Cytodifferentiation of the adenohypophysis of the domestic fowl

Summary In the chick embryo the first membrane-bound secretory granules occur in the cytoplasm of occasional cells in the cephalic lobe of pars distalis at the 7th day of incubation. On the 8th day most of the cells in both the cephalic and caudal lobes contain secretory granules that are variable in size, form and density.On the 9th day at least two types of glandular cells are distinguishable in the cephalic and in the caudal lobes; however, these cells are not comparable with those of the adult gland. Differentiation of acidophils and basophils occurs, apparently simultaneously, in 11-day embryos.The cells of the cephalic and caudal lobes are morphologically distinct from their first appearance. Thus it is concluded that these two lobes develop independently and differently from an early stage of ontogenesis.The secretory granules are formed in the Golgi area of the hypophysial cells after the 8th day of incubation. However, secretory material may be synthesized also by a process not involving the Golgi apparatus.Nerve fibers containing granules first appear in the superficial layer of the median eminence on the 8th embryonic day and by the 12th day three types of granules and two types of clear vesicles are identifiable.The investigation reported herein was supported by grant from Japan-U.S. Cooperative Science Program of Japan Association for Science Promotion to Professor Mikami and by U.S.-Japan Cooperative Science Program Grant No. GF-33334 to Professor Farner.     

Immunocytological study on the differentiation of chick and quail adenohypophysis epithelial rudiments, grafted or cultivated in vitro: evidence for polypeptidic hormones

Epithelial rudiments of adenohypohysis were removed from chick and quail embryos between days 3 and 5 of development. Chick rudiments were grafted for 11--13 days onto the chorioallantoic membrane of decapitated chick embryo hosts. Quail rudiments were cultivated in vitro for 6 days. Both grafted and cultivated Rathke's pouches differentiated into adenohypophyseal tissue. The adenohypophyseal tissue cultured on chorio-allantoic membrane exhibited cells reacting with the following immune sera: anti-beta-(1--24)ACTH, anti-alpha-(17--39)-ACTH, anti-alpha-endorphin, anti-beta-endorphin and anti-beta-LPH, which also gave a positive reaction when applied to adenohypophysis of corresponding age which had differentiated in situ. In situ, corticotrophs were located exclusively in the cephalic lobe of adenohypophysis. Therefore, the differentiation of corticotrophs in the whole graft, i.e., from both cephalic and caudal lobes of Rathke's pouch, showed that the cells of the caudal lobe, or at least some of them, were uncommitted when the rudiment was removed. In vitro, tissue derived from Rathke's pouch contained cells reacting with antibodies to beta-(1--24)-ACTH, alpha-(17--39)-ACTH, and beta-LPH, as did adenohypophysis from quail embryos of corresponding age (9--10 days), differentiated in situ. The differentiation of quail Rathke's pouch in vitro corroborates that differentiation can occur without influence from hypothalamus and, moreover, shows that at least some kinds of cells can differentiate without influence exerted by any other encephalic factors, and in the absence of mesenchyme. The question arises whether fibroblastic cells derived from Rathke's pouch cells act as feeder-cells and/or secrete some factors promoting differentiation.     

Developmental Changes in β-Citryl-L-G1utamate Concentration and Its Synthetic and Hydrolytic Activities in Neuronal Cells Cultured from Chick Embryo Optic Lobes

Developmental changes in the concentration of beta-citryl-L-glutamate(beta-CG) have been examined in the cerebrum and optic lobe of the developing chick brain and in primary cultured neuronal cells from the chick embryo optic lobes with gas chromatographic and HPLC methods originated in our studies. A sharp peak was shown by beta-CG, with a maximal concentration at 13 days of incubation in the optic lobe of the developing chick brain but decreasing markedly to adult levels. The developmental change in primary cultured neurons was similar to that in the optic lobe of the developing chick brain. Changes in synthetic and hydrolytic activities of beta-CG were studied during growth of primary cultured neurons. Incorporation of radioactivities from radiolabeled pyruvate and alanine into beta-CG increased significantly on day 3 of culture, reaching a plateau on day 6, whereas that from radioactive glutamine and glutamate increased gradually from day 3 to day 12 of culture. The hydrolyzing enzyme activity of beta-CG during neuron growth was low until day 3 of culture, when it increased significantly until day 12. Similar developmental changes were observed in the developing chick embryo optic lobes.     

