clearly indicate that the more slowly migrating
complex II is supershifted by the addition of anti-CREB-1 antibody
(lane 3), whereas complex III is supershifted by the
addition of anti-ATF-1 antibody (lane 2). No abrogation of
complex formation or supershifts were observed with all other
antibodies tested. These results led us to conclude that PC1
CRE-1 complexes II and III contain CREB-1 and ATF-1 homodimers,
respectively. Both transcription factors have been shown to activate
transcription in response to cAMP/protein kinase A-mediated mechanisms.
The results of experiments investigating whether ATF-1 and CREB-1 are
involved in the regulation of PC1 gene expression are
presented below.
To investigate the nature of PC1 CRE-1 complex I in more
detail, antibody supershift experiments were performed with the AtT-20 and -TC3 nuclear extracts. As can be seen in Fig. 3B, the
addition of the c-Jun antibody gives rise to a supershift of complex I in AtT-20 (lane 2) and
-TC3 (lane 5) nuclear
extracts and does not interfere with the formation of complexes II and
III. Therefore, complex I seems to contain c-Jun, a member of the bZIP
transcription factor superfamily. It has been demonstrated that c-Jun
can form heterodimers with members of the bZIP family and subsequently bind to CRE sequences (26). However, heterodimerization is highly selective due to the leucine zipper structure of each factor. Since all
other antibodies tested did not interfere with the formation of complex
I, this complex does not seem to represent either the well described
c-Jun/Fos (AP-1) heterodimer or a c-Jun/ATF-2 heterodimer. Both
heterodimers have been shown to interact with palindromic CREs (26,
32). Another option would be that complex I represents the binding of
c-Jun homodimers to the CRE-1 motif. However, in the presence of c-Fos,
Jun/Fos heterodimers are preferred. Moreover, the binding of c-Jun
homodimers to palindromic CREs is of lower affinity and therefore does
not seem to reflect the in vivo situation. In an additional
EMSA, we tested a probe containing a consensus AP-1-binding sequence
(TGAGTCA). As can be seen in Fig. 3C, the addition of the
AP-1 probe resulted in strong complex formation with proteins present
in the AtT-20 and COS-1 nuclear extracts. The observed retarded complex
migrates clearly differently from CRE-1 complex I. When the anti-c-Jun
or anti-Fos antibodies were included (Fig. 3C, lanes
6 and 8), supershifts were observed. This indicates
that both the c-Jun and Fos bZIP transcription factors are present in
these nuclear extracts and therefore do not underlie the differential
complex I formation as observed with the CRE-1 probe. In conclusion,
the results from the complex I antibody supershifts led us to
hypothesize that complex I is composed of c-Jun, which binds to the
PC1 CRE-1 site through heterodimerization with a novel, yet
unidentified partner protein present in AtT-20 and
-TC3 cells, but
not in COS-1 cells.
To obtain additional information on the presumed partner protein present in the heterodimeric c-Jun-containing PC1 CRE-1 complex I, we performed UV cross-linking experiments. The results are presented below.
