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ABSTRACT

Three regions required for the expression of a mouse major urinary protein (MUP) transgene were identified by a deletion analysis. One of these was located upstream of the cap site between −2139 and −1800, another was the proximal promoter region downstream of −324 and the third lay within the 338 nucleotide intron 1. Both the proximal promoter and intron 1 are involved in sexually dimorphic expression of the transgene (male/female ratio 20), which is dictated by the different temporal profiles of circulating GH in the two sexes. The data also indicated that the region between exons 3 and 7 may contribute to full expression in males and that a region between −718 and −324 may contribute towards the low expression level that obtains in females, but compared with the three principal regions the effects of these regions are relatively minor. We propose (1) that full expression of the transgene requires the co-operation of transcription factors binding to the three principal regions and (2) that the difference in expression between the sexes relates to interactions between transcription factors bound to the proximal promoter and to sites in intron 1. Our results complement earlier in vitro footprinting and gel-retardation studies of the homologous rat α_2u-globulin genes. These identified a number of response elements, including putative C/EBP and AP1 sites in the proximal promoter and intron 1 respectively and three putative ΨNF-1 sites, two in the proximal promoter and one in intron 1, but proof of the functionality of these sites in regulating transcription was lacking. The proximal promoter also contained a 34 nucleotide sequence that has 70% identity with the SPI GH response element.

ABSTRACT

Hypogonadal (hpg) mutant mice, with a congenital deficiency of hypothalamic gonadotrophin-releasing hormone (GnRH), and testicular feminized (tfm) mice, which lack a functional androgen receptor, were used to study the effects of the potent GnRH agonist 'Zoladex' (ICI 118630; d-Ser (Bu^t)⁶, Azgly¹⁰-GnRH) on pituitary and gonadal function. Zoladex (0.5 mg) in a sustained-release lactide—glycolide copolymer depot was administered subcutaneously under anaesthesia and was left in place for 7 days, after which time the effects of the drug upon pituitary and serum gonadotrophin concentrations, glycoprotein hormone subunit mRNAs and testicular morphology were investigated.

At the pituitary level, Zoladex treatment resulted in a substantial reduction in LH content in normal males, and LH content was depressed in hpg mice even below the basal levels normally found in these mutants. Pituitary LH content in the Zoladex-treated animals was depressed in the tfm groups, but not to the same levels as those found in the normal and castrated normal mice. Zoladex treatment at the time of castration prevented the post-operative elevation in serum LH associated with castration alone. In the androgen-deficient tfm mouse, Zoladex did not depress the normally elevated serum LH levels. Serum LH in the hpg animals was, in all cases, below the limit of detection of the assay.

Pituitary FSH content was depressed into the hpg range in both the normal and castrated animals, but there was no further depression in the hpg mice. The pituitary content was reduced in the tfm mice, again the effects not being as dramatic as in the normal and castrated animals. Serum FSH content, as measured by radioimmunoassay, was depressed by 50% in normal mice; there was no reduction in the hpg mice, however.

With regard to pituitary gonadotrophic hormone gene expression, Zoladex administration to normal mice caused a dramatic reduction in LHβ mRNA content, to a level approximating that found in untreated hpg mice. The drug also depressed LHβ mRNA in the castrated group to the hpg range when given at the time of castration, whereas in untreated castrated mice there was a significant increase in LHβ mRNA. In the tfm mouse, which can be considered as a model for long-term failure of androgen feedback, Zoladex again induced a fall in LHβ mRNA, but not to the same extent as in the normal and normal castrated group. Zoladex had no effect on the already low levels of LHβ mRNA found in hpg mice.

Pituitary FSHβ mRNA levels were not significantly altered by Zoladex in any of the treatment groups, whereas the drug induced a substantial rise in the common α-subunit mRNA in normal and hpg mice, to a level equalling that found in castrated tfm mice. In the latter two groups, Zoladex treatment did not result in a further increase in α-subunit mRNA above that found after castration alone, or in the untreated tfm mutant.

Treatment for 7 days with Zoladex resulted in a significant increase in testis weight, with spermatogenesis advancing beyond the first meiotic division with many round spermatids found within the seminiferous tubules. However, the interstitial cells remained atrophic and there was evidence of seminal vesicle growth. Nevertheless, there was a small but significant increase in testicular androgen content. Administration of the agonist to hypophysectomized hpg mice did not stimulate testicular or seminal vesicle growth, suggesting that the drug does not stimulate steroidogenesis via a direct action upon the testis.

Overall, the pharmacological effects of the drug appear to have turned off the transcription of the LHβ gene, with a consequent reduction in LH synthesis and probably also secretion in the longer term. With FSHβ, gene transcription was apparently unchanged and, with a substantial increase in the common α-subunit message, it would appear that the pituitary gland of Zoladex-treated animals may be predominantly biased towards FSH secretion. Although the circulating FSH levels as measured by radioimmunoassay were unaltered by Zoladex, there are several reports that GnRH agonists increase serum levels of bioactive hormones, perhaps by altering glycosylation of the FSH dimer glycoprotein.