Evolution of placenta-specific gene expression: comparison of the equine and human gonadotropin alpha-subunit genes

Squelching of ETS2 transactivation by POU5F1 silences the human chorionic gonadotropin CGA subunit gene in human choriocarcinoma and embryonic stem cells

The subunit genes encoding human chorionic gonadotropin, CGA, and CGB, are up-regulated in human trophoblast. However, they are effectively silenced in choriocarcinoma cells by ectopically expressed POU domain class 5 transcription factor 1 (POU5F1). Here we show that POU5F1 represses activity of the CGA promoter through its interactions with ETS2, a transcription factor required for both placental development and human chorionic gonadotropin subunit gene expression, by forming a complex that precludes ETS2 from interacting with the CGA promoter. Mutation of a POU5F1 binding site proximal to the ETS2 binding site does not alter the ability of POU5F1 to act as a repressor but causes a drop in basal promoter activity due to overlap with the binding site for DLX3. DLX3 has only a modest ability to raise basal CGA promoter activity, but its coexpression with ETS2 can up-regulate it 100-fold or more. The two factors form a complex, and both must bind to the promoter for the combination to be transcriptionally effective, a synergy compromised by POU5F1. Similarly, in human embryonic stem cells, which express ETS2 but not CGA, ETS2 does not occupy its binding site on the CGA promoter but is found instead as a soluble complex with POU5F1. When human embryonic stem cells differentiate in response to bone morphogenetic protein-4 and concentrations of POU5F1 fall and hCG and DLX3 rise, ETS2 then occupies its binding site on the CGA promoter. Hence, a squelching mechanism underpins the transcriptional silencing of CGA by POU5F1 and could have general relevance to how pluripotency is maintained and how the trophoblast lineage emerges from pluripotent precursor cells.

Molecular cloning and characterization of porcine homeodomain transcription factor Msx1

We cloned a porcine ortholog of homeodomain transcription factor Msx1 from the porcine pituitary cDNA library. The amino acid sequence of Msx1 shows high conservation among mammalian species. RT-PCR for porcine fetal and postnatal pituitaries showed that Msx1 is already expressed at early fetal day 40, decreases to a low level before birth and then remarkably decreases after birth. On the other hand, Msx1 expression was observed in all pituitary-derived cell line tested, with most in a gonadotrope lineage LbetaT4. Transfection assay demonstrated that Msx1 markedly repressed the basal Cga and Fshb gene expression, while Lhb expression was affected slightly. Taken together, Msx1 may play a role in repressing gene expression in the fetal and postnatal periods.

Cofactor CLIM2 promotes the repressive action of LIM homeodomain transcription factor Lhx2 in the expression of porcine pituitary glycoprotein hormone alpha subunit gene

We have cloned a porcine orthologue of cofactor CLIM2 (Ldb1/NLI) from the porcine pituitary cDNA library by protein-protein interaction with the Yeast Two-Hybrid System using porcine Lhx2 as a bait protein. Porcine CLIM2 shows a high identity (99%) in the dimerization domain, nuclear localization signal and LIM binding domain with those of man and mouse. The expression of CLIM2 gene in the anterior pituitary lobe was detected during the porcine fetal and postnatal period by RT-PCR analysis, suggesting that this protein is constitutively expressing and plays a basic role in the anterior pituitary. Transfection assay to the pituitary tumor derived LbetaT2 cells, and the Chinese hamster ovary cells demonstrated that CLIM2 acts as a corepressor of the porcine Lhx2 function. Interestingly, CLIM2 alone apparently repressed the high level of alphaGSU gene expression in LbetaT2 cells. These data suggest that CLIM2 is a basic factor in the pituitary development and function, and plays the role of repressor to modify the function of Lhx2 on the alphaGSU gene expression.

Transcriptional regulation of aromatase in placenta and ovary

Our goal is to define the cellular and molecular mechanisms for tissue- and cell-specific, developmental and hormonal regulation of the human CYP19 (aromatase P450/P450arom) gene in estrogen-producing cells. In this article, we review studies using transgenic mice and transfected cells to identify genomic regions and response elements that mediate CYP19 expression in placenta and ovary, as well as to define the molecular mechanisms for O2 regulation of differentiation and CYP19 gene expression in human trophoblast cells in culture. We also highlight recent findings regarding LRH-1 versus SF-1 mRNA expression and cellular localization in the mouse ovary during the estrous cycle and various stages of pregnancy. Spatial and temporal expression patterns of mRNAs encoding these orphan nuclear receptors in comparison to those of P450arom and 17alpha-hydroxylase/17,20-lyase mRNAs, suggest an important role of LRH-1 together with SF-1 in ovarian steroidogenesis.

Multiple and overlapping combinatorial codes orchestrate hormonal responsiveness and dictate cell-specific expression of the genes encoding luteinizing hormone

Normal reproductive function in mammals requires precise control of LH synthesis and secretion by gonadotropes of the anterior pituitary. Synthesis of LH requires expression of two genes [alpha-glycoprotein subunit (alphaGSU) and LHbeta] located on different chromosomes. Hormones from the hypothalamus and gonads modulate transcription of both genes as well as secretion of the biologically active LH heterodimer. In males and females, the transcriptional tone of the genes encoding alphaGSU and LHbeta reflects dynamic integration of a positive signal provided by GnRH from hypothalamic neurons and negative signals emanating from gonadal steroids. Although alphaGSU and LHbeta genes respond transcriptionally in the same manner to changes in hormonal input, different combinations of regulatory elements orchestrate their response. These hormone-responsive regulatory elements are also integral members of much larger combinatorial codes responsible for targeting expression of alphaGSU and LHbeta genes to gonadotropes. In this review, we will profile the genomic landscape of the promoter-regulatory region of both genes, depicting elements and factors that contribute to gonadotrope-specific expression and hormonal regulation. Within this context, we will highlight the different combinatorial codes that control transcriptional responses, particularly those that mediate the opposing effects of GnRH and one of the sex steroids, androgens. We will use this framework to suggest that GnRH and androgens attain the same transcriptional endpoint through combinatorial codes unique to alphaGSU and LHbeta. This parallelism permits the dynamic and coordinate regulation of two genes that encode a single hormone.

Unique regulation of expression of human aromatase in the placenta

The expression of human placental aromatase is transcriptionally regulated through the promoter region of exon 1a (I.1) of the gene. We examined the transcriptional regulation by using human choriocarcinoma-derived JEG-3 cells which also express aromatase mRNA transcribed under the control of the placenta-specific promoter of the exon 1a. Aromatase in the cells was induced by forskolin (cAMP) and phorbol ester (TPA) in both levels of the activity and the mRNA. However, any elements responsible for the cAMP-responsiveness have not yet identified. To identify and characterize the specific elements, CAT assay of the placenta-specific promoter was performed. We reconstructed an 11.5 kb gene structure consisting of exons 1a (I.1), 1b (I.4), 1c (I.3), and 1d (PII) and their proximal promoter regions to mimic the native structure of human aromatase gene and performed a promoter assay by the transient expression of a CAT reporter carrying the mini-gene structure. The construct was transcribed from exon 1a in JEG-3 cells and exon 1b in HepG2 cells to produce tissue-specific mRNAs from the exons 1-CAT hybrid gene, indicating that the mini-gene structure contained promoter regions essential for the tissue-specific expression. However, unexpectedly exons 1-CAT hybrid mRNA in JEG-3 cells was not induced by forskolin. Then, we prepared JEG-3 cells transformed by incorporation of the exons 1-CAT hybrid gene into the chromosomal DNA. The cells stably expressed the hybrid reporter gene which was transcribed from exon 1a and induced by forskolin and TPA. These results suggest that enhancers on the promoter regions of exons 1b, 1c, and 1d might interact with a transcriptional machinery of exon 1a in the induction by forskolin and TPA. Finally, a beta-galactosidase gene connected with the 11.5 kb gene structure was introduced into mouse eggs to produce transgenic mice. The hybrid gene was transcribed from exon 1c in the gonadal tissues of all lines of the transgenic mice in accordance with the tissue-specificity of human aromatase gene, whereas it was not transcribed from exon 1a, but from exons 1b and 1c in the all placentae. The results suggest that the mouse placenta might lack in the transcriptional elements or factors essential for the placenta-specific expression of human aromatase gene.

