Summary
SEM reveals that the inner surface of the pituitary cleft is lined by a continuous layer of marginal cells possessing microvillous and ciliated apical surfaces. The ciliated cells are more numerous on the posterior side (toward the pars intermedia) than on the anterior side of the cleft (toward the pars distalis). In contrast small infoldings (crypts) were occasionally noted only on the marginal layer covering the distal part of the hypophysis. In some areas of the cleft the surface features of the marginal cells are rather similar to the epithelial cells populating the upper parts of the respiratory tract in their topography and distribution. In other regions they also show striking similarities with the ependymal cells (tanycytes) lining the lateral recesses of the 3rd ventricle and the infundibular process with which the pituitary cleft has a very close topographical relationship.
The parenchymal cells of the pars distalis are closely related to the flattened marginal cells of the cleft. The intercellular spaces of the pars distalis form a three-dimensional labyrinthic series of cavities continuous with the submarginal spaces of the cleft. Further SEM and TEM results demonstrate that the majority of the microvillous marginal cells lining both sides of the cleft possess surface features such as bulbous protrusions, laminar evaginations and large cytoplasmatic vacuoles, which are very likely the expression of an active transport of fluids.
On the basis of these results it is concluded that the fluid-like material (colloid) present in the pituitary cleft is mainly derived from the fluids contained in the lacunar spaces of the pars distalis. Thus, marginal cells by absorbing fluids from the cleft by active endocytosis, may transport to the pars intermedia material (or hormones) produced in the distal part of the gland and vice versa.
The cilia present on many marginal cells, based on their 9+2 tubular pattern, possess a kynetic role. This is very similar to that shown by the ciliated cells of the ependyma lining the brain ventricles. The occurrence of ciliated cells within the pituitary parenchyma (mainly in the follicles) suggests that they probably arise from the ciliated cells populating the marginal layer of the cleft and with which the parenchyma cells are closely related.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Allen DJ (1975) Scanning electron microscopy of epiplexus macrophages (Kolmer cells) in the dog. J Comp Neurol 161:197–214
Allen DJ, Persky B, Low FN (1978) Some regional variations in ventricular lining material in laboratory mammals and man. SEM: 1978 Vol II, Becker RP, Johari D (eds). SEM Inc AMF O'Hare, IL USA, pp 45–52
Andrews PM (1974) A scanning electron microscopic study of the extrapulmonary respiratory tract. Am J Anat 139:299–324
Barberini F, Sartori S, Van Blerkom J, Motta P (1978) Changes in the surface morphology of the rabbit endometrium related to the estrous and progestational stages of the reproductive cycle. A scanning and transmission electron microscopic study. Cell Tissue Res 190:207–222
Bleier R (1975) Surface fine structure of supraependimal elements and ependyma of hypothalamic third ventricle of mouse. J Comp Neurol 161:555–568
Brauer RW (1963) Liver circulation and function. Physiol Rev 43:115–213
Ciocca DR (1980) Scanning electron microscopy of the cleft of the rat pituitary. Cell Tissue Res 206:139–143
Ciocca DR, Gonzales CB (1978) The pituitary cleft of the rat. An electron microscopic study. Tissue and Cell 10:725–733
Coates PW (1977) The third ventricle of monkeys: scanning electron microscopy of surface features in mature males and females. Cell Tissue Res 77:307–316
Cocchia D, Miani N (1981) Immunocytochemical localization of the brain specific S-100 protein in the pituitary gland of adult rat (in press)
Correr S, Caggiati A, Motta P (1979) Scanning electron microscopy of the rat hypophysary cleft. Proc 5th Europ Anat Congr September 10–14 (abstract) p 70 Prague
Dingemans KP, Feltkamp CA (1972) Non granulated cells in the mouse adenohypophysis. Z Zellforsch Mikrosk Anat 124:387–405
Dubois P, Girod C (1970) Observation au microscope électronique d'un reliquat de la fente hypophysaire chez la hamster doré adulte. Cr Séanc Soc Biol (Paris) 164:157–160
Enders AC, Nelson DM (1973) Pinocytotic activity of the uterus of the rat. Am J Anat 138:277–300
Flament-Durand J, Vienne G, Dustin P (1978) Scanning electron microscopic study of the ependyma of the hypothalamic region in man. SEM: 1978 Vol II, Becker RP, Johari D (eds). SEM Inc AMF O'Hare, IL USA, pp 151–156
