The sheep pars tuberalis: an immunohistochemical study. Demonstration of the presence of glycoprotein and lipotropin hormones

Using indirect immunofluorescence with fourteen different antisera raised against pituitary hormones and peptides, we characterized immunochemically the cells of the sheep pars tuberalis. The presence of LH- and FSH-containing cells, shown in previous studies, was also observed in the present investigation. In addition, we found TSH-containing cells, never observed in sheep, and beta LPH-containing cells. The latter hormone has never been found in any studied species. It appeared that a small amount of perikarya (less than 20%) were immunolabelled and, that the sheep pars tuberalis contained a majority of immunonegative cells as in the guinea-pig rabbit and rhesus monkey. This study may contribute to a better knowledge of the function of the sheep pars tuberalis.     

An immunohistochemical study of epithelial cells in the posterior lobe and pars tuberalis of the human adult pituitary gland

Summary Pituitary glands were examined using reference staining (hematoxylin and eosin, periodic acid-Schiff and alcian blue) and the peroxidase-labeled antibody method, for 1) invading anterior cells in the posterior lobe, 2) intermediate colloid forming follicles, and 3) pars tuberalis cells.The results showed: 1) that the majority of cases possessed invading anterior cells of various amount. Most of these cells were positive for ACTH^1–18, ACTH^17–39 and -MSH. However, on a few occasions, scattered GH, PRL, FSH, FSH, LH and even TSH cells were also present. 2) Colloid forming follicular cells were mostly ACTH cells, but also contained occasional other hormone-secreting cells. Hormone negative cells were correlated with salivary type epithelium. Well established acinic type salivary glands and ciliated epithelium were negative for any hormones immunohistochemically. 3) Pars tuberalis cells were predominantly gonadotrophs but also included TSH and ACTH cells. Some cells appeared to contain both FSH and LH. When these cells underwent squamous metaplasia, they seemed to lose their hormone secreting activity.Part of this study was supported by a Grant-in-Aid for Cancer Research from the Ministry of Education, Science and Culture, Japan     

Seasonal changes in cell proliferation in the adult sheep brain and pars tuberalis

To adapt to seasonal variations in the environment, most mammalian species exhibit seasonal cycles in their physiology and behavior. Seasonal plasticity in the structure and function of the central nervous system contributes to the adaptation of this physiology in seasonal mammals. As part of these plasticity mechanisms, seasonal variations in proliferation rate and neuron production have been extensively studied in songbirds. In this report, we investigated whether this type of brain plasticity also occurs in sheep, a seasonal species, by assessing variations in cell proliferation in the sheep diencephalon. We administered the cell birth marker 5'-bromodeoxyuridine (BrdU) to adult female sheep in July and December, during long and short photoperiod, respectively. The BrdU incorporation was analyzed and quantified in the hypothalamus, a key center for neuroendocrine regulations, as well as in other structures involved in relaying neuroendocrine and sensory information, including the median eminence, the pars tuberalis of the pituitary gland, and the thalamus. In December, 2-fold and 6-fold increases in the number of BrdU+ nuclei were observed in the hypothalamus and thalamus, respectively, when compared with July. This variation is independent of the influence of peripheral gonadal estradiol variations. An inverse seasonal regulation of cell proliferation was observed in the pars tuberalis. In contrast, no seasonal variation in cell proliferation was seen in the subventricular zone of the lateral ventricle. Many of the newborn cells in the adult ovine hypothalamus and thalamus differentiate into neurons and glial cells, as assessed by the expression of neuronal (DCX, NeuN) and glial (GFAP, S100B) fate markers. In summary, we show that the estimated cell proliferation rates in the sheep hypothalamus, thalamus, and pars tuberalis are different between seasons. These variations are independent of the seasonal fluctuations of peripheral estradiol levels, unlike the results described in the brain nuclei involved in song control of avian species.     

