Early Determination of Developmental Fate in Presumptive Intestinal Endoderm of the Chicken Embryo

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.     

BMPs are necessary for stomach gland formation in the chicken embryo: a study using virally induced BMP-2 and Noggin expression

Epithelial-mesenchymal interactions are necessary for the normal development of various digestive organs. In chicken proventriculus (glandular stomach), morphogenesis and differentiation of the epithelium depend upon the inductive signals coming from underlying mesenchyme. However, the nature of such signals is still unclear despite extensive analyses carried out using experimental tissue recombinations. In this study we have examined the possible involvement of bone morphogenetic proteins (BMPs) in the formation of stomach glands in the chicken embryo. Analysis of the expression patterns of BMP-2, -4 and -7 showed that these BMPs were present in the proventricular mesenchyme prior to the initiation of the proventricular gland formation. BMP-2 expression, in particular, was restricted to the proventriculus among anterior digestive organs. Virus-mediated BMP-2 overexpression resulted in an increase in the number of glands formed. Moreover, ectopic expression of Noggin, which antagonizes the effect of BMPs, in the proventricular mesenchyme or epithelium, led to the complete inhibition of gland formation, indicating that BMP signals are necessary for the proventricular gland formation. These findings suggest that BMPs are of prime importance as mesenchymal signals for inducing proventricular glands.     

Cryptosporidiosis in zoo and pet birds.

Cryptosporidiosis is recognized as a primary disease in commercially raised chickens, turkeys, and bobwhite quail. Little is known about cryptosporidial infections in zoo and pet birds, although, infections of the small intestines, proventriculus, respiratory tract, and kidneys have been reported. In the present study, we reviewed cases of cryptosporidial infections in zoo and pet birds submitted to the State Veterinary Diagnostic Laboratory, Auburn, Alabama for necropsy or histopathologic examination. We identified infections in cockatiels, white-lored euphonias, bronze mannikin finches, and Australian diamond firetailed finches. Infections in the cockatiels occurred mostly in the small intestine, but parasites were also observed in the esophageal glands, air sacs, and proventriculus of some birds. Separate cases of small intestinal and proventricular infections were identified in the white-lored euphonias. Cryptosporidial parasites were found only in the proventriculus of the bronze mannikin finches and Australian diamond firetail finches. No cases of renal cryptosporidiosis were observed. Co-pathogens or other disease conditions were present in all birds. The Cryptosporidium species responsible for causing proventricular infection in zoo and pet birds may be different from C. meleagridis and C. baileyi.     

Pepsinogen Induction in Chick Stomach Epithelia by Reaggregated Proventricular Mesenchymal Cells In Vitro

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.     

Tissue interaction regulates expression of a spasmolytic polypeptide gene in chicken stomach epithelium

The primitive epithelium of embryonic chicken proventriculus (glandular stomach) differentiates, after day 6 of incubation, into luminal epithelium, which faces the lumen and abundantly secretes mucus, and glandular epithelium, which invaginates into mesenchyme and later expresses embryonic chicken pepsinogen (ECPg). So far it is not well understood how undifferentiated epithelial cells differentiate into these two distinct cell populations. Spasmolytic polypeptide (SP) is known to be expressed in surface mucous cells of mammalian stomach. In order to obtain the differentiation marker for proventricular luminal epithelial cells, we cloned a cDNA encoding chicken SP ( cSP ). Sequence analysis indicated that cSP has the duplicated cysteine-rich domain characteristic of SP. Examination of the spatial and temporal expression pattern of cSP gene revealed that, during embryogenesis, cSP was expressed in luminal epithelial cells of the proventriculus, gizzard, small intestine, and lung, but not the esophagus. In the proventriculus, cSP mRNA was first detected on day 8 of incubation and was localized to differentiated luminal epithelial cells. By using cSP as a molecular marker, the effects of mesenchyme on the differentiation of epithelium were analyzed in vitro . On the basis of these data, a model is presented concerning the differentiation of proventricular epithelium.     

