Chx10 functions as a regulator of molecular pathways controlling the regional identity in the primordial retina.

The light-sensitive neural retina (NR) and the retinal pigmented epithelium (RPE) develop from a common primordium, the optic vesicle, raising the question of how they acquire and maintain distinct identities. Here, we demonstrate that sustained misexpression of the Chx10 homeobox gene in the presumptive RPE in chick suppresses accumulation of melanin pigments and promotes ectopic NR-like neural differentiation. This phenotypic change involved ectopic expression of NR transcription factor genes, Sox2, Six3, Rx1 and Optx2, which, when misexpressed, counteracted RPE development without upregulating Chx10. These results suggest that Chx10 can function as a cell autonomous regulator of the regional identity in the primordial retina, presumably through a downstream transcriptional cascade.

Temporal dissociation of developmental events in the chick eye under low temperature conditions.

The chick embryonic eye is an excellent model for the study of vertebrate organogenesis. Key events in eye development involve thickening, invagination and cytodifferentiation of the lens primordium. While these events occur successively at different developmental stages, the extent to which these events are temporally related is largely unknown. Here we show that the lens invagination is highly sensitive to temperature. Lowering of incubation temperature to 29°C at embryonic day 2 delayed the onset of invagination of the lens, but not thickening and cytodifferentiation, leading to abnormal protrusion of the eye. The temperature shift also delayed the inward bending of the underlying retinal primordium, even in the absence of the lens. Taken together, our results suggest that lens invagination is initiated independently of thickening and cytodifferentiation, possibly by mechanisms associated with morphogenesis of the primordial retina.

Phospholipase C-delta1 is an essential molecule downstream of Foxn1, the gene responsible for the nude mutation, in normal hair development.

Nude mice exhibit athymia and hairlessness by a loss-of-function mutation in the transcription factor Foxn1 gene. Although the immunological functions of Foxn1 have been studied intensively, there have been relatively few studies of its functions in skin. Foxn1 regulates expression of hair keratins, which is essential for normal hair structure; however, how Foxn1 regulates hair keratin expression and hair formation is largely unknown. In the present study, we found that mice lacking phospholipase C (PLC)-delta1, a key molecule in the phosphoinositide signaling pathway, and nude mice show similar hair abnormalities, such as lack of cuticle and bending. We also found that expression of hair keratins was remarkably decreased in skin of PLC-delta1 knockout mice. Furthermore, expression of PLC-delta1 was induced in Foxn1-transfected U2OS cells. In addition, we showed that PLC-delta1 expression was remarkably decreased in skin of nude mice. In skin and keratinocytes of nude mice as well as PLC-delta1 KO mice, activation of PLC downstream effectors, such as PKC and nuclear factor of activated T cells, was impaired. These results indicate that PLC-delta1 is an essential molecule downstream of Foxn1 in normal hair formation, and strongly suggest that hairlessness in nude mice is caused by insufficient expression of PLC-delta1.

Molecular analysis of endoderm regionalization.

We have engaged in a number of studies in our laboratory that have focused on the molecular mechanisms underlying gut formation, with particular attention being paid to the establishment of regional differences found in the entire gut and within each digestive organ. We have found from our analyses that the presumptive fate of the endoderm in the embryos of vertebrates is determined quite early during development, but the realization of this fate often requires molecular cues from the neighboring tissues such as the lateral plate mesoderm and the mesenchyme derived from it. The mesenchyme seems often to exert instructive or supportive induction effects and, in some cases, a completely inhibitory role during the differentiation of the endodermal epithelium. In addition, many reports on the formation of the stomach, intestine, liver and salivary gland in vertebrates, and of Drosophila gut, all indicate that the morphogenesis and cytodifferentiation of these organs are regulated by the regulated expression of genes encoding growth factors and transcription factors. We have further shown that the epithelium can regulate the differentiation of the mesenchyme into the connective tissue and the smooth muscle layers, thus demonstrating the occurrence of literally interactive processes in the development of the digestive organs.

Expression patterns of the chicken peroxisome proliferator-activated receptors (PPARs) during the development of the digestive organs.

