Blood cell induction in Xenopus animal cap explants: Effects of fibroblast growth factor, bone morphogenetic proteins, and activin

 Cultures of Xenopus blastula animal caps were used to explore the haematopoietic effects of three candidate inducers of mesoderm: basic fibroblast growth factor (bFGF), bone morphogenetic proteins (BMPs) and activin A. In response to either bFGF or activin A, explants expanded into egg-shaped structures, and beneath an outer layer of epidermis, a ventral mesodermal lining surrounded a fluid-filled cavity containing ”blood-like cells”. Immunocytochemistry identified some of these cells as early leukocytes, but erythrocytes were rare. BMP-2 or BMP-4 induced primitive erythrocytes as well as leukocytes, and a high concentration was required for these cells to differentiate in only a small proportion of explants. BMP-2 but not BMP-4 induced ventral mesoderm concomitantly. High concentrations of activin A dorsalized explants, which contained infrequent leukocytes, and an optimal combination of activin A and bFGF caused differentiation of muscle with few blood cells. By contrast, BMP-2 or BMP-4 plus activin A synergistically increased the numbers of both leukocytes and erythrocytes. Explants treated with BMPs plus activin contained a well organized cell mass in which yolk-rich cells mixed with blood cells and pigmented cells did not. BMP-2 plus bFGF also induced numerous leukocytes and fewer erythrocytes, but BMP-4 antagonized the leukopoietic effect of bFGF. The data suggest that the signalling pathways these three factors use to induce leukopoiesis overlap and that erythropoiesis may be activated when inducers are present in combination. Received: 3 August 1998 / Accepted: 7 October 1998     

The Xenopus platelet-derived growth factor α receptor: cDNA Cloning and demonstration that mesoderm induction establishes the lineage-specific pattern of ligand and receptor gene expression

We have cloned the Xenopus PDGF α receptor cDNA and have used this clone, along with cDNA encoding PDGF A, to examine their expression pattern in Xenopus embryos and to determine the factors responsible for lineage specificity. Recombinant Xenopus α receptor expressed in COS cells exhibits PDGF-A-dependent tyrosine kinase activity. We find that receptor mRNA is present in cultured marginal zone tissue explants and in animal cap tissue induced to form mesoderm either by grafting to vegetal tissue or by treatment with recombinant activin A. In contrast, PDGF A mRNA is expressed in cultured, untreated animal cap tissue and is suppressed by mesoderm induction. These results suggest that ectodermally produced PDGF A may act on the mesoderm during gastrulation and that mesoderm induction establishes the tissue pattern of ligand and receptor expression. © 1993Wiley-Liss, Inc.     

Induction of tooth and eye by transplantation of activin A-treated, undifferentiated presumptive ectodermal Xenopus cells into the abdomen

Activin A can induce the Xenopus presumptive ectoderm (animal cap) to form different types of mesoderm and endoderm at different concentrations and the animal cap treated with activin can function as an organizer during early development. The dissociated Xenopus animal cap cells treated with activin form an aggregate and it develops into various tissues in vitro. In this study, to induce jaw cartilage from undifferentiated cells effectively, we developed a culture method to manipulate body patterning in vitro, using activin A and dissociated animal cap cells. An aggregate consisting only of activin A-treated dissociated cells developed into endodermal tissues. However, when activin A-treated cells were mixed with untreated cells at a ratio of 1:5, the aggregate developed cartilage with the maxillofacial regional marker genes, goosecoid, Xenopus Distal-less 4 and X-Hoxa2. When this aggregate was transplanted into the abdominal region of host embryos, maxillofacial structures containing cartilage and eye developed. We raised these embryos to adulthood and found that tooth germ had developed in the transplanted tissue. Here, we show the induction of jaw cartilage, tooth germ and eye structures from animal caps using activin A in the aggregation culture method. This differentiation system will help to promote a better understanding of the regulating mechanisms of body patterning and tooth induction in vertebrates.     

Identification of members of the HSP30 small heat shock protein family and characterization of their developmental regulation in heat-shocked xenopus laevis embryos

In the present study we have characterized the synthesis of members of the HSP30 family during Xenopus laevis development using a polyclonal antipeptide antibody derived from the carboxyl end of HSP30C. Two-dimensional PAGE/immunoblot analysis was unable to detect any heat-inducible small HSPs in cleavage, blastula, gastrula, or neurula stage embryos. However, heat-inducible accumulation of a single protein was first detectable in early tailbud embryos with an additional 5 HSPs at the late tailbud stage and a total of 13 small HSPs at the early tadpole stage. In the Xenopus A6 kidney epithelial cell line, a total of eight heat-inducible small HSPs were detected by this antibody. Comparison of the pattern of protein synthesis in embryos and somatic cells revealed a number of common and unique heat inducible proteins in Xenopus embryos and cultured kidney epithelial cells. To specifically identify the protein product of the HSP30C gene, we made a chimeric gene construct with the Xenopus HSP30C coding sequence under the control of a constitutive promoter. This construct was microinjected into fertilized eggs and resulted in the premature and constitutive synthesis of the HSP30C protein in gastrula stage embryos. Through a series of mixing experiments, we were able to specifically identify the protein encoded by the HSP30C gene in embryos and somatic cells and to conclude that HSP30C synthesis was first heat-inducible at the early tailbud stage of development. The differential pattern of heat-inducible accumulation of members of the HSP30 family during Xenopus development suggests that these proteins may have distinct functions at specific embryonic stages during a stress response.     