Extracellular signal-regulated kinase and c-Src, but not Jun N-terminal kinase, are involved in basal and gonadotropin-releasing hormone-stimulated activity of the glycoprotein hormone alpha-subunit promoter

Addition of a GnRH agonist (GnRH-A) to alphaT3-1 cells stimulates different MAPK cascades: ERK, Jun N-terminal kinase (JNK), and p38. Activation of JNK, ERK, and p38 shows a unique fold activation ratio of 25:12:2, which might encode signal specificity. ERK is translocated to the nucleus within 20 min with a peak at 120 min of GnRH-A stimulation. We used the human alpha-subunit promoter linked to chloramphenicol acetyl transferase (alphaCAT) to examine the role of ERK, JNK, and c-Src, which is implicated in MAPK activation, in basal and GnRH-stimulated alphaCAT. Addition of GnRH-A resulted in a 3-fold increase in alphaCAT, whereas the Ca(2+) ionophore ionomycin and the protein kinase C (PKC) activator 12-O-tetradecanoylphorbol-13-acetate (TPA) had no effect. Addition of GnRH-A and TPA, but not GnRH-A and ionomycin, produced a synergistic response, whereas removal of Ca(2+), but not down-regulation of TPA-sensitive PKCs, abolished GnRH-A-stimulated alphaCAT. Thus, regulation of alpha-promoter activity by GnRH is Ca(2+) dependent and is further augmented by PKC. Cotransfection of alphaCAT and constitutively active or dominant negative plasmids of ERK and JNK cascade members, or the use of the ERK inhibitor PD98059, revealed that ERK, but not JNK, is involved in basal and GnRH-A-stimulated alphaCAT. Because c-Src participates in MAPK activation by GnRH, we also studied its role. Cotransfection of alphaCAT and the dominant negative form of c-Src or incubation with the c-Src inhibitor PP1 reduced GnRH-A-stimulated alphaCAT. The 5'-deletion analysis revealed that the -846/-420 region participated in basal alpha-transcription. In addition, the -346/-156 region containing the pituitary glycoprotein hormone basal element, alpha-basal elements, glycoprotein-specific element, and upstream response element is involved in basal and GnRH-A-stimulated alphaCAT. ERK contribution to GnRH maps to -346/-280 containing the pituitary glycoprotein hormone basal element and alpha-basal elements 1/2. Surprisingly, although c-Src is involved in GnRH-A-stimulated ERK, its involvement is mapped to another region (-280/-180) containing the glycoprotein-specific element. Thus, ERK and c-Src but not JNK are involved in basal and GnRH-A-stimulated-alphaCAT, whereas c-Src contribution is independent of ERK activation.

Mechanism of gonadotropin gene expression. Identification of a novel negative regulatory element at the transcription start site of the glycoprotein hormone alpha-subunit gene

Regulation of the glycoprotein hormone alpha-subunit (GPHalpha) gene has been studied extensively in pituitary and placental cell lines, but little is known of the transcriptional regulators important for its ectopic expression. To investigate the molecular basis for ectopic expression, it was critical to define cis-regulatory elements and their cognate trans-acting factors that modulate promoter activity in epithelial cell types that do not normally express GPH. DNA-mediated transient expression of promoter-reporter constructs was used to identify a novel negative regulatory element located at the GPHalpha gene transcription start site. Truncation or site-directed mutagenesis of this element produced up to a 10-fold increase in promoter activity. Electrophoretic mobility shift analysis detected a protein that binds specifically to a DNA motif encompassing the cap site. Based on competitive DNA binding studies with mutated oligonucleotides, it was determined that bases from -5 to -2 and +4 to +11 are critical for protein binding. The DNA sequence flanking the transcription start site from -9 to +11 is an imperfect palindrome; consequently, this motif is referred to as the cap site diad element (CSDE) and the cognate factor as the cap site-binding protein (CSBP). CSBP activity was present at different levels in nuclear extracts prepared from a variety of cell types. Significantly, the ratio of activities exhibited by the GPHalpha promoter with a mutated CSDE compared with the promoter with a wild-type CSDE was dependent on the transfected cell line and its content of CSBP. These results indicate that a negative regulatory element centered at the GPHalpha gene cap site and its cognate DNA-binding protein make a significant contribution to the production of alpha-subunit in a variety of tumor tissues. A detailed understanding of this cis/trans pair may further suggest a mechanism to explain, at least in part, how this gene becomes activated in nonendocrine tumors.

An activator protein-1 complex mediates epidermal growth factor regulation of equine glycoprotein alpha subunit expression in trophoblast cells

Equids and primates are the only species known to express the placental hormone chorionic gonadotropin (CG). CG is a member of the heterodimeric glycoprotein family and is composed of an alpha subunit linked to a hormone-specific beta subunit. Previously, we have reported that epidermal growth factor (EGF) regulates the equine glycoprotein hormone alpha subunit promoter through a protein kinase C (PKC)/mitogen-activated protein kinase (MAPK) signal transduction pathway in trophoblasts. The current study investigates the regulatory element/factors involved in the induction of equine glycoprotein alpha subunit gene expression by EGF. Using 5' deletion mutagenesis, we have delineated the primary EGF/PKC responsive region of the equine alpha subunit gene to be located between -2039 to -2032 base pairs upstream of the transcriptional start site. The sequence within this region contains an activator protein 1 (AP-1)-like response element (TGAATCA) and is similar to a consensus AP-1 (TGAC/GTCA) response element. This element appeared to preferentially interact with a c-fos/JunD heterodimer. Stimulation by EGF induced the binding of c-fos and JunD to this element and subsequently elevated promoter activity. In conclusion, an EGF/PKC/MAPK signal transduction pathway regulates equine glycoprotein alpha subunit gene expression through a distinct regulatory element(s) that lies between -2039 to -2032 of the equine glycoprotein alpha subunit promoter in trophoblasts and involves an AP-1 complex.

Chorionic gonadotropin has a recent origin within primates and an evolutionary history of selection

Chorionic gonadotropin (CG) is a critical signal in establishing pregnancy in humans and some other primates, but this placentally expressed hormone has not been found in other mammalian orders. The gene for one of its two subunits (CG beta subunit [CGbeta]) arose by duplication from the luteinizing hormone beta subunit gene (LHbeta), present in all mammals tested. In this study, 14 primate and related mammalian species were examined by Southern blotting and DNA sequencing to determine where in mammalian phylogeny the CGbeta gene originated. Bats (order Chiroptera), flying lemur (order Dermoptera), strepsirrhine primates, and tarsiers do not have a CGbeta gene, although they possess one copy of the LHbeta gene. The CGbeta gene first arose in the common ancestor of the anthropoid primates (New World monkeys, Old World monkeys, apes, and humans), after the anthropoids diverged from tarsiers. At least two subsequent duplication events occurred in the catarrhine primates, all of which possess multiple CGbeta copies. The LHbeta-CGbeta family of genes has undergone frequent gene conversion among the catarrhines, as well as periods of strong positive selection in the New World monkeys (platyrrhines). In addition, newly generated DNA sequences from the promoter of the CG alpha subunit gene indicate that platyrrhine monkeys use a different mechanism of alpha gene expression control than that found in catarrhines.