Immunohistochemical studies on the development of avian embryo pituitary corticotrophs under normal and experimental conditions

Summary Immunofluorescent ACTH cells are present in the developing chick pituitary gland from the 9th day of incubation.Rathke pouch grafts from 4–5 day or 5.5 and 6.5 day-old chicks, grafted into chick chorioallantoic membrane and grown for 12 days, gave rise to tinctorially normal pituitary glands in both cases.The early grafts were of pouch epithelium alone, separated from mesenchyme by trypsinization. The later grafts were surrounded by their attached mesenchyme, from which they are virtually inseparable.In 17 out of 18 of the 4.5 day grafts no immunofluorescent ACTH cells developed. (In the 18th case a few feebly stained single cells). In 16 out of 30 of the 5.5 and 6.5 day grafts ACTH cells were present in normal numbers.Of the 3 hypotheses put forward to explain these findings only one appears valid. This is that the ACTH cells are contributed directly by the mesectoderm (neural crest) surrounding the 5.5 and 6.5 day pituitary primordia.     

The differentiation of prolactin cells in an organ culture of chick embryo adenohypophysis

We have studied differentiation of prolactin cells in explants of cephalic and caudal parts of Rathke's pouch of 4.5 day and 5.5 day old chick embryos after their incubation in vitro lasting for 7-8 days. Indirect immunofluorescence using an antiserum against bovine prolactin was used to detect prolactin cells in the cultures. Differentiation of prolactin cells was detected regularly in explants of the cephalic lobe of the adenohypophysis anlage in 5.5 day old embryos; under certain growth conditions prolactin cells were found in explants of the same lobe in 4.5 day old embryos. Prolactin cells were either absent or found in small numbers in cultures of the caudal part of adenohypophysis of 5.5 day old embryos. Our results provide evidence for the appearance of the committed precursors of prolactin cells in the Rathke's pouch at late stages of its formation and for their regional localization in the cephalic part of the anlage. This localization is in correspondence with the distribution of differentiated cells of this type in definitive adenohypophysis.     

Early development of the primitive cranial vault in the chick embryo.

The calcified tissues involved in the early morphogenesis of the cranial vault were studied by microradiographic analysis and histological techniques in 12 chick embryos on the 9th, 12th, and 14th days of incubation. On the 9th day, the frontal, parietal, and squamosal bones are comprised of a thin lamina of chondroid tissue deposited at a short distance from the fibers of the dura mater. Woven bone formation takes place in the calvarial mesenchyme only after the 12th day of incubation and occurs mainly on the external side of the chondroid primordium. The present data obviously indicate that the primitive desmocranium of the chick embryo, which is usually known to be formed by intramembranous ossification, consists first of chondroid tissue. This tissue represents thus the initial modality of skeletogenic differentiation within the cephalic mesenchyme of the cranial vault.     

Immunohistochemistry of the hypothalamic neuropeptides and anterior pituitary cells in the Japanese quail

The pars distalis of the avian adenohypophysis consists of well-defined cephalic and caudal lobes which are distinct in their cellular constituents. Immunocytochemical investigations on the pituitary hormones of the pars distalis of the Japanese quail reveal five types of secretory cells, adenocorticotropin (ACTH) cells, prolactin (PRL) cells, thyroid-stimulating hormone (TSH) cells, growth hormone GH (STH) cells, and FSH/LH (gonadotropic) cells. The ACTH cells, TSH cells, and PRL cells are restricted to the cephalic lobe, and GH (STH) cells are confined to the caudal lobe, while FSH/LH cells are distributed throughout the cephalic and caudal lobes. The median eminence of birds has distinct anterior and posterior divisions, each with different neuronal components. The avian hypophysial portal vessels also consists of two groups, anterior and posterior. The peculiar arrangement and distribution of the avian hypophysial portal vessels are possibly related to the distribution of neuropeptides in the two divisions of the median eminence and to the cytological and functional differentiation of two lobes of the pars distalis. The localization of perikarya and fibers containing luteinizing hormone releasing hormone (LHRH), somatostatin, vasotocin, mesotocin, corticotropin-releasing factor (CRF), vasoactive intestinal polypeptide (VIP), glucagon, metenkephalin, and substance P in the hypothalamus and median eminence of the Japanese quail has been investigated by means of immunohistochemistry using antisera against the respective neuropeptides. LHRH-, somatostatin-, VIP-, met-enkephalin-, and substance P-immunoreactive fibers are localized in the external layer of the anterior and posterior divisions of the median eminence, while CRF- and vasotocin-reactive fibers are demonstrated only in the external layer of the anterior division of the median eminence. The metenkephalin fibers are thicker in the anterior median eminence but the substance P fibers are more abundant in the posterior division. Mesotocin fibers occur only in the internal layer of the median eminence and neural lobe.     