Localization of an endocannabinoid system in the hypophysial pars tuberalis and pars distalis of man

The hypophysial pars tuberalis (PT) acts as an important interface between neuroendocrine brain centers (hypothalamus, pineal organ) and the pars distalis (PD) of the hypophysis. Recently, we have identified an endocannabinoid system in the PT of hamsters and provided evidence that 2-arachidonoylglycerol is a messenger molecule that appears to play an essential role in seasonal reproduction and prolactin release by acting on the cannabinoid receptors in the PD. We now demonstrate the enzymes involved in endocannabinoid synthesis and degradation, namely sn-1-selective diacylglycerol lipase α, N-acylphosphatidylethanolamine-specific phospholipase D, and monoacylglycerol lipase, in the PT of man by means of immunohistochemistry. High-performance liquid chromatography coupled with tandem mass spectrometry revealed 2-arachidonoylglycerol and other endocannabinoids in the human PT. Furthermore, we detected the expression of the cannabinoid receptor 1 (CB1), a primary receptor for endocannabinoids, in the PD. Double-immunofluorescence staining for CB1 and various hypophysial hormones or S-100, a marker for folliculostellate (FS) cells, revealed that CB1 immunoreactivity was mainly localized to corticotrophs and FS-cells. A limited number of lactotrophs and somatotrophs also showed CB1 immunoreactivity, which was however absent from gonadotrophs and thyrotrophs. Our data thus indicate that the human PT comprises an endocannabinoid system, and that corticotrophs and FS-cells are the main target cells for endocannabinoids. The functional significance of this newly discovered pathway remains to be elucidated in man; it might be related to the control of stress responses and/or reflect a remnant seasonal control of hypophysial hormonal secretion.     

Cell organization of the rat pars tuberalis. Evidence for open communication between pars tuberalis cells, cerebrospinal fluid and tanycytes

The pars tuberalis (PT) is the only pituitary region in close contact with the medial-basal hypothalamus and bathed by cerebrospinal fluid (CSF). Although PT has long been recognized as an endocrine gland, certain aspects of its structure remain obscure. The present investigation has been designed to gain information concerning (1) the cellular organization of PT, (2) the PT/median eminence spatial relationship and (3) the exposure of various cell compartments of PT to CSF. Non-endocrine cells (S100-reactive) appear as the organizer of the PT architecture. The apical poles of these cells line large cistern-like cavities and the processes of these cells establish a close spatial relationship with PT-specific secretory cells, portal capillaries and tanycytes. The cisterns are also endowed with clusters of ciliated cells and with a highly electron-dense and PAS-reactive content. The unique spatial organization of endocrine and non-endocrine cells of the PT supports a functional relationship between both cell populations. PT endocrine cells display a hallmark of PT-specific cells, namely, the paranuclear spot, which is a complex structure involving the Golgi apparatus, a large pool of immature secretory granules and a centriole from which originates a single 9+0 cilium projecting to the intercellular channels. Horseradish peroxidase (HRP) injected into the CSF readily reaches the intercellular channels of PT and the inner channel of the single cilium and is incorporated by the endocytic machinery of the secretory cells. The PT endocrine cells, through their single 9+0 cilium, may act as sensors of the CSF. HRP also reaches the lumen of the cisterns, indicating that this PT compartment is also exposed to CSF. PT endocrine cells establish direct cell-to-cell contacts with hypothalamic β₁ tanycytes, suggesting a second means of brain-PT communication.     

Demonstration of gonadotropic cells in the adenohypophysis (pars distalis and pars tuberalis) of the monkey Macacus irus. Immunofluorescence study using human anti-beta-FSH and ovine anti-beta-LH antibodies

Indirect immunofluorescence technique with anti-beta FSH and anti-beta oLH antisera has allowed us to detect "gonadotropic cells" in the pars distalis and in the pars tuberalis of the adenohypophysis of the monkey Macacus irus. In the pars distalis, 85-90 % of the "gonadotropic cells" react simultaneously with these two antisera ; 10-15 % of these cells react only either with anti-beta hFSH or anti-beta oLH antisera. The gonadotropic cells are dispersed in the whole pars distalis, amid the other cellular types ; indeed, in the female, there is a "gonadotropic zone" in the median zone of the lateral lobes of the gland. In the pars tuberalis, we have observed "gonadotropic cells" which react only with anti-beta oLH antiserum. These results are compared with observations of some authors.     

