Brachyury (T) expression in embryos of a larvacean urochordate, Oikopleura dioica, and the ancestral role of T

The Brachyury, or T, gene is required for notochord development in animals occupying all three chordate subphyla and probably also had this role in the last common ancestor of the chordate lineages. In two chordate subphyla (vertebrates and cephalochordates), T is also expressed during gastrulation in involuting endodermal and mesodermal cells, and in vertebrates at least, this expression domain is required for proper development. In the basally diverging chordate subphylum Urochordata, animals in the class Ascidiacea do not employ T during gastrulation in endodermal or nonaxial mesodermal cells, and it has been suggested that nonnotochordal roles for T were acquired in the cephalochordate-vertebrate lineage after it split with Urochordata. To test this hypothesis, we cloned T from Oikopleura dioica, a member of the urochordate class Appendicularia (or Larvacea), which diverged basally in the subphylum. Investigation of the expression pattern in developing Oikopleura embryos showed early expression in presumptive notochord precursor cells, in the notochord, and in parts of the developing gut and cells of the endodermal strand. We conclude that the ancestral role of T likely included expression in the developing gut and became necessary in chordates for construction of the notochord.     

Conservation of the Developmental Role ofBrachyuryin Notochord Formation in a Urochordate, the AscidianHalocynthia roretzi

The notochord is one of the characteristic features of the phylum Chordata. The vertebrateBrachyurygene is known to be essential for the terminal differentiation of chordamesoderm into notochord. In the ascidian, which belongs to the subphylum Urochordata, differentiation of notochord cells is induced at the late phase of the 32-cell stage through cellular interaction with adjacent endoderm cells as well as neighboring notochord cells. The ascidianBrachyurygene (As-T) is expressed exclusively in the notochord-lineage blastomeres, and the timing of gene expression at the 64-cell stage precisely coincides with that of the developmental fate restriction of the blastomeres. In addition, experimental studies have demonstrated a close relationship between the inductive events andAs-Texpression. In the present study, we show that overexpression ofAs-Tby microinjection of the synthesizedAs-TRNA results in the occurrence, without the induction, of notochord-specific features in the A-line presumptive notochord blastomeres. We also show that overexpression ofAs-TRNA leads to ectopic expression of notochord-specific features in non-notochord lineages, including those of spinal cord and endoderm. These results strongly suggest that the developmental role of theBrachyuryis conserved throughout chordates in notochord formation.     

Chordate evolution and the three-phylum system

Traditional metazoan phylogeny classifies the Vertebrata as a subphylum of the phylum Chordata, together with two other subphyla, the Urochordata (Tunicata) and the Cephalochordata. The Chordata, together with the phyla Echinodermata and Hemichordata, comprise a major group, the Deuterostomia. Chordates invariably possess a notochord and a dorsal neural tube. Although the origin and evolution of chordates has been studied for more than a century, few authors have intimately discussed taxonomic ranking of the three chordate groups themselves. Accumulating evidence shows that echinoderms and hemichordates form a clade (the Ambulacraria), and that within the Chordata, cephalochordates diverged first, with tunicates and vertebrates forming a sister group. Chordates share tadpole-type larvae containing a notochord and hollow nerve cord, whereas ambulacrarians have dipleurula-type larvae containing a hydrocoel. We propose that an evolutionary occurrence of tadpole-type larvae is fundamental to understanding mechanisms of chordate origin. Protostomes have now been reclassified into two major taxa, the Ecdysozoa and Lophotrochozoa, whose developmental pathways are characterized by ecdysis and trochophore larvae, respectively. Consistent with this classification, the profound dipleurula versus tadpole larval differences merit a category higher than the phylum. Thus, it is recommended that the Ecdysozoa, Lophotrochozoa, Ambulacraria and Chordata be classified at the superphylum level, with the Chordata further subdivided into three phyla, on the basis of their distinctive characteristics.     

On a possible evolutionary link of the stomochord of hemichordates to pharyngeal organs of chordates

As a group closely related to chordates, hemichordate acorn worms are in a key phylogenic position for addressing hypotheses of chordate origins. The stomochord of acorn worms is an anterior outgrowth of the pharynx endoderm into the proboscis. In 1886 Bateson proposed homology of this organ to the chordate notochord, crowning this animal group “hemichordates.” Although this proposal has been debated for over a century, the question still remains unresolved. Here we review recent progress related to this question. First, the developmental mode of the stomochord completely differs from that of the notochord. Second, comparison of expression profiles of genes including Brachyury, a key regulator of notochord formation in chordates, does not support the stomochord/notochord homology. Third, FoxE that is expressed in the stomochord‐forming region in acorn worm juveniles is expressed in the club‐shaped gland and in the endostyle of amphioxus, in the endostyle of ascidians, and in the thyroid gland of vertebrates. Based on these findings, together with the anterior endodermal location of the stomochord, we propose that the stomochord has evolutionary relatedness to chordate organs deriving from the anterior pharynx rather than to the notochord. genesis 52:925–934, 2014. © 2014 Wiley Periodicals, Inc.     

