Developmental expression of the amphioxus <Emphasis Type="Italic">Tbx1</Emphasis>/<Emphasis Type="Italic">10</Emphasis> gene illuminates the evolution of vertebrate branchial arches and sclerotome

We have isolated an amphioxus T-box gene that is orthologous to the two vertebrate genes, Tbx1 and Tbx10, and examined its expression pattern during embryonic and early larval development. AmphiTbx1/10 is first expressed in branchial arch endoderm and mesoderm of developing neurulae, and in a bilateral, segmented pattern in the ventral half of newly formed somites. Branchial expression is restricted to the first three branchial arches, and disappears completely by 4 days post fertilization. Ventral somitic expression is restricted to the first 10–12 somites, and is not observed in early larvae except in the most ventral mesoderm of the first three branchial arches. No expression can be detected by 4 days post fertilization. Integrating functional, phylogenetic and expression data from amphioxus and a variety of vertebrate model organisms, we have reconstructed the early evolutionary history of the Tbx1/10 subfamily of genes within the chordate lineage. We conclude that Tbx1/10-mediated branchial arch endoderm and mesoderm patterning functions predated the origin of neural crest, and that ventral somite specification functions predated the origin of vertebrate sclerotome, but that Tbx1 was later co-opted during the evolution of developmental programs regulating branchial neural crest and sclerotome migration.Edited by M. Akam     

Expression profile of rrbp1 genes during embryonic development and in adult tissues of Xenopus laevis

Recent studies suggest that ribosome-binding protein 1 (RRBP1) is involved in multiple diseases such as tumorigenesis and cardiomyopathies. However, its function during embryonic development remains largely unknown. We searched Xenopus laevis database with human RRBP1 protein sequence and identified two cDNA sequences encoding Xenopus orthologs of RRBP1 including rrbp1a (NM_001089623) and rrbp1b (NM_001092468). Both genes were firstly detected at blastula stage 8 with weak signals in animal hemisphere by whole mount in situ hybridization. Evident expression of rrbp1 was mainly detected in cement gland and notochord at neurula and tailbud stages. Heart expression of rrbp1 was detected at stage 36. RT-PCR results indicated that very weak expression of rrbp1a was firstly detected in oocytes, followed by increasing expression until stage 39. Differently, very weak expression of rrbp1b was firstly observed at stage 2, and then maintained at a lower level to stage 17 followed by an intense expression from stages 19–39. Moreover, both expression profiles were also different in adult tissues. This study reports Xenopus rrbp1 expression during early embryonic development and in adult tissues. Our study will facilitate the functional analysis of Rrbp1 family during embryonic development.     

Generation of BAC Transgenic Tadpoles Enabling Live Imaging of Motoneurons by Using the Urotensin II-Related Peptide (ust2b) Gene as a Driver

Xenopus is an excellent tetrapod model for studying normal and pathological motoneuron ontogeny due to its developmental morpho-physiological advantages. In mammals, the urotensin II-related peptide (UTS2B) gene is primarily expressed in motoneurons of the brainstem and the spinal cord. Here, we show that this expression pattern was conserved in Xenopus and established during the early embryonic development, starting at the early tailbud stage. In late tadpole stage, uts2b mRNA was detected both in the hindbrain and in the spinal cord. Spinal uts2b⁺ cells were identified as axial motoneurons. In adult, however, the uts2b expression was only detected in the hindbrain. We assessed the ability of the uts2b promoter to drive the expression of a fluorescent reporter in motoneurons by recombineering a green fluorescent protein (GFP) into a bacterial artificial chromosome (BAC) clone containing the entire X. tropicalis uts2b locus. After injection of this construction in one-cell stage embryos, a transient GFP expression was observed in the spinal cord of about a quarter of the resulting animals from the early tailbud stage and up to juveniles. The GFP expression pattern was globally consistent with that of the endogenous uts2b in the spinal cord but no fluorescence was observed in the brainstem. A combination of histological and electrophysiological approaches was employed to further characterize the GFP⁺ cells in the larvae. More than 98% of the GFP⁺ cells expressed choline acetyltransferase, while their projections were co-localized with α-bungarotoxin labeling. When tail myotomes were injected with rhodamine dextran amine crystals, numerous double-stained GFP⁺ cells were observed. In addition, intracellular electrophysiological recordings of GFP⁺ neurons revealed locomotion-related rhythmic discharge patterns during fictive swimming. Taken together our results provide evidence that uts2b is an appropriate driver to express reporter genes in larval motoneurons of the Xenopus spinal cord.     

