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J. Biol. Chem., Vol. 275, Issue 43, 33365-33372, October 27, 2000
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From the
Received for publication, July 31, 2000
Transcription of pituitary Thyrotropin (TSH)1 is a
member of a pituitary and placental glycoprotein hormone family, which
also includes follicle-stimulating hormone, luteinizing hormone, and
chorionic gonadotropin. These hormones consist of two non-identical and
noncovalently linked subunits termed Interestingly, the TSH- In contrast, the human Several investigators have shown that CREB-binding protein (CBP)
integrates a number of diverse cell signaling pathways involving protein kinase A, protein kinase C, and nuclear hormone receptors (18).
We and others have recently shown that CBP can constitutively bind to
Pit-1 and synergistically activate transcription of promoters containing Pit-1 DNA-binding sites (19, 20). We have demonstrated previously that CBP and Pit-1 enhance protein kinase A induction of the
prolactin gene in a synergistic manner (20). In this report, we explore
the hypothesis that CBP may play a pivotal role in TRH induction of
both of the TSH subunit genes and whether distinct TRH signaling
mechanisms are responsible for induction of these genes.
Plasmids--
The TSH-
All Pit-1, CBP, and CREB constructs are in the SV40 expression
construct pSG5. Pit-1a and W261C are modifications of the original WT
Pit-1 cDNA and therefore contain the same translation initiation site. CBP deletion mutants were made using restriction enzyme digestion
and removal of mouse WT CBP domains as indicated: aa 1-1334,
BstXI; Transfections and Luciferase Assay---
In a 6-well
format, 2 µg of reporter, 8 µg of WT CBP in pSG5, 1.5 µg of mouse
TRH receptor cDNA in pCDM8, and/or 1 µg of either Pit-1 or P-Lim
construct were transfected per well by a calcium phosphate method
(Specialty Media, Inc., Lavallette, NJ) for CV-1 cells or by the
LipofectAMINE method (LipofectAMINE PLUSTM, Life
Technologies, Inc.) for GH3 cells. Sixteen hours after transfection, cultures were treated with serum-free Dulbecco's modified Eagle's medium for 8 h. For TRH stimulation, 50 nM TRH was added to the medium. All transfections were
balanced for the same amount of expression vector using empty vector as
needed. All experiments were repeated at least three times. For
analysis of the expression of transfected CBP constructs and Pit-1
constructs, their expression vectors were transfected as described
above, and Western blotting of total cell lysate was performed using an
anti-CBP antibody that recognizes the extreme N terminus (aa 2-22) of
CBP or an anti-Pit-1 antibody (Santa Cruz Biotechnology, Santa Cruz, CA).
CREB Phosphorylation Assay--
After incubation with serum-free
Dulbecco's modified Eagle's medium overnight, 50 nM TRH
or 10 µM forskolin was added to GH3 cells.
Whole cell extracts from GH3 cells were prepared, and
Western blotting was done using two antibodies, one recognizing the
CREB protein and a second specific for the phospho-CREB species at serine 133 (New England Biolabs Inc., Beverly, MA), using previously described methods (20).
cAMP Assay--
Nearly confluent GH3 cells in 10-cm
plates were incubated with serum-free Dulbecco's modified Eagle's
medium overnight, and then 50 nM TRH or 10 µM
forskolin was added to the cells for up to 60 min. Cells were harvested
and precipitated with 6% trichloroacetic acid. To measure cAMP levels,
a 125I-labeled cAMP radioimmunoassay kit (PerkinElmer Life
Sciences) was employed in three different experiments.
Avidin-Biotin Complex DNA Binding Assay--
Whole cell extracts
from GH3 cells were mixed with 3 µg of biotinylated
oligonucleotides containing a P-Lim consensus DNA-binding site in
binding buffer (phosphate-buffered saline, 1% Igepal CA-630 (Sigma),
0.5% sodium deoxycholate, 0.1% SDS, 1 mM dithiothreitol, 1 mM sodium orthovanadate, 2% (v/w) CompleteTM
proteinase inhibitor mixture (Roche Molecular Biochemicals), and 0.1 mg/ml phenylmethylsulfonyl fluoride) at 4 °C for 2 h. Following
this incubation period, 20 µl of streptavidin-agarose (Life
Technologies, Inc.) was added and incubated at 4 °C for an
additional hour. Streptavidin-agarose resin was precipitated by
centrifugation, washed intensively with binding buffer, and resolved on
an 8% SDS-polyacrylamide gel. Western blotting performed to detect
specific bound proteins. Rabbit anti-LIM-3 polyclonal antibody
(Chemicon International, Inc., Temecula, CA) and the anti-CBP antibody
(which recognizes the extreme N terminus (aa 2-22) of CBP) were
employed for detecting P-Lim and CBP, respectively.
