Epichordal vertebral column formation in Xenopus laevis.

Although Xenopus Laevis is the most widely used model amphibian, skeletal development of its vertebral column has not been well illustrated so far. The mode of vertebral column development in anurans has been classified into two modes: perichordal and epichordal. Xenopus vertebral column formation is believed to follow the epichordal mode, but this aspect has been underemphasized, and illustrative examples are currently unavailable to the scientific community. This study documents the entire process of vertebral column formation in X. laevis, from the initial neural arch formation to the completion of metamorphosis. These images reveal that the neural arch arises from the dorsal lamina and lateral pedicle primordia, with no strict adherence to an anteroposterior sequence. Unlike other species, Xenopus centrum primordia exclusively form at the expanded ventral margins of neural arches, rather than from the cartilaginous layer surrounding the notochord. These paired centrum primordia then fuse at the ventral midline, dorsal to the notochord, and subsequently the notochord degenerates. This mode of centrum formation differs from the traditional epichordal mode, indicating that Xenopus might have lost the ability to form a cartilaginous layer around the notochord. Instead, the neural arch's ventral margin appears to have evolved to incorporate centrum precursor cells at its base, thereby forming a centrum-like structure compensating for the absence of a true centrum. It is widely accepted that postsacral vertebrae lack centra, only possessing neural arches, and eventually fuse with the hypochord to form the urostyle. However, we have shown that the paired ventral ends of the postsacral vertebrae also fuse at the midline to form a centrum-like structure. This process might extend to the trunk region during centrum formation. In addition to these findings, we offer evolutionary insights into the reasons why Xenopus retains centrum primordia at the base of neural arches.

Non-neural and cardiac differentiating properties of Tbx6-expressing mouse embryonic stem cells.

T-box transcription factors play important roles in vertebrate mesoderm formation. Eomesodermin is involved in the initial step of the prospective mesodermal cells recruited near the primitive streak. Then T or Brachyury gene is responsible for general and axial mesodermal development. Tbx6, on the other hand, promotes paraxial mesodermal development while suppressing neural differentiation. Here, we studied differentiative properties of mouse ES cells (mESCs) with its Tbx6 expression regulated under the Tet-off system. mESCs were treated with noggin to promote neural differentiation. When Tbx6 was simultaneously turned on, later neural differentiation of these cells hardly occurred. Next, mESCs were subjected to formation of the embryoid bodies (EBs). When Tbx6 was turned on during EB formation, the rate of later cardiac troponin T (cTnT)-positive cells increased. If the cells were further treated with a wnt inhibitor KY02111 after EB formation, a synergistic increase of cTnT-positive cells occurred. Tbx6 expression in mESCs influenced the constituent ratio of the cardiac myosin light chain types, such that atrial species markedly increased over ventricular ones. These results are coincident with the function of Tbx6 in normal development, in that Tbx6 strongly suppressed neural differentiation while promoting cardiac development in a cooperative manner with wnt inhibition.

MytiLec, a Mussel R-Type Lectin, Interacts with Surface Glycan Gb3 on Burkitt's Lymphoma Cells to Trigger Apoptosis through Multiple Pathways.

MytiLec; a novel lectin isolated from the Mediterranean mussel (Mytilus galloprovincialis); shows strong binding affinity to globotriose (Gb3: Galα1-4Galß1-4Glc). MytiLec revealed ß-trefoil folding as also found in the ricin B-subunit type (R-type) lectin family, although the amino acid sequences were quite different. Classification of R-type lectin family members therefore needs to be based on conformation as well as on primary structure. MytiLec specifically killed Burkitt's lymphoma Ramos cells, which express Gb3. Fluorescein-labeling assay revealed that MytiLec was incorporated inside the cells. MytiLec treatment of Ramos cells resulted in activation of both classical MAPK/ extracellular signal-regulated kinase and extracellular signal-regulated kinase (MEK-ERK) and stress-activated (p38 kinase and JNK) Mitogen-activated protein kinases (MAPK) pathways. In the cells, MytiLec treatment triggered expression of tumor necrosis factor (TNF)-α (a ligand of death receptor-dependent apoptosis) and activation of mitochondria-controlling caspase-9 (initiator caspase) and caspase-3 (activator caspase). Experiments using the specific MEK inhibitor U0126 showed that MytiLec-induced phosphorylation of the MEK-ERK pathway up-regulated expression of the cyclin-dependent kinase inhibitor p21, leading to cell cycle arrest and TNF-α production. Activation of caspase-3 by MytiLec appeared to be regulated by multiple different pathways. Our findings, taken together, indicate that the novel R-type lectin MytiLec initiates programmed cell death of Burkitt's lymphoma cells through multiple pathways (MAPK cascade, death receptor signaling; caspase activation) based on interaction of the lectin with Gb3-containing glycosphingolipid-enriched microdomains on the cell surface.