Peroxisome proliferator-activated receptors (PPARs) play very important roles in various biological phenomena such as regulation of lipid metabolism, homeostasis, cell differentiation and proliferation, in a variety of organs and tissues. However, their functions in the development of the digestive organs have not been studied yet, although it has been supposed that they are involved in the tumor development and regression of digestive organs. To provide fundamental data to analyze functions of PPARs in the developing digestive organs in the chicken embryos, we performed thorough analysis of expression of PPARalpha, beta (delta) and gamma in the esophagus, proventriculus (glandular stomach), gizzard (muscular stomach), small and large intestines from early developmental stages to post hatch stages. The results showed that each PPAR is expressed in spatio-temporally regulated manner. In general, PPARbeta is widely expressed among digestive organs whereas PPARalpha and gamma showed restricted expression. In the intestine, all PPARs are expressed after hatch, indicating that they play important roles in the physiology of the adult intestine.

Expression of Fgf10 and Fgf receptors during development of the embryonic chicken stomach.

Fibroblast growth factor 10 (FGF10) is involved in numerous different aspects of embryonic development and especially in active epithelial-mesenchymal interactions during morphogenesis of many organs as a mesenchymal regulator by activating its receptors (FGFR1b and FGFR2b) expressed in the epithelial tissue. FGFR2b is also activated by FGF7 although FGF7 does not bind to FGFR1b. To provide basic data to analyze function of FGFs in the developing gut, here we cloned Fgf7 and studied expression patterns of Fgf7, Fgf10 and Fgfr1-4 during the development of chicken stomach (glandular stomach; proventriculus and muscular stomach; gizzard). Fgf10 is expressed both in the proventricular and gizzard mesenchyme while Fgf7 is expressed only in gizzard mesenchyme. Fgfr1-4 are expressed both in the epithelium and mesenchyme with a different spatial expression patterns. Furthermore, RT-PCR analysis reveals that Fgfr1b and Fgfr2b are expressed only in epithelia of both organs.

Down-regulation of endodermal Shh is required for gland formation in chicken stomach.

During the development of the proventriculus (glandular stomach) of the chicken embryo, the endodermal epithelium invades into the surrounding mesenchyme and forms glands. The glandular epithelial cells produce pepsinogen, while the non-glandular (luminal) epithelial cells secrete mucus. Sonic hedgehog is expressed uniformly in the proventricular epithelium before gland formation, but its expression ceases in gland cells. Here we present evidence that down-regulation of Sonic hedgehog is necessary for gland formation in the epithelium using a specific inhibitor of Sonic hedgehog signaling and virus mediated overexpression of Sonic hedgehog. We also show that gland formation is not induced by down-regulation of Sonic hedgehog alone; a mesenchymal influence is also required.

Molecular analysis of the determination of developmental fate in the small intestinal epithelium in the chicken embryo.

Determination of the developmental fate in the small intestinal epithelium of the chicken embryo has not been fully analyzed up to the present. This study was carried out to analyze the determination time of the developmental fate of the small intestinal epithelium under the influence of other mesenchymes. The small intestinal epithelium reassociated and cultivated with the proventricular or gizzard mesenchyme or the dermis expressed chicken intestinal fatty acid binding protein, sucrase and CdxA as occurs during the normal development of the small intestinal epithelium. The presumptive intestinal endoderm taken from an earlier stage embryo and associated and cultivated with the proventricular or gizzard mesenchyme, showed gene expression patterns which were the same as those found in normal development. However, when the dermis was associated, the epithelium expressed sonic hedgehog, but never expressed intestinal epithelial- or stomach epithelial-markers. These results indicate that the determination of the developmental fate in the small intestinal epithelium and acquisition of autodifferentiation potency occur at the early stage of the gut development. Moreover the presumptive intestinal endoderm needs the supportive influence of the gut mesenchyme in order to differentiate fully into the intestinal epithelium.

Expression of DDSG1, a novel gene encoding a putative DNA-binding protein in the embryonic chicken nervous system.

In an attempt to clone genes expressed in the gizzard of the chicken embryo by differential display, we obtained a cDNA of a gene encoding a protein with a putative nuclear localization signal and a DNA-binding motif and designated it DDSG1 (differential display-screened gene expressed in the gizzard-1). Besides its expression in the gizzard, the gene is expressed in central and peripheral nervous systems such as brain, spinal cord and dorsal root ganglia in specific patterns.

