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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 Mice¹

Animal Reproduction and Biotechnology Laboratory (D.L.D., T.M.N., C.M.C.), Department of Physiology, Colorado State University, Fort Collins, Colorado 80523; Department of Pharmacology (C.C.Q.), Case Western Reserve University School of Medicine, Cleveland, Ohio 44106; USDA-CSREES-NRI (D.L.H.), Washington, DC 200250–2241

Address all correspondence and requests for reprints to: Colin M. Clay, ARBL-Foothills Campus, Colorado State University, Fort Collins, Colorado 80523. E-mail: cclay{at}cvmbs.colostate.edu

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.

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