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.     

Functional morphology of the digestive tract epithelium in Phoronis vancouverensis (Pixell): an ultrastructural and histochemical study

The ultrastructure of the gut regions of the marine filter-feeder Phoronis vancouverensis was correlated with enzyme activity as revealed histochemically. The oesophagus, proventriculus, and stomach epithlia showed intense esterase and acid and alkaline phosphatase activity. The staining reaction was confined primarily to small globules in the apical cytoplasm of the epithlial cells. Electron micrographs of the same regions showed a high incidence of zymogenlike granules, with a corresponding abundance of ribosomes and of rough endoplasmic reticulum. Also, the proventricular and to a lesser extent the stomach epithelia were found to contain a large number of lipid bodies. This was confirmed with positive Sudan IV staining for fats. The intestinal region of the gut was found devoid of esterase and phosphatase activity. The epithelial surface in this region was found elaborated into microvilli. The entire gut is ci iated. A new paired-cilium apparatus is described in this phylum. From these findings Phoronis vancouverensis is concluded to be suitably adapted to its continuous filter-feeding existence, with the anterior gut epithelia synthesizing hydrolytic enzymes for release into the lumina of the proventriculus and stomach. Subsequently, in the hindgut the products of initial extra-cellular digestion are absorbed via the microvilli and treated intracellularly within the intestinal epithelium. The proventriculus is further thought to function in lipid absorption and storage. The presence of chromaffin-like granules observed in some proventricular and intestinal epithelial cells suggests that digestion in this phylum may in part be under neurosecretory control.     

Gizzard epithelium of chick embryos can express embryonic pepsinogen antigen,a marker protein of proventriculus

Summary The avian stomach is composed of two distinct organs, the proventriculus and the gizzard. Pepsinogen expression in the proventricular and gizzard epithelia of chick embryos was investigated immunohistochemically with anti-embryonic chick pepsinogen (anti-ECPg) antiserum. In normal development, the ECPg antigen was expressed only in the glandular epithelial cells of the embryonic proventriculus from the 8th day of incubation onwards. However, both proventricular and gizzard epithelia of 6-day embryos expressed the ECPg antigen when recombined and cultured with the proventricular mesenchyme. Chronological studies revealed that the ECPg antigen was first detected in a few epithelial cells at 3 days of cultivation. The percentage of ECPg-positive cells among the total epithelial cells in each recombinant increased with the length of the culture period and all the glandular epithelial cells were positive at 9 days. During this process, the percentage of ECPg-positive cells in each cultured recombinant was similar in proventricular and gizzard epithelia. Moreover, both epithelia could express the ECPg antigen when recombined and cultured with the oesophageal or small-intestine mesenchyme for 9 days, though the percentage of ECPg-positive cells in each cultured recombinant was much lower than that in the cultured recombinant with the proventricular mesenchyme. These results indicate that the gizzard epithelium of 6-day chick embryos possesses a similar potential for pepsinogen expression as the proventricular epithelium of the same age.     

Expression and function of Wnt5a in the development of the glandular stomach in the chicken embryo

The epithelium of the chicken embryonic glandular stomach (proventriculus) differentiates into both a glandular and a luminal epithelium, the cells of which express specific marker genes. The subsequent formation and differentiation of the glands then proceed under the influence of the mesenchyme. To search for possible candidates for the mesenchymal factors involved, we have now investigated the expression and function of Wnt5a in this process. Our current results show that Wnt5a is expressed in the mesenchyme during active gland formation and that overexpression of this gene in ovo results in the increased and ectopic expression of some of the marker genes of the luminal and glandular epithelia. In particular, the overexpression of Wnt5a markedly enhances the expression of the embryonic chicken pepsinogen gene, a marker of the glandular epithelium, indicating its role as a mesenchymal factor that regulates the differentiation of the proventricular epithelium.     

