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J. Biol. Chem., Vol. 275, Issue 29, 22098-22103, July 21, 2000
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From the Hormone and Metabolic Research Unit, Université
catholique de Louvain and Christian de Duve Institute of Cellular
Pathology (ICP), Avenue Hippocrate 75, B-1200 Brussels, Belgium
Received for publication, February 2, 2000, and in revised form, May 4, 2000
Transcription factors of the ONECUT class, whose
prototype is HNF-6, contain a single cut domain and a divergent
homeodomain characterized by a phenylalanine at position 48 and
a methionine at position 50. The cut domain is required for DNA
binding. The homeodomain is required either for DNA binding or for
transcriptional stimulation, depending on the target gene.
Transcriptional stimulation by the homeodomain involves the F48M50
dyad. We investigate here how HNF-6 stimulates transcription. We
identify transcriptionally active domains of HNF-6 that are conserved
among members of the ONECUT class and show that the cut domain of HNF-6
participates to DNA binding and, via a LXXLL motif,
to transcriptional stimulation. We also demonstrate that, on a target
gene to which HNF-6 binds without requirement for the homeodomain,
transcriptional stimulation involves an interaction of HNF-6 with the
coactivator CREB-binding protein (CBP). This interaction depends both
on the LXXLL motif of the cut domain and on the F48M50 dyad
of the homeodomain. On a target gene for which the homeodomain is
required for DNA binding, but not for transcriptional stimulation,
HNF-6 interacts with the coactivator p300/CBP-associated factor
but not with CBP. These data show that a transcription factor can act
via different, sequence-specific, mechanisms that combine distinct
modes of DNA binding with the use of different coactivators.
Cell differentiation and maintenance of the differentiated
phenotype rely on the cell type-specific expression of genes. This expression is tightly controlled by transcription factors that display
a restricted tissue distribution. The study of transcription factors
has identified their protein domains involved in transcriptional activation or repression and in DNA binding and has led to
classification of these factors on the basis of the structure of such
domains. The liver-enriched transcription factors belong to six
families (1). These are the CCAAT/enhancer-binding proteins (2) and the
proline/acid-rich factors (3), which contain a leucine zipper; the
hepatocyte nuclear factor
(HNF)1-1 family of proteins,
which contain a variant homeodomain (4-6); the HNF-3 family, which
contains a forkhead domain (7, 8); the HNF-4 factors (9) and
fetoprotein transcription factor/human B1-binding
factor/CYP7A promoter-binding factor (10-12), which are
steroid receptor-related and have a zinc-finger DNA-binding domain; and
the ONECUT proteins HNF-6 and OC-2 (13-15).
Transfection studies (13, 16-20) have shown that, in the liver, HNF-6
controls transcription of the genes that code for HNF-3 The ONECUT proteins contain a bipartite DNA-binding domain composed of
a single cut domain and a divergent homeodomain. Homeodomains are 60 residues long and are organized into three Based on sequence alignments of their cut domains and of their
homeodomains, the ONECUT proteins, which have been found in mammals and
in Caenorhabditis elegans, appear as a separate class of cut
homeoproteins (14). A further comparison of their amino acid sequence
(15) revealed the presence of conserved regions outside the cut domain
and the homeodomain, namely a serine/threonine/proline-rich region,
which we call the STP box, and a C-terminal serine-rich region. In
addition, the two known mammalian ONECUT proteins, HNF-6 and OC-2,
contain a polyhistidine tract located downstream of the STP box.
How the HNF-6 homeodomain stimulates transcription and how the HNF-6
regions conserved among the ONECUT proteins are involved in
transcriptional control is unknown. We characterize here the function
of the STP box, of the C-terminal serine-rich region and of the
polyhistidine tract of HNF-6. Moreover, we show that HNF-6 recruits
either the coactivator CREB-binding protein (CBP) or
p300/CBP-associated factor (p/CAF), depending on the type of target
sequence bound by HNF-6. The interaction of CBP with HNF-6 involves the
F48M50 dyad of the homeodomain and an LXXLL motif in the cut
domain. Taken together, our data identify two target-specific modes of
action of HNF-6 in transcriptional stimulation.