XRASGRP2 expression during early development of Xenopus embryos

Previously, we described the DNA microarray screening of vascular endothelial cells that were formed by treatment of aggregates prepared from Xenopus animal cap cells with activin and angiopoietin-2. One of the genes identified in this screening showed homology to human RASGRP2 which plays a role in the regulation of GTP-GDP exchange of the Ras and Rap proteins, and was named XRASGRP2. In the present study, we analyzed the expression pattern of xrasgrp2 during Xenopus embryogenesis. The xrasgrp2 mRNA was expressed after stage 24, as assessed by stage PCR analysis. Whole-mount in situ hybridization showed that xrasgrp2 mRNA was located in the vascular region of the embryo. Loss-of-function analysis revealed that the formation of blood and endothelial cells in the explants transplanted into Xenopus embryos was inhibited by antisense morpholino oligonucleotides that block xrasgrp2 translation. These results suggest that XRASGRP2 plays a role in angiogenesis in Xenopus embryos.     

Different spatial distribution of mRNAs for activin receptors (type IIA and IIB) and follistatin in developing embryos of Xenopus laevis

Spatial distribution of mRNAs for activin receptors and follistatin was studied by Northern blot hybridization using RNAs from different parts of dissected Xenopus embryos. mRNAs of two activin receptors (type IIA and IIB) occurred uniformly in pre-gastrular embryos, but occurred in larger amounts in ectoderm (in gastrulae), neural plate (in neurulae) and anterior (head) regions (in tailbud embryos) than in other embryonic regions. By contrast, follistatin mRNA appeared almost exclusively in the dorsal mesoderm including invaginating organizer region at the gastrula stage, in notochord and in dorsal ectoderm at the neurula stage, then in anterior part at the tailbud stage. The localized patterns of the distribution of these mRNAs may be due to the regionally different zygotic expression of genes in embryos at later stages. From the relatively widespread pattern of distribution of their mRNAs, we assume that both type IIA and type IIB activin receptors have broad functions in ectodermal and neural differentiation. On the other hand, follistatin mRNA showed quite a restricted pattern of expression, and therefore, we assume that follistatin may have functions more specifically related to the sites of expression of its mRNA. Thus, follistatin may be involved in the differentiation of notochord itself and/or directly be responsible for organizer functions such as neural induction and subsequent differentiation of induced neural tissues at the gastrula and later stages.     

Activin A signaling directly activates Xenopus winged helix factors XFD-4/4’, the orthologues to mammalian MFH-1

We investigated the Xenopus winged helix gene XFD-4, its cDNA, and a pseudoallelic cDNA, termed XFD-4’, representing Xenopus orthologues to chicken CWH-2 and mammalian MFH-1. XFD-4/4’ genes are activated after midblastula transition in dorsolateral mesoderm but not within the dorsal lip. Later, expression is found in two segmented lines of cells bordering the somites, in head mesenchyme, in ventral abdominal muscle, and in the tail tip. Smad2 RNA injection leads to ectopic expression of XFD-4’. Since activation is also observed in activin A treated animal cap explants in the presence of cycloheximide, XFD-4/4’ genes represent direct targets of activin signaling. Note that the future nomenclature for XFD-4 will be FoxC2a and for XFD-4’ will be FoxC2b (Fox Nomenclature Committee). Received: 1 September 1999 / Accepted: 16 December 1999     

Acute phase response in amputated tail stumps and neural tissue‐preferential expression in tail bud embryos of the Xenopus neuronal pentraxin I gene

