The problem of germ layers in sponges (Porifera) and some issues concerning early metazoan evolution

Nowadays the formation of germ layers (endoderm and mesoderm) is associated with gastrulation. The question of whether the cell movements during early embryonic development in sponges (Porifera) are gastrulation as in eumetazoans remains in dispute. Recent data on the histological organization, digestion and embryonic morphogenesis in sponges are analyzed here in an attempt to answer this question. Unique features of these basal Metazoa are the lack of intestinal epithelium, digestive parenchyma or any cell population specialized in digestion. Food particles are captured by cells of almost all types. These data show that sponges have no embryonic layers such as ectoderm or endoderm, characteristic to eumetazoans, and, consequently, no gastrulation. We make an assumption that the formation of germ layers cannot be considered as a recapitulation of events that took place in the common ancestor of Porifera and Eumetazoa. The unity of Metazoa is expressed not in the presence of gastrulation processes per se, but in the universal nature of cell movement mechanisms ensuring various types of morphogenesis, including those underlying gastrulation. It is concluded that metazoan mechanisms of morphogenetic movements must have emerged in the course of evolution prior to the separation of the germ layers like endoderm and ectoderm.     

Fate mapping study of the splanchnopleural mesoderm of the 1.5-day-old chick embryo

Various portions of the splanchnopleural mesoderm lateral to the somites of 1.5-day chick embryos were marked in ovo by local injection of Dil, and the distribution of the labelled cells in the digestive-tract mesoderm formed after 3 days' reincubation was analysed. The presumptive area of the digestive organs was confined to bands of splanchnic mesoderm lying lateral to the somites, on both sides, with a width two or three times that between the midline of the embryo and the lateral edge of the somite. Each band generally contributed cells to its own side of the digestive-tract mesoderm, except for the region around the bile duct. The anterior and posterior portion of the pre-gut area contributed cells to the anterior and posterior region of the digestive tract, respectively, but label originating from the portion furthest from the somite took the more ventral and posterior position. Thus, the presumptive areas of the respective digestive organs were located anteroposteriorly in the same order as in the digestive tract with their boundaries lying oblique to the embryonic axis.     

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.     

The molecular mechanisms of stomach development in vertebrates

The tissue interactions between endodermal epithelium and mesenchyme originated from splanchnic mesoderm are essential during the formation of digestive tract. In this review, we introduce a series of works to elucidate the molecular mechanisms of the epithelial-mesenchymal interaction of stomach development in mainly the chicken embryo. We also describe some molecular studies in mouse stomach development.     

Induction and Inhibition of Epithelial Differentiation by the Mixed Cell Aggregates of the Mesenchymes from the Chicken Embryonic Digestive Tract

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.     

Sonic hedgehog expression in developing chicken digestive organs is regulated by epithelial–mesenchymal interactions

Sonic hedgehog (Shh) gene encodes a secreted protein that acts as an important mediator of cell–cell interactions. A detailed analysis of Shh expression in the digestive organs of the chicken embryo was carried out. Shh expression in the endoderm begins at stage 7, when the formation of the foregut commences, and is found as narrow bands in the midgut. Shh expression around the anterior intestinal portal at stage 15 is restricted to the columnar endoderm lined by the thick splanchnic mesoderm, suggesting that the existence of thick splanchnic mesoderm might be necessary for Shh expression in the columnar endoderm. After the gut is closed, Shh expression is found universally in digestive epithelia, including the cecal epithelium. However, its expression ceases in the epithelium of the proventricular glands, the ductus choledochus and ductus pancreaticus that protrude from the main digestive duct. When the gizzard epithelium differentiated into glands under the influence of the proventricular mesenchyme, the glandular epithelium lost the ability to express Shh . These findings suggest that Shh expression in the epithelium may be regulated by surrounding mesenchyme throughout organogenesis of the digestive organs and is closely involved in epithelial–mesenchymal interactions in developing digestive organs.     