Cell growth and thymidine incorporation changes induced by Dolichos lectin in embryo fibroblasts at various stages of differentiation.

We report here the effect of Dolichos lectin on chick embryo fibroblasts from embryos between 6th and 16th day of development. There is evidence that Dolichos lectin decreases cell number and proportion of cells incorporating tritium labelled thymidine in case of chick embryo fibroblasts of 6th, 8th and 10th day of development. Dolichos lectin stimulated the proliferation of 16-day old embryo cells. No effect was noticed on 12-day embryo cells at different concentrations of Dolichos lectin used. This lectin is specifically inhibited by N-acetyl-D-galactosamine and anti-Dolichos lectin serum. The difference in response by cells during different stages of embryonic development could perhaps be explained as some regulatory changes occurring on the cell surface.     

Tissue-specific antigen of chick adenohypophysis appearing at early stages of histotypic differentiation]

The tissue-specific water-soluble antigen characterized by alpha1-globulin electrophoretic mobility was revealed in chick adenohypophysis. The antigen was shown to appear in embryogenesis at early stages of histotypical differentiation of the adenohypophysis by indirect immunofluorescence. The first cells with specific fluorescence were found simultaneously in the cephalic and caudal lobes of 6-day embryo adenohypophysis. The bright patterned fluorescence was observed in all cellular cords of the adenohypophysis by the 8--10th day of the development. This antigen may be used as a common marker for pituitary cell differentiation.     

Cell types in the adenohypophysis of the Japanese quail and effects of injection of luteinizing hormone-releasing hormone

The cells of the adenohypophysis of the Japanese quail were studied by both light and electron microscopy after exposure to long photoperiods or injection of lutenizing hormone-releasing hormone (LRH). Six cell types were identified in the adenohypophysis by examining alternate thick and thin sections by light and electron microscopy. In the cephalic lobe, there are four types of glandular cells. They are the prolactin cells, ACTH cells, TSH cells, and gonadotropic cells (FSH?). In the caudal lobe, there are two types of cells, STH cells and gonadotropic cells (LH?). After exposure to long daily photoperiods, gonadotropic cells in both lobes were strongly activated. They became larger and accumulated many granules. ACTH cells became vacuolated; granules were sparse. Synthetic LRH injection (10 mug/0.2 ml/day) for 10 days to the non-photostimulated quail stimulated certain numbers of the gonadotropic cells in the both lobes, although the response of the cells was less than that induced by photostimulation. No response was seen in the other cell types.     

The cell types in the adenohypophysis of the South-American lungfish,Lepidosiren paradoxa,with special reference to immunocytochemical identification of the corticotropin-containing cells

The histological features and distribution of cell types in the distal lobe of Lepidosiren resemble those of Protopterus. Three "basophilic" cell types are described, whereas the identification of two acidophilic cell types is uncertain. In the intermediate lobe two cell types have been found. Anti-(1-24)ACTH IgG was used in the unlabeled antibody-enzyme method to identify corticotropin-containing cells in the adenohypophysis of Lepidosiren with light and electron microscopy. Corticotropin was demonstrated in cells of the distal lobe and the intermediate lobe. The staining reaction in the distal lobe is localized in the rostrally distributed lead-hematoxylin positive cells. At the ultrastructural level the immunoreaction in these distal lobe cells is localized on polymorphic granules ranging from 130 to 210 nm. Absorption experiments show that the immunoreactive cells in the distal lobe contain at least residues 1-3 and 14-17 of the naturally occurring corticotropin hormone, while the intermediate lobe cells contain alpha-MSH or at least residues 1-3 of ACTH. The plasma level of corticotropin was determined to be 71 ng/l by means of radioimmunoassay (RIA).     

Experimental analysis of the migration and differentiation of neuroblasts of the autonomic nervous system and of neurectodermal mesenchymal derivatives, using a biological cell marking technique