EMSA Complexes with CRE-2 of the Human PC1 PromoterIn
previous studies (23), we have demonstrated that the CRE-2 motif
mediates activation of the human PC1 promoter in response to
cAMP-mediated signal transduction. To identify the
trans-acting factor(s) involved, we have performed EMSAs
with the CRE-2 probe and nuclear extracts from the neuroendocrine
AtT-20 and -TC3 cells and the non-neuroendocrine COS-1 cells. As can
be seen in Fig. 4A, CRE-2 complex formation
was only detected in AtT-20 and
-TC3 cells (lanes 3 and
4), but not in COS-1 cells (lane 5). The absence
of complex formation in COS-1 cells is not due to the quality of
nuclear extracts since reference AP-1 probe (Fig. 3C,
lane 4) and the CRE-1 probe (Fig. 4A, lane
1) clearly produced retarded protein-DNA complexes. As has also
been shown above (Fig. 1), the mobility of the CRE-2 complex is clearly
different from the mobilities of CRE-1 complexes I-III and is therefore
likely to represent binding of nuclear protein(s) different from the ones identified in complexes I-III with the CRE-1 probe. To assess the
specificity of CRE-2 complex formation, competition experiments were
performed. As can be deduced from Fig. 4B (lanes
1-3), binding to the CRE-2 probe was efficiently competed for
when unlabeled CRE-2 was added to the binding reaction. However,
unlabeled CRE-2mut did not compete for binding of nuclear
proteins to the wild-type CRE-2 probe (Fig. 4B, lanes
4-6). This is in agreement with our observation that labeled
CRE-2mut did not bind nuclear proteins in EMSAs (data not
shown). In a previous report (23), we have shown that in addition to
CRE-1 mutagenesis, the conversion of the CRE-2 sequence into
CRE-2mut clearly affects the cAMP-mediated transcriptional
induction of the proximal PC1 promoter. This indicates that,
in addition to the CRE-1-bound proteins, the CRE-2-interacting protein
is also involved in regulating PC1 promoter activity in response to cAMP-mediated signal transduction.
It has been demonstrated in Fig. 2C that CRE-2 did not
compete for binding of nuclear proteins to the labeled CRE-1 probe. In
the reciprocal experiment, we tested whether the addition of excess
unlabeled CRE-1 competitor could prevent CRE-2 complex formation. The
results, as depicted in Fig. 4C, clearly indicate that CRE-1
did not compete for binding of nuclear factors to the labeled CRE-2
probe. This strongly suggests that the CRE-2-bound protein is distinct
from the CRE-1-interacting transcription factors. Subsequently, we
performed antibody supershift experiments with the same set of
monospecific antibodies used in the CRE-1 EMSAs. In these immunoshift
experiments, we did not observe any effect of the addition of the
antibodies on CRE-2/protein complex formation with nuclear extracts
derived from both AtT-20 and -TC3 cells (data not shown). In
conclusion, although we were not able to identify the CRE-2-bound
protein(s), the EMSA results strongly suggest that the interacting
protein is distinct from known members of the bZIP superfamily of
transcription factors.
Information on the molecular mass of the PC1 CRE-1- and PC1 CRE-2-binding proteins was obtained by UV cross-linking experiments. In these experiments, AtT-20 nuclear extracts were incubated with CRE-1 or CRE-2 probes in standard EMSA reaction mixtures and size-fractionated on EMSA gels as described above. Subsequently, the gel was exposed to UV light, and the various cross-linked protein-DNA complexes were visualized by autoradiography of the wet gel. Gel slices containing cross-linked CRE-1 complexes I-III and the CRE-2 complex were excised from the gel, boiled in SDS sample buffer, size-fractionated on a 10% SDS-polyacrylamide gel, and visualized by autoradiography.
As can be seen in Fig. 5 (lane 1),
cross-linking of the nuclear proteins present in CRE-1 complex I to
radiolabeled CRE-1 results in two protein-DNA complexes of ~50 and
110 kDa. Because the protein-DNA samples were boiled and the molecular
mass of the single-stranded oligonucleotides was ~9 kDa, it can be
deduced that the proteins present in CRE-1 complex I are ~40 and 100 kDa in size. The detection of a protein of ~40 kDa is in agreement with our previous observation in antibody supershifts that c-Jun (39 kDa) is present in this complex. Therefore, the novel heterodimerized partner of c-Jun as present in PC1 CRE-1 complex I is now
determined to be ~100 kDa in size. In a similar way as for CRE-1
complex I, the proteins of CRE-1 complexes II and III, cross-linked to radiolabeled CRE-1, were determined to be 35 and 45 kDa in size (Fig.
5, lane 2). This coincides with the data obtained in the antibody supershift experiments, in which the presence of ATF-1 (36 kDa) and CREB-1 (43 kDa) in these complexes was clearly demonstrated. As can be seen in Fig. 5 (lane 3), the PC1 CRE-2
sequence is bound by a nuclear protein of ~60 kDa. This is, in
addition to the distinct CRE-1 and CRE-2 EMSA patterns (Figs. 1,
3C, and 4A), another difference between the CRE-1
and CRE-2 DNA-binding proteins.