Regeneration of lost organs involves complex processes, including host defense from infection and rebuilding of lost tissues. We previously reported that Xenopus neuronal pentraxin I (xNP1) is expressed preferentially in regenerating Xenopus laevis tadpole tails. To evaluate xNP1 function in tail regeneration, and also in tail development, we analyzed xNP1 expression in tailbud embryos and regenerating/healing tails following tail amputation in the ‘regeneration’ period, as well as in the ‘refractory’ period, when tadpoles lose their tail regenerative ability. Within 10 h after tail amputation, xNP1 was induced at the amputation site regardless of the tail regenerative ability, suggesting that xNP1 functions in acute phase responses. xNP1 was widely expressed in regenerating tails, but not in the tail buds of tailbud embryos, suggesting its possible role in the immune response/healing after an injury. xNP1 expression was also observed in neural tissues/primordia in tailbud embryos and in the spinal cord in regenerating/healing tails in both periods, implying its possible roles in neural development or function. Moreover, during the first 48 h after amputation, xNP1 expression was sustained at the spinal cord of tails in the ‘regeneration’ period tadpoles, but not in the ‘refractory’ period tadpoles, suggesting that xNP1 expression at the spinal cord correlates with regeneration. Our findings suggest that xNP1 is involved in both acute phase responses and neural development/functions, which is unique compared to mammalian pentraxins whose family members are specialized in either acute phase responses or neural functions.     

Ectopic formation of primordial germ cells by transplantation of the germ plasm: Direct evidence for germ cell determinant in Xenopus

In many animals, the germ line is specified by a distinct cytoplasmic structure called germ plasm (GP). GP is necessary for primordial germ cell (PGC) formation in anuran amphibians including Xenopus. However, it is unclear whether GP is a direct germ cell determinant in vertebrates. Here we demonstrate that GP acts autonomously for germ cell formation in Xenopus.EGFP-labeled GP from the vegetal pole was transplanted into animal hemisphere of recipient embryos. Cells carrying transplanted GP (T-GP) at the ectopic position showed characteristics similar to the endogenous normal PGCs in subcellular distribution of GP and presence of germ plasm specific molecules. However, T-GP-carrying-cells in the ectopic tissue did not migrate towards the genital ridge. T-GP-carrying cells from gastrula or tailbud embryos were transferred into the endoderm of wild-type hosts. From there, they migrated into the developing gonad. To clarify whether ectopic T-GP-carrying cells can produce functional germ cells, they were identified by changing the recipients, from the wild-type Xenopus to transgenic Xenopus expressing DsRed2. After transferring T-GP carrying cells labeled genetically with DsRed2 into wild-type hosts, we could find chimeric gonads in mature hosts. Furthermore, the spermatozoa and eggs derived from T-GP-carrying cells were fertile. Thus, we have demonstrated that Xenopus germ plasm is sufficient for germ cell determination.     

Occurrence of nonlymphoid leukocytes that are not derived from blood islands in Xenopus laevis larvae

Previous immunohistochemical observations using the monoclonal antibody (XL-1) which recognizes all types of leukocytes in Xenopus laevis revealed the occurrence of XL-1+ cells in the mesenchyme throughout the early larval body, before the appearance of any lymphocytes. The present experiments were performed to determine whether these leukocytes originate, like lymphocytes and red blood cells (RBCs), in the ventral blood islands (VBI) or the dorsolateral plate (DLP). For tracing the derivation of cells, a specific staining by quinacrine to nuclei of X. laevis and Xenopus borealis hybrid (LB) cells was used to distinguish them from X. laevis (LL) cells. Orthotopic graftings of VBI tissue from st.22-23 LB embryos to the stage-matched LL embryos and examinations at st.44-45 before differentiation of the lymphocytes showed that the proportion of XL-1+ LB cells was always significantly lower than that of RBCs with the same marker in all experimental larvae. The head (LB)-body (LL) chimeras from st.22-23 embryos and culture of the head-portions as VBI- and DLP-free explants from st.14-23 embryos both demonstrated that a significant number of XL-1+ cells which had originated in the head portions had begun to differentiate by st.42-43. These results indicate that there is a significant population of larval nonlymphoid leukocytes (mostly macrophages) that do not originate from either the VBI or DLP region, and are distributed in the mesenchyme throughout the body.     

Induction of cells expressing vascular endothelium markers from undifferentiated Xenopus presumptive ectoderm by co-treatment with activin and angiopoietin-2

Activin is a potent inducer of mesoderm in amphibian embryos. We previously reported that low concentrations of activin could induce the formation of blood cells from Xenopus explants (animal caps). Both hematopoietic and vascular endothelial cell lineages are believed to share a common precursor, termed hemangioblasts. In this study, we tried to induce differentiation of vascular endothelial cells in aggregates derived from Xenopus animal caps. Aggregates formed from cells that were co-treated with activin and angiopoietin-2 expressed the vascular endothelial markers, X-msr, Xtie2 and Xegfl7. However, none of these aggregates expressed the hematopoietic marker genes, globin alpha T3, alpha T5, alpha A or GATA-1. We used microarray analysis to compare the gene expression profiles of aggregates treated with activin alone or with activin and angiopoietin. The combination, but not activin alone, induced expression of vascular-related genes such as Xl-fli and VEGF. These results demonstrate that treatment of dissociated animal cap cells with activin and angiopoietin-2 can induce differentiation of endothelial cells, and provides a promising model system for the in vitro study of blood vessel induction in vertebrates.     