Plasmid Constructions--
pECE-HNF6 Transfections and Cell Extracts--
Rat hepatoma FTO-2B cells
were grown in Dulbecco's modified Eagle's medium/Ham's F-12 medium
supplemented with 10% fetal calf serum. Cells (1 × 105 cells/well on 24-well plates) were transfected in
medium without fetal calf serum by lipofection using LipofectAMINE-PLUS
(Life Technologies, Inc.), 400 ng of pHNF-6/HNF3 Electrophoretic Mobility Shift Assays (EMSA)--
COS-7 cells
lysates (5 µl) were incubated on ice for 20 min in a final volume of
20 µl containing 10 mM HEPES (pH 7.6), 1 mM
dithiothreitol, 1 mM MgCl2, 0.5 mM
EGTA, 50 mM KCl, 10% (v/v) glycerol, 4 µg of
poly(dI-dC), and the 32P-labeled probe (30,000 cpm). The
samples were loaded on a 7% acrylamide gel (acrylamide/bisacrylamide
ratio was 29:1) in 0.25× TBE buffer and electrophoresed at 200 V. The
double-stranded oligonucleotide probes used in EMSA were as follows
(the HNF-6 binding site is underlined): HNF-3 In Vitro Protein/Protein Interaction Assays--
Full-length
HNF-6 Identification of Domains of HNF-6 That Control
Transcription--
The sequence alignment of the proteins of the
ONECUT class, to which HNF-6 belongs, had revealed the presence of
three conserved regions outside the cut domain and the homeodomain.
These are a 24-residue-long serine/threonine/proline-rich region (STP
box) corresponding to amino acids 99-122 of HNF-6, a polyhistidine tract (amino acids 123-138), and a C-terminal serine-rich region (amino acids 449-465) (15). To identify the role of these domains, we
constructed expression vectors for HNF-6 mutants devoid of these
domains and tested their activity on two different reporter constructs
in transfected rat hepatoma FTO-2B cells. One reporter contains the
luciferase gene under the control of a TATA box and six copies of the
HNF-6 site found in the hnf3
We first verified by EMSA that the various HNF-6 The Cut Domain of HNF-6 Is Bifunctional--
The cut domain of
HNF-6 and of all of the other ONECUT class proteins contains a LSDLL
sequence that matches the LXXLL helical motif. This motif
has been identified as being involved in transcription factor/coactivator interactions (25, 26). We therefore determined whether the LSDLL sequence in the cut domain of HNF-6 plays a role in
transcriptional activation. To do so, we constructed an expression
vector coding for HNF6 CBP Is a Target-specific Coactivator of
HNF-6--
LXXLL motifs are known to interact with CBP.
This protein, which is present in limiting amounts, does not bind DNA
but instead acts as a bridge between transcription factors and
the transcriptional machinery (25, 27-29). To test the hypothesis that
HNF-6 uses CBP as a coactivator, we transfected FTO-2B cells with the
HNF-6
Our earlier experiments (14) had shown that stimulation of the
HNF-3 Target-specific Recruitment of p/CAF by HNF-6--
To investigate
whether a coactivator other than CBP is involved in the stimulation of
the TTR-type reporter by HNF-6, we tested steroid receptor
coactivator-1 (SRC-1/nuclear receptor coactivator-1), receptor-associated coactivator-3 (RAC-3/p300/CBP
cointegrator-associated protein/activator of the thyroid and retinoic
acid receptor/amplified in breast cancer 1/TR activator molecule), and
p/CAF. FTO-2B cells were cotransfected with the HNF-6
To confirm the interaction between p/CAF and HNF-6 The data presented here show that HNF-6 displays two modes of
transcriptional stimulation, which are determined by the way in which
it interacts with DNA, this in turn depending on the sequence of target
DNA. On one type of target, whose prototype is the HNF-6 binding
sequence present in the hnf3 Work by others has provided examples of a single DNA-binding protein
recruiting different transcriptional activators, depending on the
context. However, none of them uses the same discriminatory mechanism
as HNF-6. The T cell factor LEF-1, which contains a high mobility group
DNA-binding domain but lacks an activation domain, needs a partner to
stimulate transcription. This partner is The LSDLL sequence in HNF-6 is required for transcriptional stimulation
of the two types of target sequences studied here. On the HNF-3 In the present work, we demonstrate that the cut domain of HNF-6 is
involved not only in DNA binding but also in transcriptional stimulation. The cut domain occurs in three copies in the homeoproteins of the Cux class, which includes the Drosophila cut protein
and its mammalian homologs (14). To our knowledge, there is no evidence that the cut domain of these proteins has a function(s) other than DNA
binding. One of the three cut domains of the CUX class proteins
contains a VSDLL sequence. Such a sequence in the receptor interacting
protein-140 retains the ability to bind CBP and is therefore compatible
with the LXXLL motif (26). If the CUX class proteins recruit
CBP, it is unlikely that they do so by the same mechanism as HNF-6.