Fujita T (1977) Concept of paraneurons. Arch Histol Jp 40, Suppl 1–12
Hamilton WJ, Boyd JD, Mossman HW (1973) Human embryology 4th edit. W Heffer & Sons Ltd, Cambridge
Harrison RG (1960) The adrenal circulation. Blackwell, Oxford
Hosoya Y, Fujita T (1973) Scanning electron microscope observation of intraventricular macrophages (Kolmer cells) in the rat brain. Arch Histol Jpn 35:133–140
Kagayama M, Ando A, Yamamoto TY (1969) On the epithelial lining of the cleft between pars distalis and pars intermedia in the mouse adenohypophysis. Gunma Symp Endocrinol 6:125–136
Kessel RG, Kardon RH (1979) Tissues and organs. A text-atlas of scanning electron microscopy. WH Freeman and Co, San Francisco
Ketelbant-Balasse P, Rodesch F, Neve P, Pasteels JM (1973) Scanning electron microscope observations of apical surfaces of dog thyroid cells. Exp Cell Res 79:111–119
Kurosomi K, Fujita H (1975) Functional Morphology of endocrine glands. An atlas of electron micrographs. Igaku-Shoin Ltd, Tokyo
Langman J (1975) Medical Embryology. Human development, normal and abnormal. 3rd Edit. The Williams & Wilkins Company, Baltimore
Mestres P (1978) Old and new concepts about circumventricular organs: an overview. SEM/1978 Vol II, Becker RP, Johari O (eds). SEM Inc AMF O'Hare, IL USA, pp 137–142
Mestres P, Breipohl W (1976) Morphology and distribution of supraependymal cells in the third ventricle of the albino rat. Cell Tissue Res 168:303–314
Motta P (1977) The three-dimensional fine structure of the liver as revealed by scanning electron microscopy. Int Rev Cytol (Suppl 6). Studies in Ultrastructure. Acad Press, New York San Francisco London, pp 347–401
Motta P, Porter KR (1974) Structure of rat liver sinusoids and associated tissue spaces as revealed by scanning electron microscopy. Cell Tissue Res 148:111–125
Motta P, Muto M, Fujita T (1979) Three-dimensional organization of mammalian adrenal cortex. A scanning electron microscopic study. Cell Tissue Res 196:23–38
Motta P, Andrews PM, Porter KR (1977) Microanatomy of cell and tissue surfaces. An atlas of scanning electron microscopy. Lea & Febiger, Philadelphia
Nunez E, Wallis J, Gershon MD (1974) Secretory processes in follicular cells of the bat thyroid. III. The occurrence of extracellular vesicles and colloid droplets during hibernation. Am J Anat 141:179–202
Ottaviani G (1953) Linfatico Sistema. Enciclopedia medica italiana. Vol 5, pp 1877–1881 USE Firenze
Parr MB, Parr EL (1977) Endocytosis in the uterine epithelium of the mouse. J Reprod Pert 50:151–153
Pearse AGE (1969) The cytochemistry and ultrastructure of polypeptide hormon-producing cells of the APUD series and the embryologic, physiologic and pathologic implications of the concept. J Histochem Cytochem 17:303–313
Pearse AGE, Takor Takor T (1979) Embryology of the diffuse neuroendocrine system and its relationship to the common peptides. Federation Proc 38:2288–2294
Porter KR, Prescott D, Frye J (1973) Changes in the surface morphology of chinese hamster ovary cells during the cell cycle. J Cell Biol 57:815–836
Sano M, Sasaki F (1969) Embryonic development of the mouse anterior pituitary studied by light and electron microscopy. Z Anat Entw Gesch 129:195–222
Smolich JJ, Stratford BF, Maloney JE, Ritchie BC (1977) Postnatal development of the epithelium of larynx and trachea in the rat: scanning electron microscopy. J Anat 124:657–673
Takor Takor T, Pearse AGE (1975) Neuroectodermal origin of ovarian hypothalamo-hypophyseal complex. The role of the ventral neural ridge. J Embryol Exp Morphol 34:311–325
Yoshimura F, Soji T, Kiguchi Y (1977) Relationship between the follicular cells and marginal layer cells of the anterior pituitary. Endocrinol Jpn 24(3): 301–305
Van Blerkom J, Motta P (1978) A scanning electron microscopic study of the luteo-follicular complex. III. Formation of the corpus luteum and repair of the ovulated follicle. Cell Tissue Res 189:131–154
Vanha-Perttula T, Arstila AV (1970) On the epithelium of the rat pituitary residual lumen. Z Zellforsch 108:487–500
Venable JH, Coggeshall R (1965) A simplified lead citrate stain for use in electron microscopy. J Cell Biol 25:407–408
Vila-Porcile E (1972) Le réasou des cellules folliculo-stellaires et les follicules de l'adenohypophyse du rat (pars distalis). Z Zellforsch 129:328–369
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Correr, S., Motta, P.M. The rat pituitary cleft: A correlated study by scanning and transmission electron microscopy. Cell Tissue Res. 215, 515–529 (1981). https://doi.org/10.1007/BF00233528
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00233528