Repression of Ets-2-induced transactivation of the tau interferon promoter by Oct-4

Oct-4 is a POU family transcription factor associated with potentially totipotent cells. Genes expressed in the trophectoderm but not in embryos prior to blastocyst formation may be targets for silencing by Oct-4. Here, we have tested this hypothesis with the tau interferon genes (IFNT genes), which are expressed exclusively in the trophectoderm of bovine embryos. IFNT promoters contain an Ets-2 enhancer, located at -79 to -70, and are up-regulated about 20-fold by the overexpression of Ets-2 in human JAr choriocarcinoma cells, which are permissive for IFNT expression. This enhancement was reversed in a dose-dependent manner by coexpression of Oct-4 but not either Oct-1 or Oct-2. When cells were transfected with truncated bovine IFNT promoters designed to eliminate potential octamer sites sequentially, luciferase reporter expression from each construct was still silenced by Oct-4. Full repression required both the N-terminal and POU domains of Oct-4, but neither domain used alone was an effective silencer. Oct-4 and Ets-2 formed a complex in vitro in the absence of DNA through binding of the POU domain of Oct-4 to a site located between the "pointed" and DNA binding domains of Ets-2. The two transcription factors were also coimmunoprecipitated after being expressed together in JAr cells. Oct-4, therefore, silences IFNT promoters by quenching Ets-2 transactivation. The POU domain most probably binds to Ets-2 directly, while the N-terminal domain inhibits transcription. These findings provide further evidence that the developmental switch to the trophectoderm is accompanied by the loss of Oct-4 silencing of key genes.

Epidermal growth factor regulation of equine glycoprotein hormone alpha subunit expression in trophoblast cells

Primates and equids are the only species known to express the placental glycoprotein hormone, chorionic gonadotropin (CG), a heterodimeric glycoprotein composed of an alpha subunit linked to a hormone-specific beta subunit. The regulatory mechanisms involved in the induction of equine glycoprotein alpha subunit gene expression have not been identified. Epidermal growth factor (EGF) receptor is known to transduce signals that alter a number of different cellular functions (cell proliferation, differentiation, hormone secretion, and gene regulation). In the present study, we investigated the regulation of the equine alpha subunit gene by EGF in trophoblasts. We found that 2800 base pairs of 5' flanking sequence from the equine alpha subunit promoter is sufficient for basal expression in human choriocarcinoma cells. Epidermal growth factor and phorbol 12-myristate 13-acetate (PMA), an activator of protein kinase C (PKC), increased transcriptional activity of the equine alpha subunit promoter (-2800/+21). These responses were blocked by pretreatment with bisindolylmaleimide-I, an inhibitor of PKC, suggesting an involvement of this pathway downstream of EGF. In addition, PD98059, an inhibitor of the extracellular signal-regulated kinase (ERK) pathway, completely blocked activation of the equine alpha promoter by PMA, suggesting that mitogen-activated protein kinase (MAPK) cascade was involved downstream of the PKC pathway. In conclusion, the EGF/PKC/MAPK pathway regulates equine glycoprotein alpha subunit gene expression through a distinct regulatory region (-2300 to -1900) in trophoblasts, while essential elements for basal expression appear to exist within the -2800 to -1900 region of the promoter.

Chromatin structure of the bovine Cyp19 promoter 1.1. DNaseI hypersensitive sites and DNA hypomethylation correlate with placental expression

Expression of the Cyp19 gene, encoding aromatase cytochrome P450, is driven by several tissue-specific promoters. The underlying mechanisms of this complex regulation have not yet been elucidated in detail. In the present report we investigate a possible link between chromatin structure and tissue-specific regulation of the bovine Cyp19 gene. We analysed the DNA methylation status and mapped DNaseI hypersensitive sites in the region encompassing the Cyp19 promoter 1.1 (P1.1) which controls Cyp19 expression in the bovine placenta. We show that P1.1 is hypomethylated in placental cotyledons (foetal layer) whereas it is methylated in placental caruncles (maternal layer), testis and corpus luteum. Furthermore, two placenta-specific DNaseI hypersensitive sites, HS1 and HS2, were observed within P1.1. Both DNA hypomethylation and the presence of DNaseI hypersensitive sites correlate with transcriptional activity of P1.1. Sequence analysis of hypersensitive sites revealed potential cis-regulatory elements, an E-box in HS1 and a trophoblast-specific element-like sequence in HS2. It could be demonstrated by electrophoretic mobility shift assays that both sequence motifs are specific targets for placenta-derived nuclear factors. In conclusion, observed tissue-specific differences of the chromatin structure which correlate with tissue-specific promoter activity suggest that chromatin might be an important regulator of aromatase expression in cattle.

Genomic organization, chromosomal localization, and the complete 22 kb DNA sequence of the human GCMa/GCM1, a placenta-specific transcription factor gene

The genomic sequence of the human GCMa/GCM1 gene, a mammalian homologue of Drosophila melanogaster GCM, was determined. Drosophila GCM is a neural transcription factor that regulates glial cell fate. The mammalian homolog however, is a placenta-specific transcription factor that is necessary for placental development. The 22 kb DNA sequence spanning the GCMa gene contains six exons and five introns, encoding a 2.8 kb cDNA. Overall genomic organization is similar for the human and mouse. Several potential binding sites for transcription factors like GATA, Oct-1, and bHLH proteins were found in the 5'-flanking region of the human gene. A DNA motif for GCM protein binding exists in the 5'-flanking region that is highly homologous with that of the mouse gene. The location of this gene was mapped to chromosome 6 using fluorescence in situ hybridization.

cAMP response element-binding protein-binding protein mediates thyrotropin-releasing hormone signaling on thyrotropin subunit genes

Transcription of pituitary alpha-glycoprotein hormone subunit (alpha-GSU) and thyrotropin beta subunit (TSH-beta) 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 GH(3) 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-beta promoter, and amino acids 1-450 of CBP were sufficient for the TRH effect. In contrast, on the human alpha-GSU promoter, CREB and P-Lim mediated TRH signaling. Intriguingly, CREB was phosphorylated upon TRH stimulation, leading to CBP recruitment to the alpha-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 alpha-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.

Sequence analysis of the human glycoprotein hormone alpha-subunit gene 5'-flanking DNA and identification of a potential regulatory element as an alu repetitive sequence

The nucleotide sequence of the human glycoprotein hormone alpha-subunit (GPHalpha) gene 5'-flanking DNA was determined from -1637 to +49 relative to the cap site (+1). Comparison of the upstream sequence of the human gene with those of rhesus and mouse demonstrates regions with variable identity. When the 1.7 kb fragment was used to drive the expression of chloramphenicol acetyltransferase (CAT) in transiently transfected HeLa cells, it was found that CAT activity was elevated about 3-fold when the fragment was truncated from -1637 to -846, suggesting the presence of a negative regulatory element in the distal 5'-flanking DNA. This overlaps an Alu repetitive sequence (ARS) located between nucleotides -1330 and -1007. Gel mobility shift and DNase protection analyses identified a protein binding site centered around -1100 in the ARS second monomer. The GPHalpha upstream ARS was cloned in both orientations in positions upstream and downstream from the bacterial CAT gene under control of the herpes simplex virus thymidine kinase (tk) promoter. DNA-mediated transient transfection of these plasmids revealed a marked inhibition (79-82%) of CAT production by the ARS when it was cloned upstream from the tk promoter and in the same orientation as that found in the GPHalpha 5'-flanking DNA. Smaller decreases (29-57%) were produced by the ARS cloned upstream from the tk promoter in the reverse orientation. In marked contrast, the Alu repetitive element had little or no effect when cloned in either orientation downstream from the tk-CAT gene. Introduction of a second ARS downstream from the CAT reporter gene in vectors already containing an ARS upstream from the tk promoter significantly reduced the strong negative effect elicited by the upstream repetitive element. When compared to the Blur 8 Alu element, the GPHalpha upstream ARS differs markedly with respect to its effect on tk-CAT expression in transient assays and as a substrate for DNA binding proteins present in HeLa nuclear extracts. Together, the transient expression results demonstrate that ARS elements can influence expression of nearby class II promoters. The extent of this effect depends on element position and orientation, cell type, the particular ARS (e.g., GPHalpha or Blur 8), and whether copies were present both upstream and downstream from the transcription unit.

