Msx1 and Msx2 have shared essential functions in neural crest but may be dispensable in epidermis and axis formation in Xenopus

The homeodomain factors Msx1 and Msx2 are expressed in essentially identical patterns in the epidermis and neural crest of Xenopus embryos during neurula stages. Disruption of Msx1 and Msx2 RNA splicing with antisense morpholino oligonucleotides shows that both factors are also required for expression of the neural crest gene Slug. Loss of Msx1 can be compensated by overexpression of Msx2 and vice versa. Loss of Msx factors also leads to alterations in the expression boundaries for neural and epidermal genes, but does not prevent or reduce expression of epidermal keratin in ventrolateral ectoderm, nor is there a detectable effect on dorsal mesodermal marker gene expression. These results indicate that Msx1 and Msx2 are both essential for neural crest development, but that the two genes have the same function in this tissue. If Msx genes have important functions in epidermis or axial mesoderm induction, these functions must be shared with other regulatory proteins.     

Expression of the N-myc proto-oncogene during the early development of Xenopus laevis

The N-myc proto-oncogene is expressed in a wide range of tissues during mammalian embryogenesis. This observation, along with the oncogenic capacity of this gene, has led to the suggestion that N-myc plays an important role in early development. However, due to the complexity of the expression pattern and the difficulty of manipulating mammalian embryos, little progress has been made towards understanding the developmental function of this gene. To enable a more detailed analysis of the role of this gene in early development, a study of the Xenopus homologue of N-myc was undertaken. Xenopus N-myc cDNA clones were isolated from a neurula library using a murine N-myc probe. Analysis of the timing of expression of N-myc mRNA and of the distribution of N-myc protein during Xenopus development indicate that this gene may be playing an important role in the formation of a number of embryonic structures, including the nervous system. N-myc is initially expressed as a maternal RNA, but this mRNA is degraded by the gastrula stage of development. Zygotic expression does not commence until late neurula. Examination of the distribution of the N-myc protein by whole-mount immunohistochemistry indicates that the early embryonic expression occurs in the central nervous system, the neural crest, the somites and the epidermis. Later expression is mostly within the head and somites. Specific structures within the head that express the protein include the eye, otic vesicle, fore and hindbrain and a number of cranial nerves. The results demonstrate that while N-myc is expressed in the developing nervous system of Xenopus, the timing of expression indicates that it is unlikely to be involved in regulation of the very first stages of neurogenesis.     

Inhibition of BMP activity by the FGF signal promotes posterior neural development in zebrafish

The expression patterns of region-specific neuroectodermal genes and fate-map analyses in zebrafish gastrulae suggest that posterior neural development is initiated by nonaxial signals, distinct from organizer-derived secreted bone morphogenetic protein (BMP) antagonists. This notion is further supported by the misexpression of a constitutively active form of zebrafish BMP type IA receptor (CA-BRIA) in the zebrafish embryos. It effectively suppressed the anterior neural marker, otx2, but not the posterior marker, hoxb1b. Furthermore, we demonstrated that the cells in the presumptive posterior neural region lose their neural fate only when CA-BRIA and Xenopus dominant-negative fibroblast growth factor (FGF) receptors (XFD) are coexpressed. The indications are that FGF signaling is involved in the formation of the posterior neural region, counteracting the BMP signaling pathway within the target cells. We then examined the functions of Fgf3 in posterior neural development. Zebrafish fgf3 is expressed in the correct place (dorsolateral margin) and at the correct time (late blastula to early gastrula stages), the same point that the most precocious posterior neural marker, hoxb1b, is first activated. Unlike other members of the FGF family, Fgf3 had little mesoderm-inducing activity. When ectopically expressed, Fgf3 expands the neural region with suppression of anterior neural fate. However, this effect was mediated by Chordino (zebrafish Chordin), because Fgf3 induces chordino expression in the epiblast and Fgf3-induced neural expansion was substantially suppressed in dino mutants with mutated chordino genes. The results obtained in the present study reveal multiple actions of the FGF signal on neural development: it antagonizes BMP signaling within posterior neural cells, induces the expression of secreted BMP antagonists, and suppresses anterior neural fate.     

Stimulation of premature retinoic acid synthesis in Xenopus embryos following premature expression of aldehyde dehydrogenase ALDH1.

In order for nuclear retinoic acid receptors to mediate retinoid signaling, the ligand retinoic acid must first be produced from its vitamin A precursor retinal. Biochemical studies have shown that retinal can be metabolized in vitro to retinoic acid by members of the aldehyde dehydrogenase enzyme family, including ALDH1. Here we describe the first direct evidence that ALDH1 plays a physiological role in retinoic acid synthesis by analysis of retinoid signaling in Xenopus embryos, which have plentiful stores of maternally derived retinal. The Xenopus ALDH1 gene was cloned and shown to be highly conserved with chick and mammalian homologs. Xenopus ALDH1 was not expressed at blastula and gastrula stages, but was expressed at the neurula stage. We used a retinoic acid bioassay to demonstrate that retinoic acid is normally undetectable in embryos from fertilization to the initial gastrula stage, but that a tremendous increase in retinoic acid occurs during neurulation when ALDH1 is first expressed. Overexpression of ALDH1 by injection of Xenopus embryos with mRNAs encoding the mouse, chick or Xenopus ALDH1 homologs induced high levels of retinoic acid detection during the blastula stage. Thus, premature expression of ALDH1 stimulates premature synthesis of retinoic acid. These findings reveal an important conserved role for ALDH1 in retinoic acid synthesis in vivo, and demonstrate that conversion of retinoids from the aldehyde form to the carboxylic acid form is a crucial regulatory step in retinoid signaling.     

