Inhibition of human UGT2B7 gene expression in transgenic mice by the constitutive androstane receptor

The xenobiotic receptors, constitutive androstane receptor (CAR), and pregnane X receptor (PXR) regulate and alter the metabolism of xenobiotic substrates. Among the 19 functional UDP-glucuronosyltransferases (UGTs) in humans, UGT2B7 is involved in the metabolism of many structurally diverse xenobiotics and plays an important role in the clearance and detoxification of many therapeutic drugs. To examine whether this gene is regulated by CAR and PXR in vivo, transgenic mice expressing the entire UGT2B7 gene (TgUGT2B7) were created. Gene expression profiles revealed that UGT2B7 is differentially expressed in liver, kidney, adipocytes, brain, and estrogen-sensitive tissues, such as ovary and uterus. Liver UGT2B7 expression levels were decreased when TgUGT2B7 mice were treated with the CAR ligand 1,4-b-s-[2-(3,5,-dichloropyridyloxy)] (TCPOBOP) but not the PXR ligand pregnenolone 16α-carbonitrile. Although TCPOBOP decreased the levels of UGT2B7 mRNA in TgUGT2B7 mice, it had no affect on Tg(UGT2B7)Car(-/-) mice, adding support for a CAR-dependent mechanism contributing toward UGT2B7 gene suppression. Expression of promoter constructs in HepG2 cells showed the CAR-dependent inhibition was linked to hepatocyte nuclear factor-4α (HNF4α)-mediated transactivation of the UGT2B7 promoter. The inhibitory effect of CAR on UGT2B7 gene expression was validated in chromatin immunoprecipitation assays in which TCPOBOP treatment blocked HNF4α binding to the UGT2B7 promoter. These results suggest that HNF4α plays an important role in the constitutive expression of hepatic UGT2B7, and CAR acts as a negative regulator by interfering with HNF4α binding activity.

Immortalized hypothalamic gonadotropin-releasing hormone neurons

The neuroendocrine hypothalamus has been intensively studied using whole animals and tissue slices. However, it has been difficult to approach questions at the molecular and cellular level. By targeting expression of the oncogene product, simian virus 40 T antigen, in transgenic mice using the regulatory domain of the rat gonadotropin-releasing hormone (GnRH) gene, we have produced specific hypothalamic tumours. These tumours have been cultured to produce clonal cell lines (GT-1 cells) that express T antigen, GnRH and many other neuronal markers, but do not express other hypothalamic hormones. These immortal cell lines have a distinctive neuronal phenotype, process the GnRH peptide accurately and secrete GnRH in a pulsatile pattern. Thus, by targeting oncogenesis to a defined population of neurons using the regulatory region of a gene that is expressed late in differentiation of that cell lineage, we have succeeded in immortalizing hypothalamic GnRH neurons. The GT-1 cell lines are an excellent model for future molecular, cell biological, physiological and biochemical investigations into the mechanisms involved in regulation of GnRH and the characteristics of an isolated central nervous system neuron. Their derivation demonstrates the utility of targeting tumorigenesis to specific differentiated neurons of the central nervous system in transgenic mice.

Cell-specific transcriptional regulation of follicle-stimulating hormone-beta by activin and gonadotropin-releasing hormone in the LbetaT2 pituitary gonadotrope cell model

FSH is secreted by gonadotropes of the anterior pituitary and plays a crucial role in mammalian reproduction. However, little is known about FSH gene regulation due to the lack of a gonadotrope cell line that synthesizes FSH. The LbetaT2 mouse pituitary cell line, isolated by targeted tumorigenesis in transgenic mice, has the characteristics of a mature gonadotrope, including expression of GnRH receptor, steroidogenic factor 1, and both the alpha- and beta-subunits of LH, but was thought not to express FSH. Using RT-PCR, we show that these cells synthesize FSH beta- subunit messenger RNA, which is induced by activin and inhibited by follistatin. Furthermore, in transient transfections an ovine FSHbeta 5'-regulatory region (5.5 kb) confers LbetaT2 cell-specific expression to a reporter gene compared with other pituitary and nonpituitary cell lines. This FSHbeta regulatory region responds to activin specifically in LbetaT2 cells, an effect that is blocked by follistatin. The LHbeta, alpha-subunit, and GnRH receptor regulatory regions are induced by activin and blocked by follistatin. Furthermore, LbetaT2 cells express the components of the activin system, and addition of follistatin alone reduces FSHbeta gene expression, demonstrating that an endogenous activin autocrine loop regulates FSH in these cells. In addition, GnRH stimulates both the FSHbeta and LHbeta regulatory regions, specifically in LbetaT2 cells. Surprisingly, GnRH induction is reduced by follistatin, suggesting its dependence on endogenous activin. As the mouse GnRH receptor promoter is inhibited by follistatin, reduction of GnRH receptor levels might be one mechanism by which follistatin interferes with GnRH induction of gonadotropin genes. In summary, LbetaT2 cells exhibit the characteristics of fully differentiated gonadotropes, including the expression of LH, FSH, GnRH receptor, and components of the activin/follistatin system, as well as display the appropriate responses to activin and GNRH:

Submandibular gland adenocarcinoma of intercalated duct origin in Smgb-Tag mice

A line of transgenic mice that develops submandibular gland adenocarcinoma of intercalated duct origin was established. In these mice, the oncogene SV40 T antigen (Tag) is expressed from the neonatal submandibular gland secretory protein b (Smgb) gene promoter. This hybrid gene directs expression of the oncoprotein to neonatal submandibular gland proacinar and terminal tubule cells and to intercalated ducts of the adult gland. Transgene expression resulted in duct luminal cell hyperplasia as early as 20 to 30 days postnatally, which progressed to dysplasia by 3 to 4 months of age. Marked dysplasia and in situ carcinoma were evident at 4 to 6 months of age. All histologic changes were more pronounced in males. Submandibular gland adenocarcinoma developed stochastically in more than half of the adult male mice by 12 months of age (average age: 10.8 months, range: 6 to 13.5 months). Tag expression persisted in in situ carcinoma and all tumors. Using a combination of immunocytochemical and ultrastructural criteria, submandibular gland dysplasia and tumors were found to originate from intercalated ducts. The dysplastic ducts and adenocarcinoma in Smgb-Tag mice were morphologically similar to previously reported Tag-induced dysplasias of striated ducts and granular convoluted tubules and a Tag-induced adenocarcinoma of striated duct origin. These findings demonstrate that salivary gland dysplasias and tumors of similar histologic appearance can arise from distinct differentiated cell types. Analysis of the molecular changes accompanying tumor formation in Smgb-Tag mice could increase knowledge of human salivary gland tumorigenesis.

Activation of translation in pituitary gonadotrope cells by gonadotropin-releasing hormone

The neuropeptide GnRH is a central regulator of mammalian reproductive function produced by a dispersed population of hypothalamic neurosecretory neurons. The principal action of GnRH is to regulate release of the gonadotropins, LH and FSH, by the gonadotrope cells of the anterior pituitary. Using a cultured cell model of mouse pituitary gonadotrope cells, alphaT3-1 cells, we present evidence that GnRH stimulation of alphaT3-1 cells results in an increase in cap-dependent mRNA translation. GnRH receptor activation results in increased protein synthesis through a regulator of mRNA translation initiation, eukaryotic translation initiation factor 4E-binding protein, known as 4EBP or PHAS (protein, heat, and acid stable). Although the GnRH receptor is a member of the rhodopsin-like family of G protein-linked receptors, we show that activation of translation proceeds through a signaling pathway previously described for receptor tyrosine kinases. Stimulation of translation by GnRH is protein kinase C and Ras dependent and sensitive to rapamycin. Furthermore, GnRH may also regulate the cell cycle in alphaT3-1 cells. The activation of a signaling pathway that regulates both protein synthesis and cell cycle suggests that GnRH may have a significant role in the maintenance of the pituitary gonadotrope population in addition to directing the release of gonadotropins.