Indeed, we have shown here that recruitment of CBP by HNF-6 involves
not only the cut domain but also the homeodomain and that changing the
F48M50 dyad of HNF-6 to the W48H50 dyad of the CUX class proteins
prevents coactivation by CBP. This may explain the evolutionary
conservation of these critical residues within the ONECUT class.
Interestingly, recruitment of p300, a homolog of CBP, by the
homeoprotein NK-4 has been reported recently (32). In contrast to
HNF-6, which binds the N-terminal moiety of CBP, NK-4 binds the
C-terminal moiety of p300, and this involves mainly the N-terminal
portion (activation domain) of NK-4.
CBP serves as a docking platform for several nuclear proteins that are
end points of transduction cascades triggered by cell surface signaling
(33). Since CBP is present in rate-limiting amounts in cells, its
concomitant recruitment by different transcription factors on the same
gene can promote synergistic stimulation of transcription, whereas
competitive recruitment on different promoters may lead to antagonistic
interactions (34). This may be relevant to the functioning of the
liver-specific transcription factors. Indeed, D-binding protein (35),
HNF-4 (36-38), and HNF-6 (this paper) interact with CBP and are
members of a network of liver-specific transcription factor that is
regulated by extracellular signals such as insulin (39) and growth
hormone (40). Our identification of HNF-6 as a partner of CBP broadens
our understanding of this integrative mechanism. First, this hints at a
possible modulation of HNF-6 activity by extracellular signals. Second,
insofar as HNF-6 is a tissue-restricted transcription factor that
recruits CBP to only a subset of its target genes, our model provides a new mechanism for the tissue-specific and gene-specific transcriptional effects of such signals.
We are grateful to S. Schreek and B. Lüscher for help in initiating the study on HNF-6-CBP
interactions. We thank J. Nyborg for the CBP expression vector; R. Costa for the HNF-3 *
This work was supported by grants from the Belgian State
Program on Interuniversity Poles of Attraction, Prime Minister's Office, Federal Office for Scientific, Technical and Cultural Affairs;
from the Délégation Générale, Higher Education
and Scientific Research of the French Community of Belgium; from the Fund for Scientific Medical Research (Belgium); and from the National Fund for Scientific Research (Belgium).The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
§
Present address: Laboratory of Neurobiology, University of
Zaragoza, 50013 Zaragoza, Spain.
¶
Present address: Developmental Signalling Laboratory, Imperial
Cancer Research Fund, London WC2A 3PX, United Kingdom.
Published, JBC Papers in Press, May 12, 2000, DOI 10.1074/jbc.M000855200
The abbreviations used are:
HNF, hepatocyte
nuclear factor;
TTR, transthyretin;
CBP, CREB-binding protein;
p/CAF, p300/CBP-associated factor;
SRC-1, steroid receptor coactivator-1;
RAC-3, receptor-associated coactivator-3;
EMSA, electrophoretic
mobility shift assay;
STP, serine/threonine/proline-rich;
GST, glutathione S-transferase.
Transcriptional Stimulation by Hepatocyte Nuclear Factor-6
TARGET-SPECIFIC RECRUITMENT OF EITHER CREB-BINDING PROTEIN (CBP)
or p300/CBP-ASSOCIATED FACTOR (p/CAF)*
,
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
and HNF-4,
for plasma transport proteins (transthyretin, 
-fetoprotein), for coagulation factors (protein C), and for enzymes that regulate glucose metabolism (6-phosphofructo-2-kinase) or steroid metabolism (Cyp2C12). A number of other genes expressed in the liver
contain HNF-6 binding sites, but their actual control by HNF-6 has yet to be demonstrated (16). HNF-6 is also a mediator of growth hormone
action (18) and a modulator of glucocorticoid action on the
6-phosphofructo-2-kinase and phosphoenolpyruvate carboxykinase genes in
the liver (20). During embryonic life, HNF-6 is expressed starting at
the onset of pancreas development (19, 21), suggesting that it plays a
role in this process. This has been confirmed by investigations on
hnf6
/ mice (22).