意大利工蜂前胃显微结构观察

通过解剖镜和扫描电子显微镜对意大利工蜂Apismellifera ligusticaL.前胃的形态结构进行了观察,发现前胃包括前胃瓣和前胃管两部分。前胃瓣是由4个瓣片环围而成,球形,在蜜囊中,每个瓣片的长度约为0.8mm,前端为三角形结构,可以运动,边长约为0.35mm,三角形的前缘有较长的毛形结构。在每个三角形顶端各有一个直径约为50μm瘤形突起。前胃瓣最大孔径为0.89～1.00mm,具有调整和控制食物进入中肠的功能。前胃管是一直径0.01～0.02mm的较为柔软的管道,插入中肠5mm,该结构可防止中肠食物的倒流。前胃瓣上有7种毛状结构,分布在前胃瓣的不同部位,该结构的功能是分离和过滤、捕捉和感觉功能。本研究为理解工蜂前胃在消化系统中的功能和作用以及昆虫形态学和昆虫分类学提供理论依据。     

Developmental changes in the ability to express embryonic pepsinogen in the stomach epithelia of chick embryos

Summary The avian stomach is subdivided into two parts, the proventriculus and the gizzard. It has been shown that the gizzard epithelium can express embryonic chick pepsinogen (ECPg) antigen, a marker protein of the proventricular epithelium, as well as normal proventricular epithelium, under the appropriate experimental conditions. To study the possible mechanisms involved in the suppression of ECPg synthesis in the gizzard epithelium during normal development, we carried out heterotypic and heterochronic recombination experiments of the epithelium and mesenchyme of these two organ rudiments. When recombined and cultured with 6-day proventricular mesenchyme, gizzard epithelium of 3.5- to 12-day embryos expressed pepsinogen at all stages tested. However, the ratio of ECPg-positive cells to total epithelial cells in the gizzard epithelium decreased rapidly when epithelium older than 7 days was cultured with proventricular mesenchyme. In contrast to proventricular mesenchyme, 6-day gizzard mesenchyme did not allow ECPg expression in associated proventricular epithelium of 3.5- to 7-day embryos. These results indicate that gizzard epithelium does not express pepsinogen in normal development because of both a decrease in ability to express the enzyme in itself in the course of development and a repressive influence of gizzard mesenchyme.     

Localized distribution of a novel mesenchyme-specific antigen in developing chick digestive organs

Summary The mesenchymes of the two avian stomachs, the proventriculus (glandular stomach) and the gizzard (muscular stomach), exert different inductive influences on stomach epithelial morphogenesis and cytodifferentiation. To search for a molecular difference between these two mesenchymes, we have produced monoclonal antibodies directed against chick proventriculi and gizzards and have screened those that differently recognized proventricular and gizzard mesenchymes. Finally, we obtained one monoclonal antibody, T95, and characterized it immunohistochemically. T95 characteristically stains the mesenchymal region just under the gizzard epithelium from 6 days of incubation onward to about 10 days of incubation, while it stains proventricular mesenchyme only weakly during these stages. We also examined immunohistochemically the distribution of well-known extracellular matrix molecules, such as fibronectin, laminin and tenascin, and none of them showed the same localization as T95 antigen in proventricular and gizzard mesenchymes. These results indicate that T95 will be an interesting marker which distinguishes the proventricular and gizzard mesenchymes, at the time when they have different inductive ability.     

Comparative study of the digestive system of three species of tinamou. I. Crypturellus tataupa,Nothoprocta cinerascens,and Nothura maculosa (Aves: Tinamidae)