Interaction between SPARC and tubulin in <Emphasis Type="Italic">Xenopus</Emphasis>

Secreted protein, acidic, rich in cysteine (SPARC) is an ancient calcium-binding glycoprotein associated with the extracellular matrices of invertebrates and vertebrates. We have previously reported an intracellular association of SPARC with the 9+2 microtubule arrays of cilia on the surface ectoderm of Xenopus embryos. During early development in Xenopus, ciliated cell precursors are associated with the inner sensorial layer of the two-layered embryonic skin. The ciliated cell precursors migrate to the overlying surface ectoderm where they undergo ciliogenesis. Whole-mount immunohistochemical data indicate SPARC is associated with the ciliary tuffts until ciliated cells begin to disappear from the surface ectoderm during late tailbud development. We now report an association between SPARC and tubulin in Xenopus embryonic cell lysates by co-immunoprecipitation. Tubulin is not co-immunoprecipitated by anti-SPARC antibodies that show no cross-reactivity to Xenopus SPARC by whole-mount immunocytochemical analysis. An association of SPARC with tubulin has also been observed in pull-down assays with biotinylated SPARC as bait. These data indicate that SPARC may have intracellular and extracellular functions during development in Xenopus.     

Ontogeny and tissue distribution of leukocyte-common antigen bearing cells during early development of Xenopus laevis

To analyze the ontogenic emergence of leukocytes during early development, a mouse monoclonal antibody (IgG1), designated as XL-1, was produced against the peritoneal macrophages of adult Xenopus laevis. The XL-1 determinant was expressed on all types of leukocytes, including lymphocytes, granulocytes, thrombocytes and macrophages, but not on erythrocytes of either larvae or adults. Immunohistochemical observations of the hemopoietic organs revealed that the XL-1+ cells with granulocyte and/or macrophage morphology appeared at st.36-37 in the liver, at st.44-45 in the mesonephric and the thymus rudiments, and at st.47 in the spleen. The XL-1 determinant was expressed on the precursor cells of T lymphocytes in the thymus rudiments at st.46-47, on the pre-B cells in the liver rudiments at st.47, and on lymphocytes in the spleen at st.48-49. A few XL-1+ cells were present in the ventral blood island of the st.35/36 embryos, where differentiating erythrocytes had predominated since st.28. XL-1+ cells with a macrophage-like morphology were found in several locations of the mesenchyme in the st.32 embryos, before the establishment of vascularization at st.33/34 and far earlier than the emergence of lymphocytes.     

Knockdown of SPARC leads to decreased cell-cell adhesion and lens cataracts during post-gastrula development in Xenopus laevis

SPARC is a multifunctional matricellular glycoprotein with complex, transient tissue distribution during embryonic development. In Xenopus laevis embryos, zygotic activation of SPARC is first detected during late gastrulation, undergoing rapid changes in its spatiotemporal distribution throughout organogenesis. Injections of anti-sense Xenopus SPARC morpholinos (XSMOs) into 2- and 4-cell embryos led to a dose-dependent dissociation of embryos during neurula and tailbud stages of development. Animal cap explants derived from XSMO-injected embryos also dissociated, resulting in the formation of amorphous ciliated microspheres. At low doses of XSMOs, lens cataracts were formed, phenocopying that observed in Sparc-null mice. At XSMOs concentrations that did not result in a loss of axial tissue integrity, adhesion between myotomes at intersomitic borders was compromised with a reduction in SPARC concentration. The combined data suggest a critical requirement for SPARC during post-gastrula development in Xenopus embryos and that SPARC, directly or indirectly, promotes cell?Ccell adhesion in vivo.     

Ventral cell rearrangements contribute to anterior-posterior axis lengthening between neurula and tailbud stages in Xenopus laevis

Studies of morphogenesis in early Xenopus embryos have focused primarily on gastrulation and neurulation. Immediately following these stages is another period of intense morphogenetic activity, the neurula-to-tailbud transition. During this period the embryo is transformed from the spherical shape of the early stages into the long, thin shape of the tailbud stages. While gastrulation and neurulation depend largely on active cell rearrangement and cell shape changes in dorsal tissues, we find that the neurula-to-tailbud transition depends in part on activities of ventral cells. Ventral explants of neurula lengthen autonomously as much as the ventral sides of intact embryos, while dorsal explants lengthen less than the dorsal sides of intact embryos. Analyses of cell division, cell shapes, and cell rearrangement by transplantation of labeled cells and by time lapse recordings in live intact embryos concur that cell rearrangements in ventral mesoderm and ectoderm contribute to the autonomous anterior-posterior axis lengthening of ventral explants between neurula and tailbud stages.