Expression of the high mobility group A family member p8 is essential to maintaining tumorigenic potential by promoting cell cycle dysregulation in LbetaT2 cells.

The mechanism by which the HMGA protein p8 facilitates tumorigenesis may be cell cycle dysregulation. Control- (C) LbetaT2 cells, which express p8, form tumors at a rate five-times faster than p8-knockdown (p8-KD)-LbetaT2 cells. In association with this heightened tumorigenic potential, p8-expressing C-LbetaT2 cells avoid G(0)/G(1) arrest and become genetically unstable while p8-KD-LbetaT2 cells arrest in G(0)/G(1), become senescent upon overgrowth, and maintain a diploid population. These phenotypic changes correspond to altered cell cycle regulation at the G(1)-to-S transition that may be due to p8-mediated changes in expression of the Cip/Kip family members of cell cycle inhibitors, p21, p27, and p57.

A single Pitx1 binding site is essential for activity of the LHbeta promoter in transgenic mice.

Reproduction depends on regulated expression of the LHbeta gene. Tandem copies of regulatory elements that bind early growth response protein 1 (Egr-1) and steroidogenic factor 1 (SF-1) are located in the proximal region of the LHbeta promoter and make essential contributions to its activity as well as mediate responsiveness to GNRH: Located between these tandem elements is a single site capable of binding the homeodomain protein Pitx1. From studies that employ overexpression paradigms performed in heterologous cell lines, it appears that Egr-1, SF-1, and Pitx1 interact cooperatively through a mechanism that does not require the binding of Pitx1 to its site. Since the physiological ramifications of these overexpression studies remain unclear, we reassessed the requirement for a Pitx1 element in the promoter of the LHbeta gene using homologous cell lines and transgenic mice, both of which obviate the need for overexpression of transcription factors. Our analysis indicated a striking requirement for the Pitx1 regulatory element. When assayed by transient transfection using a gonadotrope-derived cell line (LbetaT2), an LHbeta promoter construct harboring a mutant Pitx1 element displayed attenuated transcriptional activity but retained responsiveness to GNRH: In contrast, analysis of wild-type and mutant expression vectors in transgenic mice indicated that LHbeta promoter activity is completely dependent on the presence of a functional Pitx1 binding site. Indeed, the dependence on an intact Pitx1 binding site in transgenic mice is so strict that responsiveness to GnRH is also lost, suggesting that the mutant promoter is inactive. Collectively, our data reinforce the concept that activity of the LHbeta promoter is determined, in part, through highly cooperative interactions between SF-1, Egr-1, and Pitx1. While Egr-1 can be regarded as a key downstream effector of GnRH, and Pitx1 as a critical partner that activates SF-1, our data firmly establish that the Pitx1 element plays a vital role in permitting these functions to occur in vivo.

Chronic hypersecretion of luteinizing hormone in transgenic mice disrupts both ovarian and pituitary function, with some effects modified by the genetic background.