Vegetalising factor extracted from the fish swimbladder and tested on presumptive ectoderm ofTriturus embryos

Summary Vegetalising factor was isolated from swimbladder of crusian carp (Carassius auratus) by solubilishing with 8 M urea the precipitate obtained after digesting the swimbladder with collagenase. The urea-soluble fraction vegetalised isolated presumptive ectoderm ofTriturus gastrula and produced both undifferentiated mesodermal and endodermal cells. Brief heating of the fraction changed its capacity to produce organised mesodermal tissues, such as notochord and somite, and the frequency of induction of undifferentiated cells was reduced. By inserting the urea-soluble fraction into the blastocoel of an early gastrula, embryos without epidermis were obtained. Some of the embryos consisted of undifferentiated mesodermal and endodermal cells, but in the remaining ones small fragments of notochord, small numbers of somites and pronephros developed, enclosed by endodermal cells.     

p68, a DEAD-box RNA helicase, is expressed in chordate embryo neural and mesodermal tissues

The p68 DEAD-box RNA helicases have been identified in diverse organisms, including yeast, invertebrates, and mammals. DEAD-box RNA helicases are thought to unwind duplexed RNAs, and the p68 family may participate in initiating nucleolar assembly. Recent evidence also suggests that they are developmentally regulated in chordate embryos. bobcat, a newly described member of this gene family, has been found in eggs and developing embryos of the ascidian urochordate, Molgula oculata. Antisense RNA experiments have implicated this gene in establishing basic chordate features, including the notochord and neural tube in ascidians (Swalla et al. 1999). We have isolated p68 homologs from chick and Xenopus in order to investigate their possible role in vertebrate development. We show that embryonic expression of p68 in chick, frog, and ascidian embryos is high in the developing brain and spinal cord as well as in the sensory vesicles. In frog embryos, p68 expression also marks the streams of migrating cranial neural crest cells throughout neural tube development and in tailbud stages, but neural crest expression is faint in chick embryos. Ascidian embryos also show mesodermal p68 expression during gastrulation and neurulation, and we document some p68 mesodermal expression in both chick and frog. Thus, as shown in these studies, p68 is expressed in early neural development and in various mesodermal tissues in a variety of chordate embryos, including chick, frog, and ascidian. Further functional experiments will be necessary to understand the role(s) p68 may play in vertebrate development.     

Gastrulation in the sea anemone Nematostella vectensis occurs by invagination and immigration: an ultrastructural study

The sea anemone Nematostella vectensis has recently been established as a new model system for the understanding of the evolution of developmental processes. In particular, the evolutionary origin of gastrulation and its molecular regulation are the subject of intense investigation. However, while molecular data are rapidly accumulating, no detailed morphological data exist describing the process of gastrulation. Here, we carried out an ultrastructural study of different stages of gastrulation in Nematostella using transmission electron microscope and scanning electron microscopy techniques. We show that presumptive endodermal cells undergo a change in cell shape, reminiscent of the bottle cells known from vertebrates and several invertebrates. Presumptive endodermal cells organize into a field, the pre-endodermal plate, which undergoes invagination. In parallel, the endodermal cells decrease their apical cell contacts but remain loosely attached to each other. Hence, during early gastrulation they display an incomplete epithelial–mesenchymal transition (EMT). At a late stage of gastrulation, the cells eventually detach and fill the interior of the blastocoel as mesenchymal cells. This shows that gastrulation in Nematostella occurs by a combination of invagination and late immigration involving EMT. The comparison with molecular expression studies suggests that cells expressing snailA undergo EMT and become endodermal, whereas forkhead/brachyury expressing cells at the ectodermal margin of the blastopore retain their epithelial integrity throughout gastrulation.     

The postanal tail of the enteropneust Saccoglossus kowalevskii is a ciliary creeping organ without distinct similarities to the chordate tail

