Tsutomu Kinoshita

Murine homologs of deltex define a novel gene family involved in vertebrate Notch signaling and neurogenesis.

Notch signaling plays an important role in cell‐fate specification in multicellular organisms by regulating cell–cell communication. The Drosophila deltex gene encodes a modulator of the Notch pathway that has been shown to interact physically with the Ankyrin repeats of Notch. We isolated four distinct cDNAs corresponding to mouse homologs of deltex — mouse Deltex1 (MDTX1), mouse Deltex2 (MDTX2), mouse Deltex2ΔE (MDTX2ΔE), and mouse Deltex3 (MDTX3). Deduced amino acid sequences of these four cDNAs showed a high degree of similarity to Drosophila Deltex and its human homolog, DTX1 throughout their lengths, even though they possess distinct structural features. MDTX proteins formed homotypic and heterotypic multimers. We found that these genes were expressed in the central, peripheral nervous system and in the thymus, overlapping with those of mouse Notch1. In mammalian tissue culture cells, overexpression of any of the four mouse deltex homologs suppressed the transcriptional activity of E47, a basic helix‐loop‐helix (bHLH) protein, in a manner similar to suppression by an activated form of human Notch1 or human DTX1. In addition, overexpression of MDTX2 and MDTX2ΔE in C2C12 cells under differentiation‐inducing conditions suppressed the expression of myogenin, one of the myogenic transcriptional factors; this was also similar to a previously reported activity of constitutively activated Notch. Furthermore, misexpression of any of the MDTX genes in Xenopus embryos resulted in an expansion of the region expressing the neural cell adhesion molecule (N‐CAM) gene, a marker for the neuroepithelium. Collectively, our results suggest that these mouse deltex homologs are involved in vertebrate Notch signaling and regulation of neurogenesis.

Bisphenol A disrupts Notch signaling by inhibiting gamma-secretase activity and causes eye dysplasia of Xenopus laevis

Bisphenol A (BPA) is being recognized as an endocrine-disrupting chemical (EDC). Recently, several reports indicated that BPA affects the central nervous system (CNS) during embryonic development. However, the molecular mechanism of BPA in the CNS is not well known. Here, we show that BPA affected Notch signaling by inhibiting the activity of the Notch intracellular domain (NICD) cleavage-related enzyme, gamma-secretase (gamma-secretase), at the neurula stage of the Xenopus laevis. BPA caused various morphologic aberrations including scoliosis, eye dysplasia, and loss of pigments in the X. laevis tadpole. These abnormalities were seen whenever BPA was used at the neurula stage. In addition, the expression levels of several marker mRNAs at the neurula stage were investigated by RT-PCR, and we found that the mRNAs expression of ectodermal marker, Pax6, CNS marker, Sox2, and neural crest marker, FoxD3, were decreased by treatment with BPA. These genes contribute to the neural differentiation at the neurula stage, and also the downstream factors of Notch signaling. Injection of NICD but not a Notch ligand, delta 1, rescued the abnormalities caused by BPA. We subsequently assayed the inhibition of the activities of NICD cleavage-related enzymes, tumor necrosis factor alpha converting enzyme, and gamma-secretase, by BPA and found that BPA inhibited the gamma-secretase activity. Furthermore, we expressed presenilin, a main component of gamma-secretase, in Escherichia coli and found the direct binding of BPA with presenilin. These results suggest that BPA affected the neural differentiation by inhibiting gamma-secretase activity, leading to neurodevelopmental abnormalities.

Asymmetrical Distribution of Mitochondrial rRNA into Small Micromeres of Sea Urchin Embryos

Abstract Blastomeres of the 16-cell stage embryos of the sea urchin, Hemicentrotus pulcherrimus, were separated by an elutriator. By differential display, several RNA species that are enriched in micromeres are detected and their cDNA was cloned. One of the cloned cDNA encodes mt 12S rRNA. cDNA for mt 16S rRNA was also cloned from the cDNA library of unfertilized eggs. Two mt rRNAs contain poly(A) tails in their 3′ ends. Both mt rRNAs distribute asymmetrically along a vegetal-animal axis of the 16-cell embryos and are enriched in micromeres, and this is also confirmed by whole mount in situ hybridization as well as electron microscopic in situ hybridization. As development proceeds, these mt rRNAs become more enriched in small micromeres. Results of electron microscopical in situ hybridization reveal both mt rRNAs localize extramitochondrially. Though at present we have no evidence on the role of the extramitochondrial mt rRNAs in sea urchin development, it is speculated considering roles of extramitochondrial mt 16S rRNA in Drosophila development that extramitochondrial mt rRNA may be implicated in development of sea urchin embryos.