E1A Blocks TRH Stimulation of Thyrotropin Subunit Gene Promoters in
GH3 Cells--
The adenovirus oncoprotein E1A12S is known
to bind CBP and to specifically inhibit CBP activity (21, 22). Since we
hypothesized that CBP would play an important role in TRH stimulation
of the TSH subunit genes, we cotransfected E1A12S and an E1A mutant
(E1A CBP and Pit-1 Act Synergistically in TRH Stimulation of the TSH-
Two lines of evidence indicate that Pit-1 DNA binding to and function
on the TSH- Amino acids 1-450 of CBP Are Sufficient for the Synergistic
Response with Pit-1 in TRH Stimulation of the TSH- CREs in the Human TRH Elevates cAMP Levels and Phosphorylates CREB in Pituitary
Cells--
Based on evidence showing that CBP is an important factor
for TRH stimulation in the pituitary (Fig. 1, a-c) and that
CREs on A Second Region of the
Next, we examined whether P-Lim would interact with CBP on the P-Lim
DNA-binding site. As shown in Fig. 5d, we performed an avidin-biotin complex DNA binding assay using a biotinylated WT or
mutant P-Lim DNA-binding site and GH3 whole cell extracts, which were obtained before or after treatment with TRH. Western blot
analysis showed that a biotinylated P-Lim DNA fragment specifically bound both P-Lim and CBP. P-Lim binding to this DNA fragment was constitutive, whereas CBP binding was increased in extracts prepared from TRH-treated GH3 cells. Since TRH treatment did not
increase CBP content in the cells or the amount of P-Lim bound
to DNA, these data suggest that CBP recruitment to the P-Lim site is
augmented by TRH in GH3 cells.
P-Lim and CBP Act Synergistically in TRH Stimulation of the Human
We also mapped the CBP domain responsible for TRH stimulation using the
CV-1 cells. Since we found that both CREB and P-Lim interact with CBP,
we utilized a In this report, we show that CBP mediates TRH signaling on both
the human Like the TSH- However, we also found that CBP was able to enhance TRH stimulation on
this promoter in the absence of CREs, albeit to a lesser extent. This
finding is important since the CREs found in the human In conclusion, CBP plays a pivotal role in TRH stimulation of the human
TSH subunit genes via different amino-terminal domains. As suggested in
the model in Fig. 7, recruitment of CBP to the TSH subunit genes
involves different DNA-binding transcription factors. The involvement
of CBP in TRH stimulation might allow for the integration of other
pathways impinging on these genes, such as their negative regulation by
thyroid hormone.
We thank M. C. Gershengorn, R. H. Goodman, J. L. Jameson, R. A. Maurer, and M. Montminy for
providing the plasmids used in this study.
*
This work was supported by grants from the National
Institutes of Health (to L. E. C., S. R., and F. E. W.).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.
¶
To whom correspondence should be addressed: Dept. of
Medicine, Section of Endocrinology, University of Chicago, 5841 South Maryland Ave., Chicago, IL 60637. Tel.: 773-702-6217; Fax:
773-834-0486; E-mail: fwondisf@medicine.bsd.uchicago.edu.
Published, JBC Papers in Press, August 7, 2000, DOI 10.1074/jbc.M006819200
The abbreviations used are:
TSH, thyrotropin;
cAMP Response Element-binding Protein-binding Protein
Mediates Thyrotropin-releasing Hormone Signaling on Thyrotropin Subunit
Genes*
,,¶
Thyroid Unit, Division of Endocrinology,
Beth Israel Deaconess Medical Center and § Children's
Hospital, Harvard Medical School,
Boston, Massachusetts 02215
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-glycoprotein
hormone subunit (-GSU) and thyrotropin 
subunit (TSH-) genes
is stimulated by thyrotropin-releasing hormone (TRH). Since cAMP
response element-binding protein (CREB)-binding protein (CBP)
integrates a number of cell signaling pathways, we investigated whether
CBP is important for TRH stimulation of the TSH subunit genes.