-helices. Within the DNA
recognition helix, amino acid 48 of the homeodomain is part of
the hydrophobic core, and amino acid 50 is essential for sequence-specific DNA binding (23, 24). In the ONECUT proteins, residue
48 is a phenylalanine, not a tryptophan as in all of the other
homeoproteins; residue 50 is a methionine, an amino acid never found at
this position in the other homeodomains. The F48M50 dyad is therefore
characteristic of the homeodomain of ONECUT proteins. Our studies on
the DNA binding properties of HNF-6 (14) showed that the cut domain is
required for binding to all HNF-6 sites, while the homeodomain is
required for binding to only a subset of sites. Mutation of the F48M50
dyad into tryptophan and histidine (W48H50), which converts the
divergent homeodomain into a classical homeodomain, does not affect DNA
binding. However, this mutation reduces the transcriptional stimulation
of those target genes to which HNF-6 binds without requirement for the homeodomain. These observations indicate that the homeodomain of HNF-6
has a dual role; it is involved either in DNA binding or in
transcriptional stimulation, depending on the target gene.
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
and
pECE-HNF6F48W+M50H have been described (13, 14).
pECE-HNF6
Ser codes for amino acids 1-451 of HNF-6 and was
obtained by cloning the EcoNI/XbaI fragment
derived from pSPcut-hd (14) into pECE-HNF6 digested by
EcoNI/XbaI. pECE-HNF6STP (amino acids 1-98
and 123-465 of HNF-6) and pECE-HNF6PH (amino acids 1-122 and
139-465 of HNF-6) were generated by subcloning the
polymerase chain reaction products obtained with the following primers: 5'-CCGGAATTCGCTCATACCTGGGGGAGTTTC-3' (BeSTP),
5'-CCGGAATTCGAACTTGTCGGACACGGTGGAG-3' (BePH),
5'-CCGGAATTCCCTCACCACCATCACCACCAC-3' (AfSTP),
5'-CCGGAATTCCAGCGCCTGGCGGGCAACGTG-3' (AfPH),
5'-CGGAATTCAACGCACAGCTGACCATGGAG-3' (2AAc),
5'-CGGGATCCTCAGTCCAGACTCCTCCTTCTCGC-3' (VLIID). Polymerase chain
reaction-amplified DNA fragments were digested with
SacII/EcoRI or with
Asp718/EcoRI and were cloned in pECE-HNF6
digested with SacII/Asp718. pECE-HNF6STP + FM was generated by deleting a SacII/Asp718
fragment from pECE-HNF6F48W+M50H and replacing it with the
corresponding SacII/Asp718 fragment derived from
pECE-HNF6STP. The site-directed mutant pECE-HNF6L350A was made
using a polymerase chain reaction-based strategy with the following
primer: 5'-TCGCAGCGCGTCCGAAAGGGTCC-3' (HNF6L350A; the mutated codon is underlined). pRc/RSV-CBP.HA contains the mouse CBP
cDNA linked to a hemagglutinin tag (9 amino acids) downstream of a
Rous sarcoma virus promoter. pSP72-HNF6 and pSP72-HNF6F48W+M50H have been described (14). The expression vector pSP72-HNF6L350A contains an Asp718-EcoNI fragment of the
HNF-6L350A cDNA derived from pECE-HNF6L350A. The reporter
constructs pHNF6/HNF3(6×)-TATA-luc and pHNF6/TTR(6×)-TATA-luc code
for firefly luciferase, and pRL-138 codes for Renilla
luciferase (14).