Effects of transgenic overexpression of diapause hormone and diapause hormone receptor genes on non-diapause silkworm

Diapause is a state of developmental arrest that is most often observed in arthropods, especially insects. The domesticated silkworm, Bombyx mori, is a typical insect that enters diapause at an early embryonic stage. Previous studies have revealed that the diapause hormone (DH) signaling molecules, especially the core members DH and DH receptor 1 (DHR1), are crucial for the determination of embryonic diapause in diapause silkworm strains. However, whether they function in non-diapause silkworm strains remains largely unknown. Here, we generated two transgenic lines overexpressing DH or DHR1 genes in a non-diapause silkworm strain, Nistari. Our results showed that developmental expression patterns of DH and DHR1 are quite similar in transgenic silkworms: both genes are highly expressed in the mid to late stages of pupae and are most highly expressed in day-6 pupae but are expressed at very low levels in other developmental stages. Moreover, the overexpression of DH or DHR1 can affect the expression of diapause-related genes but is not sufficient to induce embryonic diapause in their offspring. This study provides new insights into the function of DH and DHR1 in a non-diapause silkworm strain.     

Dynamic expression of the LAP family of genes during early development of <Emphasis Type="Italic">Xenopus tropicalis</Emphasis>

The leucine-rich repeats and PDZ (LAP) family of genes are crucial for the maintenance of cell polarity as well as for epithelial homeostasis and tumor suppression in both vertebrates and invertebrates. Four members of this gene family are known: densin, erbin, scribble and lano. Here, we identified the four members of the LAP gene family in Xenopus tropicalis and studied their expression patterns during embryonic development. The Xenopus LAP proteins show a conserved domain structure that is similar to their homologs in other vertebrates. In Xenopus embryos, these genes were detected in animal cap cells at the early gastrula stage. At later stages of development, they were widely expressed in epithelial tissues that are highly polar in nature, including the neural epithelia, optic and otic vesicles, and in the pronephros. These data suggest that the roles of the Xenopus LAP genes in the control of cell polarity and morphogenesis are conserved during early development. Erbin and lano show similar expression patterns in the developing head, suggesting potential functional interactions between the two molecules in vivo.     

Role of fibroblast growth factors as inducing agents in early embryonic development

To assess the potential role of a molecule in development we need to know three things: 1) what are the biological activities of the molecule, 2) what is its expression pattern, and 3) what are the consequences of removing it from the embryo? In the case of the FGF family in Xenopus embryos we have quite a lot of information about all three questions. Most members of the family can induce mesoderm from isolated animal caps, thus mimicking the natural “ventral vegetal” inducing signal operative in the blastula. This activity can be exerted on isolated, disaggregated cells and does not involve a change in division rate. When overexpressed from injected mRNA, the activity of FGFs depends largely on whether or not they possess a signal sequence, showing the importance of secretion in the inductive process. In addition to the mesoderm-inducing activity, there are effects of overexpression on whole embryos which lead to a suppression of anterior structures. Three types of FGF have so far been cloned from Xenopus: direct homologs of each of the mammalian types FGF-2 and FGF-3, and eFGF (“embryonic FGF”), which is equidistant in sequence from mammalian FGF-4 and FGF-6. Attempts to find homologs of mammalian FGF-5 and FGF-7 in Xenopus have proved unsuccessful. All three types of Xenopus FGF are expressed in early development. FGF-2 and eFGF are present in the oocyte and fertilized egg, and are thus both available at the time of mesoderm induction. FGF-3 and eFGF are both expressed from the embryonic genome during gastrulation and concentrated in the forming mesoderm. FGF-2 is expressed from the embryonic genome during neurulation in the brain, and a little later in the branchial arch mesenchyme and in the forming myotomes. These expression patterns suggest that there are several functions for the FGFs. The most successful strategy for inhibition of the FGF system has been the use of a dominant negative receptor construct introduced by Kirschner and colleagues. Overexpression of this construct can abolish the FGF responsiveness of animal caps. In whole embryos, the absence of FGF signaling causes a reduction, although not a total ablation, of mesoderm formation. There is also a severe effect on axis formation in which formation of the posterior parts is reduced consequent on an inhibition of invagination and elongation of the dorsal mesoderm. Thus, the present evidence suggests that the FGF system contributes to, although is not solely responsible for, mesoderm induction in vivo. It is also necessary for normal gastrulation movements, particularly in the dorsal mesoderm, and is likely to have several later functions, particularly in development of the central nervous system and the myotomes. © 1994 Wiley-Liss, Inc.     