Persistent myogenic capacity of the dermomyotome dorsomedial lip and restriction of myogenic competence

The dorsomedial lip (DML) of the somite dermomyotome is the source of cells for the early growth and morphogenesis of the epaxial primary myotome and the overlying dermomyotome epithelium. We have used quail-chick transplantation to investigate the mechanistic basis for DML activity. The ablated DML of chick wing-level somites was replaced with tissue fragments from various mesoderm regions of quail embryos and their capacity to form myotomal tissue assessed by confocal microscopy. Transplanted fragments from the epithelial sheet region of the dermomyotome exhibited full DML growth and morphogenetic capacity. Ventral somite fragments (sclerotome), head paraxial mesoderm or non-paraxial (lateral plate) mesoderm tested in this assay were each able to expand mitotically in concert with the surrounding paraxial mesoderm, although no myogenic potential was evident. When ablated DMLs were replaced with fragments of the dermomyotome ventrolateral lip of wing-level somites or pre-somitic mesoderm (segmental plate), myotome development was evident but was delayed or otherwise limited in some cases. Timed DML ablation-replacement experiments demonstrate that DML activity is progressive throughout the embryonic period (to at least E7) and its continued presence is necessary for the complete patterning of each myotome segment. The results of serial transplantation and BrdU pulse-chase experiments are most consistent with the conclusion that the DML consists of a self-renewing population of progenitor cells that are the primary source of cells driving the growth and morphogenesis of the myotome and dermomyotome in the epaxial domain of the body.     

Morphogenic machines evolve more rapidly than the signals that pattern them: lessons from amphibians

The induction of mesoderm and the patterning of its dorsal-ventral and anterior-posterior axes seems to be relatively conserved throughout the chordates, as do the morphogenic movements that produce a phylotypic stage embryo. What is not conserved is the initial embryonic architecture of the fertilized egg, and the specific cell behaviors used to drive mesoderm morphogenesis. How then do conserved patterning pathways adapt to diverse architectures and where do they diverge to direct the different cell behaviors used to shape the phylotypic body plan? Amphibians in particular, probably because of their broad range of reproductive strategies, show diverse embryonic architectures across their class and use diverse cell behaviors during their early morphogenesis, making them an interesting comparative group. We examine three examples from our work on amphibians that show variations in the use of cell behaviors to drive the morphogenesis of the same tissues. We also consider possible points where the conserved patterning pathways might diverge to produce different cell behaviors.     

Cuticle morphogenesis in crustacean embryonic and postembryonic stages

The crustacean cuticle is a chitin-based extracellular matrix, produced in general by epidermal cells and ectodermally derived epithelial cells of the digestive tract. Cuticle morphogenesis is an integrative part of embryonic and postembryonic development and it was studied in several groups of crustaceans, but mainly with a focus on one selected aspect of morphogenesis. Early studies were focused mainly on in vivo or histological observations of embryonic or larval molt cycles and more recently, some ultrastructural studies of the cuticle differentiation during development were performed. The aim of this paper is to review data on exoskeletal and gut cuticle formation during embryonic and postembryonic development in crustaceans, obtained in different developmental stages of different species and to bring together and discuss different aspects of cuticle morphogenesis, namely data on the morphology, ultrastructure, composition, connections to muscles and molt cycles in relation to cuticle differentiation. Based on the comparative evaluation of microscopic analyses of cuticle in crustacean embryonic and postembryonic stages, common principles of cuticle morphogenesis during development are discussed. Additional studies are suggested to further clarify this topic and to connect the new knowledge to related fields.     

Loss of late primitive streak mesoderm and interruption of left-right morphogenesis in the Ednrb(s-1Acrg) mutant mouse

This study characterizes defects associated with abnormal mesoderm development in mouse embryos homozygous for the induced Ednrb(s-1Acrg) allele of the piebald deletion complex. The Ednrb(s-1Acrg) deletion results in recessive embryonic lethality and mutant embryos exhibit a truncated posterior body axis. The primitive streak and node become disfigured, consistent with evidence that cell migration is impaired in newly formed mesoderm. Additional defects related to mesoderm development include notochord degeneration, somite malformations, and abnormal vascular development. Arrested heart looping morphogenesis and a randomized direction of embryonic turning indicate that left-right development is also perturbed. The expression of nodal and leftb, Tgf-beta-related genes involved in a left-determinant signaling pathway, is variably lost in the left lateral plate mesoderm. Mutational analysis has demonstrated that Fgf8 and Brachyury (T) are required for normal mesoderm and left-right development and the asymmetric expression of nodal and leftb. Fgf8 expression in nascent mesoderm exiting the primitive streak is dramatically reduced in mutant embryos, and diminished T expression accompanies the progressive loss of paraxial, lateral, and primitive streak mesoderm. In contrast, axial mesoderm persists and T and nodal appear to be appropriately expressed in their specific domains in the node and notochord. We propose that this mutation disrupts a morphogenetic pathway, likely involving FGF signaling, important for the development of streak-derived posterior mesoderm and lateral morphogenesis.     