Involvement of thyrotroph embryonic factor in calcium-mediated regulation of gene expression

In the present study, we used an expression cloning strategy to identify transcription factors that bind specifically to a limited region of the inducible cAMP early repressor (ICER) promoter and regulate transcription. Murine thyrotroph embryonic factor (mTEF) was isolated and was shown to bind to a site located at nucleotides -117 to -108 from the transcriptional start site. Transient expression of reporter constructs containing either a consensus TEFRE or the icerTEF binding site demonstrated that TEF-dependent transcription correlated with relative binding affinities, i.e. the consensus TEFRE bound TEF more tightly and was more responsive to TEF than the icerTEFRE. Because the icerTEFRE overlapped a cAMP response element, the responsiveness of these sequences to either cAMP or Ca(2+) was tested. Although TEF expression had no effect on the cAMP-regulated transcriptional response of the ICER promoter, TEF did confer calcium responsiveness to these sequences. Calcium also modestly increased the TEF-mediated transcription from a consensus TEFRE. Additional studies using Ca(2+)-activated kinases indicate that Ca(2+)/TEF/TEFRE-regulated transcription may be mediated through Ca(2+)/calmodulin-dependent kinase (CaMK) IV. Moreover, studies with the icerTEFRE in a CaMK IV-deficient cell line demonstrated that these cells were transcriptionally unresponsive to thapsigargin; however, responsiveness was restored by co-expression of the active CaMK IV. These studies are the first to demonstrate that TEF is a calcium-responsive transcription factor, and they suggest that there are two classes of TEF-regulated genes. One class, represented by a consensus TEFRE, is regulated by TEF in the resting cell; the second class, represented by icerTEFRE, is regulated by TEF in the calcium-activated cell.

Characterisation of human melatonin mt(1) and MT(2) receptors by CRE-luciferase reporter assay

A cyclic AMP response element (CRE)-luciferase reporter gene assay was used to characterise the functional responses of human melatonin mt(1) and human melatonin MT(2) receptors, stably expressed in the human embryonic kidney cell line HEK293, to a series of six naphthalenic analogues of melatonin. By comparison to the observed melatonin-mediated inhibition of stimulated luciferase levels the naphthalenic series was identified as comprising agonists, partial agonists and one antagonist of melatonin mt(1) and melatonin MT(2) receptor function. Three of the agonist/partial agonist members of this series were also identified as displaying a functional selectivity for the melatonin MT(2) receptor. Competitive displacement of 2-[125I]iodomelatonin binding to the ovine pars tuberalis melatonin ML(1) receptor demonstrated a close correlation to the observed functional luciferase responses of the human melatonin mt(1) receptor. We conclude that the CRE-luciferase reporter gene assay provides an effective functional screening method for the pharmacological characterisation of human melatonin receptor subtypes.

AP-2 family members regulate basal and cAMP-induced expression of human chorionic gonadotropin

The AP-2 family of transcriptional regulator proteins has three members, alpha, beta and gamma. AP-2alpha and gamma are expressed in placenta and in the human trophoblast cell line JEG-3. AP-2 has been shown to regulate expression of the placental human chorionic gonado-tropin (hCG) alpha- and beta-subunit genes, however, previous work did not distinguish between the family members. Tryptic peptides of the AP-2 protein complexes purified from JEG-3 cells by oligo-affinity chromatography using the hCGalpha AP-2 site match the amino acid sequence of AP-2gamma. The fact that AP-2gamma is present at significant levels and binds the hCGalpha trophoblast-specific element suggests that AP-2gamma is at least part of the binding complex in vivo and plays a role in regulating hCG expression. We show that mutation of each of four AP-2 binding sites within the hCGbeta promoter decreases expression in transfection assays, demonstrating that all four sites are required for maximal expression in JEG-3 cells. Furthermore, we find differences in regulation of the family members: AP-2alpha mRNA levels increase in response to cAMP while AP-2gamma mRNA levels do not. The demonstrated importance of the AP-2 sites in controlling hCGalpha and beta expression and the likely involvement of more than one family member suggest that a balance in AP-2 proteins is involved in coordinate regulation of these genes. Moreover, many placenta-restricted genes are regulated by AP-2 proteins, thus members of this family may play an important overall role in placenta-specific expression.

A GCM motif protein is involved in placenta-specific expression of human aromatase gene

A new cis-element, trophoblast-specific element 2 (TSE2) is located in the placenta-specific enhancer of the human aromatase gene that dictates its tissue-specific expression. In the minimum enhancer region, an element similar to the trophoblast-specific element (TSE), originally described for the human chorionic gonadotropin alpha-subunit gene, also exists (Yamada, K., Harada, N., Honda, S., and Takagi, Y. (1995) J. Biol. Chem. 270, 25064-25069). The co-presence of TSE and TSE2 is required to direct trophoblast-specific expression driven by a heterologous thymidine kinase promoter. A 2562-base pair cDNA clone encoding a 436-amino acid protein that binds to TSE2 was isolated from a human placental cDNA library using a yeast one-hybrid system with the TSE2 as a reporter sequence. The protein was revealed to be identical to hGCMa, a mammalian homologue of the Drosophila GCM (glia cells missing) protein. Expression of hGCMa is restricted to the placenta. The protein also binds to PLE1 in the leptin promoter among other cis-elements reported to confer placenta-specific expression, suggesting that hGCMa is a placenta-specific transcription regulator, possibly involved in the expression of multiple placenta-specific genes.

The equine luteinizing hormone beta-subunit promoter contains two functional steroidogenic factor-1 response elements

The requirements for basal expression of the LH beta-subunit promoter in pituitary gonadotropes are largely unknown. We have used the equine (e) LHbeta subunit promoter as a model to unravel the combinatorial code required for gonadotrope expression. Through the use of 5'-deletion mutagenesis, a region between -185 and -100 of the eLHbeta promoter was shown to play a critical role in maintaining basal promoter activity in alphaT3-1 and LbetaT2 cells. This region encompasses the steroidogenic factor-1 (SF-1) binding site that has been reported to have a functional role in expression of the LHbeta promoter in other species. We have also identified an additional SF-1 site at -55 to -48. Binding of SF-1 to both sites was confirmed by electrophoretic mobility shift assays. Mutations within these sites, either individually or in combination, did not attenuate basal activity of the eLHbeta promoter in alphaT3-1 cells, but did diminish promoter activity in LbetaT2 cells. Interestingly, cotransfection with an expression vector encoding SF-1 induced eLHbeta promoter activity, and this induction was abrogated by mutations within the SF-1 sites in alphaT3-1 cells. Block replacement mutagenesis was performed on the -185/-100 region of the eLHbeta promoter to identify DNA response elements responsible for maintaining basal promoter activity. From this analysis, two regions emerged as being important: a distal 31-bp segment (-181 to -150) and an element located immediately 3' to the distal SF-1 site (-119 to -106). It is hypothesized that these two regions as well as the SF-1 sites represent regulatory elements that contribute to a combinatorial code involved in targeting expression of the eLHbeta promoter to gonadotropes.

Influence of a cap site element on tissue-restricted expression of the glycoprotein hormone alpha-subunit gene

Little is known of the transcriptional regulators important for expression of the glycoprotein hormone alpha-subunit (GPHalpha) gene in nonendocrine tumors, which secrete free alpha-subunit at an incidence of 25-80%. Consequently, attempts were made to define cis-regulatory elements and their cognate trans-acting factors that modulate promoter activity in epithelial cell types that do not normally express the glycoprotein hormones. DNA-mediated transient expression of promoter-reporter constructs was used to identify a novel negative regulatory element located at the GPHalpha gene transcription start site. Mutagenesis of this element produced a 2- to 10-fold increase in promoter activity, depending on the particular mutation and the transfected tumor cell line. Electrophoretic mobility shift analysis detected a protein that binds specifically to a DNA motif encompassing the cap site. It was present at different levels in a variety of cell types. Significantly, the degree to which activity of the wild-type promoter was suppressed relative to that of the mutant promoter was proportional to the level of cap site binding protein in the collection of cell lines examined. These results indicate that a negative regulatory element centered at the GPHalpha gene cap site and its cognate DNA-binding protein make a significant contribution to the production of alpha-subunit in a variety of tumor tissues. A detailed understanding of this cis/trans pair may further suggest a mechanism to explain, at least in part, how this gene becomes activated in nonendocrine tumors.