The morphology and histology, as well as the cytochemistry of complex carbohydrates, of the digestive system of Crypturellus tataupa (tataupa tinamou), Nothoprocta cinerascens (brushland tinamou), and Nothura maculosa (spotted tinamou) are described. The general morphology of the digestive system of these birds follows the basic model of the avian alimentary canal, although statistical analysis shows that the lengths of the organs are significantly different among the species. From cephalic to caudal regions the alimentary tract consists of esophagus, ingluvies or crop, proventriculus or glandular stomach, ventriculus or muscular stomach, small intestine, well-developed ceca, and rectum. Histologically, each section of the tract consists of four primary tissue layers: mucosa, submucosa, muscularis, and adventitia. Variations are found in the thickness of the esophageal epithelium, which shows the highest value in C. tataupa. In the proventriculus, the depth of the compound glands is greatest in N. cinerascens. The villi of the epithelial cells in the small intestine are most extensively developed in C. tataupa. Heterogeneity of mucins is detected not only in the surface coat of the alimentary tract but in the cellular content of the glands as well. Comparisons with the morphology of the digestive system of closely related and more advanced birds are made, and the possible relationship between morphological and cytochemical variation and the diet is discussed. © 1996 Wiley-Liss, Inc.     

Histomorphology and proteolytic activity in the gastric apparatus of frugivorous, carnivorous and omnivorous species of birds.

The histomorphology of the gastric apparatus, the pepsin level and the optimum pH for pepsin were investigated in Psittacula krameri (frugivore), Lanius schach (carnivore) and Acridotheres tristis (omnivore) species of birds. The proventricular glands were found to be made up of oxynticopeptic cells. The lobules of the oxynticopeptic cells are polyhedral; they are the largest in P. krameri, and the smallest in A. tristis. However, their greater number in A. tristis enables a higher secretion of hydrochloric acid and pepsin. The villi are more developed in A. tristis than in L. schach and P. krameri. The gizzard is larger in A. tristis than in P. krameri and A. tritis than in the carnivore L. schach. Koilin lining is beset with horny cones, which were well developed in A. tristis, moderately developed in P. krameri and absent in L. schach. The pepsin activity is higher in the proventriculus of the carnivorous L. schach and the omnivorous A. tristis than in the frugivorous P. krameri. Slight pepsin activity was also observed in gizzard tissue extracts in all the three species. The optimum pH for pepsin was found to be 1.5 for P. krameri and 1.8 for both L. schach and A. tristis.     

The effect of pancreatic mesenchyme on the differentiation of endocrine cells from gastric endoderm

To determine whether mesenchyme plays a part in the differentiation of gut endocrine cells, proventricular endoderm from 4- to 5-day chick or quail embryos was associated with mesenchyme from the dorsal pancreatic bud of chick embryos of the same age. The combinations were grown on the chorioallantoic membranes of host chick embryos until they reached a total incubation age of 21 days. Proventricular or pancreatic endoderm of the appropriate age and species reassociated with its own mesenchyme provided the controls. Morphogenesis in the experimental grafts corresponded closely to that in proventricular controls, i.e. the pancreatic mesenchyme supported the development of proventricular glands from proventricular endoderm. Insulin, glucagon and somatostatin cells and cells with pancreatic polypeptide-like immunoreactivity differentiated in the pancreatic controls. The latter three endocrine cell types, together with neurotensin and bombesin/gastrin-releasing polypeptide (GRP) cells, developed in proventricular controls and experimental grafts. The proportions of the major types common to proventriculus and pancreas (somatostatin and glucagon cells) were in general similar when experimental grafts were compared with proventricular controls but different when experimental and pancreatic control grafts were compared. Hence pancreatic mesenchyme did not materially affect the proportions of these three cell types in experimental grafts, induced no specific pancreatic (insulin) cell type and allowed the differentiation of the characteristic proventricular endocrine cell types, neurotensin and bombesin/GRP cells. However, an important finding was a significant reduction in the proportion of bombesin/GRP cells, attributable in part to a decrease in their number and in part to an increase in the numbers of endocrine cells of the other types. This indicates that mesenchyme may well play a part in determining the regional specificity of populations of gut endocrine cells.     

