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.     

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.     

Early stages of testicular differentiation in the rat

Summary The initial phases of the development of the seminiferous cords (future seminiferous tubules) were studied with histological techniques and with electron microscopy. On day 14 after fertilization, seminiferous cords are well differentiated in the anterior part of the testis near the mesonephric tubules. They comprise Sertoli cells which encompass the primordial germ cells. The Sertoli cells show an expanded clear cytoplasm and microfilaments beneath the outer surface; they differentiate complex contact zones. On day 13 a few cells localized near the mesonephric tubules display the characteristics of the Sertoli cells. These cells become more and more numerous. They aggregate and they form the seminiferous cords.The primordia of male gonads explanted in vitro on the mesonephros, realize testicular organogenesis in a synthetic medium. Adding 15% fetal calf serum to the medium prevents the morphogenesis of the testicular cords, although the Sertoli cells seem to differentiate morphologically and physiologically. In these gonads differentiation of the Sertoli cells was obtained but their aggregation and the morphogenesis of the seminiferous cords were prevented. This gives new insights into testicular morphogenesis and probably provides an experimental model for a new type of gonadal anomaly.     

TEMPORAL RELATIONS BETWEEN EXTENSION OF ARCHENTERON ROOF AND REALIZATION OF NEURAL INDUCTION DURING GASTRULATION OF NEWT EMBRYO

This investigation was performed in order to analyze the basic relationships between the archenteron roof and the overlying ectoderm in primary induction in the Cynopus (Triturus) pyrrhogaster embryo.
The part of the archenteron roof that is active in inducing capacity extends linearly after invagination at the speed of 0.15 mm per hr at 23°C until stage 13b. The period of contact at each position of the presumptive neuro-ectoderm with the active archenteron roof could be estimated by the formula described in the Discussion.
Pieces of the presumptive neuro-ectoderm were isolated from gastrulae at three developmental stages and cultured separately in Holtfreter solution after being divided caudo-cranially into 4 parts. The result showed that some of them were able to differentiate into neural tissues even in the mid-gastrula stage and that the presumptive neuro-ectoderm acquired the capacity to differentiate into neural tissue along a caudocranial axis from the part adjacent to the blastopore during gastrulation.
It could be estimated that 3 hr of contact with the active archenteron roof is sufficient for the presumptive neuro-ectoderm to differentiate into neural tissue.
The present study also showed that the neuralizing capacity of the whole prospective neuro-ectodermal area has already been determined before the end of stage 13, i.e., within less than 14 hr after first contact of the ectoderm with the active archenteron roof at 23°C.     

The structure and composition of the complex that provides the adhesion of the cellular layers during the morphogenesis of the human embryonic adenohypophysis]

The area of contact between adenohypophysis and diencephalon rudiments of human embryos (5-7 weeks of development) was studied using immunohistochemistry and electron microscopy. Basement membranes of Rathke's pouch ectoderm and of diencephalon bottom neuroectoderm are connected by means of a complex consisting of thin fibrous material and collagen-like fibrils. After Ca+2 and Mg+2 ions removal, this complex with basement membranes was separated from epithelial layers. The material in the contact area differed in its composition from the basement membranes covering the adenohypophysis and diencephalon rudiments by the high content of tenascin and the absence of EDB-fibronectin. Other basement membrane components (collagen IV, heparan-sulphate proteoglycans, entactin and laminin) were also present in this area. Tenascin accumulation was also found in Rathke's pouch epithelium and cavity.     

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.     

Immunochemical identification of the growth hormone and prolactin in the hypophyseal polypeptide spectrum of chickens

Forty-eight fractions of polypeptides including 39 fractions with a molecular weight of 14-95 kD were identified in chick adenohypophysis by sodium dodecyl sulphate electrophoresis in 10-20% gradient polyacrylamide gel slabs. The immunochemical identification of the polypeptides was performed with the aid of the electroblotting of proteins and antisera to human STH, to bovine prolactin, and to the tissue-specific antigen A-1 of chick adenohypophysis. Antisera to human STH and to antigen A-1 reacted with the same major polypeptide fraction, m.w. 26 kD, characteristic of the caudal lobe of the adenohypophysis. Immunoreactive prolactin was present in chick adenohypophysis in the form of a polypeptide fraction with a molecular weight of 25 kD and in the form of two minor fractions of polypeptides with molecular weights of 27 and 28 kD. The data obtained indicate the identity of the adenohypophyseal tissue-specific antigen A-1 to chick STH.     