Functional analysis of the mouse ICER (Inducible cAMP Early Repressor) promoter: evidence for a protein that blocks calcium responsiveness of the CAREs (cAMP autoregulatory elements)

Although Ca2+ and cAMP mediate their effects through distinct pathways, both signals converge upon the phosphorylation of the cAMP response element (CRE) binding protein, CREB, thereby activating transcription of CRE-regulated genes. In WEHI7.2 thymocytes, cAMP increases the expression of the inducible cAMP early repressor (ICER) gene through CRE-like elements, known as cAMP autoregulatory elements (CAREs). Because Ca2+ -and cAMP-mediated transcription converge in WEHI7.2 thymocytes, we examined the effect of Ca2+ fluxes on the expression of the ICER gene in these cells. Despite the presence of multiple CAREs within its promoter, ICER gene transcription was not activated by Ca2+. Moreover, Ca2+ attenuated the stimulatory effect of cAMP on ICER expression. Transient expression of reporter constructs demonstrated that when these CAREs were placed in a different DNA promoter context, the elements became responsive to Ca2+. Detailed studies using chimeric promoter constructs to map the region responsible for blocking the transcriptional response to Ca2+ indicated that a small portion of the ICER promoter was necessary for the effect. Southwestern blot analysis identified a 83-kDa nuclear protein that bound specifically to that region. The relative binding activity of the factor to the ICER promoter and mutant promoter sequences correlated with an inhibition of Ca2+ -activated gene expression in WEHI7.2 cells. These data suggest that the factor functions as a putative Ca2+ -activated repressor of CREB/CRE-mediated transcription. Thus, depending on the surrounding context in which the CRE is located, CREs of individual genes can be regulated separately by Ca2+ and cAMP despite the convergence of these two signaling pathways.

An upstream regulator of the glycoprotein hormone alpha-subunit gene mediates pituitary cell type activation and repression by different mechanisms

Targeting of alpha-subunit gene expression within the pituitary is influenced by an upstream regulatory region that directs high level expression to thyrotropes and gonadotropes of transgenic mice. The same region also enhanced the activity of the proximal promoter in transfections of pituitary-derived alpha-TSH and alpha-T3 cells. We have localized the activating sequences to a 125-bp region that contains consensus sites for factors that also play a role in proximal promoter activity. Proteins present in alpha-TSH and alpha-T3 cells as well as those from GH3 somatotrope-derived cells interact with this region. The upstream area inhibited proximal alpha-promoter activity by 80% when transfected into GH3 cells. Repression in GH3 cells was mediated through a different mechanism than enhancement, as supported by the following evidence. Reversing the orientation of the area resulted in a loss of proximal promoter activation in alpha-TSH and alpha-T3 cells but did not relieve repression in GH3 cells. Mutation of proximal sites shown to be important for activation had no effect on repression. Finally, bidirectional deletional analysis revealed that multiple elements are involved in activation and repression and, together with the DNA binding studies, suggests that these processes may be mediated through closely juxtaposed or even overlapping elements, thus perhaps defining a new class of bifunctional gene regulatory sequence.

cAMP responsiveness of the bovine calpastatin gene promoter

Previous studies have shown that transcription of the gene encoding bovine calpastatin, an inhibitor of the calcium-activated cysteine protease calpain, is upregulated following activation of cAMP-dependent signaling pathways. In this study, deletion and site-directed mutagenesis experiments were performed to identify cis elements conferring cAMP responsiveness. Heterologous promoter assays demonstrated that all cAMP-responsive cis elements were located within -102 nucleotides (nt) of transcription initiation. Deletion of an element (GTCA) at nt +13 that is identical to half of the palindromic cAMP-responsive element (TGACGTCA) identified in other cAMP-responsive gene promoters had no effect on the response of the calpastatin promoter to dibutyryl-cAMP, although a 67% reduction in basal promoter activity was observed. In contrast, two point mutations in a cis element at nt -76 (GTCA to aTCt) abolished cAMP responsiveness. These results demonstrate that the calpastatin promoter sequence between nt -1653 and +130 contains a single cAMP-responsive element (GTCA) located at nt -76, and suggest a direct molecular pathway by which activation of cAMP signaling could lead to increased calpastatin gene transcription and reduction in calpain-mediated proteolysis.

Transcription factor AP-2gamma regulates murine adenosine deaminase gene expression during placental development

Trophoblast cells are specialized extra-embryonic cells present only in eutherian mammals. They play a major role in the implantation and placentation processes. To understand better the molecular mechanisms that control the development and function of trophoblast cells, we sought to identify the transcription factors that regulate murine adenosine deaminase (ADA) gene expression in the placenta. Here we report a detailed characterization of a placenta-specific footprinting region (FP1) in the Ada placental regulatory element. The sequence of FP1 was mapped by DNase I footprinting and was found to match a consensus AP-2 transcription factor-binding site. Electrophoretic mobility shift assays demonstrated that FP1 interacted with AP-2-like proteins. Further analysis using AP-2 antibody confirmed that AP-2 protein was indeed present in the placenta and bound to FP1. Mutation at the AP-2 site in FP1 abolished the ability of the Ada placental regulatory element to bind AP-2 proteins and failed to target chloramphenicol acetyltransferase reporter gene expression to placentas in transgenic mice, indicating that AP-2 is required for Ada expression in the placenta. In addition, RNase protection assays demonstrated that AP-2gamma was the predominant AP-2 family member expressed in the placenta. In situ hybridization analysis revealed that AP-2gamma expression was enriched in the trophoblast lineage throughout development, suggesting that AP-2gamma may be critical for trophoblast development and differentiation.

Functional map of a placenta-specific enhancer of the human leukemia inhibitory factor receptor gene

We recently reported a placenta-specific enhancer in the human leukemia inhibitory factor receptor (LIFR) gene and now show detailed characterization of the 226-base pair enhancer (-4625/-4400 nucleotides). Four of twenty-two mutants in linker analysis showed reduced promoter activities to 45, 30, 10, and 10%, respectively. Specific binding of region A (-4617/-4602) with nuclear extract was competed by a known Oct-1 oligo and supershifted by Oct-1 antibody. Specific binding of region B (-4549/-4535) was competed by a GATA oligo, but could not be supershifted by four GATA antibodies. Nevertheless, mutagenesis showed that critical bases in region B were identical to the GATA core motif, indicating that region B may bind to a novel GATA family transcription factor. The other two adjacent regions designated as region C (-4464/-4445) showed no known consensus binding sites, and their specific placental JEG-3 nuclear extract binding was not evident in nonplacental nuclear extracts and was not competed by a trophoblast specific element (TSE), indicating that region C is a novel placenta-specific element (PSE, CATTTCCTGAACTAGTTTTT). Footprinting localized the binding boundary of PSE-binding protein (PSEB), and three Gs were found to be important for specific PSE binding. UV cross-linking showed that PSEB had a molecular mass of approximately 160 kDa, substituting the PSE with two previously reported placenta elements TSE or chorionic somatomammotropin enhancer factor 1 (CSEF-1) motifs resulted in markedly different promoter activities, indicating that PSEB is indeed different from TSE binding protein or CSEF-1. These results are the first demonstration that a novel PSE is the major element for placenta-specific enhancer activity in human LIFR gene.