The pars tuberalis as a target of the central clock

The pars tuberalis (PT) of the pituitary has emerged from being a gland of obscure and unknown function to a tissue of central importance to our understanding of how photoperiod regulates seasonal responses. The discovery of melatonin receptors on this gland first pointed to its involvement in seasonal physiology. However, the more recent demonstration of the expression of clock genes in the PT, such as Per1, has heightened interest in the gland. Recent work shows how photoperiod, through the hormone melatonin, affects the timing and amplitude of expression of the Per1 gene, as well as other genes such as Icer. The effect of photoperiod and melatonin on the expression of Per1 in the PT is distinct to its effects on the SCN, and this probably reflects distinct functions of the clock genes in the two tissues - acting as part of the biological clock in the SCN, but as an interval timing system within the PT. The changes in amplitude of Per1 gene expression in response to altered length of photoperiod have provided the first clues as to how the durational melatonin signal is decoded within the neuroendocrine system.     

The presence of gonadotropic and thyrotropic cells in the pituitary pars tuberalis of the monkey (Macaca mulatta).

Immunocytochemistry was utilized to determine if pars tuberalis cells in the pituitary of the monkey (Macaca mulatta) have the potential to elaborate gonadotropic and thyrotropic hormones normally secreted by the pars distalis. A total of 7 males and females were studied. The hormones were localized by the peroxidase-antiperoxidase method of Sternberger, and utilized with antisera to the following human hormones: somatotropin, mammotropin, beta(1-24)-corticotropin, chorionic gonadotropin, and the beta-subunits of follicle stimulating hormone and thyrotropin. Many of the parenchymal cells in the pars tuberalis of the median eminence were composed of gonadotropic cells, probably containing luteinizing hormone and follicle stimulating hormone, and thyrotropic cells. Corticotropic and somatotropic cells were seen only rarely, and mammotropic cells were undetectable. The results indicate that the pars tuberalis is able to secrete luteinizing hormone, follicle stimulating hormone, and thyrotropin.     

A comparative in vitro study on LHRH responsiveness of LH cells of the pars tuberalis and pars distalis

Summary The aim of the present study was to test whether the luteinizing-hormone (LH) cells in the pars tuberalis (PT) of the rat and mouse respond to LH-releasing hormone (LHRH) as do those of the pars distalis. A part of the basal hypothalamus containing the pituitary stalk, median eminence and the pars tuberalis (H-PT), was dissected out and incubated in vitro.The LH-secreting capacity of the PT was investigated after removal of the pituitary body (i.e., partes distalis, intermedia and nervosa). First, some rat and mouse H-PT tissues were treated with synthetic LHRH (100ng/ml), while others were incubated without LHRH. After 24 h of incubation, variable amounts of LH release were detected in the medium. This LH discharge, however, was not LHRH-dependent but proportional to the number of PT LH cells that were immunohistochemically detected in each incubated tissue. Since there was marked individual variation in the number of LH cells in the PT, the LH levels in the incubation medium were next compared before and after LHRH treatment using the same H-PT of the rat. An effect of LHRH could not clearly be shown in this experiment.Finally, the cytological response of the PT to LHRH was investigated by incubating both the H-PT and pituitary body connected to the intact pituitary stalk. Immunohistochemical examination of LHRH-treated tissues after 24 h revealed that, in females of both rats and mice, hormone depletion occurred in LH cells of the pars distalis but not in those of the PT. These results indicate that although LH cells in the PT can release LH in vitro, their mode of hormone synthesis and/or discharge differs from that of LH cells in the pars distalis. Since there was a marked individual variation and small LH-secreting capacity by the PT tissue, it seems unlikely, at least in rats and mice, that LH of PT origin plays an important role in the normal physiological state.     