Paraxial T-box genes, Tbx6 and Tbx1, are required for cranial chondrogenesis and myogenesis.

We previously reported that Tbx6, a T-box transcription factor, is required for the differentiation of ventral body wall muscle and for segment formation and somitic muscle differentiation. Here, we show that Tbx6 is also involved, at later stages, in cartilage differentiation from the cranial neural crest and head muscle development. In Tbx6 knockdown embryos, the cranial neural crest was shown to be correctly induced at the border of the neural plate and migrated in a slightly delayed manner, but finally reached positions in the pharyngeal arches nearly similar to those in the normal embryos as revealed by in situ hybridization and the neural crest-transplantation experiments. However, the neural crest cells failed to maintain Sox9 expression. Tbx6 knockdown also reduced the expression of Tbx1, another T-box gene expressed in more anterior paraxial structures. Tbx1 knockdown caused phenotypes milder but similar to those of Tbx6 morphants, including reduced formation of head muscles and cartilages, and attenuated Sox9 expression. Furthermore, the phenotypes caused by Tbx6 knockdown were partially rescued by Tbx1 plasmid injection. These results suggest that Tbx6 is involved in the cranial cartilage and head muscle development by regulating anterior paraxial genes such as Tbx1 and Sox9.

Efficiently differentiating vascular endothelial cells from adipose tissue-derived mesenchymal stem cells in serum-free culture.

Adipose tissue-derived mesenchymal stem cells (ASCs) have been reported to be multipotent and to differentiate into various cell types, including osteocytes, adipocytes, chondrocytes, and neural cells. Recently, many authors have reported that ASCs are also able to differentiate into vascular endothelial cells (VECs) in vitro. However, these reports included the use of medium containing fetal bovine serum for endothelial differentiation. In the present study, we have developed a novel method for differentiating mouse ASCs into VECs under serum-free conditions. After the differentiation culture, over 80% of the cells expressed vascular endothelial-specific marker proteins and could take up low-density lipoprotein in vitro. This protocol should be helpful in clarifying the mechanisms of ASC differentiation into the VSC lineage.

Induction of neural crest cells from mouse embryonic stem cells in a serum-free monolayer culture.

The neural crest (NC) is a group of cells located in the neural folds at the boundary between the neural and epidermal ectoderm. NC cells differentiate into a vast range of cells,including neural cells, smooth muscle cells, bone and cartilage cells of the maxillofacial region, and odontoblasts. The molecular mechanisms underlying NC induction during early development remain poorly understood. We previously established a defined serum-free culture condition for mouse embryonic stem (mES) cells without feeders. Here, using this defined condition, we have developed a protocol to promote mES cell differentiation into NC cells in an adherent monolayer culture. We found that adding bone morphogenetic protein (BMP)-4 together with fibroblast growth factor (FGF)-2 shifts mES cell differentiation into the NC lineage. Furthermore, we have established a cell line designated as P0-6 that is derived from the blastocysts of P0-Cre/Floxed-EGFP mice expressing EGFP in an NC-lineage-specific manner. P0-6 cells cultured using this protocol expressed EGFP. This protocol could be used to help clarify the mechanisms by which cells differentiate into the NC lineage and to assist the development of applications for clinical therapy.

Glycan-binding profile and cell adhesion activity of American bullfrog (Rana catesbeiana) oocyte galectin-1.