Characterization of a human-specific regulator of placental corticotropin-releasing hormone

The hypothalamic hormone CRH is also expressed in the placentas of humans and higher primates and may play an important role in the regulation of labor. In choriocarcinoma cell lines, activation of cAMP-dependent pathways increases human (h)CRH reporter gene expression. A cAMP-responsive region distinct from the cAMP response element at -220 bp, has been identified between -200 and -99 bp, and a candidate transcription factor was identified in nuclear extracts of human, but not rodent, choriocarcinoma cell lines. This region, which does not contain a canonical cAMP response element (CRE), transfers protein kinase A responsiveness to a heterologous promoter. Electromobility shift assays and methylation and uracil interference studies localized factor binding to a 20-bp region from -128 to -109 bp of the hCRH promoter. This 20-bp fragment exhibited a similar shift in nuclear extracts from both human term placenta and from human JEG-3 cells. Base contacts, identified in interference studies, were confirmed as critical for binding, as a mutation of these bases abolished factor binding. Furthermore, a CRH promoter containing this mutation exhibited a diminished response to forskolin. UV cross-linking demonstrated the protein in nuclear extracts from human, but not rodent, choriocarcinoma cell lines and estimated its size as 58 kDa. Although this factor participates in cAMP-regulated gene expression, competition electrophoretic mobility assays demonstrated that the factor does not bind to a CRE. Furthermore, neither anti-CREB nor anti-ATF2 antibodies alter factor binding. These data identify this 58-kDa protein as the human-specific CRH activator previously identified as a candidate factor contributing to the species-specific expression of CRH in human placenta.

Multiple characteristics of a pentameric regulatory array endow the human alpha-subunit glycoprotein hormone promoter with trophoblast specificity and maximal activity

Trophoblast-specific expression of the human alpha-subunit glycoprotein hormone gene requires a tightly linked array of five different regulatory elements [trophoblast-specific element (TSE), alpha-activating element (alphaACT), a tandem cAMP response element (CRE), junctional regulatory element (JRE), and a CCAAT box]. We examined their contextual contributions to trophoblast-specific expression by using transfection assays to evaluate activity of systematic block replacement mutations made within the 1500-bp 5'-flanking region of the human alpha-subunit gene. While all five elements were required for full activity, only the TSE and JRE displayed trophoblast specificity. Interestingly, the TSE-binding protein has limited tissue distribution whereas a JRE-binding protein appears trophoblast specific. Likewise, replacement studies with an AP-1 element that binds heterodimers of jun and fos indicated that this element was incapable of compensating for either the tandem CRE or JRE. This preference for both CRE- and JRE-binding proteins provides another avenue for configuring an alpha-subunit promoter with trophoblast specificity. Additional analysis with a cAMP response element binding protein (CREB)-Gal4 fusion protein further underscored the importance of CREB as well as suggested that transcriptional contributions come from both the DNA-binding domain and transactivation domain of this protein. We also examined the interactive nature of the pentameric array by placing a 15-bp random sequence between each element. Remarkably, only the insertion 3' of the CCAAT box diminished promoter activity. This suggested the absence of direct interactions between the transcriptional factors that bind each element in the array. It also suggested that the CCAAT box is position-dependent relative to the TATA box. This position dependence appeared cell-specific, as it was not manifest in a gonadotrope cell line (alphaT3-1 cells). Thus, the CCAAT box also has tissue-specific characteristics that assist in targeting expression of the alpha-subunit gene to trophoblasts. Together, these data suggest that multiple characteristics of a complex pentameric array of regulatory elements endow the alpha-subunit promoter with trophoblast specificity and maximal activity.

Silencing of the gene for the alpha-subunit of human chorionic gonadotropin by the embryonic transcription factor Oct-3/4

CG is required for maintenance of the corpus luteum during pregnancy in higher primates. As CG is a heterodimeric molecule, some form of coordinated control must be maintained over the transcription of its two subunit genes. We recently found that expression of human CG beta-subunit (hCGbeta) in JAr human choriocarcinoma cells was almost completely silenced by the embryonic transcription factor Oct-3/4, which bound to a unique ACAATAATCA octameric sequence in the hCGbeta gene promoter. Here we report that Oct-3/4 is also a potent inhibitor of hCG alpha-subunit (hCGalpha) expression in JAr cells. Oct-3/4 reduced human GH reporter expression from the -170 hCGalpha promoter in either the presence or absence of cAMP by about 70% in transient cotransfection assays, but had no effect on expression from either the -148 hCGalpha or the -99 hCGalpha promoter. Unexpectedly, no Oct-3/ 4-binding site was identified within the -170 to -148 region of the hCGalpha promoter, although one was found around position -115 by both methylation interference footprinting and electrophoretic mobility shift assays. Site-directed mutagenesis of this binding site destroyed the affinity of the promoter for Oct-3/4, but did not affect repression of the promoter. Therefore, inhibition of hCGalpha gene transcription by Oct-3/4 appears not to involve direct binding of this factor to the site responsible for silencing. When stably transfected into JAr cells, Oct-3/4 reduced the amounts of both endogenous hCGalpha mRNA and protein by 70-80%. Oct-3/4 is therefore capable of silencing both hCGalpha and hCGbeta gene expression. We suggest that as the trophoblast begins to form, reduction of Oct-3/4 expression permits the coordinated onset of transcription from the hCGalpha and hCGbeta genes.

Regulation of the human chorionic gonadotropin alpha- and beta-subunit promoters by AP-2

Production of the placental hormone, chorionic gonadotropin (CG), increases dramatically as cytotrophoblasts fuse to form syncytiotrophoblasts. The CG alpha- and beta-promoters are both responsive to cAMP, although the kinetics of cAMP stimulation are different. In an effort to understand the mechanisms of coordinate induction of these genes, AP-2 binding sites were identified in the promoter regions of the alpha and CGbeta genes. AP-2 bound to the upstream regulatory element (-186 to -156 base pairs (bp)) in the alpha-promoter and to several different regions of the CGbeta promoter, including footprints 2 and 4B (FP2, -311 to -279 bp; FP4B, 221 to -200 bp). AP-2 antibodies induced supershifts of these complexes, confirming the identity of the protein-DNA complex. In JEG-3 cells, which contain abundant AP-2, mutations in these CGbeta AP-2 sites reduced basal activity and decreased cAMP stimulation. In AP-2-deficient Hep-G2 cells, co-transfection of AP-2 stimulated expression of the CGbeta promoter 10-20-fold, and the alpha-promoter was induced by 3-6-fold. Mutations that eliminate AP-2 binding to CGbeta FP4B reduced AP-2 stimulation by more than 80%, whereas mutations in FP2 reduced AP-2 stimulation by less than 50%. Analyses of AP-2 mutants revealed a requirement for the DNA binding/dimerization domain and the amino-terminal proline-rich and acid-rich transactivation domains for stimulation of the CGbeta promoter. Primary cultures of placental cytotrophoblasts were differentiated into syncytiotrophoblasts in vitro to examine AP-2 expression by reverse transcriptase-polymerase chain reaction. AP-2 mRNA levels increased by day 2 and continued to rise in parallel with a marked increase in alpha and CGbeta gene expression. We conclude that both the alpha and CGbeta promoters contain binding sites for AP-2 and suggest that this transcription factor provides a mechanism for coordinating the induction of these genes during placental cell differentiation.

Crosstalk during Ca2+-, cAMP-, and glucocorticoid-induced gene expression in lymphocytes

In the WEHI7.2 thymoma cell line, cAMP, glucocorticoids, or increases in cytosolic Ca2+ concentration lead to cell death by apoptosis. In the present study, we examined the effects of these compounds on cAMP response element (CRE)-mediated gene expression. Thapsigargin and A23187 were employed to increase cytosolic Ca2+ levels and induce apoptosis. Both compounds enhanced transcription from a CRE preceding apoptotic death. Moreover, the transcriptional response to the combination of forskolin and either thapsigargin or A23187 was synergistic mirroring the effect on cell death. Importantly, dexamethasone treatment, which causes an efflux of Ca2+ from the ER, induced transcription from a CRE alone or in synergy with forskolin. The increase in CRE-controlled gene expression correlated with a decrease in cell viability. Following treatment with forskolin, thapsigargin, or dexamethasone, the CRE binding protein (CREB) was phosphorylated at levels correlating with the level of induced gene expression. These data suggest that transcriptional crosstalk between independent signaling pathways occurs in lymphocytes, and CREB may play a central role in the mediation of CRE-dependent transcription by these diverse set of apoptotic agents.