Cotransfection of E1A in GH3 cells completely blocked
TRH stimulation of the TSH subunit genes, suggesting that CBP is a key
factor for TRH signaling in the pituitary. CBP and Pit-1 acted
synergistically in TRH stimulation of the TSH- promoter, and amino
acids 1-450 of CBP were sufficient for the TRH effect. In contrast, on
the human -GSU promoter, CREB and P-Lim mediated TRH signaling.
Intriguingly, CREB was phosphorylated upon TRH stimulation, leading to
CBP recruitment to the -GSU promoter. CBP also interacted with P-Lim
in a TRH-dependent manner, suggesting that P-Lim is an
important factor for non-cAMP response element-mediated TRH stimulation
of this promoter. Distinct domains of CBP were required for TRH
signaling by CREB and P-Lim on the -GSU promoter, amino acids
450-700 and 1-450, respectively. Thus, the amino terminus of CBP
plays a critical role in TRH signaling in the anterior pituitary via
both Pit-1-dependent and -independent pathways, yielding
differential regulation of pituitary gene products.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
and . The subunit
(-glycoprotein hormone subunit (-GSU)) is common to all members
of this family and is expressed in molar excess in the pituitary to
facilitate formation of the intact hormone (1). The subunit is
unique and confers specific biological activity to each dimeric hormone
(2, 3). The TSH subunit genes are coordinately regulated at a
transcriptional level by thyroid hormone (4), dopamine (5), and
thyrotropin-releasing hormone (TRH) (6). Both thyroid hormone and
dopamine reduce TSH subunit gene transcription in the anterior
pituitary, whereas TRH increases transcription of these genes. However,
the transcriptional response of the -GSU and TSH- subunit genes
is not identical for these stimuli. For example, thyroid hormone
treatment inhibits transcription of the -GSU gene more slowly and to
a lesser extent than that of the TSH- gene. In contrast,
transcription of the -GSU gene is stimulated to a somewhat greater
extent compared with the TSH- gene by TRH (5). In the anterior
pituitary, TRH bound to its receptor is known to activate phospholipase
C, leading to calcium mobilization and protein kinase C activation (6-9). It has been suggested that the pituitary-specific transcription factor GHF-1/Pit-1 (hereafter referred to as Pit-1) is required for TRH
regulation of the TSH- and prolactin genes in humans and rats (10).
Pit-1 is a member of a group of homeobox proteins containing both a
homeodomain and a POU-specific domain, both of which are important for
DNA binding (11). In addition to its signaling function in the anterior
pituitary, Pit-1 is also necessary for cell-specific expression of
prolactin, growth hormone, and TSH (12).
gene does not contain a consensus phorbol
ester response element (AP-1 site), which is known to respond to
activation of the protein kinase C pathway. Thus, the mechanism by
which TRH mediates induction of this gene is unknown. We and others
have shown that Pit-1 DNA-binding sites are required for TRH induction
of the prolactin and TSH- genes (13, 14).
-GSU gene, which is also stimulated by TRH,
has no Pit-1 DNA-binding sites, but contains two cAMP response elements
(CREs) (14-17). These data suggest that the signaling pathways
responsible for TRH stimulation of the TSH subunit genes may diverge at
least at the level of the transcription factors controlling gene transcription.
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
/luciferase reporter construct contains
bp 
1192 to +37 of the human TSH- promoter linked to the luciferase
gene in the plasmid pA3Luc. The -glycoprotein subunit gene (referred to as 846/Luc) contains bp 846 to +44 of the human
-glycoprotein gene linked to luciferase in pA3Luc. 5'-Deletions of
the 846/Luc construct (346, 250, 156, and 99) were
prepared by polymerase chain reaction (PCR) using 846/Luc as a
template and were subjected to DNA sequencing. The truncated /Luc
CRE mutants were constructed using the 846/Luc CRE mutant as a
template. The TSH- Mt (with all three Pit-1 DNA-binding sites
mutated)/Luc and 846/Luc CRE mutant constructs were prepared by
PCR-directed mutagenesis as described previously (10).