By isotopic and isochronic transplantations of fragments of quail neural tube into chick, it has been previously shown that enteric ganglion cells arise from the “vagal” (somites 1–7) and the “lumbo-sacral” (behind somite 28) levels of the neural crest, while the trunk region (somites 8–28) gives rise to orthosympathetic ganglion chain and adrenomedullary cells. The latter originate precisely from the neural crest corresponding to somites 18–24 (i.e., “adrenomedullary” level of the crest). Heterotopic transplantations of fragments of quail neural tube into chick have been carried out in the present work. When the “adrenomedullary” level of the quail neural tube is grafted into the “vagal” region of a chick, the crest cells colonize the gut and differentiate into enteric ganglia of Auerbach's and Meissner's plexi. If quail cephalic neural crest is transplanted in the “adrenomedullary” level of a chick, quail cells migrate into the suprarenal glands and differentiate into adrenomedullary cells. Mesectodermal cells migrate laterally, and differentiate into cartilage, dermis and connective tissues. Thus it appears that preferential pathways located at precise levels of the embryo lead crest cells to their definitive sites. On the other hand the differentiation of the autonomic neuroblasts is controlled by the environment in which crest cells are localized at the end of their migration. On the contrary, mesenchymal derivatives of the cephalic neural crest appear to be early determined since they differentiate according to their presumptive fate when transplanted into the trunk.     

Changes in glycogen metabolism in chick embryo liver in relation to the formation of glycosomes]

In the chick embryo liver the portion of granular glycogen increases from 15 to 90% of the total content during the period from the 8th till the 14th days of developments. The activity of glycogen synthetase (KF 2.4.1.11) localized in the fraction of granular glycogen increases from 40 to 90% of the total activity in the 18 days old embryo. The activity of phosphorylase (KF 2.4.1.1) is detected in the granular glycogen of the liver only on the 12th day of development (10% of the total activity) and increase up to 80% on the 19th day of development. The maximal activation of glycogen synthetase and phosphorylase is noted after the glycosomes of formation in the developing embryoliver. A suggestion is put forward to the effect that the process of glycosome formation is a factor of the control of glycogen synthetase and phosphorylase activity.     

Immunohistochemical detection of prolactin in the hypophysis of the chick and chick embryo

The appearance and localization of immunoreactive prolactin in the adenohypophysis of chick embryos and chickens was studied by antisera to the bovine prolactin. Immunoreactive prolactin was found in the chick embryos from the 15th day of development on using the methods of indirect immunofluorescence and of unlabelled antibodies with a complex PAP. In the chick embryos and in chickens during the first 10 days of life, the prolactin-containing cells were distributed, mainly, in the cephalic part of adenohypophysis; in the chickens, scarce cells were also found in the caudal part. These results suggest that in the domestic fowl the immunoreactive prolactin, similar by immunochemical specificity with the mammalian prolactin, is a late appearing marker of the adenohypophysis differentiation.     

Immunohistochemical study of the appearance of somatotropic hormone in the adenohypophysis of chick embryos

The differentiation of somatotropocytes was studied in the Leghorn chick embryos during 11 to 18 days of incubation and in chickens during the first week of life using the immunohistochemical method of nonlabelled antibodies with PAP complex and antiserum against human somatotropic hormone (STH). Unlike in humans, the fixation of pituitaries in the Carnoy mixture is optimal for STH to be immunohistochemically estimated in the chickens and chick embryos. STH was found in adenohypophysis from 12-13 days of development. Besides predominant localization of somatotropocytes in the adenohypophysis caudal lobe, individual STH-positive cells are also present in the cephalic lobe of chickens and chick embryos. The results obtained suggest a relatively late appearance of STH during histotypical development of adenohypophysis in chick embryos.     

Tissue specific antigen of the caudal lobe of the chicken adenohypophysis]

The tissue-specific water-soluble antigen of the chick pituitary gland was revealed by immunochemical analysis. The content of this antigen was found to be predominant in the caudal lobe of the adenohypophysis. The antigen was found from the 13th day of embryogenesis by immunoelectrophoresis and immunofluorescence. Two kinds of the antigen (with high and low relative electrophoretic mobility) were discovered in the chick adenohypophysis. A conclusion was drawn that the adenohypophysis cells differed by the differentiation level.     

Ultrastructural differentiation of glandular stomach (proventriculus) in chick embryo

Cytochemical characterization of mucosubstances of chick glanular stomach (proventriculus) changes from 15 days of development to postnatal and adult stages was studied. To corroborate these data cytochemical, ultrastructural and ultracytochemical study of chick embryo proventriculus from 7 to 20 days of development was performed. At the 7th day several layers of undifferentiated cells formed an epithelium which covered the walls of the glandular stomach. Mocosubstances were not found. Between the 9th and 5th day a single layer of cylindrical cells was encountered forming invaginations which originated deep glands. Three types of cells were separated from the above mentioned layer, dark, clear and undifferentiated. The dark cells had organelles which are involved in protein synthesis and the clear ones were rich in mitochondria. Argentaffine cells appeared at 15th day instead mucosubstances formed a thin coat on the epithelium at 9th day which increased at the end of development in the apical cytoplasm and gland cells. These observations demonstrate that proventriculus of chick embryo has ultrastructurally differentiated cells involved with enzymatic and hydrochloric acid secretion after the 9th day. These progressive events are correlated with the digestion process of yolk during embryogenesis. At the end of development the proventriculus has completely organized the glandular layer.     