Retinoic acid modifies the pattern of cell differentiation in the central nervous system of neurula stage Xenopus embryos.

Neural cell markers have been used to examine the effect of retinoic acid (RA) on the development of the central nervous system (CNS) of Xenopus embryos. RA treatment of neurula stage embryos resulted in a concentration-dependent perturbation of anterior CNS development leading to a reduction in the size of the forebrain, midbrain and hindbrain. In addition the overt segmental organization of the hindbrain was abolished by high concentrations of RA. The regional expression of two cell-specific markers, the homeobox protein Xhox3 and the neurotransmitter serotonin was also examined in embryos exposed to RA. Treatment with RA caused a concentration-dependent change in the pattern of expression of Xhox3 and serotonin and resulted in the ectopic appearance of immunoreactive neurons in anterior regions of the CNS, including the forebrain. Collectively, our results extend previous studies by showing that RA treatment of embryos at the neurula stage inhibits the development of anterior regions of the CNS while promoting the differentiation of more posterior cell types. The relevance of these findings to the possible role of endogenous retinoids in the determination of neural cell fate and axial patterning is discussed.     

Regionalization of the tail-tip epidermis requires inductive influence from vegetal cells and FGF signaling in the development of an ascidian, Halocynthia roretzi

The epidermis of an ascidian larva derived from animal-hemisphere cells is regionalized along the anterior-posterior (AP) axis through inductive signals emanating from vegetal-hemisphere cells in early stages of the development. Previously, we showed by blastomere isolation and ablation experiments that the contact between the animal and vegetal hemispheres until the 32-cell stage is necessary for the proper AP patterning of the epidermis in the tailbud-stage embryo. We here addressed the patterning mechanism of the posteriormost epidermis using a tail-tip epidermis marker, HrTT-1. Employing blastomere isolation and ablation experiments along with knockdown of a master regulator gene for posterior mesoderm, we have demonstrated that presence of the posterior vegetal cells after the 32-cell stage is necessary for the expression of HrTT-1. To explore the timing and nature of the influence of the posterior vegetal cells, we treated the embryos with FGF signaling inhibitors at various developmental stages and found that HrTT-1 expression was lost from embryos treated with the inhibitors from stages earlier than the late neurula stage, just prior to the onset of HrTT-1 expression but not after the initial tailbud stage, at which the expression of HrTT-1 had started. In embryos lacking HrTT-1 expression, the expression domain of Hrcad, which would otherwise be localized anterior to that of HrTT-1, expanded to the tail-tip. These results suggest that FGF signaling from the neurula to initial tailbud stages is necessary for the initiation but not maintenance of HrTT-1 expression in the tail-tip epidermis. The contact with posterior vegetal cells until and after the 32-cell stage may be required for FGF signaling to occur in the posterior tail, which in turn regionalizes the tail-tip epidermal territory.     

Tissue-specific expression of an Ornithine decarboxylase paralogue, XODC2, in Xenopus laevis

Ornithine decarboxylase (ODC) is involved in the biosynthesis of polyamines and hence has been found in almost all types of cells studied. Therefore it is frequently used as internal standard. We isolated a cDNA, XODC2, which is a paralogue to ubiquitous ODC and expressed in a spatial and temporal manner during the early embryogenesis of Xenopus laevis. Expression of XODC2was first detected at the animal pole at stage 9. During neurula stages the signals were found both in the extreme anterior and posterior part of the dorsal body axis. In tailbud stages the expression is further shifted to both the tail and head areas and gradually restricted to distinct tissues: forebrain, inner layer of epidermis of the head area, stomodeal-hypophyseal anlage, frontal gland, ear vesicle, branchial arches, the front tip of neural tube and proctodeum. In addition, signals were also found in the inner layer of epidermis underneath the cement gland during early tailbud stages while in later tailbud stages signals were detected at the apical zone of the cement gland. Comparative studies indeed could confirm that XODC1 in contrast to XODC2 is expressed ubiquitously throughout the whole embryos during early development of Xenopus laevis.     

Developmental expression of Shisa-2 in Xenopus laevis

Shisa is an antagonist of Wnt and FGF signaling, that functions cell autonomously in the endoplasmic reticulum (ER) to inhibit the post-translational maturation of Wnt and FGF receptors. In this paper we report the isolation of a second Xenopus shisa gene (Xshisa-2). Xenopus Shisa-2 shows 30.7% identity to Xshisa. RT-PCR analysis indicated that Xshisa-2 mRNA is present throughout early development and shows an increased expression during neurula and tailbud stages. At neurula stages Xenopus shisa-2 is initially expressed in the presomitic paraxial mesoderm and later in the developing somites. The expression profiles and pattern of Xshisa and Xshisa-2 differ significantly. During gastrulation only Xshisa mRNA is present in the Spemann-Mangold organizer and later on becomes restricted to the neuroectoderm and the prechordal plate.     

Involvement of the Xenopus homeobox gene Xhox3 in pattern formation along the anterior-posterior axis

The Xenopus homeobox gene Xhox3 shows a graded expression in the axial mesoderm, with the highest concentration in the posterior end of frog gastrula and neurula embryos. To investigate the function of the Xhox3 gene, synthetic Xhox3 mRNA was injected into different regions of developing embryos. In particular, Xhox3 was supplied in excess to anterior cells, which normally have the lowest levels of Xhox3 RNA. The results show that injection of Xhox3, but not control, mRNA into prospective anterior regions of developing embryos produces a series of graded axial defects. The injected embryos gastrulate normally but fail to form anterior (head) structures. Our findings suggest that Xhox3 is involved in establishing anterior-posterior cell identities during pattern formation of the axial mesoderm in early embryonic development.