142-705, ApaI; and aa 1-450,
EcoRI. The aa 1-700 construct of CBP was prepared by
PCR (ExpandTM20kb Taq Long PCR system, Roche
Molecular Biochemicals). The RSV-E1A12S and RSV-E1ACR1 plasmids were
a kind gift of Dr. Tony Kouzarides (Cambridge University,
Cambridge, United Kingdom). Mouse P-Lim was generated by reverse
transcription-PCR and subcloned into pSG5. The reading frame and
orientation of each construct were confirmed by DNA dideoxy sequencing
(Amersham Pharmacia Biotech).
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
CR1, where CR1 is conserved region 1) (23) that lacks CBP
binding into a rat pituitary cell line (GH3 cells). As
shown in Fig. 1a, cotransfection of E1A blocked TRH stimulation of both the -GSU and
TSH- promoters, whereas cotransfection of the E1A mutant (Fig.
1b) had no effect. As a control in these experiments,
neither E1A nor E1ACR1 blocked TRH stimulation of the mouse mammary
tumor virus promoter, which is not expressed in the pituitary (Fig. 1c). As E1A is a specific inhibitor of CBP, these data
strongly indicate that CBP is an essential factor for TRH stimulation
of the TSH subunit genes in the pituitary.
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Fig. 1.
E1A blocks TRH stimulation of the TSH subunit
gene promoters in GH3 cells. Two micrograms of
reporter plasmids and 1 µg of RSV-E1A, RSV-E1A CR1, or RSV vector
plasmid were transfected into GH3 cells in a 6-well format.
The mouse mammary tumor virus (MMTV) promoter was used as a
negative control. E1ACR1 lacks the CBP-binding domain. -Fold basal
activity is expressed as -fold induction over that of RSV
(Vector) in the absence of TRH stimulation.
Promoter--
Since a physiological relevance for CBP in TRH signaling
in the pituitary was suggested, we investigated a mechanism by which TRH stimulates the human TSH- promoter. The human TSH- promoter contains three well defined Pit-1 DNA-binding sites (14) (Fig. 2a), and these were
collectively mutated (TSH- Mt). Human TSH- promoter constructs
were transfected into GH3 cells, and the TSH- Mt
construct showed a loss of TRH stimulation, indicating that Pit-1 is a
critical factor for the TRH effect (Fig. 2b). As shown in
previous reports, Pit-1 binds to CBP, and they function synergistically on the rat proximal prolactin promoter (20). To investigate whether CBP
and Pit-1 would act synergistically in TRH stimulation of the TSH-
promoter, cotransfection assays of Pit-1 and CBP on the TSH-
reporter were performed in a cell line devoid of Pit-1 and TRH
receptors (CV-1). To reconstitute TRH stimulation, a mouse TRH receptor
expression vector was transfected into CV-1 cells (24). As shown in
Fig. 2c, basal expression of the TSH- reporter construct
was low but measurable, and Pit-1 or CBP cotransfection activated TRH
stimulation of this reporter to some extent (10.2- and 6.5-fold,
respectively). However, when both CBP and Pit-1 were cotransfected,
synergistic TRH activation was observed (68.0-fold). This synergism was
not observed on the TSH- Mt promoter (Fig. 2d).
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Fig. 2.
TRH induction of the human
TSH- subunit gene promoter. a,
shown is the sequence of the human TSH- subunit gene promoter with
mutation of all three Pit-1 DNA-binding sites shown above the primary
sequence (Mt). The most conserved sequences in the
Pit-1-binding sites are indicated by stippled boxes.
b, shown is a comparison of the wild-type TSH- promoter
(bp 1192 to +37; Wt) and a Pit-1 DNA-binding mutant
(Mt). These reporters were transfected to GH3
cells. -Fold basal activity is expressed as -fold induction over that
of TSH- Mt in the absence of TRH stimulation. c, CV-1
cells were transfected with an SV40 expression vector (pSG5) containing
either CBP and/or WT Pit-1 and a mouse TRH receptor cDNA in the
presence of the human TSH- subunit gene promoter (bp 1192 to +37).
-Fold basal activity is expressed as -fold induction over that of pSG5
(Vector) alone in the absence of TRH stimulation.
d, shown is a comparison of the wild-type TSH- promoter
(bp 1192 to +37) and a Pit-1 DNA-binding site mutant (TSH- Mt).