Functional Analysis of the CRE-1-binding Proteins
To investigate the functional significance of ATF-1, CREB-1, and c-Jun in the regulation of PC1 gene expression, we have performed transient transfection experiments in which PC1 promoter-luciferase reporter constructs containing wild-type, mutant CRE-1 (CRE-1mut), or mutant CRE-2 (CRE-2mut) sequences (23) were tested for transcriptional activation by ATF-1, CREB-1, and c-Jun. Functional analysis was performed by introducing expression vectors encoding these factors into F9 teratocarcinoma cells along with the PC1 promoter-luciferase reporter constructs and an expression vector encoding the catalytic subunit of protein kinase A. F9 cells provide a good system to analyze protein kinase A-mediated transcriptional regulation of target promoters because of low levels of endogenous protein kinase A-responsive transcription factors (33, 34, 36).
As shown in Fig. 6A, the PC1
promoter construct containing wild-type CRE-1 and CRE-2 sequences was
activated 3- and 12-fold by ATF-1 and CREB-1, respectively. Activation
was shown to be protein kinase A-dependent since no
significant change in promoter activity was observed when the
cotransfected protein kinase A DNA was replaced by a similar amount of
empty expression vector. This is in agreement with previous reports in
which transcriptional activities of ATF-1 and CREB-1 were investigated
and in which differential activation was observed (34, 36). In
addition, as shown in Fig. 6A, protein kinase A only
modestly stimulated the PC1 promoter, which coincides with
previous observations that F9 cells have low levels of endogenous
protein kinase A-responsive transcription factors (34, 36). In contrast
to the results obtained with F9 cells, introduction of the protein
kinase A expression vector, without cotransfecting ATF-1 or CREB-1, in
AtT-20 and COS-1 cells resulted in a 15-20-fold induction of
PC1 promoter activity (data not shown), which illustrates
the high levels of protein kinase A-responsive, CRE binding activities
in these cell lines. In contrast to the observed activation by ATF-1
and CREB-1, we were not able to detect an effect of c-Jun on
PC1 promoter activity in transient transfections of F9
cells, COS-1 cells, AtT-20 cells, and -TC3 cells.
In additional experiments, PC1 promoter constructs containing CRE-1mut or CRE-2mut sequences were assayed for transactivation by ATF-1 and CREB-1. The results (Fig. 6B) indicate that no activation by ATF-1 or CREB-1 is observed when CRE-1 is mutated. However, no significant difference in activation by ATF-1 and CREB-1 is seen when CRE-2 is mutated. This supports our previous observations (Fig. 3A) that ATF-1 and CREB-1 form part of the CRE-1 binding activities and that the CRE-2 binding activity is distinct from ATF-1/CREB-1 family members. In conclusion, the results from the transfection experiments indicate that ATF-1 and CREB-1 are involved in the regulation of PC1 gene expression. The functional significance of the c-Jun-containing complex, however, remains to be established.
In a previous report (23), we have shown that the proximal promoter region of the human PC1 gene confers both basal and hormone-regulated transcriptional activity. The results of site-specific mutagenesis experiments have demonstrated that two distinct, closely spaced elements (CRE-1 and CRE-2) within the proximal promoter region direct cAMP-mediated hormonal regulation of transcription of the PC1 gene. In our effort to identify the transcription factors involved, we have now focused our attention on the analysis of protein-DNA interactions at the PC1 CRE-1 and CRE-2 regulatory elements.