(6×)-TATA-luc or of pHNF-6/TTR(6×)-TATA-luc, 15 ng of the pECE-based vectors indicated or
120 ng of pCMV-based expression vector (pCMV-SRC-1, pCMV-RAC-3, or pCMV-p/CAF, gifts from I. Talianidis) or the indicated
concentration of pRc/RSV-CBP.HA, and 15 ng of pRL-138 as internal
control. After 4 h, the cells were washed with phosphate-buffered
saline and further incubated for 45 h in Dulbecco's modified
Eagle's medium/Ham's F-12 medium plus 10% fetal calf serum before
measuring luciferase activities with the Dual-Luciferase kit and
TD-20/20 Luminometer of Promega. Luciferase activities were expressed
as the ratio of reporter activity (firefly luciferase) to internal
control activity (Renilla luciferase). COS-7 cells (3 × 105 cells/6-cm dish) were transfected in Dulbecco's
modified Eagle's medium without fetal calf serum by lipofection using
N-[1-(2,3-dioleoyloxy)propyl]-N, N,N-triethylammonium methylsulfate (DOTAP; Roche Molecular
Biochemicals) and 5 µg of expression vector. Forty-eight h after
transfection, the cells were washed with phosphate-buffered saline and
harvested in 1 ml of 40 mM Tris-Cl (pH 7.5), 1 mM EDTA, 150 mM NaCl. The cells were pelleted
and resuspended in 60 µl of 50 mM Tris-Cl (pH 7.9), 500 mM KCl, 0.5 mM EDTA, 2.5 µg/ml leupeptin, 1 mM dithiothreitol, 0.1% (v/v) Nonidet-P40, 1 mM phenylmethylsulfonyl fluoride, and 20% (v/v) glycerol.
After three freeze-thaw cycles, the lysates were centrifuged, and the
supernatants were collected.
,
5'-AGCTTAAGGCCCGATATTGATTTTTTTTTCTCC-3' (150 to 118 of
the rat hnf-3 gene promoter); TTR,
5'-GTCTGCTAAGTCAATAATCAGAAT- 3' (110 to 87 of the mouse
transthyretin gene promoter).
and the CBP fragments (1-1098, 1098-1620, 1620-1897, and
1897-2441) were produced in Escherichia coli as GST fusion
proteins by the addition of 0.4 mM
isopropyl--D-thiogalactopyranoside either at 30 °C
for 3 h (HNF-6) or at room temperature overnight (CBP
fragments). The bacteria were lysed with a French press in a solution
containing 50 mM HEPES, 2 mM EDTA, 150 mM NaCl, 1% (v/v) Nonidet P-40, 0.2 mM
phenylmethylsulfonyl fluoride, 1% (w/v) aprotinin, 10 mM
dithiothreitol (pH 7.4) and cleared by centrifugation at 9000 × g for 10 min. Cleared lysates were incubated at 4 °C on a
rocking platform for 2 h with glutathione-Sepharose beads (Amersham Pharmacia Biotech). 14C-Labeled full-length
recombinant HNF-6, HNF-6L350A, HNF-6F48W+M50H, and p/CAF were
synthesized in vitro by using the corresponding pSP72
vectors with the TNT-coupled wheat germ extract (Promega). They were
incubated at 4 °C for 2 h with the immobilized GST fusion proteins in a buffer containing 50 mM HEPES, 150 mM KCl (or 100 mM KCl in Fig. 3C), 1 mM MgCl2, 10% (v/v) glycerol, 1% (v/v) Triton X-100, 0.2 mM phenylmethylsulfonyl fluoride, 1 mM dithiothreitol, and 1% (w/v) aprotinin. After extensive
washing in the same buffer, the beads were boiled, and the eluate was
loaded on a 8% SDS-polyacrylamide gel, which was dried and subjected
to autoradiography. The plasmids used for this assay were pSP72-HNF6
(13), pBS-p/CAF (a gift from T. Kouzarides),
pGST-CBP-(1-1098), pGST-CBP-(1098-1620), pGST-CBP-(1620-1897), and pGST-CBP-(1897-2441) (gifts from I. Talianidis).
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
gene. The other reporter is
identical, except that the HNF-6 sites are derived from the
transthyretin (ttr) gene. These two reporters were chosen because we had found (14) that binding of HNF-6 to the HNF-3-type reporter requires only the cut domain, while binding of HNF-6 to the
TTR-type reporter requires both the cut domain and the homeodomain.