Regulation of Sox2 in the pre‐placodal cephalic ectoderm and central nervous system by enhancer N‐4

The development of various tissues originating from the cephalic placodes is accompanied by the expression of the Sox2 gene. This Sox2 expression initiates in the pre‐placodal cephalic ectoderm, and is regulated by enhancer N‐4, which also regulates Sox2 in the embryonic central nervous system (CNS) posterior to the diencephalon. As the regulation of enhancer N‐4 in the ectoderm likely reflects that of the pre‐placodal cell state, its regulatory elements were characterized. A 110‐bp minimal and essential sequence of N‐4 (mini‐N‐4) was determined. By mutational and deletion analyses, nine regulatory elements were determined in the mini‐N‐4 sequence: three elements involved in activation in both the cephalic ectoderm and CNS, three elements specifically involved in activation in the cephalic ectoderm, three elements individually involved in activation in the mesencephalon, repression in the prosencephalon, and retinoic acid response in the rhombomeric region. The cephalic ectoderm‐specific elements include two potential sites for the binding of nuclear receptors, suggestive of a nuclear receptor‐dependent regulation. Multimers of the 3′ half of the mini‐N‐4 sequence, including all of the cephalic ectodermal elements, show strong and selective activity in the cephalic ectoderm, providing a powerful genetic tool for the manipulation of gene activities in the placodal lineages.     

Quantitative localization of polystyrene microspheres following microinjection in the avian metencephalic neural crest pathway

Polystyrene microspheres were microinjected into crest populations at two preotic sites in Hamburger-Hamilton stage 10 and 11 chick embryos to investigate factors modulating cephalic neural crest fate. Analyses of microsphere localization and comparisons with cephalic crest fate maps indicated the following: microspheres injected at stage 10 localized with derivatives reflecting the fate of the crest population at the injection site; microspheres injected at stage 11 exhibited minimal displacement; and localization in ectoderm was similar in embryos injected at either stage. These results suggest that microinjected microspheres can be used to investigate normal and abnormal craniofacial morphogenesis.     

Change of the differentiation pattern of amphibian ectoderm after the increase of the initial cell mass

Summary Early amphibian gastrula ectoderm (Triturus alpestris) has been treated with vegetalizing factor. While normal sandwiches (animal caps of two eggs) differentiated mainly into endoderm derived tissues, giant-sandwiches (a combination of 8 animal caps) formed mesodermal and neural tissues in addition. The results support the interpretation that ectoderm will differentiate into endoderm derived tissues when all or nearly all cells are induced (presumably depending on certain threshold concentrations of the inducer). This is the case in the normal sandwich after treatment with high concentrations of vegetalizing factor for 24 h. However, in a giantsandwich it must be assumed that only the cells in the vicinity of the inducer will be triggered to differentiate into endoderm derived tissues. Mesodermal structures will be formed by secondary interactions between the induced ectoderm (endoderm) and non induced ectodermal cells. The induction of neural structures could be explained as a further interaction between mesodermalized and non induced ectodermal cells. This chain of events is compared with the steps of determination in normogenesis.     

Detailed analysis of the δ-crystallin mRNA-expressing region in early development of the chick pituitary gland

Although δ-crystallin (δ-crys), also known as lens protein, is transiently expressed in Rathke's pouch (RP) of the chick embryo, detailed temporal and spatial expression patterns have been obscure. In this study, to understand the relationship between the δ-crys mRNA-expressing region and RP formation, we examined the embryonic expression pattern of δ-crys mRNA in the primordium of the adenohypophysis. δ-crys mRNA expression was initially found at stage 15 anterior to the foregut and posterior to the invaginated oral ectoderm. After RP formation, the δ-crys mRNA was expressed in the post-ventral region of RP and the anterior region of RP. δ-crys mRNA expression was then restricted to the cephalic lobe of the pituitary gland. From stage 20, the δ-crys and alpha-glycoprotein subunit (αGSU) mRNA-expressing regions were almost completely overlapping. The αGSU mRNA-expressing region is thought to be the primordium of the pars tuberalis, and these regions were overlapped with the Lhx3 mRNA-expressing region. The intensity of δ-crys mRNA expression gradually decreased with development and completely disappeared by stage 34. These results suggest that the embryonic chick pituitary gland consists of two different regions labeled with δ-crys and Lhx3.     

Detailed analysis of formation of chicken pituitary primordium in early embryonic development