The overlapping effects of thyrotropin and gonadotropins on chick embryo gonads in vitro

Pieces of 12- and 15-day-old chick embryo testes and ovaries were cultured in vitro in the presence of thyrotropin (TSH), gonadotropins (FSH + LH) and adrenocorticotropin (ACTH) for different periods. All the explants of treated gonads differentiated into typical testes or ovaries according to their genetic sex. The gonads of 12-and 15-day-old chick embryos showed a good response to both thyrotropic and gonadotropic stimulation. On the other hand, they did not respond to adrenocorticotropic stimulation. Fifteen-day-old chick embryo testes were grown in tissue culture in the presence of the said hormones. Gonadotropins and TSH enhanced the growth and migration of testicular cells as compared with the control or ACTH treated group. In addition, they maintained the germ cells on the upper surface of epithelial cells. These results have confirmed our previous results in vivo in that gonadotropins and thyrotropin hormones accelerated the development of 12- or 15-day-old chick embryo gonads.     

Changes induces by haloperidol (antidepressant drug) on the developing retina of the chick embryo

Morphological and histological studies were done on the retina of chick embryos of 6th, 10th and 16th days of incubation by a single dose of haloperidol (0.25 mg/egg), injected on day zero and 5 of incubation. To get an idea about the extent of the teratogenic effect of this drug on the development retina. Sign of malformation in the chick embryo after administration of haloperidol were seen as absent of the ear vesicles, eyes or decreased size of them. Retardation of growth of the retina at 6th, 10th and 16th days treated chick embryo were observed as evidenced of reduction of the size of the retina, associated with sign of degeneration of the retina cells.

Conclusion

The injection of haloperidol drug give rise to several side effects as retardation of growth and degeneration of the cells. The decrease of the thickness of the layers and less density of the cells was related to direct effect of the drug on the cells of this organ. Also on the DNA formation and on the retardation of cellular mitotic activates, therefore the retina appeared decrease in thickness and less cell density with degeneration its cells.     

Light- and electron-microscopic studies on the secretory cytology of the adenohypophysis of the Japanese quail,Coturnix coturnix japonica

The effects of thyroidectomy, adrenalectomy, and castration on the pars distalis of male Japanese quail, and of injection of LH-RH on sexually inactive females, were investigated by light and electron microscopy. Correlation between light and electron microscopy was attained by use of alternate thin and thick sections. Six types of secretory cells were identified and the ultrastructural characteristics described. Putative endocrine functions have been designated on the basis of responses to experimental interventions and on other criteria. The putative STH cells are characterized by the presence of large dense secretory granules (250-300 nm) that are stained with orange-G by the trichrome method. They occur only in the caudal lobe and appear to be unchanged by castration, thyroidectomy, adrenalectomy and LH-RH injection. The putative prolactin cells are characterized by large (400-600 nm), spherical or polmorphic, dense secretory granules stainable with acid fuchsin and aniline blue; prominent Golgi apparatus and well developed endoplasmic reticulum with densely packed, regularly parallel lamellae. They are found mainly in the cephalic lobe. The prolactin cells develop some vacuolization after adrenalectomy and undergo some degeneration after castration. The ACTH cells, which are restricted to the cephalic lobe, are identified by the dense, spherical granules (250-300 nm) that are stained with acid fuchsin. After adrenalectomy, they lose their secretory granules and are transformed into large, chromophobic adrenalectomy cells. TSH cells are so designated by their response to thyroidectomy including loss of their fine secretory granules and transformation to large, vacuolated thyroidectomy cells. We have found TSH cells and thyroidectomy cells only in the cephalic lobe. Basophilic cells, considered to be gonadotropes, occur in both the cephalic and caudal lobes. The gonadotropes of the cephalic lobe appear to have slightly larger (120-200 nm) granules than the caudal lobe (120-150 nm). However, after castration, the gonadotropes in both lobes become hypertrophied and vacuolated and are transformed into mutually indistinguishable castration cells. Twenty minutes after injection with LH-RH, the gonadotropes of both lobes increase in size and number, degranulate, develop vacuoles in the cytoplasm, and appear very similar to castration cells.