Moreover, the homeodomain is required for transcriptional stimulation
via the HNF-3 site but not via the TTR site (14).
mutants bound at
least as well as wild-type HNF-6 to the HNF-6 binding sites derived
from the ttr and hnf3 genes. This was the case (Fig. 1A). We then tested
their transcriptional activity. As shown in Fig. 1B,
deletion of the C-terminal serine-rich domain (HNF-6Ser) or of
the polyhistidine tract (HNF-6PH) increased slightly the transcriptional activity of HNF-6 on both types of target sequences, suggesting that these regions are inhibitory. In contrast, deletion of
the STP box (HNF-6STP) decreased by about half the activity of
HNF-6 on the two reporter constructs, indicating that this box plays
an important role in the stimulatory activity of HNF-6 on both types of
target sequences. When the deletion of the STP box was combined with
the mutation of the F48M50 dyad in the homeodomain (HNF-6STP + FM), a further decrease in transcriptional activity was observed on the
HNF-3-type reporter, consistent with the role of the F48M50 dyad in
transactivation of this reporter (14). In contrast, HNF-6STP + FM
was not less active than HNF-6STP on the TTR-type reporter, again
consistent with the lack of activation function of the F48M50 dyad on
this reporter (14). Thus, both the STP box and the homeodomain
participate in the stimulatory activity of HNF-6 on the HNF-3-type
reporter. Possible slight differences in the amount of HNF-6 proteins
produced are not responsible for these differences in transcriptional
activation. Indeed, the transfection experiments were performed under
conditions in which the reporter is saturated by HNF-6. These
conditions had been optimized in preliminary experiments in which the
saturating amounts of HNF-6 were determined by transfecting a constant
amount of reporter construct with increasing amounts of HNF-6
expression vectors (data not shown).
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Fig. 1.
Regions of HNF-6 required for transcriptional
control. A and C, extracts from
nontransfected (nt) COS-7 cells or from COS-7 cells
transfected with the expression vectors indicated above the
lanes were used as a source of proteins in EMSA with the
probes indicated below the lanes. B,
schematic representation of HNF-6 and of the HNF-6 mutants used
in the transfection experiments and in EMSA. Numbers refer
to amino acid positions. FTO-2B cells were transiently transfected with
the expression vectors and with the reporter constructs
pHNF6/HNF3(6×)-TATA-luc or pHNF6/TTR(6×)-TATA-luc, as indicated.
The data are expressed as a percentage of activity relative to HNF-6
(means ± S.E., n = 3; *, p < 0.05; **, p < 0.001 versus data for
HNF-6). STP, serine/threonine/proline-rich region;
PH, polyhistidine tract; Cut, cut domain;
Hd, homeodomain; Ser, C-terminal serine-rich
region.
L350A in which the LSDLL sequence has been
mutated into LSDAL (Fig. 1B). This mutation
abolishes the functionality of the LXXLL motif in terms of
interaction with proteins (26). The activity of the L350A mutant on the
TTR- or HNF-3-type reporter constructs was tested by transfection in
FTO-2B cells. As shown in Fig. 1B, mutation of the LSDLL
sequence present in the cut domain reduced the transcriptional activity of HNF-6 on the two reporter plasmids. This effect was more severe on the HNF-3-type reporter (75% of reduction) than on the TTR-type reporter (50% of reduction). The reduced transcriptional activity of
the L350A mutant was not a consequence of decreased DNA binding, as
could have been suspected from the known role of the cut domain in
binding to the TTR and HNF-3 sites (14). Indeed, EMSA showed that
HNF-6 and HNF-6L350A bound equally well to the two probes tested
(Fig. 1C). We conclude that the cut domain of HNF-6 is required not only for DNA binding, but also for transcriptional stimulation via the two types of HNF-6 binding sites, and that it is
therefore bifunctional.
or HNF-6L350A expression vector in the presence of
increasing amounts of a CBP expression vector and with the
HNF-3-type reporter construct. Consistent with our hypothesis, CBP
increased the activity of wild-type HNF-6 in a
dose-dependent manner (Fig.
2A). Coactivation by CBP was
abolished when transcription of the reporter was stimulated by
HNF-6L350A instead of HNF-6 (Fig. 2B). This indicated
that the LSDLL sequence of HNF-6 is required for coactivation by CBP and suggested that CBP interacts with HNF-6 via this sequence. To
investigate this hypothesis, we performed in vitro GST
pull-down experiments (Fig.