Aggregated P19 mouse embryonal carcinoma cells as a simple in vitro model to study the molecular regulations of mesoderm formation and axial elongation morphogenesis

Because of their capacity to give rise to various types of cells in vitro, embryonic stem and embryonal carcinoma (EC) cells have been used as convenient models to study the mechanisms of cell differentiation in mammalian embryos. In this study, we explored the mouse P19 EC cell line as an effective tool to investigate the factors that may play essential roles in mesoderm formation and axial elongation morphogenesis. We first demonstrated that aggregated P19 cells not only exhibited gene expression patterns characteristic of mesoderm formation but also displayed elongation morphogenesis with a distinct anterior–posterior body axis as in the embryo. We then showed by RNA interference that these processes were controlled by various regulators of Wnt signaling pathways, namely β‐catenin, Wnt3, Wnt3a, and Wnt5a, in a manner similar to normal embryo development. We further showed by inhibitor treatments that the axial elongation morphogenesis was dependent on the activity of Rho‐associated kinase. Because of the convenience of these experimental manipulations, we propose that P19 cells can be used as a simple and efficient screening tool to assess the potential functions of specific molecules in mesoderm formation and axial elongation morphogenesis. genesis 47:93–106, 2009. © 2008 Wiley‐Liss, Inc.     

The interaction of epithelial Ihha and mesenchymal Fgf10 in zebrafish esophageal and swimbladder development

Developmental patterning and growth of the vertebrate digestive and respiratory tracts requires interactions between the epithelial endoderm and adjacent mesoderm. The esophagus is a specialized structure that connects the digestive and respiratory systems and its normal development is critical for both. Shh signaling from the epithelium regulates related aspects of mammalian and zebrafish digestive organ development and has a prominent effect on esophageal morphogenesis. The mechanisms underlying esophageal malformations, however, are poorly understood. Here, we show that zebrafish Ihha signaling from the epithelium acting in parallel, but independently of Shh, controls epithelial and mesenchymal cell proliferation and differentiation of smooth muscles and neurons in the gut and swimbladder. In zebrafish ihha mutants, the esophageal and swimbladder epithelium is dysmorphic, and expression of fgf10 in adjacent mesenchymal cells is affected. Analysis of the development of the esophagus and swimbladder in fgf10 mutant daedalus (dae) and compound dae/ihha mutants shows that the Ihha–Fgf10 regulatory interaction is realized through a signaling feedback loop between the Ihha-expressing epithelium and Fgf10-expressing mesenchyme. Disruption of this loop further affects the esophageal and swimbladder epithelium in ihha mutants, and Ihha acts in parallel to but independently of Shha in this process. These findings contribute to the understanding of epithelial–mesenchymal interactions and highlight an interaction between Hh and Fgf signaling pathways during esophagus and swimbladder development.     

Antero-posterior patterning of the vertebrate digestive tract: 40 years after Nicole Le Douarin's PhD thesis

This review is dedicated to the work on chick digestive tract organogenesis that Nicole Le Douarin performed as a PhD student under the direction of Etienne Wolf. I discuss how she laid the grounds for future work by establishing fate maps at somitic stages, by describing morphogenetic movements between germ layers and by pointing to signaling events between endoderm and mesoderm. Her inspiring work was extended by others, in particular at the molecular level, leading to a better understanding of antero-posterior patterning in the digestive tract. Antero-posterior patterning of endoderm is initiated at gastrulation when future anterior and posterior endoderm ingress at different times and accordingly express different genes. Plasticity is however maintained at somite stages and even later, when organ primordia can be delineated. There is a cross-talk between endoderm and mesoderm and the two layers exchange instructive signals that induce specific antero-posterior identities as well as permissive signals required for organogenesis from previously patterned fields. Recent experiments suggest that several signaling molecules involved in neural tube antero-posterior patterning are also instrumental in the digestive tract including retinoic acid and FGF4.     

Chicken keratin-19: Cloning of cDNA and analysis of expression in the chicken embryonic gut

From many recent studies, it has been argued that keratins (cytokeratins) play important roles in the morphogenesis and differentiation of organ development. To learn the role of keratin in digestive tract development, a cDNA of the chicken homolog of keratin-19 ( GK-19 ) was cloned and its expression pattern was analyzed in the digestive tract of chicken embryos. The GK-19 full-length sequence was approximately 1.6 kb and showed more than 80% similarity to human and mouse keratin-19. The result of in situ hybridization with the proventriculus (glandular stomach) of different developmental stages showed that GK-19 expression disappeared specifically in the glandular epithelium from day 6 to day 9 of incubation. Furthermore, GK-19 was localized in the notochord, floor plate, anterior lobe of the pituitary gland and mesonephros. These results suggest the possibility that GK-19 may have multiple roles in organogenesis during embryogenesis.