CHRONOLOGICAL CHANGES IN THE INDUCTIVE ABILITY OF THE MESENCHYME OF THE DIGESTIVE ORGANS IN AVIAN EMBRYOS.

Dissociation and reassociation experiments were carried out to study the inductive ability of mesenchyme of the oesophagus, gizzard and intestine of the chicken embryo, using 3-day-old quail embryonic allantoic endoderm as an effector tissue. The mesenchyme of the oesophagus and gizzard possesses inductive ability until the Ilth day of incubation. Thereafter, it no longer has inductive influence upon the allantoic endoderm. The intestinal mesenchyme was favourable to differentiation of allantoic endoderm into intestinal epithelium even on the I5th day of incubation. In all types of recombination tested, goblet cells differentiated among allantoic endodermal cells.

OBSERVATIONS ON SUPERNUMERARY HEAD FORMATION INDUCED BY LITHIUM CHLORIDE TREATMENT IN THE REGENERATING HYDRA, PELMATOHYDRA ROBUSTA.

Lithium chloride treatment of hydras cut just proximal to the tentacle circle and just distal to the budding region induces a supernumerary head at the proximal cut surface. Such a supernumerary head does not appear in the normal course of regeneration. The bipolar hydra thus formed persists for several weeks and later separates to form two normal individuals. The supernumerary head is not formed at the proximal cut surface when the hydra is transected just distal to the budding zone and the distal portion is allowed to regenerate in the Li-containing medium. LiCl has a slight inhibitory effect on the regeneration of hypostomes or tentacles when the animal is cut at the base of the hypostome.

Induction and Inhibition of Epithelial Differentiation by the Mixed Cell Aggregates of the Mesenchymes from the Chicken Embryonic Digestive Tract: (epithelial-mesenchymal interaction/mesenchymal cell aggregates/pepsinogen induction/gland formation/in vitro differentiation).

Epithelial-mesenchymal interaction plays an important role in the differentiation of digestive tract. However, the factors of these mesenchymes involved in induction of the epithelial differentiation of each organs are still unknown. In the present study, we made reconstituted mesenchymal cell aggregates by mixing proventricular mesenchymal cells with other mesenchymal cells, recombined the reconstituted mesenchyme with gizzard epithelium, and observed the differentiation of the gizzard epithelium in the explants with special attention to the appearance of embryonic chicken pepsinogen, one of the molecular marker of the proventricular epithelial cells, in the gizzard epithelium. The results showed that the proventricular mesenchymal cells induce gland formation and pepsinogen in the gizzard epithelium and that the esophageal and gizzard mesenchymal cells have the inhibitory influence on the differentiation of epithelia toward proventricular epithelium. The cells from small-intestinal, lung and dorsal dermal mesenchyme have no such effect. Based on the results obtained so far, a hypothesis was presented to explain the mechanism regulating the differentiation of the epithelium in the digestive tract in the chicken embryo.

DIFFERENTIATION OF THE DIGESTIVE TRACT EPITHELIUM UNDER THE INFLUENCE OF THE HETEROLOGOUS MESENCHYME OF THE DIGESTIVE TRACT IN THE BIRD EMBRYOS.

The endoderm of the oesophagus, proventriculus, gizzard or small intestine of the 5-day-old chick or quail embryo was cultivated in combination with homologous or heterologous mesenchyme on a WxxxOLFFyyy and HxxxAFFHNyyy medium for 7 to 21 days or on the chorio-allantoic membrane (CAM) for 8 days. With homologous mesenchyme the epithelium always differentiated homotypically. In association with heterologous mesenchyme, the differentiation of the epithelium was both homotypical and heterotypical depending on the region of the digestive tract. The oesophagus and small intestine differentiate mainly homotypically both in culture and on CAM, but the gizzard and proventriculus show heterotypic differentiation particularly on CAM. Thus, the endoderm of the digestive tract of the 5-day-old chick or quail embryo, though rather "determined", still reacts to the heterologous stimuli of the mesenchyme to some degree.

Cultivation of chicken proventricular epithelial cells and their potential for differentiation.