When the pituitary or hypothalamus becomes resistant to steroid negative feedback, a vicious cycle ensues, resulting in chronic hypersecretion of luteinizing hormone (LH) from the pituitary and steroids from the ovaries. In women, LH hypersecretion is implicated in infertility, miscarriages, and development of granulosa cell tumors. Progress in defining the underlying mechanisms of LH toxicity, however, has been limited by the lack of well-defined animal models. To that end, we have developed a new transgenic mouse model (alpha-LHbetaCTP) wherein LH hypersecretion occurs chronically and results in several dire pathological outcomes. Chronic hypersecretion of LH was achieved by introducing a transgene containing a bovine alpha subunit promoter fused to the coding region of a chimeric LHbeta subunit. The alpha subunit promoter directs transgene expression only to gonadotropes. The LHbeta chimera contains the carboxyl-terminal peptide (CTP) of the human chorionic gonadotropin beta subunit linked to the carboxyl terminus of bovine LHbeta. This carboxyl extension extends the half-life of LH heterodimers that contain the chimeric beta subunit. In intact alpha-LHbetaCTP females, serum LH is elevated five- to ten-fold in comparison to nontransgenic littermates. Levels of testosterone (T) and estradiol (E2) also are elevated, with an overall increase in the T-to-E2 ratio. These transgenic females enter puberty precociously but are anovulatory and display a prolonged luteal phase. Anovulation reflects the absence of gonadotropin-releasing hormone (GnRH) and the inability to produce a pre-ovulatory surge of LH. The ovaries are enlarged, with reduced numbers of primordial follicles and numerous, giant, hemorrhagic follicles. Despite the pathological appearance of the ovary, females can be superovulated and mated. Although pregnancy occurs, implantation is compromised due to defects in uterine receptivity. In addition, pregnancy fails at midgestation, reflecting a maternal defect presumably due to estrogen toxicity. When the transgene is in a CF-1 background, all females develop granulosa cell tumors and pituitary hyperplasia by five months of age. They die shortly thereafter due to bladder atony and subsequent kidney failure. When the transgene is placed in other strains of mice, their ovaries develop a luteoma rather than a granulosa cell tumor and the pituitary develops pituitary hyperplasia followed by adenoma. In summary, alpha-LHbetaCTP mice provide a direct association between abnormal secretion of LH and development of a number of ovarian and pituitary pathological responses.

An NF-Y binding site is important for basal, but not gonadotropin-releasing hormone-stimulated, expression of the luteinizing hormone beta subunit gene.

Regulated synthesis of luteinizing hormone (LH) requires coordinated transcriptional control of the alpha and LHbeta subunits in pituitary gonadotropes. Several cis-acting elements and trans-acting factors have been defined for control of the LHbeta promoter through heterologous cell culture models. In this report, we describe the identification of bipartite NF-Y (CBF/CP1) binding sites within the proximal bovine LHbeta promoter. When multimerized, one of these sites activates the heterologous, minimal HSV thymidine kinase promoter in the gonadotrope-derived cell line alphaT3-1. The functional role of the promoter-distal site in regulating the full-length bovine LHbeta promoter was assessed in vivo using transgenic mice harboring a mutant promoter linked to the chloramphenicol acetyltransferase reporter gene. While this element is important for conferring high level activity of the LHbeta promoter in pituitary, it does not appear to be essential for mediating gonadotropin-releasing hormone (GnRH) regulation. This is the first characterization of a cis-acting element within this GnRH-dependent promoter that is restricted to regulating basal expression and not GnRH-induced activity.

Responsiveness of the ovine gonadotropin-releasing hormone receptor gene to estradiol and gonadotropin-releasing hormone is not detectable in vitro but is revealed in transgenic mice.

Although the ability of estradiol to enhance pituitary sensitivity to GnRH is established, the underlying mechanism(s) remain undefined. Herein, we find that approximately 9,100 bp of 5' flanking region from the ovine GnRH receptor (oGnRHR) gene is devoid of transcriptional activity in gonadotrope-derived cell lines and is not responsive to either estradiol or GnRH. In stark contrast, this same 9,100 bp promoter fragment directed tissue-specific expression of luciferase in multiple lines of transgenic mice. To test for hormonal regulation of the 9,100-bp promoter, ovariectomized transgenic females were treated with a GnRH antiserum alone or in combination with estradiol. Treatment with antiserum alone reduced pituitary expression of luciferase by 80%. Pituitary expression of luciferase in animals receiving both antiserum and estradiol was approximately 50-fold higher than animals receiving antiserum alone. The estradiol response of the -9,100-bp promoter was equally demonstrable in males. In addition, a GnRH analog (D-Ala-6-GnRH) that does not cross-react with the GnRH antiserum restored pituitary expression of luciferase in males passively immunized against GnRH to levels not different from castrate controls. Finally, treatment with both estradiol and D-Ala-6-GnRH increased pituitary expression of luciferase to a level greater than the sum of the individual treatments suggesting synergistic activation of the transgene by these two hormones. Thus, despite the complete absence of transcriptional activity and hormonal responsiveness in vitro, 9,100 bp of proximal promoter from the oGnRHR gene is capable of directing tissue-specific expression and is robustly responsive to both GnRH and estradiol in transgenic mice. To begin to refine the functional boundaries of the critical cis-acting elements, we next constructed transgenic mice harboring a transgene consisting of 2,700 bp of 5' flanking region from the oGnRHR gene fused to luciferase. As with the -9,100 bp promoter, expression of luciferase in the -2,700 lines was primarily confined to the pituitary gland, brain and testes. Furthermore, the passive immunization-hormonal replacement paradigms described above revealed both GnRH and estradiol responsiveness of the -2,700-bp promoter. Thus, 2,700 bp of proximal promoter from the oGnRHR gene is sufficient for tissue-specific expression as well as GnRH and estradiol responsiveness. Given the inability to recapitulate estradiol regulation of GnRHR gene expression in vitro, transgenic mice may represent one of the few viable avenues for ultimately defining the molecular mechanisms underlying estradiol regulation of GnRHR gene expression.