In this study, we have demonstrated that PC1 CRE-1 is bound
by multiple trans-acting factors. In EMSA experiments with a
CRE-1 probe, nuclear extracts from AtT-20, -TC3, and COS-1 cells
gave rise to the formation of two common protein-DNA complexes
(complexes II and III), which were demonstrated to contain
transcription factors CREB-1 and ATF-1, respectively. In addition, it
was demonstrated that site-specific mutagenesis of the PC1
CRE-1 element disrupted binding of both ATF-1 and CREB-1 to this
regulatory element within the human PC1 promoter. This
coincides with our previous observation (23) that the same mutation
also results in a decreased cAMP-mediated activation of the human
PC1 promoter, which is indicative of the involvement of
ATF-1 and CREB-1 in the regulation of PC1 gene expression.
Additional support for this hypothesis was provided by the results
obtained in transient transfection experiments in which both ATF-1 and
CREB-1 were shown to enhance PC1 promoter activity, although
to a different extent. Moreover, it was shown that CREB-1 was about
four times more potent in the activation of the PC1
promoter. Similar observations with various promoters have been
reported previously (36). This effect is exerted through CRE-1 since
only CRE-1 mutagenesis abolished the transcriptional activation. Since
both ATF-1 and CREB-1 activities have been shown to be differentially
modulated by the protein kinase A- and protein kinase C-mediated
phosphorylation of distinct amino acid residues (33-37), the
interaction of both ATF-1 and CREB-1 with the PC1 CRE-1
sequence provides an integration point of several signal transduction
pathways regulating the transcriptional activity of the human
PC1 gene. Apart from the crucial function of CREB-1 in
modulating the activity of several hormone-regulated
neuroendocrine-specific genes, the involvement of both CREB-1 and ATF-1
has been demonstrated for several other promoters. Recently, both
CREB-1 and ATF-1 have been shown to be involved in the cell
type-specific CRE-mediated regulation of the neural and thyroid T
cell-specific calcitonin gene (38), and both factors also represent the
regulatory DNA binding activities within oxygen tension-regulated
genes, e.g. the erythropoietin (EPO) gene
(39).
In addition to the above-mentioned PC1 CRE-1 complexes II
and III observed with AtT-20, -TC3, and COS-1 nuclear extracts, another protein-DNA interaction was detected, described as the more
slowly migrating complex I. This EMSA complex was only detected in
AtT-20 and
-TC3 nuclear extracts, but not in COS-1 nuclear extracts.
The antibody supershift experiments demonstrated that c-Jun is part of
this protein complex that can recognize PC1 CRE-1. In this
context, it is important to note that c-Jun has been demonstrated to
form heterodimers with specific members of the bZIP superfamily of
transcription factors since heterodimerization is highly selective due
to the leucine zipper structure of each factor (26). Apart from the
well described heterodimerization with c-Fos, resulting in the AP-1
complex, c-Jun has also been detected as a functional heterodimer with
ATF-2 (40). These heterodimers, which are also capable to bind to
palindromic CREs (26, 32), have been described to be essential in
regulating the transcriptional activity of their respective target
genes in response to various extracellular stimuli (41, 42). However,
the results of our antibody supershift experiments indicate that c-Jun
as present in PC1 CRE-1 complex I is bound to the DNA
through interaction with a novel partner protein that is clearly
distinct from the known members of the bZIP family. Additional
information was obtained by UV cross-linking experiments, indicating
that this protein is ~100 kDa in size. In this context, it is
interesting to note that it was recently shown that a palindromic CRE
in the murine prostaglandin synthase-2 (PGS2) promoter is
essential for transcriptional activity. Antibody supershift experiments
demonstrated that, in addition to ATF-1 and CREB-1, c-Jun participates
in a heterodimeric protein-DNA complex at the PGS2 CRE (43).
However, in this study, the partner protein was not further
characterized, although it was shown to be distinct from c-Fos, ATF-2,
and ATF-3. Recently, searches for additional c-Jun-interacting factors
have led to the identification of a 25-kDa protein, Jif-1 (44), which
binds to the bZIP domain of c-Jun, inhibits DNA binding, and reduces
transactivation by c-Jun.