These reporters were transfected into CV-1 cells as described for
b in the presence of TRH stimulation. -Fold basal activity
is expressed as -fold induction over that of pSG5 (Vector)
alone in TSH- Mt in the absence of TRH stimulation (not shown).
e, shown is a comparison of WT and mutant Pit-1 (Pit-1a and
Pit-1 W261C) proteins in CV-1 cells. -Fold basal activity is expressed
as -fold induction over that of vector alone in the absence of TRH
stimulation. f, shown is a Western blot of CV-1 cells
transfected with pSG5 (Vector) or the indicated Pit-1
expression vectors probed with an anti-Pit-1 antibody.
promoter are required for the TRH response. First, a
Pit-1 DNA-binding mutant (W261C) (25) was completely defective in this
assay. Second, an N-terminal isoform of Pit-1 containing a 26-aa
insertion and known to be defective in activating pituitary gene
expression (Pit-1a) (26-28) was also defective in TRH stimulation of
the TSH- promoter (Fig. 2e). Fig. 2f
demonstrates that equivalent expression of WT Pit-1, Pit-1 W261C, and
Pit-1a was found in transfected CV-1 cells by Western blot analysis of cell lysate probed with an anti-Pit-1 antibody. Taken together, these
data indicate that Pit-1 DNA binding and function are required for the
synergistic TRH stimulation of the TSH- gene by Pit-1 and CBP.
Promoter--
We
next determined which domains of CBP are responsible for the
synergistic effect with Pit-1 in TRH stimulation of the TSH- promoter. Various CBP deletion constructs (Fig.
3a) were cotransfected with WT
Pit-1 in CV-1 cells, and TRH stimulation of the TSH- promoter was
measured. As shown in Fig. 3b, the aa 1-1334 construct, which lacks the carboxyl terminus of CBP, was sufficient to mediate the
TRH effect. Moreover, the aa 1-700 construct of CBP, which contains
both the cysteine/histidine-rich domain 1 (designated the C/H1 domain)
and the CREB-binding domain, was also able to mediate a full TRH
response. Finally, the aa 1-450 construct, which lacks the
CREB-binding domain but contains the C/H1 domain, was fully sufficient
to mediate the TRH response, indicating that a transactivation domain
for TRH stimulation of the TSH- promoter is located in this
amino-terminal region of CBP. In contrast, the 142-705 construct,
which lacks the C/H1 and CREB-binding domains, was defective (10% of
the wild type) in mediating TRH stimulation (Fig. 3b). Taken
together, these data indicate that aa 1-450 are fully sufficient for
TRH stimulation of the TSH- promoter and that the C/H1 domain
contained within this construct is necessary for the effect. To prove
that these CBP deletion constructs were expressed in CV-1 cells,
Western blot analysis of cell lysate from transfected CV-1 cells was
performed. In Fig. 3c, an anti-N terminus antibody was used
to detect the transfected CBP proteins, and proteins of the correct
size were detected in this analysis. Thus, the sufficiency of the aa
1-450 construct in TRH stimulation was not due to enhanced expression
of this CBP construct relative to WT CBP in transfected CV-1 cells.
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Fig. 3.
Determination of CBP domains required for TRH
induction of the human TSH- subunit gene.
a, schematic diagram of the CBP deletion constructs. C/H1
and C/H3 are the cysteine/histidine-rich domains 1 and 3, respectively.
CREB BD, CREB-binding domain; HAT, histone
acetyltransferase domain. b, Western blot analysis of CV-1
cells transfected with pSG5 (Vector) or the indicated CBP
expression vectors using a common anti-CBP N terminus antibody.
c, cotransfection of CBP deletion constructs with the human
TSH- reporter. CV-1 cells were cotransfected with SV40 expression
vectors (pSG5) containing CBP deletion constructs, WT Pit-1, and a
mouse TRH receptor cDNA in the presence of TRH stimulation. Data
are shown as means ± S.E. of TRH-stimulated activity relative to
percent WT CBP induction.
-GSU Promoter Are Involved in TRH
Stimulation--
We next studied the common -GSU promoter. Since
the human -GSU promoter contains two consensus CREs (8-base
palindrome, 5'-TGACGTCA-3') in the proximal promoter, and CBP is known
to bind phosphorylated CREB (29), we mutated the CREs in the -GSU promoter (Fig. 4a) and
determined the effect of this change on TRH stimulation.
GH3 cells were transfected with both wild-type (846W) and
CRE mutant (846M) -GSU promoter constructs. As shown in Fig.
4b, the 846W reporter construct was strongly stimulated by
TRH treatment of cells, and the 846M reporter construct displayed significantly reduced TRH stimulation. Next, we tested a CRE reporter construct containing four copies of a consensus CRE upstream of a
minimal promoter in GH3 cells. As shown in Fig.