Neuron-specific expression of the rat gonadotropin-releasing hormone gene is conferred by interactions of a defined promoter element with the enhancer in GT1-7 cells

Neuroendocrine control of the reproductive cascade is mediated by GnRH, which in mammals is produced by a subset of neurons scattered throughout the hypothalamus and forebrain. Utilizing a cultured cell model of GnRH neurons (GT1-7 cells), two regulatory regions in the rat GnRH 5' flanking DNA were identified as essential for cell-type specificity: a 300-bp enhancer and a 173-bp conserved proximal promoter. Using transient transfections to compare expression in GT1-7 cells to a non-GnRH-expressing cell type (NIH 3T3), we show that the GnRH enhancer and the proximal promoter each play roles in conferring this specificity. Deletion of footprint 2 (FP2; -26 to -76) from the promoter when coupled to the GnRH enhancer diminishes reporter activity in GT1-7 cells more strongly than in NIH 3T3 cells. Furthermore, deletion of FP2 from the promoter when coupled to the heterologous Rous sarcoma virus 5'-long terminal repeat promoter abolishes the difference in reporter activity between GT1-7 and NIH 3T3 cells, suggesting that FP2 of the GnRH promoter is necessary for cell-specific expression. In addition, FP2 alone is sufficient to confer cell-specific expression and can interact with the GnRH enhancer to augment reporter gene expression specifically in GT1-7 cells. Finally, a 31-bp sequence from within FP2 (-63 to -33) synergistically activates transcription when coupled with the GnRH enhancer in GT1-7 cells but not in NIH 3T3 cells. Thus, this 31-bp region contains elements necessary for interaction between the GnRH enhancer and promoter. We show that two of five protein complexes that bind to the -63 to -33 region are GT1-7 cell specific, and both of them appear to be homeodomain proteins. The identification of a cell-specific element in the GnRH proximal promoter significantly advances our understanding of the transcriptional basis for neuron-specific GnRH gene expression.

The Otx2 homeoprotein regulates expression from the gonadotropin-releasing hormone proximal promoter

The GnRH gene is expressed exclusively in a highly restricted population of approximately 800 neurons in the mediobasal hypothalamus in the mouse. The Otx2 homeoprotein has been shown to colocalize with GnRH in embryonic mouse brain. We have identified a highly conserved bicoid-related Otx target sequence within the proximal promoter region of the GnRH gene from several species. This element from the rat GnRH promoter binds baculovirus-expressed Otx2 protein and Otx2 protein in nuclear extracts of a hypothalamic GnRH-expressing neuronal cell line, GT1-7. Transient transfection assays indicate that the GnRH promoter Otx/bicoid site is required for specific expression of the GnRH gene in GT1-7 cells and that it can confer specificity to a neutral Rous sarcoma virus (RSV) promoter in GT1-7 cells but not in NIH3T3 cells. Overexpression of mouse Otx2 in GT1-7 cells induces expression of a GnRH promoter plasmid, an effect that is dependent upon the Otx binding site. Thus, the GnRH proximal promoter is regulated by the Otx2 homeoprotein. Finally, we have now demonstrated the presence of Otx2 protein in the GnRH neurons of the adult mouse hypothalamus. These data suggest that Otx2 is important in the development of the GnRH neuron and/or in the maintenance of GnRH expression in the adult mouse hypothalamus.

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.

Transcription factors Oct-1 and C/EBPbeta (CCAAT/enhancer-binding protein-beta) are involved in the glutamate/nitric oxide/cyclic-guanosine 5'-monophosphate-mediated repression of mediated repression of gonadotropin-releasing hormone gene expression

The physiological actions of nitric oxide (NO) as a signaling molecule in endothelial and brain cells and as a toxic molecule used by activated immune cells have been the focus of a wide range of studies. Nevertheless, the downstream effector molecules of this important neuromodulator are not well understood. We have previously demonstrated that expression of the gene for the reproductive neuropeptide, GnRH, is repressed by the glutamate/NO/cyclic GMP (cGMP) signal transduction pathway through cGMP-dependent protein kinase in the hypothalamic GnRH-secreting neuronal cell line GT1-7. This repression localized within a previously characterized 300-bp neuron-specific enhancer. Here, we find that mutation of either of two adjacent elements within the enhancer eliminates repression by this pathway. An AT-rich sequence located at -1695 has homology to the octamer motif known to bind POU-homeodomain proteins, while the adjacent element at -1676 has homology to the C/EBP (CCAAT/enhancer-binding protein) protein family consensus sequence. Antibody supershift assays reveal that one of the proteins bound at the -1695 sequence is Oct-1, and one of the proteins bound to the element at -1676 is C/EBPbeta. These two proteins can bind simultaneously to the adjacent -1695 and -1676 binding sites in vitro. In nuclear extracts of GT1-7 cells treated with an NO donor, the intensity of the Oct-1 complex is increased. However, although Western blot analysis indicates that neither Oct-1 nor C/EBPbeta protein levels are increased, the relative binding affinity of Oct-1 is increased. Dephosphorylation of the nuclear extracts decreases binding of the Oct-1 complex to the -1695 site only in NO donor-treated extracts. Thus, we conclude that Oct-1 and C/EBPbeta are both downstream transcriptional regulators involved in the repression of GnRH gene expression by the glutamate/NO/ cGMP signal transduction pathway.

Impaired adrenocorticotropin-adrenal axis in combined pituitary hormone deficiency caused by a two-base pair deletion (301-302delAG) in the prophet of Pit-1 gene

The Prophet of Pit-1 gene (PROP1) encodes a paired-like homeodomain protein, which is expressed early in pituitary gland development. When mutated, it is responsible for combined pituitary hormone deficiency (CPHD) in humans, as well as in Ames dwarf mice (df/df). Several independent mutations in the homeodomain of PROP1 have been identified as causative for the human CPHD phenotype, which has been characterized, thus far, as absence or low levels of GH, PRL, TSH, LH, and FSH. Here, we report 10 CPHD cases, 9 of which were born to consanguineous marriages occurring in a large family living in an isolated area in the Southeast of Brazil. All affected patients present complete absence of puberty and low GH, PRL, TSH, LH, and FSH associated with severe hypoplasia of the pituitary gland, as seen by MRI. All 3 exons of the PROP1 genes of these patients were sequenced. The 301-302delAG frameshift mutation was found in both alleles of each affected case. Surprisingly, we observed ACTH/cortisol insufficiency associated with the PROP1 phenotype. The patients' ages varied between 8 and 67 yr, and cortisol response impairment was identified in 5 of 6 of the older patients and in an 11-yr-old patient. Previous studies have not fully characterized patients at advanced ages, leading us to conclude that the phenotype of this PROP1 mutation includes late-onset adrenal insufficiency. We present an extensive clinical analysis of all of these patients. The presence of ACTH/cortisol deficiency in this family bearing the PROP1 301-302delAG mutation indicates the importance of a complete endocrine characterization and of life-long monitoring of PROP1 patients.

The insulin-like growth factor system in the GT1-7 GnRH neuronal cell line

Evidence suggests that insulin-like growth factors (IGFs; IGF-I and IGF-II) are involved in the regulation of reproductive function including the development of the gonadotropin-releasing hormone (GnRH) neuronal system and the modulation of GnRH secretory activities. To further characterize the regulatory role of the IGF system on GnRH neuronal function, we have examined the gene expression of IGF-I, IGF-II, IGF-I receptor (IGF-IR), and IGF-binding proteins (IGFBPs) in a GnRH neuronal cell line (GT1-7 cells). The relative effects of IGFs and insulin on GnRH secretion by these cells was also investigated. RT-PCR analysis demonstrated IGF-I, IGF-II and IGF-IR mRNAs in GT1-7 cells. The mRNAs for IGFBP-2, -3, -4, -5 and -6 but not IGFBP-1 were also detected. Immunoreactive protein bands for IGFBP-2, -4 and -5 but not for other IGFBPs were demonstrated by Western blot with IGFBP-5 appearing to be the most abundant IGFBP secreted by GT1-7 cells. IGFBP-5 production by GT1-7 cells was stimulated by both IGF-I and IGF-II in a dose-dependent manner with approximately equal potency, whereas insulin caused no significant effect. GnRH secretion by GT1-7 cells treated with IGF-I or IGF-II but not insulin showed an increase (80-100%) at 2 h of treatment followed by a decrease (46%) at 6 h that continued up to 24 h. We conclude that the expression of IGFs, IGF-IR and IGFBPs and their interactions in the regulation of GnRH secretion by GT1-7 cells as demonstrated by our study provide a basis for an autocrine regulatory role for the IGF system in GnRH neuronal secretory activities.