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.     

inka1b expression in the head mesoderm is dispensable for facial cartilage development

Inka box actin regulator 1 (Inka1) is a novel protein identified in Xenopus and is found in vertebrates. While Inka1 is required for facial skeletal development in Xenopus and zebrafish, it is dispensable in mice despite its conserved expression in the cranial neural crest, indicating that Inka1 function in facial skeletal development is not conserved among vertebrates. Zebrafish bears two paralogs of inka1 (inka1a and inka1b) in the genome, with the biological roles of inka1b barely known. Here, we analyzed the expression and function of inka1b during facial skeletal development in zebrafish. inka1b was expressed sequentially in the head mesoderm adjacent to the pharyngeal pouches essential for facial skeletal development at the stage of arch segmentation. However, a loss-of-function mutation in inka1b displayed normal head development, including the pouches and facial cartilages. The normal head of inka1b mutant fish was unlikely a result of the genetic redundancy of inka1b with inka1a, given the distinct expression of inka1a and inka1b in the cranial neural crest and head mesoderm, respectively, during craniofacial development. Our findings suggest that the inka1b expression in the head mesoderm might not be essential for head development in zebrafish.     

Protocadherin-1 is expressed in the notochord of mouse embryo but is dispensable for its formation

Notochord is an embryonic midline structure that serves as mechanical support for axis elongation and the signaling center for the surrounding tissues. Precursors of notochord are initially induced in the dorsal most mesoderm region in gastrulating embryo and separate from the surrounding mesoderm/endoderm tissue to form an elongated rod-like structure, suggesting that cell adhesion molecules may play an important role in this step. In Xenopus embryo, axial protocadherin (AXPC), an orthologue of mammalian Protocadherin-1 (PCDH1), is indispensable for the assembly and separation from the surrounding tissue of the notochord cells. However, the role of PCDH1 in mammalian notochord remains unknown. We herein report that PCDH1 is expressed in the notochord of mouse embryo and that PCDH1-deficient mice form notochord normally. First, we examined the temporal expression pattern of pcdh1 and found that pcdh1 mRNA was expressed from embryonic day (E) 7.5, prior to the stage when notochord cells detach from the surrounding endoderm tissue. Second, we found that PCDH1 protein is expressed in the notochord of mouse embryos in addition to the previously reported expression in endothelial cells. To further investigate the role of PCDH1 in embryonic development, we generated PCDH1-deficient mice using the CRISPR-Cas9 system. In PCDH1-deficient embryos, notochord formation and separation from the surrounding tissue were normal. Structure and marker gene expression of notochord were also unaffected by loss of PCDH1. Major vascular patterns in PCDH1-deficient embryo were essentially normal. These results suggest that PCDH1 is dispensable for notochord formation, including the tissue separation process, in mammalian embryos. We successfully identified the evolutionary conserved expression of PCDH1 in notochord, but its function may differ among species.     

Inverted Xenopus eye primordia develop into anatomically inverted eyes

Stage 23–24 Xenopus eye primordia were inverted (rotated 180°) and transplanted to the flanks of host embryos of the same age. Inverted eyes developed inverted anatomies. Specifically inverted were: the anterodorsal to posteroventral sequence of corneal clearing, the anterodorsal to posteroventral sequence of pigment epithelium development, and the spatial patterns formed by the various optic tissues. More variation than normal was found in the precise location of entry of retinal ganglion cell axons into the optic stalk and in the position of the first fascicle of axons within the stalk. No tissue patterns appeared to realign themselves to a normal orientation with respect to the remainder of the body, and determinants of most of the anatomy of the mature eye were already stable in the Xenopus eye primordia by stage 23. Anatomically, the early eye primordia behaved like stable autonomous embryonic fields.