Stach, T. and Kaul, S. 2011. The postanal tail of the enteropneust Saccoglossus kowalevskii is a ciliary creeping organ without distinct similarities to the chordate tail. —Acta Zoologica (Stockholm) 92 : 150–160. The postanal tail of chordates is one of the key characters in chordate evolution and it has been suggested to be homologous to the postanal tail of harrimaniid enteropneusts. We present electron microscopic data of the ontogeny of the postanal tail in the enteropneust Saccoglossus kowalevskii. The postanal tail develops as a ventral posterior allometric outgrowth with a ventral extension of the telotroch. Transmission electron microscopy of serial sections reveals the epidermal organization of the postanal tail with the exception of short, bilaterally symmetric extensions of the paired metacoels. The epidermis cells are connected by apical junctions, rest basally on the extracellular matrix surrounding the mesoderm, and possess a basiepidermal nerve net. The ventral cells in the postanal tail are multiciliated and used for creeping. Dorsal cells are monociliated with numerous microvilli. Two types of glandular cells are present among the epidermis cells. The mesoderm cells contain myofilaments. We were unable to detect anatomical structures similar to the ones present in the postanal locomotory tail of chordates, such as notochord, neural tube, or endodermal strand. Thus, results of our anatomical study do not support homology of the postanal chordate tail and the postanal tail of harrimaniid enteropneusts.     

Co-expression of the HGF/SF and c-met genes during early mouse embryogenesis precedes reciprocal expression in adjacent tissues during organogenesis

Early experiments with cells in culture and recent targeting experiments have confirmed that the mesenchyme-derived growth factor hepatocyte growth factor/scatter factor (HGF/SF) is a paracrine agent that regulates the development of several epithelial and myogenic precursor cells during organogenesis. Here, we report the expression pattern of HGF/SF and its receptor, the product of the proto-oncogene c-met, during gastrulation and early organogenesis in mouse embryo. During gastrulation, the expression of HGF/SF and c-met overlaps. Initially the two genes are expressed in the endoderm and in the mesoderm along the rostro-intermediate part of the primitive streak and, later, in the node and in the notochord. Neither HGF/SF nor c-met is expressed in the ectodermal layer throughout gastrulation. During early organogenesis, overlapping expression of HGF/SF and c-met is found in heart, condensing somites and neural crest cells. However, a second and distinct pattern of expression, characterized by the presence of the ligand in mesenchymal tissues and the receptor in the surrounding ectoderm, is seen in the branchial arches and in the limb buds. At 13 days postcoitum (d.p.c.), only this second pattern of expression is observed in differentiated somites and several major organs (i.e., lungs, liver, and gut. The expression of the HGF/SF and c-met genes throughout embryogenesis suggests a shift from an autocrine to a paracrine signaling system. The shift takes place in early organogenesis and implies different roles of HGF/SF in development. During gastrulation, HGF/SF may affect the fate of migrating mesodermal cells and may play a role in axis determination, whereas during organogenesis, the expression patterns of HGF/SF and its receptor reflect the recently established roles in the growth of certain epithelia and the migration of specific myogenic precursor cells. © 1996 Wiley-Liss, Inc.     

Urodeles remove mesoderm from the superficial layer by subduction through a bilateral primitive streak

Urodeles begin gastrulation with much of their presumptive mesoderm in the superficial cell layer, all of which must move into the deep layers during development. We studied the morphogenesis of superficial mesoderm in the urodeles Ambystoma maculatum, Ambystoma mexicanum, and Taricha granulosa. In all three species, somitic, lateral, and ventral mesoderm move into the deep layer during gastrulation, ingressing through a "bilateral primitive streak" just inside the blastopore. The mesodermal epithelium appears to slide under the endodermal epithelium by a mechanism we term "subduction." Subduction removes the large expanse of superficial presumptive somitic and lateral-ventral mesoderm that initially separates the sub-blastoporal endoderm from the notochord, leaving the endoderm bounding the still epithelial notochord along the gastrocoel roof. Subduction may be a common feature of urodele gastrulation, differing in this regard from anurans. Subducting cells constrict their apices and become bottle-shaped as they approach the junction of the mesodermal and endodermal epithelia. Subducting bottle cells endocytose apical membrane and withdraw the tight junctional component cingulin from the contracting circumferential tight junctions. Either in conjunction with or immediately after subducting, the mesodermal cells undergo an epithelial-to-mesenchymal transition. The mechanism by which epithelial cells release their apical junctions to become mesenchymal, without disrupting the integrity of the epithelium, remains mysterious, but this system should prove useful in understanding this process in a developmental context.     

Sdf1/Cxcr4 signaling controls the dorsal migration of endodermal cells during zebrafish gastrulation