4c, this CRE reporter was markedly stimulated by TRH in the
rat pituitary cell line. The minimal reporter construct, lacking CREs,
was not responsive to TRH stimulation. These data indicate that a cAMP
response element mediates, in part, TRH stimulation of the human
-GSU gene.
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Fig. 4.
CREs are involved in TRH stimulation of the
human -GSU promoter, and TRH phosphorylates
CREB. a, mutation of the human -GSU promoter CREs
used in this study. Boldface letters represent the deleted
and mutated DNA sequence in the 846 CRE deletion mutant (846M).
b, comparison of 846W (wild-type) and 846M (mutant) in
GH3 cells. The indicated reporters were transfected into
GH3 cells. Relative -fold activity is expressed as -fold
induction over that of a 99 wild-type reporter (99W) in the
absence of TRH stimulation. c, CREs mediate TRH stimulation.
A minimal reporter (TATA-Luc) or one containing four copies of a CRE
was transfected into GH3 cells. Relative -fold activity is
expressed as -fold induction over that of the minimal reporter
(TATA-Luc) in the absence of TRH stimulation. d, TRH
phosphorylates CREB. GH3 cells were treated with either 50 nM TRH or 10 µM forskolin for the indicated
times, and Western blotting was performed with either a
phospho-specific antibody (Ab; S133A) or a control antibody.
The 0 min lane is common to both forskolin and TRH
stimulation. e, cAMP levels measured in GH3
cells that were treated as described for d.
-GSU are involved in TRH stimulation, we hypothesized that CREB is phosphorylated by the TRH signaling pathway (8). Previously, TRH was thought to act almost exclusively through the protein kinase C
pathway in the pituitary, such that phosphorylation of CREB at site 133 (30) by TRH would seem unlikely. Given our results, however, we tested
whether the TRH signaling pathway phosphorylates CREB in the same way
that the protein kinase A signaling pathway phosphorylates this protein
in GH3 cells. We utilized a phospho-specific antibody
directed against serine 133 and a control antibody to CREB to prove
this hypothesis. As shown in Fig. 4d, forskolin (a direct
activator of adenylyl cyclase) phosphorylated CREB at
Ser133, as expected. Unexpectedly, TRH treatment of
GH3 cells also phosphorylated CREB at this site. CREB
phosphorylation by either forskolin or TRH treatment was maximal at 5 min and then gradually decreased in TRH-treated cells, whereas
forskolin-induced phosphorylation of CREB was relatively constant. We
next investigated whether cAMP levels were elevated in GH3
cells after TRH stimulation. As shown in Fig. 4e, forskolin
elevated cAMP levels as expected, and TRH also raised cAMP levels to
maximum levels within 5 min, which declined thereafter. These data
indicate that TRH rapidly phosphorylates CREB at Ser133
through elevation of intracellular cAMP levels, suggesting a potential
mechanism for signaling cross-talk in pituitary cells.
-GSU Promoter Binds P-Lim and Mediates
TRH Stimulation--
It has been suggested that several non-CRE
cis-elements on the -GSU promoter play a pivotal role in
its tissue-specific expression (12, 31-36). We employed truncated
-GSU promoters lacking consensus CREs (e.g. 846M) and
transfected them into GH3 cells. As shown in Fig.
5a, there was a significant
reduction in TRH stimulation when the region between bp 346 and 250
was deleted, suggesting that a non-CRE cis-acting element
responsible for TRH stimulation is located there. Within this region is
a P-Lim/Lhx-3 (hereafter referred to as P-Lim)-binding site known to
activate the -GSU promoter (12, 38); we hypothesized that
P-Lim may be important for TRH stimulation and mutated this
P-Lim-binding site (Fig. 5b) (12). To prove this hypothesis,
we utilized the 346 -GSU promoter construct containing a
CRE-binding site mutation (346M), a P-Lim-binding site mutation
(346M Lim mut), or both mutations in GH3 cells. As shown
in Fig. 5c (left panel), the P-Lim mutation (346W Lim mut) showed a 55% reduction in TRH stimulation compared with the wild-type construct (346W). On the other hand, when both the
CRE- and P-Lim-binding sites were mutated (346M Lim mut), TRH
stimulation was abolished (right panel).