Epithelial cells of chicken proventriculus (glandular stomach) differentiate into two types; luminal and glandular epithelial cells. The molecules regulating the differentiation of proventricular epithelial cells are not well understood. As the first step in screening the molecular determinants involved in the cell differentiation process, we tried to establish an in vitro culture system for isolated proventricular epithelial cells. Various basal media, growth factors and sera were tested. The medium that supports well the proliferation of epithelial cells was composed of Ham's F12 as the basal medium with epidermal growth factor (10 µg/mL), insulin (10 µg/mL), cholera toxin (1 µg/mL) and bovine pituitary extract (100 µg/mL). Fetal calf serum stimulated cell proliferation 1.7-fold, while horse serum was rather toxic. Proventricular epithelial cells proliferated for 3 days, but began to die out within 1 week of culture. Cultured epithelial cells never expressed embryonic chicken pepsinogen (ECPg), a marker gene of glandular epithelial cells, or maintained ECPg expression. The capacity for ECPg expression in cultured epithelial cells was analyzed by recombination with the proventricular mesenchyme and ECPg was detected in epithelial cells cultured up to 3 days. We concluded therefore, that epithelial cells keep the capacity for ECPg expression for 3 days of cultivation and proventricular mesenchymal cells are required for the actual expression of the ECPg gene.

Early Determination of Developmental Fate in Presumptive Intestinal Endoderm of the Chicken Embryo: (determination/epithelial-mesenchymal interaction/stomach/intestine).

The endodermal epithelia of esophagus, proventriculus and gizzard of 6-day chicken embryos can form glands and express embryonic chicken pepsinogen (ECPg), when they are subjected to the influence of proventricular mesenchyme, while intestinal epithelium of the same age cannot respond to the inductive influence of proventricular mesenchyme. We attempted in this paper to know whether this regional difference of epithelia to respond to mesenchymal influence originates very early in development or it is established gradually in the course of development of digestive tract. The young presumptive intestinal endoderm taken from embryos having 15-20 somites was associated and cultivated with 6-day proventricular mesenchyme. The presumptive intestinal endoderm never expressed ECPg although it formed gland-like structures. In the control explants composed of presumptive stomach endoderm and proventricular mesenchyme, glands were formed and gland cells expressed ECPg detected by immunocytochemistry and in situ hybridization. These results indicate that the developmental fate of presumptive intestinal endoderm is determined rather strictly at very early developmental stage, and suggest that the segregation of at least two cell lineages occurs early in the development; one which can express ECPg under the influence of proventricular mesenchyme, and another one which cannot express ECPg and differentiates mainly into intestinal epithelium.

Pepsinogen Induction in Chick Stomach Epithelia by Reaggregated Proventricular Mesenchymal Cells In Vitro: (stomach/organ culture/pepsinogen/induction/epithelial-mesenchymal interaction).

In vitro organ culture system which permits embryonic chick proventriculus (glandular stomach) to synthesize pepsinogen de novo was developed. Explants of the proventricular rudiment were cultured on Millipore filters in Medium 199 with Earle's salts supplemented with 50% 12-day embryo extract at 38°C in 95% air and 5% CO2 . In these culture conditions, pepsinogen, a functional marker protein of proventriculus, was first detected after 3 days of cultivation of 6-day chick proventricular rudiment. When recombined and cultured with 6-day proventricular mesenchyme, 6-day oesophageal, proventricular or gizzard (muscular stomach) epithelium expressed pepsinogen while small intestinal epithelium did not. These results were consistent with the previous results obtained by chorioallantoic membrane (CAM) grafting, and showed that the culture conditions are permissive for pepsinogen expression. When recombined and cultured with reaggregated mesenchymal cells isolated from 6-day proventricular mesenchymal fragments, both 6-day proventricular and gizzard epithelia formed glandular structure and expressed pepsinogen. This indicates that the proventricular mesenchymal cells retain the ability to induce morphogenesis and cytodifferentiation of the proventricular epithelium even if the normal organization of proventricular mesenchyme is once destroyed.

Localization of DNA-synthesizing cells and cell proliferation pattern in developing proventricular (glandular stomach) epithelium of embryonic and hatched chickens.