During vertebrate gastrulation, both mesodermal and endodermal cells internalize through the blastopore beneath the ectoderm. In zebrafish, the internalized mesodermal cells move towards the dorsal side of the gastrula and, at the same time, they extend anteriorly by convergence and extension (C&E) movements. Endodermal cells showing characteristic filopodia then migrate into the inner layer within the hypoblast next to the yolk syncytial layer (YSL). However, little is known about how the movement of endodermal cells is regulated during gastrulation. Here we show that sdf1a- and sdf1b-expressing mesodermal cells control the movements of the cxcr4a-expressing endodermal cells. The directional migration of endodermal cells during gastrulation is inhibited by knockdown of either cxcr4a or sdf1a/sdf1b (sdf1). We also show that misexpressed Sdf1 acts as a chemoattractant for cxcr4a-expressing endodermal cells. We further found, using the endoderm-specific transgenic line Tg(sox17:EGFP), that Sdf1/Cxcr4 signaling regulates both the formation and orientation of filopodial processes in endodermal cells. Moreover, the accumulation of phosphoinositide 3,4,5-trisphosphate (PIP(3)), which is known to occur at the leading edge of migrating cells, is not observed at the filopodia of endodermal cells. Based on our results, we propose that sdf1-expressing mesodermal cells, which overlie the endodermal layer, guide the cxcr4a-expressing endodermal cells to the dorsal side of the embryo during gastrulation, possibly through a PIP(3)-independent pathway.     

Origin of the prechordal plate and patterning of the anteroposterior regional specificity of the involuting and extending archenteron roof of a urodele, Cynops pyrrhogaster

We analyzed the notochord formation, formation of the prechordal plate, and patterning of anteroposterior regional specificity of the involuting and extending archenteron roof of a urodele, Cynops pyrrhogaster. The lower (LDMZ) and upper (UDMZ) domains of the dorsal marginal zone (DMZ) of the early gastrula involuted and formed two distinct domains: the anterior fore-notochordal endodermal roof and the posterior domain containing the prospective notochord. Cygsc is expressed in the LDMZ from the onset of gastrulation, and the Cygsc-expressing LDMZ planarly induces the notochord in the UDMZ at the early to mid gastrula stages. At the mid to late gastrula stages, part of the Cygsc-expressing LDMZ is confined to the prechordal plate. On the other hand, Cybra expression only begins at mid gastrula stage, coincident with notochord induction at this stage. Anteroposterior regional specificity of the neural plate was patterned by the posterior domain of the involuting archenteron roof containing the prospective notochord at the mid to late gastrula stages. Cynops gastrulation thus differs significantly from Xenopus gastrulation in that the regions of the DMZ are specified from the onset of gastrulation, while the equivalent state of specification does not occur in Cynops until the middle of gastrulation. Thus we propose that Cynops gastrulation is divided into two phases: a notochord induction phase in the early to mid gastrula, and a neural induction phase in the mid to late gastrula.     

Regeneration of the acorn worm pygochord with the implication for its convergent evolution with the notochord

The origin of the notochord is a central issue in chordate evolution. This study examined the development of the acorn worm pygochord, a putative homologue of the notochord. Because the pygochord differentiates only after metamorphosis, the developmental was followed process by inducing regeneration after artificial amputation in Ptychodera flava. It was found that although the regeneration of the posterior part of the body did not proceed via formation of an obvious regeneration bud, pygochord regeneration was observed within a few weeks, possibly via trans-differentiation of endoderm cells. The expression of the fibrillary collagen gene (Fcol) and elav in the pygochord during regeneration was detected. This indicates that pygochord cells are not part of gut epithelial cells, but that they differentiated as a distinct cell type. Our gene expression analyses do not provide supporting evidence for the homology between the pygochord and notochord, but rather favored the convergent evolution between them.     

A late requirement for Wnt and FGF signaling during activin-induced formation of foregut endoderm from mouse embryonic stem cells

Here we examine how BMP, Wnt, and FGF signaling modulate activin-induced mesendodermal differentiation of mouse ES cells grown under defined conditions in adherent monoculture. We monitor ES cells containing reporter genes for markers of primitive streak (PS) and its progeny and extend previous findings on the ability of increasing concentrations of activin to progressively induce more ES cell progeny to anterior PS and endodermal fates. We find that the number of Sox17- and Gsc-expressing cells increases with increasing activin concentration while the highest number of T-expressing cells is found at the lowest activin concentration. The expression of Gsc and other anterior markers induced by activin is prevented by treatment with BMP4, which induces T expression and subsequent mesodermal development. We show that canonical Wnt signaling is required only during late stages of activin-induced development of Sox17-expressing endodermal cells. Furthermore, Dkk1 treatment is less effective in reducing development of Sox17⁺ endodermal cells in adherent culture than in aggregate culture and appears to inhibit nodal-mediated induction of Sox17⁺ cells more effectively than activin-mediated induction. Notably, activin induction of Gsc-GFP⁺ cells appears refractory to inhibition of canonical Wnt signaling but shows a dependence on early as well as late FGF signaling. Additionally, we find a late dependence on FGF signaling during induction of Sox17⁺ cells by activin while BMP4-induced T expression requires FGF signaling in adherent but not aggregate culture. Lastly, we demonstrate that activin-induced definitive endoderm derived from mouse ES cells can incorporate into the developing foregut endoderm in vivo and adopt a mostly anterior foregut character after further culture in vitro.