3A). Bacterially expressed
fusion proteins consisting of portions of CBP linked to GST were
immobilized on glutathione-Sepharose beads and tested for their ability
to retain radioactively labeled recombinant HNF-6. These experiments
showed that the N-terminal third (amino acids 1-1098) of CBP
specifically interacts with HNF-6. In contrast, this fragment of CBP
did not interact with HNF-6L350A (Fig. 3B). These results
confirm the cotransfection data described above in which HNF-6, but
not HNF-6L350A, is coactivated by CBP. We conclude that the LSDLL
sequence of the HNF-6 cut domain is required for interacting with
CBP.
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Fig. 2.
Target-specific recruitment of CBP by HNF-6
and involvement of the cut domain and of the homeodomain. FTO-2B
cells were transiently transfected with the reporter construct
pHNF6/HNF3 (6×)-TATA-luc or pHNF6/TTR(6×)-TATA-luc and with the
indicated amount (in ng) of expression vectors coding for HNF-6,
HNF-6L350A, HNF-6F48W+M50H, or CBP. The data are expressed as
-fold stimulation with respect to empty vector (pECE72). Data are
means ± S.E., n = 3 (*, p < 0.05; **, p < 0.001 versus data for
HNF-6 alone).
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Fig. 3.
Interaction between HNF-6 and
coactivators. A-C, bacterially expressed GST,
GST fragments of CBP, and GST-HNF-6 fusion proteins were
bound to glutathione-Sepharose beads. 14C-Labeled HNF-6
or its mutants or 14C-labeled p/CAF produced in a wheat
germ extract was incubated as indicated for 2 h at 4 °C with
the beads, which were then washed and processed for SDS-polyacrylamide
gel electrophoresis followed by autoradiography. An aliquot
(
of the input in the incubation mixture) of the radioactive
proteins was run as a control.
-type reporter by HNF-6 requires an intact F48M50 dyad in the
HNF-6 homeodomain. We therefore verified if the F48M50 dyad is involved
in coactivation with CBP. This was done by transfecting an HNF-6
mutant in which the F48M50 dyad has been changed to W48H50 (14). This
not only reduced transcriptional stimulation, consistent with earlier
work (14), but also abolished coactivation by CBP (Fig. 2C).
These effects of the F48W+M50H mutation were not due to decreased HNF-6
binding to the reporter gene, since we have shown earlier that this
mutation does not reduce DNA binding (14). This is consistent with the
fact that the homeodomain is not involved in HNF-6 binding to the
HNF-3-type reporter (14). To test whether the F48M50 dyad is also
required for the interaction of HNF-6 with CBP, we repeated the GST
pull-down of CBP-(1-1098) with the HNF-6F48W+M50H mutant. As shown
in Fig. 3B, the amount of HNF-6·CBP complex relative to the
input was 5 times less with the F48W+M50H mutant than with wild-type
HNF-6. This indicates that HNF-6F48W+M50H bound much less well to
CBP than wild-type HNF-6. We conclude that, on an HNF-3-type of
target, CBP is a coactivator of HNF-6 and that coactivation occurs via
an interaction of HNF-6 with CBP that involves the LSDLL sequence of
the cut domain and the F48M50 dyad of the homeodomain. The mutation of the LSDLL sequence in the HNF-6 cut domain reduced transcriptional stimulation not only of the HNF-3-type reporter but also of the TTR-type reporter (Fig. 1B). We therefore verified whether
the stimulatory effect of HNF-6 on the TTR target also involves
coactivation with CBP. This was not the case. In contrast to the
results obtained with the HNF-3-type reporter, cotransfection of the
TTR-type reporter with the CBP expression vector failed to amplify the effect of wild-type HNF-6 (Fig. 2D).
expression
vector and an expression vector coding for the coactivator tested. None
of these coactivators affected transcription when tested alone (Fig.
4A). In the presence of HNF-6,
however, p/CAF doubled the transcriptional stimulation of the TTR-type
reporter construct by HNF-6. The other coactivators tested did not
amplify the effect of HNF-6 (Fig. 4A). We repeated these
experiments with the HNF-3 reporter construct. Here, p/CAF did not
enhance the transcriptional stimulation mediated by HNF-6. SRC-1 had
no effect, and RAC-3 amplified the effect of HNF-6 only modestly (Fig.
4B).
View larger version (20K):
[in a new window]
Fig. 4.