Localization of DNA-synthesizing cells in the developing proventricular (glandular stomach) epithelium of embryonic and hatched chickens was investigated. DNA-synthesizing cells were scattered throughout the proventricular epithelium during all developmental stages studied. The results indicate that there is no clear proliferative zone in the proventricular epithelium of the chicken. The labeling indices (LI) of proventricular epithelial cells were measured. On the 6.5th day of incubation, the LI of glandular epithelium reached 29.5 ± 1.5%. the highest value of all the stages studied. This extremely rapid cell proliferation can be considered to be a driving force for the elongation of the proventricular glands during the following stages. Just after hatching, the LI of both the glandular and luminal (non-glandular) epithelia significantly increased from those on the 18th day of incubation. It is suggested that the rise in LI possibly reflected proventricular growth to fit in the change in the method of nourishment after hatching. In 2 week old chickens, the LI of both the glandular and luminal epithelia were reduced to approximately 1%. The active production of embryonic chicken pepsinogen in all glandular epithelial cells of the embryonic chicken revealed that proliferation and differentiation are not necessarily exclusive during the embryonic stages of proventricular development.

Mucus-associated antigen in epithelial cells of the chicken digestive tract: Developmental change in expression and implications for morphogenesis-function relationships.

The embryonic chicken digestive tract consists of endodermal epithelium and mesenchyme derived from splanchnic mesoderm. Interactions between these two tissues are important for the establishment of regionality and the subsequent differentiation of digestive organs. In the present study we obtained a monoclonal antibody that reacted with mucus-associated antigen and named it the MA antibody. From 6 days of incubation, this antibody reacted with the esophageal, proventricular and gizzard epithelia. In the proventriculus, the MA antigen was expressed in luminal epithelial cells, while pepsinogen-producing gland cells became MA antigen-negative. The intestinal goblet cells, which secrete mucus, became positive to the antibody from day 13 of incubation. When the esophageal, proventricular or gizzard epithelium of a 6 day embryo was associated and cultivated with the proventricular mesenchyme, the luminal epithelial cells remained reactive to the MA antibody while gland cells were negative or only weakly positive. If the small-intestinal epithelium was cultivated with the proventricular or gizzard mesenchyme, the antigen was detected on the apical surface of the epithelium, suggesting that the expression of the MA antigen was induced by mesenchymal influences in the small-intestinal epithelium. These results suggest that spatio-temporally regulated expression of the MA antigen is controlled by the epithelial-mesenchymal interactions.

Immunological Relationships among Embryonic and Adult Chicken Pepsinogens: A Study with Monoclonal and Polyclonal Antibodies: (chicken pepsinogens/development/antibodies/immunocytochemistry/immunoblotting).

To investigate the immunological relationships of pepsinogen isozymes present in embryonic and adult chicken proventriculi, we obtained monoclonal and polyclonal antibodies to these pepsinogens. Zymograms and immunoblots demonstrated that monoclonal antibody Y37 reacted with both embryonic and slow-migrating adult pepsinogens, while polyclonal antibodies against embryonic pepsinogen and fast-migrating adult pepsinogen were specific for these respective antigens. Shift from embryonic to adult-type pepsinogen occurred at about the time of hatching and the localizations of embryonic and adult-type pepsinogens within proventricular gland cells were found to differ by the indirect immunofluorescence method. Results with these antibodies revealed the immunological relations of these pepsinogens and the unique properties of embryonic chicken pepsinogen.

Versatile roles for sonic hedgehog in gut development.

Sonic hedgehog (Shh) is a gene encoding a protein that can be secreted and act as a morphogen. The protein exerts versatile and important effects on the surrounding cells by binding a specific receptor, named patched. So far Shh has been shown to be involved in the morphogenesis and cytodifferentiation of many organ systems, such as notochord, floor plate, limb, pancreas, and pituitary gland, to mention only a few examples. Shh is also involved in the determination of left-right asymmetry, at least in the chicken embryo. Here we present evidence that Shh is one of the key genes whose activity is pivotal for the normal morphogenesis and differentiation of digestive organs. Epithelial Shh regulates the formation of stomach glands and stratification of the mesenchyme into connective tissue and smooth muscle. It exerts its effect often through the induction of bone morphogenetic protein (BMP) genes in the mesenchyme. Thus, Shh is a key player in the epithelial-mesenchymal interactions in the development of the gut.