Regulation of rat growth hormone receptor gene expression

A cDNA encoding the growth hormone (GH) receptor was cloned from rat liver. Both the nucleotide and translated amino acid sequence share greater than 70% similarity with the GH receptors from rabbit and human. An RNA probe was generated from this sequence for use in a solution hybridization assay to quantitate GH receptor mRNA expression in rat tissues. Expression was detected in 9/12 tissues examined, with the highest levels observed in the liver. Expression in liver, kidney, heart and muscle was developmentally regulated, being low at birth and rising to adult levels in 5 weeks. No difference was observed between hepatic expression in males and females, although livers from pregnant rats had elevated levels. Hypophysectomy and GH treatment did not affect hepatic GH receptor mRNA levels.     

Ovarian renin gene expression is regulated by follicle-stimulating hormone

The regulation of renin and renin messenger RNA (mRNA) in the rat ovary was examined to test the hypothesis that the expression of renin gene and the secretion of renin in the ovary is the estrogen-mediated process that responds to follicle-stimulating hormone (FSH). In the ovary of the immature 25-day female rats, the concentration of renin mRNA was comparatively low, but 36 h after injection of FSH, the renin mRNA content showed a three-fold increase compared to the basal level. This increase was consistent with the stimulation of the total renin concentration in the ovary. On the other hand, the total renin concentration in the rat uterus gradually decreased, suggesting that the enhancement of the contents of renin and renin mRNA by FSH is an ovary-specific phenomenon. In hypophysectomized rats, the total renin concentration in the rat ovary was stimulated by the estrogen as well as FSH. These findings suggest that the production of ovarian renin is regulated by the pituitary hormone, particularly FSH.     

Tissue-specific regulation of the expression of rat kallikrein gene family members by thyroid hormone.

We have altered the thyroid hormonal status of both male and female rats and examined the expression of six functional members of the rat kallikrein gene family (PS, S1, S2, S3, K1 and P1) in the submandibular gland (SMG), kidney, prostate, testis and anterior pituitary gland (AP) of these animals. On Northern-blot analysis with gene-specific oligonucleotide probes, the steady-state mRNA levels of S1, S2, S3, K1 and P1 were all dramatically altered in the SMG of male and female rats treated with propylthiouracil (PTU; 100 mg/litre of drinking water) or thyroxine (T4; 10 micrograms/100 mg body wt.) for 3 weeks. The SMG mRNA levels of these five genes were all lowered (30-90%) in hypothyroid (PTU-treated) male and female rats and elevated (1.4-4-fold, male; 1.5-11-fold, female) in the hyperthyroid (T4-treated) and PTU/T4-treated animals. In contrast, PS (true kallikrein) mRNA levels in the male or female SMG or kidney were essentially unchanged. K1 mRNA levels in the kidney were considerably less responsive to thyroid status than those in the SMG. Changes in S3 and P1 mRNA levels in the prostate were also variable, but essentially unaffected by these treatments. AP PS mRNA levels were also unaffected by changes in thyroid-hormonal status, as were levels of a novel P1-like mRNA in the testis. In summary, these studies demonstrate that the same kallikrein gene family member(s) may be differentially regulated by thyroid hormones in the rat SMG, kidney, prostate and pituitary, and thus further extend the concept of tissue-specific expression and hormonal regulation of the kallikrein gene family in the rat.     

The effects of 5-azacytidine on the expression of the rat growth hormone gene. Methylation modulates but does not control growth hormone gene activity

The role of DNA methylation in the expression of the rat growth hormone (rGH) gene was assessed by using a hypomethylating agent, 5-azacytidine, and the iso-schizomeric restriction enzymes MspI and HpaII. 5-Azacytidine increased rGH mRNA 3-8-fold in GH3D6 cells, a subclone of rat pituitary tumor cell lines that expresses one-tenth to one-fifteenth the GH expressed by two other clones, GH3 and GC. The effect was also detected at the level of pre-mRNA. The effect was independent of glucocorticoids and thyroid hormones and was found to be inheritable. The DNA methylation pattern generated by the isoschizomeric restriction enzymes indicated that the HpaII sites in the rGH gene were mostly methylated in GH3D6 cells but mostly unmethylated in GC cells. After treatment with 5-azacytidine, about 22% of these HpaII sites in GH3D6 cells became unmethylated. Thus, DNA methylation correlates inversely with the expression of the rGH gene in these cell lines. However, three other observations indicate that factors in addition to DNA methylation control rGH expression. First, in GC cells, even though most of the HpaII sites are unmethylated, the gene is not fully expressed. Second, in rat hepatoma cells, which do not express GH at all, the GH gene is less methylated than that in GH3D6 cells. Third, within the sensitivities of the assay methods, 5-azacytidine has no effect on the GH gene when it is completely silent. Taken together, the findings indicate that DNA methylation modulates but does not control GH gene expression. It is tempting to speculate that DNA methylation can influence expression only when the gene is committed to express.     

Effects of thyroid hormone deficiency and replacement on rat hypothalamic growth hormone (GH)-releasing hormone gene expression in vivo are mediated by GH

The role of thyroid hormone and GH in the regulation of hypothalamic GH-releasing hormone (GRH) gene expression in the rat was examined after the induction of thyroid hormone deficiency by thyroidectomy. Thyroidectomy resulted in a time-dependent decrease in hypothalamic GRH content, which was significant by 2 weeks postoperatively, and a reduction in pituitary GH content to 1% of the control level by 4 weeks. In contrast, GRH secretion by incubated hypothalami under both basal and K(+)-stimulated conditions was increased after thyroidectomy. Hypothalamic GRH mRNA levels also exhibited a time-dependent increase, which was significant at 1 week and maximal by 2 weeks after thyroidectomy. Administration of antirat GH serum to thyroidectomized rats resulted in a further increase in GRH mRNA levels. T4 treatment of thyroidectomized rats for 5 days, which also partially restored pituitary GH content, lowered the elevated GRH mRNA levels. However, comparable effects on GRH mRNA levels were observed by rat GH treatment alone. These results suggest that the changes in hypothalamic GRH gene expression after thyroidectomy in the rat are due to the GH deficiency caused by thyroidectomy, rather than a direct effect of thyroid hormone on the hypothalamus, since the changes were reversible by GH alone despite persistent thyroid hormone deficiency. In addition, they further support the role of GH as a physiological negative feedback regulator of GRH gene expression.