Activin A regulation of gonadotropin-releasing hormone synthesis and release in vitro

Activin is essential for the regulation of normal mammalian reproductive function at both the pituitary and gonadal levels. However, its central actions in the control of the hypothalamic-pituitary-gonadal axis remain largely unexplored. The present study aims to determine whether activin could regulate the reproductive axis at the level of the hypothalamus, through control of the GnRH neuroendocrine system. Using the GnRH-secreting GT1-7 neuronal cell line as a model system, we demonstrate expression of mRNAs encoding activin receptor types I, IB, and II. We examined the effects of activin A on GnRH protein secretion and mRNA levels in GT1-7 cells. Treatment with rh-activin A regulated both GnRH protein secretion and GnRH mRNA expression in the GT1-7 cells in a time-dependent fashion. Using transient transfection assays, we explored a potential transcriptional basis for these changes. Activin A increased reporter gene activity driven by minimal GnRH enhancer and promoter elements, suggesting that activin may regulate GnRH gene expression at the level of transcription. Lastly, activin A treatment of male rat hypothalami, in vitro, increased GnRH protein secretion. Collectively, molecular and physiological evidence support the presence of an activin system which might act at a hypothalamic site to regulate mammalian reproduction via activation of GnRH synthesis and release.

The thyrotropin beta-subunit gene is repressed by thyroid hormone in a novel thyrotrope cell line, mouse T alphaT1 cells

TSH is expressed in two populations of thyrotropes in the pituitary: one in the pars distalis and a second in the pars tuberalis. Pars distalis thyrotropes exhibit classical endocrine inhibition of TSH by thyroid hormone, whereas pars tuberalis thyrotropes do not. The majority of our understanding of TSH subunit gene regulation has come from studies conducted in dispersed pituitary, dispersed thyrotropic tumors, or the GH3 somatolactotrope cell line. However, the dispersed pituitary model is limited because of its inherent heterogeneity, thyrotropic tumors are difficult to grow and maintain, and the GH3 cells lack endogenous TSH expression. The recent derivation of a clonal thyrotrope cell line, T alphaT1, that expresses thyrotrope-specific markers, overcomes these limitations. However, because it was not possible to distinguish whether the tumor from which the T alphaT1 cells are derived originated in the pars distalis or the pars tuberalis, it was necessary to define their cellular origin and thereby establish their status as representative thyrotrope cells for future molecular studies. In this study, we demonstrate that the T alphaT1 cells express thyroid hormone receptors (beta1 and beta2) and their heterodimeric partner, retinoid X receptor-gamma. Treatment with T3 causes a dose- and time-dependent decrease in the expression of the TSH beta-subunit messenger RNA. In contrast to previous reports in rat pituitary cultures, T3 does not alter TSH beta-subunit messenger RNA stability in the T alphaT1 cells. Based on these data and the presence of thyrotrope-specific isoforms of the transcription factor Pit-1, we conclude that the T alphaT1 cells represent differentiated thyrotropes of the pars distalis and will be a useful model system for future analysis of the cis- and trans-acting factors necessary for thyrotrope-specific and thyroid hormone-regulated TSH gene expression.

Discrete stages of anterior pituitary differentiation recapitulated in immortalized cell lines

Targeted expression of oncogenes in transgenic mice can immortalize specific cell types to serve as valuable cultured model systems. Utilizing promoter regions from pituitary genes activated in the gonadotrope/thyrotrope lineage at discrete stages of development, we have demonstrated that targeted oncogene expression in transgenic mice can produce cell lines representing sequential stages of differentiation. Each cell line expresses a specific subset of the genes denoting differentiated function such as the subunits of the glycoprotein hormones, hormone receptors, and transcriptional regulatory proteins. These model systems have allowed detailed investigations into molecular and cellular mechanisms otherwise inaccessible in vivo or in complex primary pituitary cell cultures.

Expression of GATA-4 in migrating gonadotropin-releasing neurons of the developing mouse

The hypothalamic gonadotropin-releasing hormone (GnRH) neurons are important regulators of reproductive function. During development, these cells arise in the olfactory placode and migrate to the central nervous system, where they form a diffuse population of neurosecretory cells that mediate central nervous system control of reproduction. Little is known of the mechanisms regulating the differentiation of these cells. Studies of the transcriptional regulation of the GnRH gene have demonstrated the importance of the GATA family of zinc-finger transcription factors in gene expression. Although GATA factors are not highly expressed in mature GnRH-secreting neurons, we report that GATA-4 is highly expressed in migrating GnRH neurons in the developing mouse. We also report that a second DNA binding activity regulating GnRH gene expression at the site of GATA-factor action persists in mature hypothalamus and may also play a role in gene expression in the differentiated GnRH neuron.

The GnRH promoter: target of transcription factors, hormones, and signaling pathways

Gonadotropin-releasing hormone (GnRH) is essential for normal reproductive maturation and function. We present a review of the known mechanisms of hypothalamic GnRH transcriptional control through the conserved GnRH promoter. Understanding this promoter region will allow us to comprehend better the complexities of the hypothalamic pituitary-gonadal axis.

The basic helix-loop-helix, leucine zipper transcription factor, USF (upstream stimulatory factor), is a key regulator of SF-1 (steroidogenic factor-1) gene expression in pituitary gonadotrope and steroidogenic cells

Tissue-specific expression of the mammalian FTZ-F1 gene is essential for adrenal and gonadal development and sexual differentiation. The FTZ-F1 gene encodes an orphan nuclear receptor, termed SF-1 (steroidogenic factor-1) or Ad4BP, which is a primary transcriptional regulator of several hormone and steroidogenic enzyme genes that are critical for normal physiological function of the hypothalamic-pituitary-gonadal axis in reproduction. The objective of the current study is to understand the molecular mechanisms underlying transcriptional regulation of SF-1 gene expression in the pituitary. We have studied a series of deletion and point mutations in the SF-1 promoter region for transcriptional activity in alphaT3-1 and L/betaT2 (pituitary gonadotrope), CV-1, JEG-3, and Y1 (adrenocortical) cell lines. Our results indicate that maximal expression of the SF-1 promoter in all cell types requires an E box element at -82/-77. This E box sequence (CACGTG) is identical to the binding element for USF (upstream stimulatory factor), a member of the helix-loop-helix family of transcription factors. Studies of the SF-1 gene E box element using gel mobility shift and antibody supershift assays indicate that USF may be a key transcriptional regulator of SF-1 gene expression.

Oct-1 binds promoter elements required for transcription of the GnRH gene

The GnRH gene is exclusively expressed in a discrete population of neurons in the hypothalamus. The promoter-proximal 173 bp of the rat GnRH gene are highly conserved through evolution and are bound by multiple nuclear proteins found in the neuronal cell line, GT1-7, a model for the GnRH-expressing hypothalamic neuron. To explore the protein-DNA interactions that occur within this promoter and the role of these interactions in targeting GnRH gene expression, we have mutagenized individual binding sites in this region. Deoxyribonuclease I protection experiments reveal that footprint 2, a 51-bp sequence that confers a 20-fold induction of the GnRH gene, is comprised of at least three independent protein-binding sites. Transfections of the GnRH promoter-reporter plasmid containing a series of block mutations of footprint 2 into GT1-7 neurons indicate that each of the three putative component sites contributes to transcriptional activity. Mutations in footprint 4 also decrease GnRH gene expression. Footprint 4 and the promoter-proximal site in footprint 2 contain octamer-like motifs, an element that is also present in the neuron-specific enhancer of the rat GnRH gene located approximately 1.6 kb upstream of the promoter. Previous studies in our laboratory have demonstrated that two enhancer octamer sites are bound by the POU-homeodomain transcription factor Oct-1 in GT1-7 cells. We now show that Oct-1 binds the octamer motifs within footprints 2 and 4. Thus, Oct-1 plays a critical role in the regulation of GnRH transcription, binding functional elements in both the distal enhancer and the promoter-proximal conserved region.