In the case of palindromic CREs, it has been shown that c-Jun mediates
transcriptional activation. Since the c-Jun-containing PC1
CRE-1 complex I was only detected in AtT-20 and -TC3 cells, this may
provide additional means for the regulation of PC1 promoter activity in these cell lines. In transient transfection experiments, however, we were unable to detect an effect of c-Jun on PC1
promoter activity. This may be due to special features of the c-Jun
partner protein, e.g. required modifications, essential for
transcriptional activity, but not provided in the transfection
experiments. It may be essential for this protein to be present in a
similar amount as exogenous c-Jun. Since the nature of the c-Jun
partner protein is still unknown, evaluation of the functional
significance of the c-Jun-containing CRE-1-binding complex requires
additional investigations. However, functional significance is
suggested by our findings that this c-Jun-containing complex is the
predominant protein-DNA complex detected in EMSAs with
-TC3-derived
nuclear extracts. The observed differential abundance of the CRE-1
complexes may very well underlie a potential difference in the
regulation of PC1 promoter activity in response to various
extracellular stimuli. As ATF-1, CREB-1, and c-Jun represent the final
targets of various intracellular signal transduction pathways, they
could act as mediators of pathway cross-talk resulting in the
versatility of the transcriptional response to signal transduction.
We have demonstrated before that CRE-1 mutagenesis only partially
abrogated activation of the PC1 promoter and that
site-directed mutagenesis of CRE-2 also resulted in decreased
PC1 promoter activation. Moreover, only when both CRE-1 and
CRE-2 were mutated was transcriptional activation completely abrogated
(23). Therefore, it is interesting to identify the transcription
factor(s) involved in PC1 promoter activation via CRE-2. In
the present study, we have demonstrated in EMSAs that a nuclear factor
that is specifically present in AtT-20 and -TC3 cells interacts with
CRE-2. The antibody supershifts indicated that this protein is not a
known member of the bZIP transcription factor family and is also not an
immunologically related factor. Since CRE-2 mutagenesis abrogated
complex formation in EMSAs and also decreased transcriptional
activation in transient transfection analysis (23), this suggests that
the CRE-2-bound protein is involved in the regulation of PC1
gene expression. By means of UV cross-linking experiments, we have
determined that the molecular mass of this putative novel
trans-acting factor is ~60 kDa.
A sequence homology search of known cAMP-responsive regions in various
promoters revealed until now only one additional example of a
functional regulatory element homologous to the core sequence of the
PC1 CRE-2 motif. This motif is present in one of the three 21-bp repeats of the HTLV-I long terminal repeat. These three 21-bp
repeats all contain a core TGACGT motif with small variations in
flanking sequences and mediate transcriptional activation. Moreover, it
was shown that the most 5-located CRE (TGACGTCT) and the CRE
(TGACGTGT) within the central repeat are indispensable for
transcriptional activation by the HTLV-I-encoded Tax protein. HTLV-I is
the etiologic agent of adult T cell leukemia and a degenerative neurologic syndrome. Tax is critical for modulating HTLV-I gene expression and is also involved in cellular transformation. Recently, it was demonstrated that this nuclear protein, which does not directly
interact with DNA, activates transcription through interaction with
cellular factors that are able to bind to the HTLV-I long terminal
repeat, including members of the CREB/ATF family (45). In addition, it
was shown that Tax activates transcription of the human
immunodeficiency virus type I long terminal repeat and several cellular
CRE-containing genes including interleukin-2 and proenkephalin (46,
47). Since this transcriptional activation is dependent on the presence
of CREs, Tax may be a potential activator of human PC1
expression.
In summary, our data have shown that multiple factors interact with the CRE motifs within the proximal PC1 promoter. Our observations support a direct involvement of ATF-1 and CREB-1 in the regulation of PC1 gene expression. Gene regulation through CRE motifs is of particular interest since these motifs have been found in the promoter regions of various genes encoding hormones and peptides. Proper functioning of neuroendocrine cells requires the coordinate expression of hormones and their respective processing enzymes.
We thank Dr. Douglas Hanahan for kindly
providing the -TC3 cell line and Marleen Willems for cell
culture.