Discrete cis-active genomic sequences dictate the pituitary cell type-specific expression of rat prolactin and growth hormone genes

The anterior pituitary gland, which is derived from a common primordium originating in Rathke's pouch, contains phenotypically distinct cell types, each of which express discrete trophic hormones: adrenocorticotropic hormone (ACTH), thyroid-stimulating hormone (TSH), prolactin, growth hormone, and follicle stimulating hormone (FSH)/luteinizing hormone (LH). The structurally related prolactin and growth hormone genes, which are evolutionarily derived from a single primordial gene, are expressed in discrete cell types--lactotrophs and somatotrophs, respectively--with their expression virtually limited to the pituitary gland. The pituitary hormones exhibit a temporal pattern of developmental expression with rat growth hormone and prolactin characteristically being the last hormones expressed. The reported co-expression of these two structurally related neuroendocrine genes within single cells prior to the appearance of mature lactotrophs, in a subpopulation of mature anterior pituitary cells, and in many pituitary adenomas raises the possibility that the prolactin and growth hormone genes are developmentally controlled by a common factor(s). We now report the identification and characterization of nucleotide sequences in the 5'-flanking regions of the rat prolactin and growth hormone genes, respectively, which act in a position- and orientation-independent fashion to transfer cell-specific expression to heterologous genes. At least one putative trans-acting factor required for the growth hormone genomic sequence to exert its effects is apparently different from those modulating the corresponding enhancer element(s) of the prolactin gene because a pituitary 'lactotroph' cell line producing prolactin but not growth hormone selectively fails to express fusion genes containing the growth hormone enhancer sequence.     

Transgenic mice with inducible dwarfism

The pituitary gland, composed of the anterior, intermediate and posterior lobe, represents a principal regulatory interface through which the central nervous system controls body physiology. The ontogeny of the growth hormone (GH) and prolactin (Prl) producing cells of the anterior pituitary has been analysed in transgenic mice, using the thymidine kinase obliteration system (TKO). Cells expressing the herpes virus 1 thymidine kinase (HSV1-TK) gene acquire pharmacological sensitivity to synthetic nucleosides such as FIAU (1-(2-deoxy-2-fluoro-beta-delta-arabinofuranosyl)-5-iodouracil), whose metabolites kill dividing cells. Consequently we created transgenic mice carrying the HSV1-TK gene under the control of either the rat growth hormone or the rat prolactin promoter. If transgenic mice expressing HSV1-TK in somatotropes (GH-producing cells) are treated with FIAU, they develop as dwarfs. The anterior pituitary in these animals is nearly devoid of both somatotropes and lactotropes (Prl-producing cells). By contrast, transgenic mice expressing HSV1-TK in the lactotropes, treated with FIAU, have anatomically and histologically normal pituitaries. Because toxicity depends on cell division, we conclude that Prl expression and lactotrope differentiation are post-mitotic events. These results indicate that both somatotropes and lactotropes derive from a common GH-expressing stem-somatotrope. Unexpectedly, the stemsomatotrope is still present in the adult animal and is capable of repopulating the pituitaries of treated animals with mature GH and Prl producing cells.     

Expression of human growth hormone-releasing factor in transgenic mice results in increased somatic growth

The neurohumoral regulation of growth hormone secretion is mediated in part by two hypothalamic peptides that reach the anterior pituitary via the hypothalamo-hypophysial portal blood system. Somatostatin inhibits the release of growth hormone, whereas growth hormone-releasing factor (GRF) positively regulates both growth hormone synthesis and secretion. Two forms of human GRF, 40 and 44 amino acids long, have been characterized from extra-hypothalamic tumours as well as from the hypothalamus. Analysis of human GRF complementary DNA and genomic clones indicates that the GRF peptides are first synthesized as a 107- or 108-amino-acid precursor protein. To examine the physiological consequences of GRF expression, we have established strains of transgenic mice containing a fusion gene including the promoter/regulatory region of the mouse metallothionein-I (MT-I) gene and the coding region of the human GRF gene. We report that expression of the human GRF precursor protein in these animals results in measurable levels of human GRF and increased levels of mouse growth hormone in plasma and accelerated growth rates relative to control littermates. These results demonstrate a direct role for GRF in the positive regulation of somatic growth. Unexpectedly, female transgenic mice carrying the MT-GRF fusion gene are fertile, in contrast to female transgenic mice expressing human or rat growth hormone, which are generally infertile. These transgenic mouse strains should provide useful animal models for the study of several types of human growth disorders.     

Changes in hypothalamic preproenkephalin A mRNA following stress and opiate withdrawal

The median eminence of the pituitary is rich in opioid receptors, and exogenous opioids have major effects on the release of adrenocorticotropic hormone (ACTH), luteinizing hormone (LH), prolactin, growth hormone (GH) and thyrotropin. Stress results in similar changes in anterior pituitary hormone secretion. Enkephalin immunoreactivity has been reported in the medial parvocellular neurons of the hypothalamic paraventricular nucleus which project to the median eminence, the site where hypothalamic releasing factors are secreted into the portal blood and thence to the anterior pituitary gland. The endocrine response to stressful stimuli might therefore, at least in part, be mediated through the activation of hypothalamic enkephalinergic neurons. We show that two stressful stimuli, opiate withdrawal and intraperitoneal injection of hypertonic saline, both result in very rapid and marked increases in enkephalin mRNA in the parvocellular paraventricular nucleus. The activation of hypothalamic enkephalin neurons may be important in the neuroendocrine response to stress.