Multiple factors interacting at the GATA sites of the gonadotropin-releasing hormone neuron-specific enhancer regulate gene expression

Neuron-specific expression of the GnRH gene is dependent on an upstream multicomponent enhancer. This enhancer is functional in a small population of GnRH-producing hypothalamic neurons which, through the secretion of GnRH, mediates central nervous system control of reproductive function. GnRH enhancer function requires activation by the GATA family of transcription factors that act through tandem consensus GATA-binding motifs, GATA-A and GATA-B. Here we show that two newly identified DNA-binding factors, termed GBF-A1/A2 and GBF-B1, bind the GnRH enhancer at sites overlapping the GATA factor-binding motifs. In vitro bindings of GATA, GBF-A1/A2, and GBF-B1 to the GnRH enhancer sequences are independent. Specific mutation of either the consensus GATA motif or the GBF-B1 site of GATA-B does not alter binding of the overlapping factor in vitro. Utilizing a GnRH-expressing neuronal cell line as a model system, we show by transient transfection that GBF-B1 is necessary for enhancer activity and independently activates the GnRH promoter. Transactivation of the GnRH enhancer in GT1 cells and in NIH 3T3 cells by GATA-4 is modulated by GBF-B1 binding, suggesting GBF-B1 interferes with GATA factor binding through a steric mechanism.

Immortalization of pituitary cells at discrete stages of development by directed oncogenesis in transgenic mice

Targeted expression of oncogenes in transgenic mice can immortalize specific cell types to serve as valuable cultured model systems. Utilizing promoter regions from a set of genes expressed at specific stages of differentiation in a given cell lineage, we demonstrate that targeted oncogenesis can produce cell lines representing sequential stages of development, in essence allowing both spatial and temporal immortalization. Our strategy was based on our production of a committed but immature pituitary gonadotrope cell line by directing expression of the oncogene SV40 T antigen using a gonadotrope-specific region of the human glycoprotein hormone alpha-subunit gene in transgenic mice. These cells synthesize alpha-subunit and gonadotropin-releasing hormone (GnRH) receptor, yet are not fully differentiated in that they do not synthesize the beta-subunits of luteinizing hormone (LH) or follicle-stimulating hormone (FSH). This observation lead to the hypothesis that targeting oncogenesis with promoters that are activated earlier or later in development might immortalize cells that were more primitive or more differentiated, respectively. To test this hypothesis, we used an LHbeta promoter to immortalize a cell that represents a subsequent stage of gonadotrope differentiation (expression of alpha-subunit, GnRH receptor, and LH beta-subunit but not FSH beta-subunit). Conversely, targeting oncogenesis with a longer fragment of the human alpha-subunit gene (which is activated earlier in development) resulted in the immortalization of a progenitor cell that is more primitive, expressing only the alpha-subunit gene. Interestingly, this transgene also immortalized cells of the thyrotrope lineage that express both alpha- and beta-subunits of thyroid-stimulating hormone and the transcription factor GHF-1 (Pit-1). Thus, targeted tumorigenesis immortalizes mammalian cells at specific stages of differentiation and allows the production of a series of cultured cell lines representing sequential stages of differentiation in a given cell lineage.

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.

The L beta T2 clonal gonadotrope: a model for single cell studies of endocrine cell secretion

We have used single gonadotropes from the newly derived line, LbetaT2, to investigate the modulation of Ca2+ signaling and exocytosis by the steroid hormone environment. This cell line, derived by targeted oncogenesis in transgenic mice, has recently been shown to secrete LH in response to GnRH. We have characterized the effects of both GnRH and membrane depolarization on exocytosis and intracellular [Ca2+] ([Ca2+]i) in individual LbetaT2 cells. GnRH (1-100 nM) evoked concentration-dependent increases in [Ca2+]i and secretion, as monitored by measurement of plasma membrane capacitance (Cm) using the whole-cell perforated-patch technique, and the extent of these changes were dependent upon steroid hormone background. GnRH treatment of cells cultured in medium containing charcoal-treated FBS (ct-FBS) showed smaller changes in [Ca2+]i than cells cultured in untreated FBS. However, when estradiol (E2) and dexamethasone (Dex) were added to the ct-FBS medium (E2/Dex-ct-FBS), the elevations in [Ca2+]i stimulated by GnRH increased almost 2-fold. Additionally, the rates of secretion in the E2/Dex-ct-FBS-cultured cells were greater than in either ct-FBS- or FBS-cultured cells. The increase in secretory response observed with E2/Dex-ct-FBS appeared to be due to both an increase in the peak [Ca2+]i stimulated by GnRH and a shift toward increased sensitivity of the Ca2+ dependency of exocytosis. In contrast to GnRH-evoked responses, the increases in [Ca2+]i elicited by depolarization were greater in cells cultured in ct-FBS than in E2/Dex-ct-FBS; however, the secretory rates were no different in the two groups. Likewise, there was no apparent effect of steroid treatment on the Ca2+ dependency of depolarization-evoked exocytosis. In summary, these results 1) clearly demonstrate the utility of this cell line for single-cell studies of both agonist- and depolarization-evoked secretion; 2) reveal that steroid hormone background has profound effects on LbetaT2 cells, both on stimulus-induced calcium mobilization and on the apparent Ca2+ -sensitivity of exocytosis; and 3) show that expression of the steroid hormone effect on Ca2+ -sensitivity is dependent upon receptor occupation by GnRH.

Steroid and pulsatile gonadotropin-releasing hormone (GnRH) regulation of luteinizing hormone and GnRH receptor in a novel gonadotrope cell line

Properties of a pituitary gonadotrope include the capacity to regulate gonadotropin synthesis and secretion in response to a GnRH signal. Progress in identifying the steps involved in these processes has been impeded by the lack of a homogeneous in vitro model of gonadotropes. This paper presents functional characterization of a L beta T2 gonadotrope cell line generated by tumorigenesis in transgenic mice carrying the rat LH beta-subunit regulatory region linked to the SV40 T-antigen oncogene. This cell line expresses LH beta, alpha-subunit, and GnRH-receptor (GnRH-R) mRNAs (though not FSH beta), responds to glucocorticoid treatment with a reversible dampening of proliferation, and responds to pulsatile, concentration-dependent GnRH administration with LH secretion. L beta T2 cells presented with four GnRH pulses (10 nM, 90-min interpulse interval) on each of 4 days respond with incremental increases in LH secretion on successive days. This increase was greatest (15-fold) in the presence of estradiol and dexamethasone. Part of the enhanced responsiveness is apparently due to an increase in GnRH-R; pulsatile GnRH treatment alone as well as steroid treatment alone led to an increase in GnRH-R mRNA levels. When secretion was stimulated on day 4 with 54 mM [K+] pulses, bypassing the GnRH-R, the LH-secretory response indicated that the GnRH pulse history as well as estradiol and dexamethasone have actions on L beta T2-secretory capacity distinct from changes in the GnRH-R. This increase can be explained in part by the marked up-regulation of LH beta, but not alpha-subunit, mRNA observed in GnRH-pulsed cells. In summary, L beta T2 clonal gonadotropes exhibit functional characteristics consistent with those of normal pituitary gonadotropes such as LH secretion via a regulated pathway and changes in GnRH-R and LH beta gene expression in response to signaling by GnRH and steroid hormones and therefore should be a useful tool for dissecting the cellular and molecular events involved in these fundamental gonadotrope properties.

NMDA and nitric oxide act through the cGMP signal transduction pathway to repress hypothalamic gonadotropin-releasing hormone gene expression

The key roles of the excitatory neurotransmitter glutamate and its second messengers, nitric oxide (NO) and cGMP, in long-term potentiation and neural plasticity are well documented. However, complex functions such as memory are likely to require long term changes in synaptic efficacy which require gene expression and protein synthesis. Here we demonstrate that the glutamate receptor agonist, N-methyl-D-aspartic acid (NMDA), nitric oxide (NO) and cGMP each repress expression of the gonadotropin-releasing hormone (GnRH) gene in the hypothalamic cell line, GT1. This repression is dependent upon signals from NMDA receptors activating NO synthase to synthesize NO. In turn NO induces guanylyl cyclase to synthesize cGMP, activating cGMP- dependent protein kinase. Repression requires elevation of calcium because it only occurs in the presence of calcium ionophore or with release of intracellular calcium. Repression also requires protein synthesis. Activation of this pathway specifically represses expression of a reporter gene containing the regulatory region of the GnRH gene in transfected GT1 cells, indicating that repression occurs at the transcriptional level. Furthermore the target for transcriptional repression is a 300 bp neuron-specific enhancer found 1.5 kb upstream of the GnRH gene which is sufficient to confer repression to a heterologous promoter. Thus the NMDA/NO/cGMP neurotransmitter signal transduction pathway controls not only synaptic function but also neuron-specific gene expression.