The cAMP response elements of the alpha subunit gene bind similar proteins in trophoblasts and gonadotropes but have distinct functional sequence requirements

The alpha subunit gene encodes a common subunit shared by all glycoprotein hormones. This single copy gene is expressed in pituitary gonadotropes and thyrotropes of all mammals and in placental trophoblasts of primates and horses. Tandem cAMP response elements (CREs) in the promoter of the human gene are key mediators of this pattern of cell-specific expression. Replacing the palindromic CREs with non-primate variant CREs significantly attenuated activity in trophoblasts but not in gonadotropes. Furthermore, proteins binding the palindromic CRE cross-reacted with antibodies for CREB, CREM, ATF1, ATF2, and c-Jun, while proteins binding the variant CRE cross-reacted only with ATF2 and c-Jun antibodies. The data suggest that ATF2 and c-Jun can activate transcription through the CREs in gonadotropes but not in trophoblasts. Additional analyses indicated that while promoters with either palindromic or variant CREs have similar overall activity in gonadotropes, the variant CREs make a much smaller contribution to promoter activity than their palindromic counterparts. The weaker contribution of the variant CREs is compensated by the activity of two upstream elements present in the promoter. This compensation probably occurs through an indirect mechanism, as the binding affinity of proteins to the CRE is not influenced by the presence of these upstream elements.

The proximal 350 bp of 5'-flanking sequence of the human α-subunit glycoprotein hormone gene functions in the pituitary gland, but not the placenta, in transgenic mice

To understand better the minimal DNA sequence requirements for regulated expression of the human α-subunit glycoprotein hormone gene (Hα), two lines of transgenic mice were constructed that contained a fusion gene (Hα-350CAT) consisting of only 350 bp of 5'-flanking sequence of Hα linked to the bacterial gene encoding chloramphenicol acetyltransferase (CAT). CAT activity was detectable in pituitary, but not in brain, heart, kidney, liver, lung, pancreas, or spleen in transgenic mice. Gonadectomy increased (p<0.05) CAT activity in the pituitaries of males (6.5±1.4% conversion/μg protein; mean ± SEM) and females (14.5±4.2) compared to intact males (1.2±0.3) and females (6.7±1.0). In addition, administration of a GnRH antagonist (antide; 60 μg/injection; one injection every other day) for 10 d to gonadectomized animals decreased (p<0.05) CAT activity in males (3.5±0.8) and females (2.9±0.5) compared to gonadectomized animals that received saline. Antide also reduced (p<0.05) serum concentrations of luteinizing hormone in gonadectomized males and females compared to gonadectomized animals that received saline. Surprisingly, CAT activity in the placenta of Hα-350CAT transgenic mice was not detectable (<3 SD above the mean of CAT activity in placenta from nontransgenic mice;n=77). Thus, expression of the human α-subunit promoter in the placenta of transgenic mice appears to require DNA sequences upstream of the proximal 350 bp of 5'-flanking sequence, whereas the proximal 350 bp of the human α-subunit gene contains sufficient DNA sequence to target pituitary-specific expression and confer responsiveness to gonadal hormones and GnRH.

Selective constraints on the activation domain of transcription factor Pit-1

The POU transcription factor Pit-1 activates members of the prolactin/growth hormone gene family in specific endocrine cell types of the pituitary gland. Although Pit-1 is structurally conserved among vertebrate species, evolutionary changes in the pattern of Pit-1 RNA splicing have led to a notable "contraction" of the transactivation domain in the mammalian lineage, relative to Pit-1 in salmonid fish. By site-directed mutagenesis we demonstrate that two splice insertions in salmon Pit-1, called beta (29 aa) and gamma (33 aa), are critical for cooperative activation of the salmon prolactin gene. Paradoxically, Pit-1-dependent activation of the prolactin gene in rat is enhanced in the absence of the homologous beta-insert sequence. This apparent divergence in the mechanism of activation of prolactin genes by Pit-1 is target gene specific, as activation of rat and salmon growth hormone genes by Pit-1 splice variants is entirely conserved. Our data suggest that efficient activation of the prolactin gene in the vertebrate pituitary has significantly constrained the pattern of splicing within the Pit-1 transactivation domain. Rapid evolutionary divergence of prolactin gene function may have demanded changes in Pit-1/protein interactions to accommodate new patterns of transcriptional control by developmental or physiological factors.

Silencing of the gene for the beta subunit of human chorionic gonadotropin by the embryonic transcription factor Oct-3/4

The transcription factor Oct-3/4 may be important in maintaining embryonic cells in an undifferentiated state. It is probably down-regulated at about the time that human chorionic gonadotropin (hCG) is first expressed in embryonic trophectoderm. Here we report that Oct-3/4 strongly inhibits the hCGbeta subunit (hCGbeta) promoter in JAr choriocarcinoma cells. Oct-3/4 reduced chloramphenicol acetyltransferase (CAT) reporter expression from the -305hCGbeta promoter by about 90% in transient co-transfection assays, but had no effect on expression from the -249hCGbeta promoter. The -305/-249 hCGbeta fragment specifically bound synthetic Oct-3/4 protein as measured in electrophoretic mobility shift assays, and the Oct-3/4-binding site was localized around -270 by methylation interference footprinting. Site-directed mutagenesis of this binding site abolished Oct-3/4 repression. When stably transfected into JAr cells, Oct-3/4 reduced the amounts of both endogenous hCGbeta messenger RNA and hCG protein to less than 10% of controls. We suggest that silencing of Oct-3/4 in trophectoderm is a prerequisite for hCG up-regulation in early human embryos at the time of maternal recognition of pregnancy.

GATA factors are essential for activity of the neuron-specific enhancer of the gonadotropin-releasing hormone gene

The multicomponent neuron-specific enhancer of the gonadotropin-releasing hormone (GnRH) gene specifically targets expression to the GnRH-secreting neurons of the hypothalamus, a small population of specialized cells which play a central role in regulating reproductive function. Utilizing the GnRH-secreting hypothalamic neuronal cell line, GT1, as a model system, we show that members of the GATA family of transcription factors regulate GnRH transcription through two GATA factor-binding motifs that occur in a tandem repeat within the GnRH neuron-specific enhancer. Although GT1 cells contain GATA-2 and GATA-4 mRNAs, only GATA-4 was detected in a GnRH enhancer GATA site-specific complex. Cotransfection experiments with wild-type and mutant GnRH enhancer reporter plasmids with wild-type and dominant negative GATA factor expression vectors demonstrated that both GATA-binding elements are functional in the context of the enhancer. We conclude that GATA-binding proteins are important factors in regulating the neuron-specific expression of the GnRH gene in hypothalamic cells. Although the presence of GATA-2 in a neuronal cell type is not unusual, the presence of GATA-4 in GT1 cells is novel for a neuronal cell type. However, the presence of GATA-4 is consistent with the unique developmental origin of GnRH neurons and may provide insight into the transcriptional mechanisms mediating the differentiation of this limited population of GnRH-secreting neurons.

Different composite regulatory elements direct expression of the human alpha subunit gene to pituitary and placenta

To identify elements of the human alpha subunit gene necessary for cell-specific expression, we generated an array of block mutations spanning approximately 400 base pairs (bp) of promoter proximal region and examined them using transient transfection analysis in pituitary (alpha T3) and placental (BeWo) cell lines. Comparison of promoter activity in the two cell types revealed both common and unique elements required for transcription in pituitary and placenta. Two strong elements, the cyclic AMP response element (CRE) and the upstream regulatory element (URE), regulate expression of the alpha subunit gene in BeWo cells. In contrast, promoter activity in alpha T3 cells requires an array of weaker elements. These include the CREs, the URE, as well as two previously described elements, pituitary glycoprotein hormone basal element (PGBE) and gonadotrope-specific element (GSE), and two new elements we designated as the alpha basal elements 1 and 2 (alpha BE1 and alpha BE2). These new elements reside between -316 and -302 bp (alpha BE1) and -296 and -285 bp (alpha BE2) of the human alpha subunit promoter and bind distinct proteins designated alpha BP1 and alpha BP2, respectively. Southwestern blot analysis revealed that alpha BE1 specifically binds 54- and 56-kDa proteins. Additional studies disclosed several potential interactions between proteins that bind the CRE and proteins that occupy PGBE, alpha BE1, and alpha BE2, suggesting that gonadotrope-specific expression occurs through a unique composite regulatory element that includes components of the placenta-specific enhancer.