The glycan-binding profile of a beta-galactoside-binding 15 kDa lectin (Galectin-1) purified from the oocytes of the American bullfrog, Rana catesbeiana, was studied using 61 pyridyl-aminated oligosaccharides by frontal affinity chromatography. Human blood type-A-hexasaccharide (GalNAcalpha1-3(Fucalpha1-2)Galbeta;1-4GlcNAcbeta1-4Galbeta1-4Glc) was found to exhibit the strongest ligand binding to the galectin while Forssman antigen (GalNAcalpha1-3GalNAcbeta1-3Galalpha1-4Galbeta1-4Glc) and type-A-tetrasaccharide (GalNAcalpha1-3(Fucalpha1-2)Galbeta1-4GlcNAcbeta1-4Glc) were also extensively recognized. The kinetics of affinity of galectin-1 to type-A oligosaccharide was analysed by surface plasmon resonance using neoglycoprotein with type-A oligosaccharides. R. catesbeiana oocyte galectin adhered to human rhabdomyosarcoma cells dose dependently and the activity was specifically cancelled by the neoglycoprotein. It was concluded that galectin-1 from R. catesbeiana oocytes possesses different and rare glycan-binding properties from typical members in galectin family.

The Xenopus Bowline/Ripply family proteins negatively regulate the transcriptional activity of T-box transcription factors.

Bowline, which is a member of the Xenopus Bowline/Ripply family of proteins, represses the transcription of somitogenesis-related genes before somite segmentation, which makes Bowline indispensable for somitogenesis. Although there are three bowline/Ripply family genes in each vertebrate species, it is not known whether the Bowline/Ripply family proteins share a common role in development. To elucidate their developmental roles, we examined the expression patterns and functions of the Xenopus Bowline/Ripply family proteins Bowline, Ledgerline, and a novel member of this protein family, xRipply3. We found that the expression patterns of bowline and ledgerline overlapped in the presomitic mesoderm (PSM), whereas ledgerline was additionally expressed in the newly formed somites. In addition, we isolated xRipply3, which is expressed in the pharyngeal region. Co-immunoprecipitation assays revealed that Ledgerline and xRipply3 interacted with T-box proteins and the transcriptional co-repressor Groucho/TLE. In luciferase assays, xRipply3 weakly suppressed the transcriptional activity of Tbx1, while Ledgerline strongly suppressed that of Tbx6. In line with the repressive role of Ledgerline, knockdown of Ledgerline resulted in enlargement of expression regions of the somitogenesis-related-genes mespb and Tbx6. Inhibition of histone deacetylase activity increased the expression of mespb, as seen in the Bowline and Ledgerline knockdown experiments. These results suggest that the Groucho-HDAC complex is required for the repressive activity of Bowline/Ripply family proteins during Xenopus somitogenesis. We conclude that although the Xenopus Bowline/Ripply family proteins Bowline, Ledgerline and xRipply3 are expressed differentially, they all act as negative regulators of T-box proteins.

PMesogenin1 and 2 function directly downstream of Xtbx6 in Xenopus somitogenesis and myogenesis.

T-box transcription factor tbx6 and basic-helix-loop-helix transcription factor pMesogenin1 are reported to be involved in paraxial mesodermal differentiation. To clarify the relationship between these genes in Xenopus laevis, we isolated pMesogenin2, which showed high homology with pMesogenin1. Both pMesogenin1 and 2 appeared to be transcriptional activators and were induced by a hormone-inducible version of Xtbx6 without secondary protein synthesis in animal cap assays. The pMesogenin2 promoter contained three potential T-box binding sites with which Xtbx6 protein was shown to interact, and a reporter gene construct containing these sites was activated by Xtbx6. Xtbx6 knockdown reduced pMesogenin1 and 2 expressions, but not vice versa. Xtbx6 and pMesogenin1 and 2 knockdowns caused similar phenotypic abnormalities including somite malformation and ventral body wall muscle hypoplasia, suggesting that Xtbx6 is a direct regulator of pMesogenin1 and 2, which are both involved in somitogenesis and myogenesis including that of body wall muscle in Xenopus laevis.

Physical interaction between Tbx6 and mespb is indispensable for the activation of bowline expression during Xenopus somitogenesis.