The POU homeodomain transcription factor Oct-1 is essential for activity of the gonadotropin-releasing hormone neuron-specific enhancer

The mechanisms of specification of gene expression in a complex tissue such as the brain remain poorly understood. To provide a model system for the study of gene regulation in a specific subpopulation of differentiated neurons, we have derived cell lines from tumors created in transgenic mice by targeting simian virus 40 T antigen expression by using the regulatory regions of the gene for gonadotropin-releasing hormone (GnRH), a decapeptide released from specialized neurons in the hypothalamus. Transfections into the cultured GnRH-secreting hypothalamic neuronal cell line GT1 have identified a neuron-specific enhancer, 1.5 kb upstream of the GnRH gene, which binds multiple GT1 nuclear proteins. In particular, one AT-rich protein-binding region, AT-a, is critical for enhancer activity. In this study, we used electrophoretic mobility shift assays to detect a GT1 nuclear protein complex that binds the AT-a region. Close inspection of the AT-a bottom-strand sequence revealed homology to the octamer motif, a sequence known to bind members of the POU homeodomain transcription factor family. Although we demonstrate expression of a number of POU homeodomain genes in GT1 cells, a supershift assay with Oct-1 antibody demonstrates that Oct-1 is the protein binding the enhancer. Finally, specific mutations in the AT-a region that affected Oct-1 binding were correlated with decreased transcription. Thus, Oct-1 binds to the GnRH enhancer in vitro, and this binding is critical to the transcriptional activity of this neuron-specific enhancer in GT1 cells.

Mechanism of action of gonadotropin-releasing hormone upon gonadotropin alpha-subunit mRNA levels in the alpha T3-1 cell line: role of Ca2+ and protein kinase C

Addition of [D-Trp6]gonadotropin-releasing hormone (GnRHa) to alpha T3-1 cells induced a very rapid response upon gonadotropin alpha-subunit mRNA which was detected after 30-60 min and was abolished by pretreatment with actinomycin D. A similar response was obtained with the protein kinase C (PKC) activator phorbol 12-myristate 13-acetate (PMA), or the Ca2+ ionophore, ionomycin. GnRHa (10 nM) also stimulated a secondary rise in alpha-subunit mRNA levels between 12 and 24 h of incubation. No additivity was obtained (at 60 min) upon the combined addition of GnRHa and PMA, GnRHa and ionomycin, or PMA and ionomycin. The effect of GnRHa upon alpha-subunit mRNA was blocked by the PKC inhibitors staurosporine or GF 109203X. Down-regulation of endogenous PKC activity resulted in inhibition of the stimulatory effect of gonadotropin-releasing hormone (GnRH), PMA and ionomycin. Removal of extra-cellular Ca2+ abolished the effect of GnRHa and PMA upon alpha-subunit mRNA levels. Interestingly PMA and ionomycin had no effect on alpha-subunit mRNA levels at 24 h of incubation; however, the combined addition of the drugs mimicked the late phase of GnRHa (10 nM) action. The data provide evidence that PKC and Ca2+ are involved in mediating the early and the late responses of GnRHa upon alpha-subunit mRNA elevation and that differential cross-talk exists between the messengers.

Regulation of gonadotropin-releasing hormone transcription by protein kinase C is mediated by evolutionarily conserved promoter-proximal elements

We previously demonstrated that down-regulation of protein kinase C (PKC) by prolonged 12-O-tetradecanoylphorbol-13-acetate (TPA) treatment leads to the specific repression of GnRH transcription in GT1-7 hypothalamic neurons. Here we have investigated the regulatory sequences and cognate DNA-binding proteins that mediate this transcriptional response. The promoter-proximal section of the GnRH gene contains an evolutionarily conserved sequence that is bound along its entire length by GT1-7 nuclear proteins in DNase I protection assays. Two distinct regions within this sequence are required for PKC regulation of the GnRH gene, as excision of either region results in loss of TPA repression of transcription. Excision of either of these regions also decreases basal transcription, demonstrating their role in GnRH promoter function. One region encompasses three AT-rich protein-binding sites; the other is an extended region of continuous DNase I protection, 50 nucleotides in length, that contains consensus recognition motifs for the CCAAT/EBP and helix-loop-helix families of transcription factors. Mobility shift analysis of binding to the latter region reveals that TPA treatment of GT1-7 neurons induces the formation of a specific DNA-protein complex with kinetics of appearance consistent with a role in repression of GnRH transcription. Thus, the sequences that mediate PKC regulation of GnRH are proximal to the promoter, evolutionarily conserved, and form TPA-inducible complexes with GT1-7 nuclear proteins.

A neuron-specific enhancer targets expression of the gonadotropin-releasing hormone gene to hypothalamic neurosecretory neurons

The molecular mechanisms specifying gene expression in individual neurons of the mammalian central nervous system have been difficult to study due to the cellular complexity of the brain and the absence of cultured model systems representing differentiated central nervous system neurons. We have developed clonal, differentiated, neuronal tumor cell lines of the hypothalamic GnRH-producing neurons by targeting tumorigenesis in transgenic mice. These cells (GT1 cells) provide a model system for molecular studies of GnRH gene regulation. Here we present the identification and characterization of a neuron-specific enhancer responsible for directing expression of the rat GnRH gene in GT1 hypothalamic neurons. This approximately 300 base pair (bp) upstream region (-1571 to -1863) confers enhancer activity to a short -173-bp GnRH promoter or to a heterologous promoter only in GT1 cells. The enhancer is bound by multiple GT1 nuclear proteins over its entire length. Deletion of more than 30 bp from either end dramatically reduces activity, and even large internal fragments carrying seven of the eight DNAse I-protected elements show decreased activity. Scanning replacement mutations demonstrate that several of the internal elements are required for activity of the enhancer. Thus, the GnRH gene is targeted to hypothalamic neurons by a complex multicomponent enhancer that relies on the interaction of multiple nuclear-protein binding enhancer elements.

Down-regulation of the gonadotropin-releasing hormone receptor messenger ribonucleic acid by activation of adenylyl cyclase in alpha T3-1 pituitary gonadotrope cells

Pituitary regulation of reproductive processes depends on the sensitivity of gonadotrope cells to both positive and negative regulators. Hypothalamic GnRH is the primary stimulus for gonadotropin synthesis and secretion. Therefore, the ability of the gonadotrope to respond to GnRH and the status of GnRH receptors (GnRH-R) are critical in the control of reproduction. In the present study, we address the role of GnRH and two second messenger activators, a phorbol ester (12-O-tetradecanoylphorbol-13-acetate) and forskolin, in the regulation of GnRH-R gene expression in the alpha T3-1 gonadotrope cell line. Using Northern blot analysis to monitor endogenous GnRH-R steady state messenger RNA (mRNA) levels, we found that although GnRH and 12-O-tetradecanoylphorbol-13-acetate do not change GnRH-R mRNA levels, forskolin causes a time-dependent decline. All three treatments stimulate glycoprotein alpha-subunit gene expression. To dissect the molecular mechanism of forskolin action on GnRH-R gene expression, de novo RNA synthesis was inhibited with the transcription inhibitor, actinomycin-D (act-D). Act-D alone does not change GnRH-R message levels. However, in the presence of both act-D and forskolin, GnRH-R mRNA levels decline dramatically. These data demonstrate that forskolin alters GnRH-R posttranscriptionally by destabilizing its mRNA. Our data do not, however, exclude possible direct transcriptional effects. This study suggests that activators of the protein kinase-A pathway may alter gonadotrope sensitivity to GnRH by decreasing GnRH-R gene expression and, therefore, indirectly affect reproductive status.

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.