Regulation of placenta-specific expression of the aromatase cytochrome P-450 gene. Involvement of the trophoblast-specific element binding protein

The aromatase (cytochrome P-450AROM) gene contains multiple untranslated exons I that are differentially transcribed in a tissue-specific manner. DNA sequences within the initial -301 upstream of placenta-specific exon I (exon Ia) are sufficient for placenta-specific expression of aromatase. In gel mobility shift assay, three separate domains in this region form specific binding complexes with proteins extracted from choriocarcinoma JEG-3 nuclei. A fragment containing these domains activates transcription driven by a heterologous promoter in a cell type-specific manner. Two of the binding domains that form major complexes in gel shift assay compete with each other and with a DNA fragment containing the trophoblast-specific element (TSE), which is derived from the enhancer region of the human chorionic gonadotropin alpha-subunit gene and is believed to confer placenta-specific expression of the gene. The core sequence RNCCTNNRG is sufficient for recognition of the TSE-binding protein, which is detected only in nuclear extracts prepared from placenta and choriocarcinoma. A mutation introduced in the distal TSE core in aromatase promoter resulted in marked reduction of transcriptional activity, although TSE region by itself did not show enhancer activity as that in human chorionic gonadotropin alpha-subunit gene.

Studies on the structure and function of the carp gonadotropin alpha subunit by site-directed mutagenesis

There are two genes encoding the alpha subunit of carp gonadotropin (alpha 1 and alpha 2 subunits). Our previous data have demonstrated that both alpha 1 and alpha 2 subunits expressed in insect cells are able to associate with the beta subunit, but only the alpha 1/beta heterodimer displays biological activity. In the mature protein, there are only four amino-acid residues different between the alpha 1 and alpha 2 subunits. In this study we used site-directed mutagenesis and expressed different mutant alpha subunits in insect cells to identify which residue might be important for biological activity of the alpha subunit. Our results suggested that the change of Arg-71 to Gln-71 affected the activity of the carp gonadotropin alpha subunit.

GATA factor activity is required for the trophoblast-specific transcriptional regulation of the mouse placental lactogen I gene

The molecular determinants governing tissue-specific gene expression in the placenta are at present only poorly defined, particularly with respect to the regulation of specific hormone genes whose products are vital to embryonic development and the maintenance of a nurturing maternal environment. In continuing our analysis of the trophoblast-specific expression of the mouse placental lactogen I gene, we now demonstrate that the transcription factors GATA-2 and GATA-3 regulate the activity of this gene promoter. These factors are expressed in placental trophoblast cells, with peak levels of the GATA-2, GATA-3 and placental lactogen I mRNAs each accumulating at midgestation. Analysis of a region of the placental lactogen I gene promoter, previously shown to be sufficient for directing trophoblast-specific transcription, revealed the presence of three consensus binding sites for GATA-2 or GATA-3. Both GATA-2 and GATA-3 bind to these sites in vitro and mutation of these sites results in a significant decrease in promoter activity as assayed by transient transfection into the choriocarcinoma-derived cell line Rcho-1, which expresses endogenous GATA-2 and GATA-3. Furthermore, overexpression of GATA factors in Rcho-1 cells stimulates transcription from a co-transfected placental lactogen I gene promoter. Most significantly, expression of GATA-2 or GATA-3 was found to induce transcription from this promoter in transfected non-trophoblast (fibroblast) cells. These data indicate that GATA factors are both limiting and required transcriptional regulatory molecules in placental trophoblasts, and that the tissue specificity of the placental lactogen I gene is determined, at least in part, by GATA-2 and/or GATA-3.

GATA-binding proteins regulate the human gonadotropin alpha-subunit gene in the placenta and pituitary gland

The human glycoprotein hormone alpha-subunit gene is expressed in two quite dissimilar tissues, the placenta and anterior pituitary. Tissue-specific expression is determined by combinations of elements, some of which are common and others of which are specific to each tissue. In the placenta, a composite enhancer confers specific expression. It contains four protein-binding sites: two cyclic AMP (cAMP) response elements that bind CREB, a trophoblast-specific element that binds TSEB, and a sequence motif, AGATAA, that matches the consensus binding site for a family of transcription factors termed the GATA-binding proteins. In pituitary gonadotropes, the cAMP response elements remain important for expression, TSEB is absent, and elements further upstream participate in tissue-specific expression. Here we establish a regulatory role for the GATA element in both the placenta and pituitary by demonstrating that a mutation of this element decreases alpha-subunit gene expression 15-fold in JEG-3 human placental cells and 2.5-fold in alpha T3-1 mouse pituitary gonadotropes. In JEG-3 cells, human GATA-2 (hGATA-2) and hGATA-3 are highly expressed and both proteins bind to the alpha-subunit gene GATA element. In alpha T3-1 cells, the GATA motif is bound by mouse GATA-2 (mGATA-2) and an mGATA-4-related protein. Cotransfection of hGATA-2 or hGATA-3 into alpha T3-1 cells activates the alpha-subunit gene threefold. These studies establish a role for the GATA-binding proteins in placental and pituitary alpha-subunit gene expression, significantly expanding the known target genes of GATA-2, GATA-3, and perhaps GATA-4.

GATA-binding proteins regulate the human gonadotropin alpha-subunit gene in the placenta and pituitary gland

The human glycoprotein hormone alpha-subunit gene is expressed in two quite dissimilar tissues, the placenta and anterior pituitary. Tissue-specific expression is determined by combinations of elements, some of which are common and others of which are specific to each tissue. In the placenta, a composite enhancer confers specific expression. It contains four protein-binding sites: two cyclic AMP (cAMP) response elements that bind CREB, a trophoblast-specific element that binds TSEB, and a sequence motif, AGATAA, that matches the consensus binding site for a family of transcription factors termed the GATA-binding proteins. In pituitary gonadotropes, the cAMP response elements remain important for expression, TSEB is absent, and elements further upstream participate in tissue-specific expression. Here we establish a regulatory role for the GATA element in both the placenta and pituitary by demonstrating that a mutation of this element decreases alpha-subunit gene expression 15-fold in JEG-3 human placental cells and 2.5-fold in alpha T3-1 mouse pituitary gonadotropes. In JEG-3 cells, human GATA-2 (hGATA-2) and hGATA-3 are highly expressed and both proteins bind to the alpha-subunit gene GATA element. In alpha T3-1 cells, the GATA motif is bound by mouse GATA-2 (mGATA-2) and an mGATA-4-related protein. Cotransfection of hGATA-2 or hGATA-3 into alpha T3-1 cells activates the alpha-subunit gene threefold. These studies establish a role for the GATA-binding proteins in placental and pituitary alpha-subunit gene expression, significantly expanding the known target genes of GATA-2, GATA-3, and perhaps GATA-4.

Tissue-specific gene expression in the pituitary: the glycoprotein hormone alpha-subunit gene is regulated by a gonadotrope-specific protein

The molecular mechanisms for the development of multiple distinct endocrine cell types in the anterior pituitary have been an area of intensive investigation. Though the homeodomain protein Pit-1/GHF-1 is known to be involved in differentiation of the somatotrope and lactotrope lineages, which produce growth hormone and prolactin, respectively, little is known of the transcriptional regulators important for the gonadotrope cell lineage, which produces the glycoprotein hormones luteinizing hormone and follicle-stimulating hormone. Using transgenic mice and transfection into a novel gonadotrope lineage cell line, we have identified a regulatory element that confers gonadotrope-specific expression to the glycoprotein hormone alpha-subunit gene. A tissue-specific factor that binds to this element is purified and characterized as a 54-kDa protein which is present uniquely in cells of the gonadotrope lineage and is not Pit-1/GHF-1. The human and equine alpha-subunit genes are also expressed in placental cells. However, the previously characterized placental transcription factors designated TSEB and alpha-ACT are not found in the pituitary gonadotrope cells, indicating that independent mechanisms confer expression of these genes in the two different tissues.