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Fig. 5.
P-Lim is a key factor for non-CRE-mediated
TRH stimulation of the -GSU promoter.
a, a series of truncated -GSU CRE mutant promoters were
transfected into GH3 cells. Relative -fold activity is
expressed as -fold induction over that of the 99 wild-type
reporter (99W) in the absence of TRH stimulation. b, shown
are the sequence and mutation of a P-Lim-binding site (Lim mut) in the
human -GSU promoter. The P-Lim-binding site is a palindrome as
indicated. c, a P-Lim-binding site is involved in TRH
signaling. The 346 -GSU promoter construct (346W) or one
containing a CRE-binding site mutation (346M), a P-Lim-binding site
mutation (346W Lim mut), or both mutations (346M Lim mut) was
transfected in GH3 cells. Relative -fold activity is
expressed as -fold induction over that of the 99 wild-type
reporter (99W) in the absence of TRH stimulation (not shown).
d, shown are the results from the avidin-biotin complex DNA
binding assay using a biotinylated P-Lim-binding site (P-Lim
wt) or a mutant (P-Lim mut) fragment. The WT P-Lim
fragment contains bp 341 to 314 of the -GSU promoter. The mutant
P-Lim fragment contains the exact mutation as indicated in
b. B, biotin; SA,
streptavidin-agarose. e, CV-1 cells were cotransfected with
the -GSU promoter, CBP, Pit-1, P-Lim, and the mouse TRH receptor.
-Fold basal activity is expressed as -fold induction over that of
vector alone in the absence of TRH.
-GSU Promoter--
We next investigated whether P-Lim and CBP would
act synergistically in TRH stimulation of the human -GSU promoter.
For this purpose, we employed the CV-1 cell line, which is devoid of
TRH receptors and P-Lim and contains a low amount of endogenous CBP. To
reconstitute TRH stimulation, a mouse TRH receptor expression vector
was cotransfected. As shown in Fig. 5e, P-Lim increased TRH
stimulation of the -GSU promoter ~4-fold, and P-Lim and CBP cotransfection augmented the TRH effect by ~23-fold, indicating synergism.
346 WT construct (346W), a 346 construct containing
a mutant P-Lim-binding site (346W Lim mut), or a 346 construct
containing a mutant CREB-binding site (346M). As shown in Fig.
6a, the aa 1-700 construct
was sufficient for TRH stimulation of the WT reporter, but the
142-705 construct was defective; the aa 1-450 construct had
intermediate activity. In contrast, both the 142-705 and aa 1-450
constructs were defective on the 346M reporter, and only the
142-705 construct was inactive on 346W Lim mut. These data
indicate that aa 450-700 of CBP, which contain the CREB-binding
domain, are required for TRH stimulation by the CRE site in the human
-GSU promoter, whereas aa 1-450 of CBP, which contain the C/H1
domain, are for TRH stimulation by the P-Lim site.
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[in a new window]
Fig. 6.
Mapping of CBP domains responsible for TRH
stimulation of the -GSU promoter. CBP
deletion constructs were cotransfected with the 346W (a),
346W Lim mut (b), or 346M (c) -GSU
reporter construct. CV-1 cells were cotransfected with a SV40
expression vector (pSG5) containing CBP deletion constructs or P-Lim. A
mouse TRH receptor cDNA was also cotransfected. Data are shown as
means ± S.E. of TRH-stimulated activity relative to percent WT
CBP induction.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-GSU and TSH- promoters via different mechanisms. We
have shown that CBP enhances expression of pituitary genes such as
growth hormone and prolactin (20, 39). In this study, E1A clearly
blocked TRH stimulation of the TSH subunit genes in a pituitary cell
line, indicating that CBP may play an important role in TRH stimulation
of the anterior pituitary (Fig. 1). We and others have also shown that
Pit-1 plays an important role in TRH stimulation of the prolactin and
TSH- subunit genes (10, 14, 40, 41). Recently, a mechanism was
proposed whereby CBP bound to Pit-1 would mediate the effect of certain
signaling pathways in the pituitary (19, 20). CBP binds to Pit-1 via two distinct domains, the C/H1 and C/H3 domains. On the rat proximal prolactin promoter, CBP synergistically enhances
Pit-1-dependent TRH stimulation via the C/H1 domain and
protein kinase A stimulation via the C/H3 domain (20). Our data on the
human TSH- promoter are consistent with the observation that the
amino terminus of CBP is sufficient to mediate TRH stimulation via
Pit-1 DNA response elements. Since Pit-1 binds to CBP via its C/H1 and
C/H3 domains, CBP may be a direct target of the TRH signaling pathway.