The primordium of the mammalian adenohypophysis derived from Rathke's pouch (RP) is known to be formed by oral ectoderm invagination. However, in the early phase of pituitary development, the detailed process by which the oral ectoderm develops into the adenohypophysis remains largely unknown. Using high-resolution non-radiolabeled in situ hybridization and the BrdU and TUNEL methods, we have examined the detailed expression pattern of factors involved in the formation of RP of chicken and the changes in the mitotic and apoptotic cell regions in RP. In the chicken embryo, Sonic hedgehog (Shh) mRNA was initially expressed in the stomodeal plate but not in the oral ectoderm. After prospective diencephalon had detached from the oral ectoderm, another Shh-expressing region appeared in the most rostral part of the recess. LIM homeobox gene 3 (Lhx3) mRNA first appeared in the anterior area of Rathke's recess, and expression then spread to the caudal region. alphaGSU mRNA-expressing cells were observed at both ends of the Lhx3-expressing region, and thereafter the expression area moved to the posterior region. Furthermore, a close overlap was found between the proliferating region and Lhx3 mRNA-expressing area, and TUNEL-positive cells appeared in Seessel's pouch derived from the foregut. Thus, the primordium of the pituitary gland corresponding to the Lhx3-expressing region is surrounded by the Shh-expressing region, which appears in two steps, and the mass growth and invagination of RP of chicken result from the coordination of the dorsal extension of the anterior region and the ventral extension of the posterior region of RP.     

Neural-inducing activity of newly mesodermalized ectoderm

Summary The neural-inducing activity of artificially mesodermalized ectoderm was examined. The competent ectoderm of earlyCynops gastrula was mesodermalized by being placed in contact withCarassius swimbladder. The mesodermalized ectoderm was combined with ectoderm isolated from various developmental stages of a gastrula. Neural differentiation were observed in half the combinants, even in 18 h ectoderm, which is considered to have lost its neural competence within 6 h. This indicates that mesodermalized ectoderm is capable of inducing neural tissues at the very time it comes into contact with 18 h ectoderm. From the present study, the neural-inducing activity of mesodermalized cells may possibly be closely connected to the early process of their mesodermalization.     

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.     

Head morphogenesis in embryonic avian chimeras: evidence for a segmental pattern in the ectoderm corresponding to the neuromeres

Areas of the superficial cephalic ectoderm, including or excluding the neural fold at the same level, were surgically removed from 3-somite chick embryos and replaced by their counterparts excised from a quail embryo at the same developmental stage. Strips of ectoderm corresponding to the presumptive branchial arches were delineated, thus defining anteroposterior 'segments' (designated here as 'ectomeres') that coincided with the spatial distribution of neural crest cells arising from the adjacent levels of the neural fold. This discrete ectodermal metamerisation parallels the segmentation of the hindbrain into rhombomeres. It seems, therefore, that not only is the neural crest patterned according to its rhombomeric origin but that the superficial ectoderm covering the branchial arches may be part of a larger developmental unit that includes the entire neurectoderm, i.e., the neural tube and the neural crest.     

Development of separated germ layers of rodent embryos on ectopic sites: a reappraisal.

The method of separation of germ layers of rodent embryos by treating the embryonic shields with proteolytic enzymes and by microsurgery with the subsequent transplantation to ectopic sites has helped to gain a more detailed insight into what is going on during gastrulation in mammals. The space under the kidney capsule of adult animals seems to be the most appropriate ectopic site for transplantation of early postimplantation rat embryos or separated germ layers. After transplantation the grafts develop into teratomas whose complex histological structure reflects the initial developmental capacities of the graft. At the pre-primitive streak and the early primitive streak stages the primitive ectoderm differentiates into tissue derivatives of all three definitive germ layers, often in complex organotypic combinations. This is indirect evidence that all cells of the embryonic body originate from the primitive embryonic ectoderm. Halves of the primitive ectoderm obtained by a longitudinal or transverse cut through the egg cylinder give the same result. At the head fold stage the capacity for differentiation of the ectoderm is restricted to ectodermal and mesodermal derivatives. One day before gastrulation the isolated primitive ectoderm is not able to differentiate as renal isograft. The mesoderm isolated at the head fold stage and at later stages when its segmentation occurs, differentiates almost exclusively into the brown adipose tissue. The embryonic endoderm differentiates only in combination with the mesoderm. After transplantation the embryonic ectoderm loses its epithelial organization and breaks up into a mass of mesenchyme-like cells in which epithelial structures subsequently appear and differentiate in a way reminiscent of the reaggregation of cells in mixed cell suspension in vitro.     

Substance P in the blood plasma in hypophysial portal vessels

The aim of the present study was to check if Substance P (SP) is released from the hypothalamus into the hypophysial portal vessels and by this route exerts its direct influence on the adenohypophysis. For this purpose SP radioimmunoactivity was assayed in the blood plasma collected from hypophysial portal vessels and from the cephalic end of the external jugular vein. The SP levels in blood plasma collected from hypophysial portal vessels and from the jugular vein do not differ significantly. Neither does application of a noxious factor, such as bilateral femoral bone fracture, change significantly the SP level in the blood plasma from portal vessels and from the jugular vein. Hypoxia seems to increase the SP level in portal blood plasma and may be followed by its decrease. It is concluded that hypothalamic SP is not released into the hypophysial portal vessels under normal conditions and its direct influence on the adenohypophysis is not mediated this way.