The orphan nuclear receptor, steroidogenic factor-1, regulates the glycoprotein hormone alpha-subunit gene in pituitary gonadotropes

Tissue-specific expression of the glycoprotein hormone alpha-subunit gene in pituitary gonadotropes relies on a gonadotrope-specific element (GSE), which binds an approximately 54-kilodalton protein termed GSE-binding protein 1 (GSEB1). We report here that GSEB1 is the orphan nuclear receptor steroidogenic factor-1 (SF-1), which has been shown to be a primary regulator of steroidogenic enzymes in the adrenal gland and gonadal tissues. GSEB1 from alpha T3-1 pituitary gonadotrope cells and SF-1 from Y1 adrenocortical cells and R2C testicular Leydig cells display identical binding properties with both the GSE and SF-1 elements. Antiserum specific to the SF-1 DNA-binding domain abolishes the binding of both GSEB1 and SF-1 to both elements. SF-1 mRNA is found in the mouse pituitary and in the alpha T3-1 cell line but not in other pituitary cell lines, consistent with the pattern of GSEB 1-binding activity. The GSE element specifically enhances transcription in SF-1-containing cells. The discovery that an orphan nuclear receptor regulates the expression of both the gonadotropin hormones in the pituitary and the steroidogenic enzymes in the gonad provides a potential molecular mechanism for coordinate control in reproductive function, perhaps through an as yet unidentified endocrine ligand for SF-1.

The sequence of a murine cDNA encoding Ear-2, a nuclear orphan receptor

A 1643-bp cDNA that encodes the mouse Ear-2 orphan nuclear receptor has been isolated from a pituitary cell library. The predicted 389-aa mouse Ear-2 protein bears significant homology to the known human Ear-2 protein especially in the DNA-binding domain.

Coordinate control of the alpha- and beta-subunit genes of human chorionic gonadotropin by trophoblast-specific element-binding protein

The alpha- and beta-subunit genes of hCG are coordinately regulated in the trophectoderm of the early embryo and placenta. Placenta-specific expression of the alpha-subunit gene is determined by a composite enhancer made of three clustered components: cAMP-responsive elements, a GATA site, and the trophoblast-specific element (TSE). We have investigated the basis of placenta-specific expression of the major hCG beta-subunit gene, hCG beta 5. Enhancement of expression localizes to the region from -305 to -279, whereas full cAMP regulation requires the region from -305 to -249. Four DNAse-I footprints are present, three of which can be competed by the TSE element from the alpha-subunit gene. Methylation interference establishes that binding to the element located in the key region for expression, from -301 to -275, requires contacts with a CCNNNGGG core sequence that matches the alpha-subunit gene TSE. Sequence-specific DNA affinity chromatography using the alpha-subunit gene TSE allows purification of TSE-binding protein. This purified protein binds specifically to the key element, -301 to -275, and to at least two additional TSE elements clustered in the regulatory region of the hCG beta 5 gene. We conclude that both the alpha- and beta-subunit genes of hCG require the placenta-specific factor TSE-binding protein for expression, providing a mechanism for their coordinate regulation in placental cells.

Helix-loop-helix proteins are present and differentially expressed in different cell lines from the anterior pituitary

The basic-helix-loop-helix (bHLH) class of transcriptional activators, important in the establishment of many different cell lineages, share two important properties: the ability to heterodimerize with other members of this family and to bind DNA containing the loose consensus sequence CANNTG. This study takes advantage of these shared characteristics to begin to address whether or not bHLH proteins are present in pituitary cells. Gel-shift and Southwestern assays using an oligonucleotide containing a bHLH binding consensus sequence demonstrate that pituitary-specific proteins are present in extracts from adult pituitary tissue and pituitary cell lines and bind specifically to this sequence. Pituitary extracts were also found to contain several factors which interact with Id protein, a negative regulator of bHLH activity, in Far-Western assays of protein-protein interactions. Finally, messenger RNA for Id is present in pituitary cell lines but is absent in adult pituitary tissue. Together, these studies indicate that bHLH proteins are present in pituitary cells and their levels are differentially regulated in the separate cell types.

Expression of a retinoblastoma transgene results in dwarf mice

Introduction of the normal retinoblastoma gene (RB) into different tumor cells possessing inactivated RB genes suppresses their tumorigenicity in nude mice. These results suggest that RB replacement is a potential strategy for developing future clinical treatments of cancer. In a transgenic mouse model, we found that the quantity of RB protein in a given cell may play an important role in dictating its effect. Four founder mice containing 1-7 copies of a human RB cDNA transgene under the transcriptional control of the human RB promoter were generated. Most of the transgenic mice were smaller than nontransgenic littermates. This effect was found as early as embryonic day 15. The degree of dwarfism correlated roughly with the copy number of the transgene and the corresponding level of RB protein. The expression pattern of the transgene products was similar to that of the endogenous mouse RB gene with regard to tissue and temporal distribution. Transferring the transgene to RB deficient mice, which are nonviable, resulted in the development of normal, healthy mice, indicating that the human RB gene can functionally complement the mouse homolog. These studies demonstrate that the effect of RB on overall mouse development is closely dependent upon its dosage.

Regulation of gonadotropin-releasing hormone by protein kinase-A and -C in immortalized hypothalamic neurons

As major signal transduction cascades, the protein kinase-A and -C (PKA and PKC) pathways have been implicated in the regulation of GnRH synthesis and secretion in the hypothalamus. We have investigated the roles of these pathways in the regulation of GnRH transcription, mRNA levels, propeptide processing, and secretion in GT1-7 cells, a mouse hypothalamic GnRH neuronal cell line. Forskolin, which activates adenylate cyclase to raise cAMP levels, had no effect on GnRH mRNA levels at 10 microM, but induced c-fos mRNA at 30 min. An activator of PKC, 12-O-tetradecanoylphorbol-13-acetate (TPA; 100 nM), also induced c-fos at 30 min, but produced a progressive decline in GnRH mRNA, resulting in a 70% decrease by 16 h. Coadministration of 10 nM TPA and 20 microM of a PKC inhibitor, NPC 15437 [2,6-diamino-N-([1-(1-oxotridecyl)2-piperidinyl]methyl)hexanami de], prevented c-fos induction, but did not antagonize GnRH repression. Instead, the inhibitor itself reduced GnRH mRNA levels by 56% at 16 h (with no effect on c-fos mRNA). Thus, since extended exposure to TPA can down-regulate PKC, suppression of GnRH mRNA by TPA may be due to decreased PKC activity, indicating a role for PKC in the maintenance of the GnRH gene expression (a role that is unlikely to involve c-fos). In transient transfections, the transcriptional activity from 3 kilobases of GnRH 5'-flanking sequence was repressed 2-fold by either 100 nM TPA or 20 microM NPC 15437 at 24 h, demonstrating that suppression of GnRH mRNA is at least, in part, at the level of transcription. In contrast, both TPA (100 nM) and forskolin (10 microM) stimulated secretion. Enhancement of GnRH secretion by TPA was robust and rapid (2.5 min), while the response to forskolin was relatively delayed (2 h). Over a 24-h period, unstimulated cells released primarily unprocessed prohormone, whereas forskolin and TPA stimulated the secretion of processed products. These data indicate that PKC and PKA may influence propeptide processing and/or the route of GnRH secretion. These data demonstrate that the PKA and PKC pathways regulate GnRH at the multiple levels of transcription, pro-GnRH processing, and GnRH secretion.

GHF-1-promoter-targeted immortalization of a somatotropic progenitor cell results in dwarfism in transgenic mice

During pituitary development, the homeo domain protein GHF-1 is required for generation of somatotropes and lactotropes and for growth hormone (GH) and prolactin (PRL) gene expression. GHF-1 mRNA is detectable several days before the emergence of GH- or PRL-expressing cells, suggesting the existence of a somatotropic progenitor cell in which GHF-1 transcription is first activated. We have immortalized this cell type by using the GHF-1 regulatory region to target SV40 T-antigen (Tag) tumorigenesis in transgenic mice. The GHF-Tag transgene caused developmental entrapment of somatotropic progenitor cells that express GHF-1 but not GH or PRL, resulting in dwarfism. Immortalized cell lines derived from a transgenic pituitary tumor maintain the characteristics of the somato/lactotropic progenitor in that they express GHF-1 mRNA and protein yet fail to activate GH or PRL transcription. Using these cells, we identified an enhancer that activates GHF-1 transcription at this early stage of development yet is inactive in cells representing later developmental stages of the somatotropic lineage or in other cell types. These experiments not only demonstrate the potential for immortalization of developmental progenitor cells using the regulatory regions from cell type-specific transcription factor genes but illustrate the power of such model systems in the study of developmental control.

