Summary
Comparative studies have been made of development of the adenohypophysis using the Rathke's pouch (RP)-derived model system. Rathke's pouch with associated mesenchyme and ventral hypothalamus, was microsurgically isolated from 15-day fetal rats and placed in mild trypsin solution. Three variations of donor tissue were isolated and transplanted beneath the kidney capsule of adult hosts: A) pure pouch epithelium; B) pouch epithelium plus mesenchyme; and C) pouch epithelium with mesenchyme and ventral hypothalamus. After 30 days the grafts were isolated and processed for light and electron microscopy. Cell types were characterized by immunostaining as well as by morphological criteria. In group A well differentiated mammotrophs dominated the grafts, many of which were hypertrophied with widely dilated endoplasmic reticulum and Golgi saccules. Mammotrophs, frequently with mitotic figures, were distributed evenly throughout the grafts. Somatotrophs and gonadotrophs were neither abundant nor well differentiated in group A, but were both abundant and more extensively differentiated in groups B and C. Both somatotrophs and gonadotrophs were typically localized at margins of the graft adjacent to connective tissue spaces. Well differentiated mammotrophs were present in groups B and C although there were fewer hypertrophied mammotrophs than in group A; and immunoreaction to prolactin was weaker than in group A.
Tumor-like features found in all three groups included some loss of tissue integrity and large, vascular lakes unlined by endothelium.
These findings suggest that differentiation of mammotrophs may be inhibited in part by mesenchyme associated with Rathke's pouch, since in the absence thereof these cells become hyperplastic. Conversely, differentiation of somatotrophs and gonadotrophs appears more dependent on these mesenchymal elements for normal development.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Anderson H, von Bülow FA, Møllgard K (1971) The early development of the pars distalis of human foetal pituitary gland. Z Anat Entwickl Gesch 135:117–138
Baskin DG, Mar H, Gorray KC, Fujimoto WY (1982) Electron microscopic immunoperoxidase staining of insulin using 4-chloro-1-napthol after osmium fixation. J Histochem Cytochem 30:710–712
Conklin JL (1968) The development of the human adenohypophysis. Anat Rec 160:79–92
Daikoku S, Chikamori M, Adachi T, Maki Y (1982) Effect of the basal diencephalon on the development of Rathke's pouch in rats. A study in combined organ cultures. Dev Biol 90:198–202
Etkin W (1958) Independent differentiation in components of the pituitary complex in the wood frog. Proc Soc Exp Biol Med 97:388–393
Ferrand R (1969) Différenciation en greffe chorio-allantoïdienne de l'épithelium de la poche de Rathke d'embryons de Caille et de Poulet. CR Soc Biol (Paris) 163:2669–2672
Ferrand R (1972) Étude expérimentale des facteurs de la différenciation cytologique de l'adénohypophyse chez l'embryon de Poulet. Arch Biol (Liège) 83:297–371
Fink G, Smith GC (1971) Ultrastructural features of the developing hypothalamo-hypophysial axis in the rat. Z Zellforsch 119:208–226
Fulling KH, Mills BK, Swars RL, McKeel DW (1978) Diffuse prolactin cell hyperplasia is the precursor lesion to estrogeninduced and spontaneous adenomatous neoplasia in rats. Endocrinology 102:356
Gash D, Ahmad N, Schechter J (1977) Cytodifferentiation of pituitary primordia transplanted to the kidney capsule of adult hosts. Anat Rec 189:149–160
Gash D, Ahmad N, Weiner R, Schechter J (1980) Development of presumptive mammotrophs in isografts is dependent on the endocrine state of the host. Endocrinology 106:1246–1252
Hodges GM, Hicks RM, Spasey CD (1977) Epithelial-stromal interactions in normal and chemical carcinogen treated adult bladder. Cancer Res 37:3720–3730
Kovacs K, Horvath E, Ilse RG, Ezrin C, Ilse D (1977) Spontaneous pituitary adenomas in aging rats. A light microscopic, immunocytological and fine structural study. Beitr Pathol 161:1–16
Kovacs K, Ryan N, Horvath E, Singer W, Ezrin C (1980) Pituitary adenomas in old age. J Gerontol 35:16–22
Le Douarin N, Ferrand R, Le Douarin G (1967) La différenciation de l'ébauche épitheliale de l'hypophyse séparée du plancher encéphalique et placée dans des mésenchymes hétérologues. CR Acad Sc (Paris) 264:3027–3029
Madri J, Williams SK, Wyatt T, Mezzio C (1983) Capillary endothelial cell cultures: phenotypic modulation by matrix components. J Cell Biol 97:153–165
McKeel DW, Fowler M, Jacobs LS (1978) The high prevalence of prolactin cell hyperplasia in the human adenohypophysis. Endocrinology 102:353
Mohanty S, Tandon PN, Banerji AK, Prakash B (1977) Hemorrhage into pituitary adenomas. J Neurol Neurosurg Psychiatr 40:987
Petrusz P, Meo PD, Ordronneau P, Weaver C, Keefer DA (1975) Improved immunoglobulin-enzyme bridge method for light microscopic demonstration of hormone-containing cells in the rat adenohypophysis. Histochemistry 46:9–26
Racadot J, Vila-Porcile E, Olivier L, Peillon F (1975) Electron microscopy of pituitary tumors. Progr Neurol Surg 6:95–141
Schally AV (1978) Aspects of hypothalamic regulation of the pituitary gland. Science 202:18–28
Schally AV, Arimura A, Kastin AJ (1973) Hypothalamic regulatory hormones. Science 179:341–350
Schechter J (1971) The Cytodifferentiation of the rabbit pars distalis: an electron microscopic study. Gen Comp Endocrinol 16:1–20
Schechter J, Gash D, Ahmad N (1978) Neuroembryogenesis of embryonic ventral floor of hypothalamus transplanted to kidney capsule: electron microscopy. Cell Tissue Res 190:247–254
Schechter J, Gash D, Ahmad N (1982) Estradiol stimulation of pituitary primordia transplanted to the kidney capsule. Cell Tissue Res 227:41–53
Setalo G, Nakane PK (1972) Studies on the functional differentiation of cells in fetal anterior pituitary glands of rats with peroxidase-labeled antibody method. Anat Rec 172:403–404
Sobel H (1958) The behaviour in vitro of dissociated embryonic pituitary tissue. J Embryol Exp Morphol 6:518–526
Svalander C (1974) Ultrastructure of the fetal rat adenohypophysis. Acta Endocrinol 76:1–113
Watanabe Y (1982a) Effects of brain and mesenchyme upon the cytogenesis of rat adenohypophysis in vitro. Cell Tissue Res 227:257–266
Watanabe Y (1982b) An organ culture study on the site of determination of ACTH and LH cells in the rat adenohypophysis. Cell Tissue Res 227:267–275
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Schechter, J., Gash, D. & Ahmad, N. Mesenchymal influences on the development of the adenohypophysis in the rat. Cell Tissue Res. 241, 67–76 (1985). https://doi.org/10.1007/BF00214627
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00214627