Target-specific coactivation of HNF-6 by
p/CAF. FTO-2B cells were transiently transfected with the reporter
constructs pHNF6/TTR(6×)-TATA-luc or pHNF6/HNF3 (6×)-TATA-luc and
with the expression vectors indicated. The data are expressed as -fold
stimulation with respect to empty vector (pECE72). Data are means ± S.E., n = 3 (*, p < 0.01; **,
p < 0.001 versus data for HNF-6
alone).
, we performed
in vitro GST pull-down experiments (Fig. 3C).
These showed that matrix-immobilized HNF-6 specifically interacts
with labeled p/CAF. Our attempts to delineate functionally the domain
of HNF-6 that interacts with p/CAF were unsuccessful. Indeed, Fig.
1B shows that the polyserine and polyhistidine tracts are
not involved in transcriptional stimulation of a TTR site-driven
reporter and are therefore not candidates for interaction with p/CAF.
Deletion of the STP box, mutation of the LSDLL sequence in the cut
domain, or deletion of amino acids 1-98 did not prevent coactivation
with p/CAF (data not shown). Deletion of the cut domain and/or of the homeodomain prevents DNA binding to the TTR target sequence (14). This
makes it impossible to test functionally on the TTR site the possible
interaction of the latter two domains with p/CAF. Finally, deletion of
amino acids 139-347 generated a mutant that was not expressed (data
not shown). We conclude from this set of experiments that, on a TTR
type of target, p/CAF is a coactivator of HNF-6 and interacts with it
in an LSDLL-independent way.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
promoter, DNA binding of
HNF-6 only requires its cut domain. In this case, transcriptional stimulation involves the LSDLL sequence of the cut domain and the
F48M50 dyad of the homeodomain; HNF-6 interacts with CBP and uses it as
a coactivator. On another type of target, whose prototype is the HNF-6
binding sequence present in the ttr gene promoter, DNA
binding of HNF-6 requires both the cut domain and the homeodomain. In
this case, transcriptional stimulation involves the cut domain but not
the homeodomain. On this type of target, HNF-6 does not interact with
CBP but rather with p/CAF. Thus, HNF-6 recruits either CBP or p/CAF in
a target-specific way. Coactivation of a TTR-type target by p/CAF does
not depend on the HNF-6 LSDLL sequence, although the integrity of the
latter is required for full activation of such a target.
-catenin on the
c-fos promoter or ALY (ally of LEF-1) on the TCR
enhancer. In contrast to HNF-6, the LEF-1 binding sequence is the same
in the two targets, and the mechanism of partner discrimination probably depends on the interaction of LEF-1 with different factors that bind in the vicinity (30). For nuclear hormone receptors, the
sequence of the DNA target can be mechanistically discriminatory, as is
the case for HNF-6. Here, however, binding of the same receptor to
different sequences determines whether the hormonal ligand will trigger
transcriptional stimulation via a coactivator or transcriptional
inhibition via a corepressor. Another difference with HNF-6 is that
nuclear receptors have a single DNA-binding domain, and it is via their
homo- or heterodimerization that the sequence-dependent
transcriptional specificity is achieved (31). For HNF-6, it is thanks
to the combinatorial use of two separate, bifunctional, domains that
distinct target sequences impose distinct modes of DNA binding, which,
in turn, determine different mechanisms of transcriptional stimulation.
-type
target, our data show that the LSDLL sequence is required for the
interaction with CBP and that this interaction is involved in
transcriptional stimulation. On the TTR-type target, p/CAF interacts
with HNF-6, but this does not require the HNF-6 LSDLL sequence. This
suggests that, on a TTR-type target, HNF-6 may interact with p/CAF and
with an additional coactivator that would bind to the LSDLL sequence.
ACKNOWLEDGEMENTS
-type reporter constructs; I. Talianidis and E. Soutouglou for vectors coding for GST-CBP proteins, RAC-3, SRC-1, and
p/CAF; T. Kouzarides for pBS-p/CAF; P. Jacquemin for helpful comments
on the manuscript; Y. Peignois for technical assistance; and L. Bertrand for assistance in computer work.
FOOTNOTES
Recipient of a fellowship from the Fonds pour la Formation à
la Recherche dans l'Industrie et l'Agriculture (Belgium).
Senior Research Associate from the National Fund for
Scientific Research (Belgium). To whom correspondence should be
addressed. Tel.: 32-2-764-7583; Fax: 32-2-764-7507; E-mail:
lemaigre@horm. ucl.ac.be.
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