Neural tissue within anterior pituitary tumors generated by oncogene expression in transgenic mice

Pituitary tumorigenesis occurs in a transgenic line of mice, alpha-T7, which carries a hybrid transgene composed of the 5' flanking region of the human glycoprotein hormone alpha-subunit gene (1.8 kb) linked to the coding region of the SV40 T-antigen gene (alpha-Tag). Tumor foci were identified within the anterior pituitary of both male and female transgenic mice. In addition to a parenchyma with hypertrophied endocrine cells, mostly of the gonadotrope lineage, we here report the unexpected presence of neural tissue within the anterior pituitary, either as foci as large as 1.0 mm in diameter or greater, or in delicate bundles ramifying amongst the granulated parenchymal cells. Areas richest in neural tissue frequently were associated with tumor tissue composed of giant cells of three varieties, all with electron-lucent cytoplasm and similar organellar distribution including small secretory granules (80-160 nm diameter). In type I cells, the secretory granules were aligned at the plasma membrane; in type II cells, the secretory granules were distributed throughout the cytoplasm; type III cells formed colloid-filled follicles and their secretory granules rarely exceeded 100 nm diameter. These giant cells frequently had bizarre pleomorphic nuclei intensely immunopositive for T-antigen and cytoplasm which was lightly immunopositive for alpha-subunit, and immunopositive either for the LH-beta or TSH-beta subunits. Neural tissue contacted the normal granulated parenchymal cells directly, i.e., without a basal lamina or any connective tissue intervening, but only rarely formed synaptoid junctions with these granulated cells. Synaptoid junctions containing round, smooth vesicles, as well as dense core vesicles, were numerous between the neural processes themselves and between the neural tissue and the giant cells of the tumor tissue. These data suggest that in alpha-T7 transgenic mice the giant cells represent highly transformed gonadotropes or thyrotropes, and that a neurotrophic factor may be expressed by these transformed pituitary parenchymal cells.

Gonadotropin-releasing hormone-induced calcium signaling in clonal pituitary gonadotrophs

In agonist-stimulated clonal pituitary gonadotrophs (alpha T3-1 cells), cytoplasmic calcium ([Ca2+]i) exhibited rapid and prominent peak increases, followed by lower, but sustained, elevations for up to 15 min. The [Ca2+]i response to GnRH was rapidly inhibited by prior addition of a potent GnRH antagonist. In the absence of extracellular Ca2+ the initial peak [Ca2+]i response was only slightly decreased, but the prolonged increase in [Ca2+]i was abolished, indicating that the peak is derived largely from intracellular calcium mobilization and the sustained phase from Ca2+ influx. Application of the endoplasmic reticulum Ca(2+)-ATPase blocker thapsigargin caused progressive and dose-dependent elevation of [Ca2+]i and decreased the peak amplitude of the GnRH-induced Ca2+ response. On the other hand, addition of dihydropyridine calcium channel antagonists before or after GnRH treatment prevented or terminated the plateau phase, respectively, consistent with entry of Ca2+ through L-type voltage-sensitive Ca2+ channels (VSCC) as the major Ca2+ influx pathway during GnRH action. The presence of L-type VSCC in alpha T3-1 cells was further indicated by the ability of elevated extracellular K+ levels and the dihydropyridine calcium channel agonist Bay K 8644 to elevate [Ca2+]i in an extracellular calcium-dependent manner. These actions of depolarization and Bay K 8644 were inhibited by nifedipine, with an IC50 of 10 nM. High extracellular K(+)- and GnRH-induced Ca2+ entry was also attenuated by phorbol esters and permeant diacylglycerols, indicating that protein kinase-C exerts inhibitory modulation of VSCC activity. In contrast to normal pituitary gonadotrophs, in which GnRH induces a frequency-modulated oscillatory [Ca2+]i response, single alpha T3-1 cells exhibited a nonoscillatory amplitude-modulated signal during agonist stimulation. The [Ca2+]i responses observed in alpha T3-1 gonadotrophs indicate that the immortalized cells retain functional GnRH receptors and their coupling to the Ca2+ signaling pathway. Ca2+ influx through L-type channels maintains the plateau phase of the [Ca2+]i response during agonist stimulation and is inhibited by activation of protein kinase-C.

Cloning and functional expression of a mouse gonadotropin-releasing hormone receptor

GnRH plays a pivotal role in the reproductive system, and GnRH analogs have wide therapeutic applications ranging from the treatment of prostatic cancer to infertility. Determination of the predicted structure of the GnRH receptor (GnRHR) would illuminate the mechanisms of receptor activation and regulation and allow directed design of improved GnRH analogs. We report the cloning of a cDNA representing the mouse GnRHR and confirm its identity using Xenopus oocyte expression. Injection of sense RNA transcript leads to the expression of a functional, high affinity GnRHR. Expression of the GnRHR using gonadotrope cell line RNA, however, is blocked by an antisense oligonucleotide. In situ hybridization in the rat anterior pituitary reveals a characteristic GnRHR distribution. The nucleotide sequence encodes a 327-amino acid protein which has the seven putative transmembrane domains characteristic of G protein-coupled receptors, but which lacks a typical intracellular C-terminus. The unusual structure and novel potential regulatory domain of the GnRHR may explain unique aspects of its signal transduction and regulation.

Analysis of DNA sequences required for pituitary-specific expression of the glycoprotein hormone alpha-subunit gene

Transient transfection studies have been used to determine the DNA sequences of the glycoprotein hormone alpha-subunit gene that are required for tissue-specific expression. In the initial phase of these studies, a variant mouse alpha gene was identified which contains a fully palindromic cAMP response element (CRE). The corresponding region of a previously cloned and sequenced mouse alpha gene contains a single point mutation that disrupts the symmetrical nature of this element. DNase footprint studies demonstrate that the fully palindromic CRE binds the CRE-binding protein with much higher affinity than the imperfect palindrome. Transfection experiments using both mouse alpha gene variants demonstrate differences in basal and cAMP-induced expression. Studies of the cAMP response of the human alpha gene indicated that this gene contains sequences other than the known CRE that are sufficient to permit a transcriptional response to cAMP in both placental and pituitary cells. Expression of human and mouse alpha-subunit genes has been examined in cells of the gonadotrope, thyrotrope, and trophoblast lineages to identify DNA sequences that mediate selective transcription of the alpha gene in these cells. The results demonstrate that sequences between about -500 and -200 are important for expression in the pituitary, but not the placenta. Clustered point mutations were used to further characterize sequences required for expression in the pituitary. Two regions, one at positions -445 to -438 and one at positions -337 to -330, were required for expression in cells of the gonadotrope lineage. One of these regions, at -337 to -330, is also important for expression in thyrotropes. When linked to a minimal promoter, multiple copies of the -344 to -300 region had transcriptional enhancer activity in gonadotropes and thyrotropes, but not in several other cell types. These results are consistent with a model involving different combinations of regulatory elements that determine cell-specific alpha expression in gonadotropes and thyrotropes.

Intrinsic pulsatile secretory activity of immortalized luteinizing hormone-releasing hormone-secreting neurons

Mammalian reproduction is dependent upon intermittent delivery of luteinizing hormone-releasing hormone (LHRH) to the anterior pituitary. This mode of secretion is required to sensitize maximally the gonadotrophs to LHRH stimulation and to regulate gonadotropin gene expression. While LHRH secretion is pulsatile in nature, the origin of the pulse generator is unknown. In this report, we show that this oscillator could be located within the LHRH neuronal network. When immortalized LHRH neurons are placed into a perifusion system, LHRH is secreted into the medium in a pulsatile fashion under basal conditions. LHRH secretion and the number of LHRH pulses are reduced when calcium is removed from the medium. Perifusion also influences pro-LHRH processing, since the molar ratio of its processed products varies dramatically when the cells are transferred from a static system. Several different cellular mechanisms may underlie these changes in secretion and processing. Lucifer yellow experiments reveal that some cells are dye-coupled. Hence, these cells could be electrically coupled through gap junctions such that secretion from individual cells could be coordinated. Secretion could also be synchronized through the observed synapse-like contacts. These contacts could perform a negative-feedback role to regulate not only the amount of LHRH released but also the molecular forms secreted. The organization of LHRH neurons into interconnected clusters could serve to coordinate LHRH secretion from individual cells and, thereby, orchestrate functions in vivo as diverse as the onset of puberty, the timing of ovulation, and the duration of lactational infertility.