Immunohistochemical study of the pars tuberalis of the adenohypophysis in the monkey,Macaca irus

Summary The pars tuberalis of the hypophysis in the monkey Macaca irus encompasses the hypophysial stem up to the median eminence. Histologically, it consists of several layers of chromophobic cells. A few PAS¹-positive cells also stainable with Alcian blue (pH 3.0) can be observed among the unstained elements. Using the indirect immunofluorescence antibody technique, scattered immunoreactive cells were revealed with the anti-oLH antibody; these cells did not react with the anti-hFSH antibody. In contrast, the immunoreactions to anti-hGH, anti-hPRL, anti-ACTH, anti-MSH, anti-LPH and anti-endorphin sera were completely negative. Single cells reacting with the anti-hTSH serum were observed at the inferior end of the hypophysial stalk (zona tuberalis), i.e., beyond the pars tuberalis proper. These results are compared with data reported in the literature.

---

Résumé La pars tuberalis de l'hypophyse du Singe Macacus irus entoure la tige infundibulaire jusqu'à l'éminence médiane. En techniques histologiques, elle apparaît constituée de plusieurs assises cellulaires d'aspect chromophobe. On y observe quelques cellules PAS-positives réagissant simultanément avec le bleu Alcian (pH3.0). En technique d'immunofluorescence indirecte, des cellules dispersées sont mises en évidence uniquement avec un anticorps anti-oLH; ces cellules ne réagissent pas avec un anticorps anti-hFSH. L'utilisation d'anticorps anti-hGH, anti-hPRL, anti-ACTH, anti-MSH, anti-LPH et antiendorphines ne permet pas de révéler des cellules immunoréactives. Quelques cellules réagissant avec un anticorps anti-hTSH s'observent à la base de la tige hypophysaire (zona tuberalis), c'est-à-dire au-delà de la pars tuberalis proprement dite. Ces résultats sont confrontés à ceux rapportés dans la littérature.

---

Abbreviations used in this Article PAS periodic acid Schiff - oLH ovine luteinizing hormone - hFSH human follicle stimulating hormone - hGH human growth hormone - hPRL human prolactin - ACTH corticotropin - MSH melanotropin - LPH lipotropin - hTSH human thyrotropin - BSA and HSA bovine and human serum albumin     

The structure and vascularization of the pars tuberalis of the hypophysis of Rana temporaria

Summary The pars tuberalis of the hypophysis of Rana temporaria presents the general structural and the cytological characteristics of an endocrine gland. It is composed of elongated cells with long, branching processes ending on the external basement membrane of the pericapillary space. The pars tuberalis cells produce secretory granules which are accumulated in the pericapillary endings of the processes.Corresponding to its separate localization, the pars tuberalis of Rana temporaria has a separate vascularization of which the efferent capillaries anastomose with the capillary plexus of the median eminence. The general direction of the blood flow of the pars tuberalis is towards the capillaries of the median eminence. Also, the secretory products of the pars tuberalis pass into the blood stream of the hypophysial portal system.Several characteristics of the pars tuberalis show that its function must be different from that of the pars distalis of the hypophysis. Moreover, in contrast with the pars distalis, the activity of the pars tuberalis is not regulated by neurohumoral factors.The results show that a role of the pars tuberalis in the regulation of the activity of the pars distalis of the hypophysis is not excluded.     

Hes1 regulates formations of the hypophyseal pars tuberalis and the hypothalamus

The hypophyseal pars tuberalis surrounds the median eminence and infundibular stalk of the hypothalamus as thin layers of cells. The pars tuberalis expresses MT1 melatonin receptor and participates in mediating the photoperiodic secretion of pituitary hormones. Both the rostral tip of Rathke’s pouch (pars tuberalis primordium) and the pars tuberalis expressed αGSU mRNA, and were immunoreactive for LH, chromogranin A, and TSHβ in mice. Hes genes control progenitor cell differentiation in many embryonic tissues and play a crucial role for neurulation in the central nervous system. We investigated the Hes1 function in outgrowth and differentiation of the pars tuberalis by using the markers for the pars tuberalis. In homozygous Hes1 null mutant embryos, the rostral tip was formed in the basal-ventral part of Rathke’s pouch at embryonic day (E)11.5 as well as in wild-type embryos. In contrast to the wild-type, the rostral tip of null mutants could not extend rostrally with age; it remained in the low extremity of Rathke’s pouch during E12.5–E13.5 and disappeared at E14.5, resulting in lack of the pars tuberalis. Development of the ventral diencephalon was impaired in the null mutants at early stages. Rathke’s pouch, therefore, could not link with the nervous tissue and failed to receive inductive signals from the diencephalon. In a very few mutant mice in which the ventral diencephalon was partially sustained, some pars tuberalis cells were distributed around the hypoplastic infundibulum. Thus, Hes1 is required for development of the pars tuberalis and its growth is dependent on the ventral diencephalon.     