Intestinal mesenchyme provokes differentiation of intestinal endocrine cells in gizzard endoderm

The gizzard (muscular stomach) of chicks is deficient in endocrine cells at hatching. It has previously been shown that proventricular types and proportions of endocrine cells can be induced in gizzard endoderm under the influence of proventricular (glandular stomach) mesenchyme. In order to test its capacity to form nongastric endocrine cell types, gizzard endoderm of 3.75- to 5-day chick embryos was combined with mesenchyme from the small intestine of 3.5- to 4-day quail embryos. The combinations were grown as chorio-allantoic grafts until they attained an incubation age comparable to that of hatching chicks. Controls comprised reassociated endoderm and mesenchyme of chick gizzard and of quail intestine. In the experimental grafts, morphogenesis was predominantly intestinal but some grafts showed gizzard-like features, particularly if the endoderm had been provided by older donors. All intestinal endocrine cell types, including those also found in the normal proventriculus (serotonin-, glucagon-, pancreatic polypeptide-, neurotensin- and somatostatin-immunoreactive cells) differentiated in experimental grafts, some even where morphogenesis was gizzard-like. Hence progenitors of not only gastric, but also intestinal, endocrine cells are indeed present in gizzard endoderm. The possibility that gizzard mesenchyme is inhibitory to endocrine cell differentiation is mooted. Motilin- and secretin-immunoreactive cells, which are characteristic of the intestine but not of the proventriculus of chicks at hatching, were respectively sparse or absent when the endoderm was derived from older donors. Thus the ability of gizzard endoderm to differentiate into nongastric endocrine cell types declines before its capacity to form gastric types. The unexpected appearance of gastrin-releasing peptide (GRP)-immunoreactive cells, a proventricular type not found in normal chick intestine, suggests that the intestinal mesenchyme, at least in this instance, was exercising a permissive role.     

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.     

Gizzard formation and the role of Bapx1

The anterior-posterior gut pattern is formed from three broad domains: fore-, mid-, and hindgut that have distinct functional, morphological, and molecular boundaries. The stomach demarcates the posterior boundary of the foregut. Avian stomachs are composed of two chambers: the anterior chamber (proventriculus) and the thick muscular posterior chamber (gizzard). Expression of candidate pattern formation control factors are restricted in the chick stomach regions such that Bmp4 and Wnt5a are not expressed in the gizzard. We previously implicated Bmp4 as controlling growth and differentiation of the gut musculature. Bmp4 is not expressed in the developing gizzard but is expressed in the rest of the gut including the adjacent proventriculus and midgut. Bapx1 (Nkx3.2) is expressed in the gizzard musculature but not in the proventriculus or midgut. We show ectopic expression of Bapx1 in the proventriculus results in a gizzard-like morphology and inhibits the normal proventricular expression of Bmp4 and Wnt5a. Overexpression of a reverse-function Bapx1 construct can result in a small stomach and ectopic extension of Bmp4 and Wnt5a expression into the gizzard. We suggest the role of Bapx1 is to regulate the expression of Bmp4 and Wnt5a to pattern the avian stomach.     

The origin of stomach oil in marine birds: Analyses of the stomach oil from six species of subantarctic procellariiform birds

The stomach oil produced by many marine birds of the order Procellariiformes is an important aspect of their breeding ecology. Fifty-seven samples of stomach oil from six species of subantarctic sea birds were examined by thin-layer and gas chromatography to determine the degree of variation in stomach oil composition between individuals of the same species. The wide variability detected, the typically marine composition of the component fatty acids and alcohols of the wax esters and triacyglycerols examined and the presence of pristane, squalene, and astaxanthin in the stomach oils all indicate that the bulk of the oil is derived directly from the food. This is in contrast to the nutritive fluids produced by secretion in several other groups of birds. Many of the stomach oils contain large amounts of wax ester and marine birds represent a significant link in the marine food web for the reconversion of zooplankton wax ester to triacylglycerol. No substantial offshore pollution by petroleum hydrocarbons was indicated by the samples; stomach oil samples from pelagic birds may be valuable in monitoring offshore pollution.