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.

Mutual cross-interference between glucocorticoid receptor and CREB inhibits transactivation in placental cells

Transcription of the glycoprotein hormone alpha-subunit gene in placental cells is repressed by glucocorticoids, an effect that is mediated through the glucocorticoid receptor (GR). Although the DNA-binding domain of GR has been shown to be important, mutation of the previously identified GR-binding sites in the alpha-subunit promoter fails to abolish repression. Furthermore, mutant receptors in which the DNA-binding specificity is converted to ERE binding or in which the first zinc finger is substituted with that from thyroid receptor remain fully inhibitory, indicating that specific DNA binding to the alpha-subunit gene is not important for repression. Inhibition by GR is only effective when the alpha-subunit promoter is activated by CREB, implicating CREB as the target for GR-mediated repression. Reciprocally, overexpression of CREB interferes with GR-mediated transcriptional activation of MMTV. This activity is not affected by the phosphorylation state of CREB. Despite the mutual cross-interference with activation of gene expression, GR and CREB do not appear to have a high-affinity protein:protein interaction in vitro. Nonetheless, GR and CREB may interact directly in vivo possibly through a third protein or, more likely, may sequester a mutually required target protein.

Activin-A modulates gonadotropin-releasing hormone secretion from a gonadotropin-releasing hormone-secreting neuronal cell line

The recent development of GnRH-secreting neuronal cell lines (GT1-1, GT1-3 and GT1-7 clones) has provided a model system for the study of the neural regulation of GnRH expression and secretion. We report here that activin-A stimulates GnRH secretion by GT1-7 cells in a dose-dependent manner, with an EC50 of approximately 2.5 ng/ml. The maximal response (50% stimulation) was achieved after 2 days of incubation with 20 ng/ml activin-A. Activin-A treatment increased total GnRH (secreted + cellular) in GT1-7 cells, possibly reflecting a stimulation of GnRH biosynthetic rates. The secretory effect of activin-A was also accompanied by a change in the cellular morphology to a more neuronal phenotype. The addition of TGF-beta (10 ng/ml), which is structurally related to activins, did not significantly increase secretion of GnRH by GT1-7 cells illustrating the specificity of the activin effect on this cell line. Although inhibin (20 ng/ml) alone did not directly affect the spontaneous secretion of GnRH, it was able to partially block the stimulatory effect of activin. The present study with the GT1-7 clonal cell line suggests that activin, and perhaps inhibin, might act at hypothalamic sites to regulate reproduction through the control of GnRH production and/or secretion.

Metabolism of pro-luteinizing hormone-releasing hormone in immortalized hypothalamic neurons

An immortalized hypothalamic neuronal cell line was recently developed by genetically targeting the expression of the simian virus-40 large T-antigen in LHRH neurons. These GT1 cells were subcloned to GT1-1, GT1-3, and GT1-7 cells, and they have been shown to express the mRNA for pro-LHRH and secrete LHRH-like immunoreactive (IR) materials into the media. The purpose of our study was to biochemically and immunologically characterize the IR materials within and secreted from these cells. Both LHRH- and GnRH-associated peptide (GAP)-like IR materials were present and were secreted from these four cell lines. Up to 3% of the total cellular protein was composed of LHRH and GAP materials. When materials from the cell lysate and media were separated according to mol wt (Mr), at least three different pro-LHRH species were detected. These precursors contained both LHRH- and GAP-like IR determinants, and they eluted in the void volume and at approximately 10,000-12,000 and 8,400-8,500 Mr. A material that contained GAP-like IR eluted at approximately 6,500-6,800 Mr. This species is probably mouse GAP-(1-56) because it eluted on a reverse phase column in the approximate position of rat GAP-(1-56). Cell lysates contained a single LHRH-like IR form which coeluted on a size-exclusion column with synthetic LHRH. This material stimulated secretion of LH from anterior pituitary cells in a dose-response manner. By comparison, two different molecular forms of LHRH were detected in media at approximately 1,500 and 540 Mr. HPLC analyses revealed these peaks to be heterogeneous and to contain at least (Gln1)LHRH-(Gly11,Lys12,Arg13), (Gln1)LHRH-(Gly1,Lys12), LHRH-(Gly11), and LHRH. These experiments demonstrate that the cells contain and secrete multiple molecular forms of the pro-LHRH and that processing of the prohormone must involve 1) cleavage by an endopeptidase to give GAP-(1-56) and a C-terminally extended LHRH, 2) removal of C-terminal basic amino acids by a carboxypeptidase, 3) amidation of LHRH-(Gly11) to LHRH, and 4) cyclization of glutamine to pyroglutamate at the N-terminal of LHRH. These results provide the first evidence for intermediates in the metabolic pathway of pro-LHRH to LHRH.

Morphological characterization of immortalized hypothalamic neurons synthesizing luteinizing hormone-releasing hormone

An immortalized LHRH cell line has recently been developed by genetically targeting these neurons for tumorigenesis. One of the subclones, the GT1-7 cells, was characterized at both the light and electron microscopic levels to study the cellular and subcellular organization of these cells, particularly as they relate to biosynthesis, processing, and secretion. The cells were fixed onto slides 18-36 h after plating. LHRH and GnRH-associated peptide (GAP) immunoreactivities (IR) were detected by immunocytochemistry using colloidal gold labeling. These cultured cells exhibited the classical neuronal appearance of LHRH neurons, and they established numerous interconnections. Neighboring neurons were coupled by tight junctions, while more distant cells were interconnected with neural axon-like processes and collaterals. This cellular organization is suggestive of a neural network where neuronal activity is coordinated. At the ultrastructural level, the nondividing cells possessed indented nuclei, well developed Golgi complexes, and abundant numbers of ribosomes and secretory granules. Clathrin-coated vesicles were found in fusion with the plasma membrane. The ribosomes and secretory vesicles were particularly prominent, suggestive of high rates of protein biosynthesis and secretion. All of the cells immunostained for both LHRH and GAP; however, GAP IR was always more pronounced than that for LHRH. This finding was corroborated by biochemical data reported in a companion paper. The GAP IR was associated with ribosomes and secretory vesicles. By comparison, LHRH IR was restricted mainly to the secretory vesicles. Using colloidal gold particles of different sizes to denote LHRH or GAP IR, it was determined that both GAP and LHRH IR were colocalized within the same secretory vesicle. Taken together, these data suggest that pro-LHRH is biosynthesized on the ribosomes, packaged as an intact protein into the secretory vesicles, processed to LHRH and GAP-(1-56) within these vesicles, and transported to the periphery of the cell in preparation for secretion. These morphological data emphasize the utility of using these immortalized LHRH neuronal cells to dissect the cellular and subcellular architecture involved in biosynthesis, processing, and secretion. In addition, our results provide the first detailed evidence for the intracellular pathway involved in pro-LHRH biosynthesis, processing, and secretion in these cultured neuronal cells.

Intracellular responses to gonadotropin-releasing hormone in a clonal cell line of the gonadotrope lineage

We recently derived a GnRH-responsive pituitary cell line of the gonadotrope lineage (alpha T3-1) by targeted oncogenesis in transgenic mice. Here, we report studies characterizing the GnRH receptors present in these cells and the intracellular responses to GnRH treatment. The receptors in alpha T3-1 cells show specificity for different GnRH analogs, with dissociation constants very similar to those found in normal rat and mouse pituitary. The concentration of receptors is within the range found in normal pituitary. The addition of GnRH or GnRH agonists increases phosphoinositide turnover and protein kinase-C translocation to membranes, and enhances activation of voltage-sensitive calcium channels. However, GnRH does not affect cAMP levels. Analysis of alpha-subunit mRNA levels demonstrated induction by GnRH and phorbol esters. Our results indicate that GnRH initiates a cascade of intracellular events that generate a set of second messengers, one or more of which is involved in the regulation of gene expression. The responses of alpha T3-1 cells to GnRH appear to have characteristics equivalent to those of primary pituitary gonadotropes, indicating the utility of this cell line as a model system for the study of GnRH responses.