This is further supported by the work of others studying the prolactin gene or isolated Pit-1 DNA response elements (13, 42). CBP bound to
Pit-1 could also recruit other factors that contain histone acetyltransferase activity such as p/CAF (43) and p/CIP (44) to the
transcription complex during TRH stimulation. To date, however, these
coactivator proteins have been shown to bind to the C terminus of CBP,
which our data clearly show is not required for TRH stimulation of the
TSH subunit promoters. Moreover, Chawla et al. (45)
suggested that CBP action is also controlled by nuclear calcium- and
calmodulin-dependent kinase IV via the C terminus. This
mechanism could be involved since TRH signaling is known to increase
Ca2+ influx in the pituitary. However, calcium signaling
also appears to act on the C terminus of CBP. Regardless of the
mechanism, the amino terminus of CBP contains a coactivator function
sufficient for TRH stimulation.
gene, CBP is also able to activate TRH stimulation of
the -GSU gene. Unlike the TSH- gene, however, Pit-1 is not
required for TRH stimulation. Thus, at the level of the TSH subunit
genes, TRH signaling pathways diverge. Previous workers suggested that
CREs could in some way be involved in TRH stimulation of the human
-GSU promoter (36). We demonstrated that phosphorylation of CREB by
TRH plays an important role in the ability of CBP to enhance TRH
stimulation of this gene. Since the CREB-binding domain of CBP is also
required for TRH stimulation of the -GSU gene, we suggest that
phosphorylation of CREB by TRH recruits CBP to the -GSU promoter to
increase transcription (Fig. 7).
Traditionally, Ser133 of CREB was thought to be an
exclusive target of the protein kinase A signaling pathway (30) and, in
contrast, that the protein kinase C signaling pathway regulates
phosphorylation of the Jun·Fos (AP-1) complex (46). However, others
have suggested that calcium/calmodulin-dependent kinases,
Ras/mitogen-activated protein kinase, and protein kinase C can
phosphorylate CREB at Ser133 (47-49). Their data are
consistent with our findings since we note that the TRH signaling
pathway, which activates protein kinase C and Ras/mitogen-activated
protein kinase pathways and increases intracellular levels of calcium,
also phosphorylates CREB. The data showing an elevation in
intracellular cAMP levels upon TRH stimulation in GH3 cells
also support these findings.
View larger version (19K):
[in a new window]
Fig. 7.
Model of TRH stimulation of human TSH subunit
gene promoters. The three pairs of
white ovals on the TSH- promoter
represent Pit-1 dimers bound to DNA, and the two white ovals
and two black ovals on the -GSU promoter represent P-Lim
(dimer) and phosphorylated CREB (dimer) bound to DNA, respectively. The
phosphorylation state of Pit-1 and P-Lim bound to TSH subunit gene
promoters after TRH stimulation is unknown and is not indicated in the
model.
-GSU gene are
not conserved in lower mammalian species such as the mouse (37). Since
a significant reduction in TRH stimulation was found when the region
between bp 346 and 250 of the -GSU promoter was deleted,
we focused on the region. Located between bp 346 and 313 is a
pituitary glycoprotein hormone basal element (12) that is known to bind
LIM homeodomain proteins. Mutation of the region in the context of the
CRE mutant revealed loss of TRH signaling on the -GSU promoter. We
also demonstrated that P-Lim binds to CBP in TRH-dependent
manner on this site and that these proteins synergistically activate
the human -GSU promoter during TRH stimulation. We hypothesize that
the P-Lim·CBP complex could be a key mediator of TRH signaling of the
-GSU gene in lower mammals in which the -GSU promoter contain no
consensus CREs.
ACKNOWLEDGEMENTS
FOOTNOTES
ABBREVIATIONS
-GSU, -glycoprotein hormone subunit;
TRH, thyrotropin-releasing
hormone;
CRE, cAMP response element;
CREB, cAMP response
element-binding protein;
CBP, cAMP response element-binding
protein-binding protein;
bp, base pairs;
PCR, polymerase chain
reaction;
WT, wild-type;
aa, amino acid(s);
RSV, Rous sarcoma
virus.
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