Expression of a murine gonadotropin-releasing hormone receptor-luciferase fusion gene in transgenic mice is diminished by immunoneutralization of gonadotropin-releasing hormone.

A line of transgenic mice harboring a fusion gene consisting of 1900 bp of proximal 5'-flanking region from the murine GnRH receptor gene linked to the complementary DNA encoding luciferase was established to determine whether this promoter can direct tissue-specific expression in vivo and serve as a model for identifying the molecular mechanisms underlying hormonal regulation of this gene. Of 10 tissues screened, luciferase was detected predominantly in pituitary gland, but also in brain and testis. To assess hormonal regulation, luciferase activity was measured in intact males and ovariectomized females treated with an anti-GnRH serum alone, and in combination with testosterone or 17beta-estradiol. No effect of steroid treatment on transgene expression was detected. However, immunoneutralization of GnRH resulted in decreased serum LH concentrations and suppressed pituitary expression of luciferase. Furthermore, the effects of GnRH antiserum could be prevented by the administration of a noncross-reactive GnRH agonist. Thus, 1900 bp of 5'-flanking DNA from the murine GnRH receptor gene are sufficient to target luciferase expression in transgenic mice to established sites of GnRH receptor gene expression. Furthermore, we suggest that GnRH regulation of GnRH receptor gene expression is mediated by regulatory elements residing within 1900 bp of the 5'-flanking region.

Effects of ovariectomy and hypothalamic-pituitary disconnection on amounts of steroidogenic factor-1 mRNA in the ovine anterior pituitary gland.

Steroidogenic factor-1 (SF-1) is a transcription factor involved in regulation of steroidogenic enzymes. Recent evidence indicates that SF-1 is also important in the anterior pituitary gland, where it may influence gene expression in gonadotropes. We isolated a cDNA encoding ovine SF-1 and demonstrated that the SF-1 gene is expressed in the anterior pituitary gland of sheep. SF-1 transcripts and luteinizing hormone (LH) were colocalized in gonadotropes by in situ hybridization and immunohistochemistry, respectively. To test the hypothesis that GnRH stimulates pituitary expression of ovine SF-1 mRNA, ewes were ovariectomized to increase endogenous secretion of GnRH. Compared to ovary-intact ewes, ovariectomy resulted in three- and fourfold increases in steady-state amounts of mRNA encoding SF-1 and LH beta subunit, respectively. In ovariectomized ewes in which delivery of GnRH to the anterior pituitary gland was prevented by hypothalamic-pituitary disconnection (HPD), steady-state amounts of mRNA encoding SF-1 and LH beta-subunit were decreased. These results provide evidence that pituitary SF-1 gene expression in sheep is regulated by GnRH. Coordinate regulation of mRNAs encoding SF-1 and LH beta-subunit raises the possibility that SF-1 may be an important transcriptional regulator of LH beta-subunit gene expression in ovine gonadotropes.