During vertebrate somitogenesis, various transcriptional factors function coordinately to determine the position of the somite boundary. Previously, we reported on the signaling crosstalk that occurs between two major transcription factors involved in somitogenesis, Tbx6 and mespb/mesp2. These factors synergistically activated the expression of a downstream gene, bowline/Ripply2, which is essential for precise formation of the somite boundary. However, the molecular mechanism underlying this synergistic effect remains unclear. In this report, we found that the Tbx6 and mespb proteins interacted physically with each other. Pulldown assays with various deletion mutants of these proteins identified the essential domains for this physical interaction. Finally, we found that interference with the physical interaction by a dominant-negative form of mespb, mespbDeltaDBD, abrogated the expression of the bowline gene during Xenopus somitogenesis. These results indicate that the appropriate expression of bowline/Ripply2 is regulated by a direct interaction between the Tbx6 and mespb proteins during Xenopus somitogenesis.

Tbx6, Thylacine1, and E47 synergistically activate bowline expression in Xenopus somitogenesis.

T-box factor, Tbx6, is a prerequisite for somite segmentation in vertebrates. We recently identified a negative regulator of Tbx6, Bowline, which represses the expression of genes involved in somite segmentation by suppressing the transcriptional activity of Tbx6. According to this function, bowline gene expression is restricted to the most anterior presomitic mesoderm where the somite segmentation program terminates, although it remains unclear how bowline expression is activated. To address this, we investigated the cis-regulatory region of bowline. Measuring luciferase activity driven by the bowline promoter, we found that Tbx6, Thylacine1, and E47 synergistically activate bowline expression in vitro. We also found that Tbx6, Thylacine1, and E47 are spatiotemporally sufficient to induce bowline expression in Xenopus somitogenesis. Our findings indicated that besides being a negative regulator of Tbx6, bowline itself is also regulated by Tbx6, suggesting the negative feedback loop of Tbx6-Bowline in the termination step of somite segmentation.

Xtbx6r, a novel T-box gene expressed in the paraxial mesoderm, has anterior neural-inducing activity.

T-box proteins are important transcriptional regulators in animal development. We searched the Xenopus laevis expressed sequence tag (EST) database using zebrafish tbx24 (Ztbx24) as a query and found a sequence. We then obtained corresponding clones from a neurula cDNA library. This novel gene has a T-box showing 53% homology with Xenopus laevis tbx6 (Xtbx6) and 51% with Ztbx24 at the amino acid level and is relatively close to Xtbx6 indicated by alignment analysis. In situ hybridization showed that it is expressed in the paraxial mesoderm in the caudal region in a very similar manner to Xtbx6, with a slight difference in that the former is emphasized more dorsally and has a more restricted distribution along the antero-posterior axis. From these results we named this gene Xtbx6r (tbx6-related). Xtbx6r or Xtbx6r-EnR, when overexpressed in animal caps, induced anterior neural markers but not mesodermal markers. In contrast, Xtbx6r-VP16, Xtbx6 and Ztbx24 induced various mesodermal markers. These results indicate that Xtbx6r is a transcriptional repressor and has activity different from that of Xtbx6 or Ztbx24. Xtbx6r induced Otx2, XAG and Pax6 in animal caps. This activity differed from that of Xbra-EnR or Xtbx6-EnR, suggesting that some differences in biological activity exist among the tested repressor-type T-box genes. Depletion of Xtbx6r by antisense morpholino oligo produced curved embryos, but did not affect expressions of MyoD, Myf5, XWnt8 or thylacine2, nor inhibited muscle differentiation or segmentation. The results of knockdown and overexpression experiments suggest that Xtbx6r is involved in some morphogenesis in the paraxial mesoderm.

GATA factors as key regulatory molecules in the development of Drosophila endoderm.

Essential roles for GATA factors in the development of endoderm have been reported in various animals. A Drosophila GATA factor gene, serpent (srp, dGATAb, ABF), is expressed in the prospective endoderm, and loss of srp activity causes transformation of the prospective endoderm into ectodermal foregut and hindgut, indicating that srp acts as a selector gene to specify the developmental fate of the endoderm. While srp is expressed in the endoderm only during early stages, it activates a subsequent GATA factor gene, dGATAe, and the latter continues to be expressed specifically in the endoderm throughout life. dGATAe activates various functional genes in the differentiated endodermal midgut. An analogous mode of regulation has been reported in Caenorhabditis elegans, in which a pair of GATA genes, end-1/3, specifies endodermal fate, and a downstream pair of GATA genes, elt-2/7, activates genes in the differentiated endoderm. Functional homology of GATA genes in nature is apparently extendable to vertebrates, because endodermal GATA genes of C. elegans and Drosophila induce endoderm development in Xenopus ectoderm. These findings strongly imply evolutionary conservation of the roles of GATA factors in the endoderm across the protostomes and the deuterostomes.