Embryonic development and secretory differentiation in the pars tuberalis of the mouse hypophysis

Summary The pars tuberalis (PT) of the mouse, like that of other mammals, consists mainly of glandular cells rich in glycogen and peculiar to this lobe. In the mouse, the glandular cells are characterized by large, dense secretory vesicles (up to 300 nm in diameter), the abundance of which indicates a marked secretory activity. The PT develops from a distinct antero-ventral area of Rathke's pouch. The border between the anlagen of the PT and the pars distalis is formed by Atwell's recessus which represents the access for the vessels afferent to the pars distalis. The pedicle of Rathke's pouch is incorporated into the PT anlage, thus contributing to its formation. The entire PT anlage is characterized by glycogen accumulation from the commencement of its formation and persisting in the adult tuberal lobe. Secretory differentiation of the glandular cells of the PT occurs at day 12 of gestation, preceding that of all other adenohypophysial cell types. The secretory features of these cells (development of ergastoplasm and Golgi apparatus, abundance of dense secretory vesicles) appear at an early stage of the embryonic life (14 days) comparable to those of mature cells. These results confirm earlier observations in the foetal rat where hypophysial secretion also begins in the PT. The existence of peculiar glandular cells speaks in favour of a specific but still unknown function of the PT during foetal and adult life.This work is dedicated to Professor F. Stutinsky     

Immunocytochemistry of the pituitary glycoprotein hormones.

The storage sites of the pituitary glycoprotein hormones were identified with the use of electron microscopic immunocytochemical techniques and antisera to the beta (beta) chains of follicle-stimulating hormone (FSH), luteinizing hormone (LH) and thyroid-stimulating hormone (TSH). The TSH cells in normal rats is ovoid or angular and contains small granules 60-160 nm in diameter. In TSH cells hypertrophied 45 days after thyroidectomy, staining is in globular patches in granules or diffusely distributed in the expanded profiles of dilated rough endoplasmic reticulum. The gonadotrophs (FSH and LH cells) exhibited three different morphologies. Type I cells are ovoid with a population of large granules and a population of small granules. Staining for FSHbeta or LHbeta was intense and specific only in the large granules (diameter of 400 nm or greater). Type II cells are angular or stellate and contain numerous secretory granules averaging 200-220 nm in diameter. They predominate during stages in the estrous cycle when FSH or LH secretion is high. Type III cells look like adrenocorticotropin (ACTH) cells in that they are stellate with peripherally arranged granules. They generally stain only with anti-FSHbeta and their staining can not be abolished by the addition of 100 ng ACTH. In preliminary quantitative studies of cycling females, we found that on serial sections FSH cells and LH cells show similar shifts to a more angular population of cells during stages of active secretion. However, the shifts are not in phase with one another. Furthermore, there are at least 1.5 times more FSH cells than LH cells at all stages of the cycle. Our collection of serial cells shows that some cells (usually type I or II) stain for both gonadotropic hormones, whereas others (usually type II or III) contain only one.     

Neuroglandular contacts between vasopressin-reactive fibers and cells of the pars tuberalis in the rat

Summary In electron micrographs fibers containing vasopressin-immunoreactive elementary granules 100–120 nm in diameter are observed within the basal lamina of the adenohypophyseal pars tuberalis adjacent to the rostral portion of the median eminence. The concept of a neuroglandular transmitter function of vasopressin is discussed.Supported by the Deutsche Forschungsgemeinschaft (Grant Nr. Kr. 569/2) and the Stiftung VolkswagenwerkThe excellent technical assistance of Mrs. Helga Prien is thankfully acknowledged