Acromegaly is characterized by coarsening of facial features, acanthosis nigricans, hypertrichosis and oily skin. To determine the site through which GH exerts these effects, we have used immunohistochemistry to localize the GH receptor/binding protein (BP) in rat, rabbit and human skin. Three monoclonal antibodies (MAb 1, 43, 263) were immunoreactive in identical locations, whereas no immunoreactivity was evident when control monoclonal antibodies (MAb 50.8 and MAb 7 (rat] were used. Skin from neonatal and adult animals was used to determine whether GH receptor/BP expression was developmentally regulated. Immunoreactivity of the GH receptor/BP in the three species was consistently localized in the stratum basale and stratum spinosum. Intermittent staining was observed in the stratum granulosum. Scattered basal epidermal cells often displayed more intense immunoreactivity. This distribution was observed at all maturational stages examined. Intense GH receptor/BP immunoreactivity was observed in all histological layers of the lower one-third of hair follicles and in hair matrix cells of the dermal papillae. Immunoreactivity was also detected in the outer epithelial root sheath of the upper two-thirds of hair follicles, in sebaceous glands and in fibroblasts of the connective tissue sheath surrounding the follicle. GH receptor/BP immunoreactivity was also present in the secretory duct and myoepithelial cells of human eccrine sweat glands. Fibroblasts, Schwann cells of peripheral nerve fascicles, skeletal muscle cells and adipocytes of the dermis were also immunoreactive as were medial smooth muscle and endothelial cells of arteries. These results provide evidence that GH acts locally on the epidermis and epidermal appendages concordant with our recent localization of GH receptor/BP to epithelial cell types of the gastrointestinal and reproductive systems.
1. The growth hormone (GH) receptor was the first of the class 1 cytokine receptors to be cloned. It shares a number of structural characteristics with other family members and common signalling mechanisms based on common usage of the Janus kinase 2 (JAK2). 2. Growth hormone receptor activation is initiated by GH-induced homodimerization of receptor molecules. This has enabled the creation of specific hormone antagonists that block receptor dimerization. 3. The details of the transcription factors used by the activated receptor are being revealed as a result of promoter analyses and electrophoretic mobility gelshift analysis. 4. Growth hormone receptors are widespread and their discovery in certain tissues has led to the assignment of new physiological roles for GH. Some of these involve local or paracrine roles for GH, as befits its cytokine status. 5. Four examples of such novel roles are discussed. These are: (i) the brain GH axis; (ii) GH and the vitamin B12 axis; (iii) GH in early pre-implantation development; and (iv) GH in development of the tooth. 6. We propose that the view that GH acts through the intermediacy of insulin-like growth factor-1 is simplistic; rather, GH acts to induce an array of growth factors and their receptors and the composition of this array varies with tissue type and, probably, stage of development.
We have demonstrated and localized human GH (hGH) gene expression in surgical specimens of normal human mammary gland and in proliferative disorders of the mammary gland of increasing severity using sensitive in situ RT-PCR methodology. hGH mRNA identical to pituitary hGH mRNA was first detected by RT-PCR of RNA derived from samples of normal human mammary gland. Cellular localization of hGH gene expression in the normal mammary gland exhibited restriction to luminal epithelial and myoepithelial cells of the ducts and to scattered stromal fibroblasts. We subsequently examined the expression of the hGH gene in three progressive proliferative disorders of the human mammary gland, i.e. a benign lesion (fibroadenoma), a pre-invasive stage (intraductal carcinoma) and an invasive ductal carcinoma. hGH mRNA was readily detected in the tumoral and nontumoral epithelial components and also in cells of the reactive stroma including fibroblasts, myofibroblastic and myoepithelial cells, inflammatory infiltrate lymphocytes and endothelial cells in areas of neovascularization. In all three proliferative disorders examined, the intensity of the cellular labeling observed in both the epithelial and stromal compartments was always stronger compared with that in adjacent normal tissue. hGH protein was also present in significantly higher concentration in extracts derived from proliferative disorders of the mammary gland compared with extracts derived from normal mammary gland. We also examined hGH gene expression in axillary lymph nodes not containing and containing metastatic mammary carcinoma. hGH gene expression was evidenced in metastatic mammary carcinoma cells and in reactive stromal cells by both in situ hybridization and in situ RT-PCR. In contrast, in lymph nodes not containing metastatic mammary carcinoma, hGH mRNA was detected only by use of in situ RT-PCR. Thus, increased expression of the hGH gene in the epithelial component and the de novo stromal expression in proliferative disorders of the mammary gland are suggestive of a pivotal role for autocrine hGH in neoplastic progression of the mammary gland.
In the rat a GH-binding protein (GHBP) exists that is derived from the GH receptor gene by an alternative messenger RNA splicing mechanism such that the transmembrane and intracellular domains of the GH receptor are replaced by a hydrophilic carboxy terminus. Previous immunohistochemical studies detailing the localization of the GH receptor binding protein (BP) have used monoclonal antibodies that recognize extracellular region-specific epitopes common to both the GH receptor and GHBP. In this study we have used a monoclonal antibody (MAb 4.3) specific for the carboxy terminus of the rat GHBP to map its somatic distribution in the rat and have compared this distribution with that of a MAb recognizing both the BP and the GH receptor. A variety of tissues including the skeletal and muscular systems, the gastrointestinal tract and derivatives, the male and female reproductive systems, skin, central and peripheral nervous systems, and the 18 day gestation fetus were investigated. The distribution of GHBP immunoreactivity (MAb 4.3) was widespread and identical to that previously reported for the extracellular region of the GH receptor (MAbs 263 and 43). Immunoreactivity was both cytoplasmic and nuclear, indicating a possible role for the GHBP in intracellular function. GHBP immunoreactivity was predominantly associated with epithelial/endothelial cell subtypes and with mesenchymal elements such as muscle, chondrocytes, and osteoblasts, as previously described for the GH receptor extracellular region. We also report here the distribution of the GH receptor/GHBP in the kidney, cardiovascular, and respiratory systems. The most prominent immunoreactivity (MAbs 4.3 and 263) was associated with the distal convoluted tubules and collecting ducts of the kidney, with the epithelium and smooth muscle of the broncho-alveolar tree (including type I and II pneumocytes), with the Purkinje and myocardial fibers of the heart and with the endothelium and smooth muscle of blood vessels. Thus we have identified sites of direct GH action in the cardiovascular, renal, and respiratory systems. In conclusion, the extensive cellular distribution of the GHBP in the rat indicates physiological function(s) other than the binding of GH in plasma. Since GHBP mRNA has also been reported in a number of tissues, it may be that the GHBP is synthesized locally to mediate intracellular transport of GH and/or transcriptional regulation by GH in a variety of target tissues.
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