Drosophila Tbx6-related gene, Dorsocross, mediates high levels of Dpp and Scw signal required for the development of amnioserosa and wing disc primordium.

Regional differentiation along the dorsoventral (DV) axis of the Drosophila embryo primarily depends on a graded BMP signaling activity generated by Decapentaplegic (Dpp) and Screw (Scw). We have identified triplicated Dpp and Scw target genes Dorsocross1, 2 and 3 (Doc1, 2, 3) that have a conserved T-box domain related to the vertebrate Tbx6 subfamily and act redundantly to induce dorsal structures. Doc genes are expressed in the dorsal region in the early blastoderm. After gastrulation, newly expressed Doc appears in a segmental pattern in the ectoderm. This expression correlates spatially with the second phase of Dpp expression in the ectoderm. Doc expression in the early blastoderm is abolished in either dpp or scw mutant embryos, whereas the ectodermal segmented expression depends only on Dpp. Inactivation of Doc genes with RNAi dramatically affected the development of amnioserosa and wing disc primordia, both of which depend on high levels of BMP signaling, although leg disc primordium, which depends on low levels of BMP, remained intact. Doc1 mRNA expressed in Xenopus embryos induced ventral mesoderm, suppressed activin-induced events and induced Xvent genes, which are analogous to the effects of native Tbx6 and its upstream regulator, BMP-4. These results suggest that the Tbx6 subfamily act in the BMP signaling pathway required for embryonic patterning in both animals.

Induction of Pronephric Tubules by Activin and Retinoic Acid in Presumptive Ectoderm of Xenopus laevis: (RA/kidney/mesoderm induction/Xenopus laevis).

Correlation between activin and retinoic acid (RA), both of which affect early amphibian development, was studied using Xenopus laevis embryos. In the first set of experiments, two isomers of RA, all-trans RA and 13-cis RA, were compared in terms of stability of biological activity against light. Xenopus blastulae were dipped in RA solutions which had either been kept away from light, or had been exposed to light for a few hours. At doses ranging from 10-4 to 10-6 M, RA elicited head deformity. All-trans RA, under both dark and light conditions, had similarly potent effects. On the other hand, 13-cis RA under dark conditions had much weaker effects than it did under light conditions. In the second set of experiments, activin was mixed with all-trans RA, and the inducing effects on the animal cap explants were investigated. Activin at a concentration of 10 ng/ml induced notochord. In combination with 10-6 M RA, muscle was well induced instead of notochord. In combination with 10-5 M RA, pronephric tubules were markedly induced. Pronephric tubules were never induced by activin alone, at any of the various concentrations employed. This is the first report on the very high frequency of induction of pronephric tubules by the combination of activin A and all-trans RA in the Xenopus ectoderm.

Follistatin inhibits the mesoderm-inducing activity of activin A and the vegetalizing factor from chicken embryo.

The induction of mesoderm is an important process in early amphibian development. In recent studies, activin has become an effective candidate for a natural mesoderm-inducing factor. In the present study, we show that follistatin, an activin-binding protein purified from porcine ovary, inhibits the mesoderm-inducing activity of recombinant human activin A (rh activin A), which is identical to the erythroid differentiation factor (EDF). The quantity of follistatin required for effective suppression of activin was more than three-fold that of activin (w:w). Follistatin also inhibited the mesoderm-inducing activity of the vegetalizing factor purified from chick embryos, suggesting that the vegetalizing factor is closely related to activin.

Concentration-dependent inducing activity of activin A.

Human recombinant activin A, which is identical with erythroid differentiation factor (EDF), was tested for its mesoderm-inducing activity in concentrations from 0.3-50 ng/ml, using ectoderm of Xenopus late blastula (Stage 9) as the responding tissue. At a low concentration of activin A, blood-like cells, mesenchyme, and coelomic epithelium were induced; at a moderate concentration muscle and neural tissue, and at a high concentration notochord. Activin A thus induced all mesodermal tissues in a dose-dependent manner, such that a low dose induced ventral structures and a high dose induced dorsal structures. Activin may act as an intrinsic inducing molecule responsible for establishing the dorso-ventral axis in early Xenopus development.