The intracellular domain of X-Serrate-1 is cleaved and suppresses primary neurogenesis in Xenopus laevis

The Notch ligands, Delta/Serrate/Lag-2 (DSL) proteins, mediate the Notch signaling pathway in a numerous developmental processes in multicellular organisms. Although the ligands induce the activation of the Notch receptor, the intracellular domain-deleted forms of the ligands cause dominant-negative phenotypes, implying that the intracellular domain is necessary for the Notch signal transduction. Here we examined the role of the intracellular domain of Xenopus Serrate (XSICD) in Xenopus embryos. X-Serrate-1 has the putative nuclear localization sequence (NLS) in downstream of the transmembrane domain. Biochemical analysis revealed that XSICD fragments are cleaved from the C-terminus side of X-Serrate-1. Fluorescence microscopic analysis showed that the nuclear localization of XSICD occurs in the neuroectoderm of the embryo injected with the full-length X-Serrate-1/GFP. Overexpression of XSICD showed the inhibitory effect on primary neurogenesis. However, a point mutation in the NLSs of XSICD inhibited the nuclear localization of XSICD, which caused the induction of a neurogenic phenotype. The animal cap assay revealed that X-Serrate-1 suppresses primary neurogenesis in neuralized animal cap, but X-Delta-1 does not. Moreover, XSICD could not activate the expression of the canonical Notch target gene, XESR-1 in contrast to the case of full-length X-Serrate-1. These results suggest that the combination of XSICD-mediated intracellular signaling and the extracellular domain of Notch ligands-mediated activation of Notch receptor is involved in the primary neurogenesis. Moreover, we propose a bi-directional signaling pathway mediated by X-Serrate-1 in Notch signaling.

X-Serrate-1 is involved in primary neurogenesis in Xenopus laevis in a complementary manner with X-Delta-1

Abstract. Notch, Delta and Serrate encode transmembrane proteins that function in cell fate specification in the Drosophila melanogaster embryo. Here we report gene expression patterns and functional characterization of a Xenopus Serrate homolog, X-Serrate-1. The isolated cDNA encoded a transmembrane protein with a Delta/Serrate/LAG-2 domain, 16 epidermal growth factor-like repeats and a cysteine-rich region. Expression of X-Serrate-1 was observed ubiquitously from unfertilized egg to tadpole, but an upregulation occurred in the tailbud stage embryo. Adult expression was found in eye, brain, kidney, heart, spleen and ovary. Whole-mount in situ hybridization revealed that the organ-related expression in eye, brain, heart and kidney occurred from an early stage of rudiment formation. Overexpression of X-Serrate-1 led to a reduction of primary neurons, whereas an intracellularly deleted form of X-Serrate-1 increased the number of primary neurons. Although the function of X-Serrate-1 in primary neurogenesis was quite similar to that of X-Delta-1, expression of X-Serrate-1 and X-Delta-1 did not affect each other. Co-injection experiments showed that wild-type X-Serrate-1 and X-Delta-1 suppressed overproduction of primary neurons induced by dominant-negative forms of X-Delta-1 and X-Serrate-1, respectively. These results suggest that X-Serrate-1 regulates the patterning of primary neurons in a complementary manner with X-Delta-1-mediated Notch signaling.

Maternal transcripts of mitotic checkpoint gene, Xbub3, are accumulated in the animal blastomeres of Xenopus early embryo.

Maternally transcribed mRNAs play the important role during early embryogenesis. Especially in patterning, distribution of the maternal transcripts has a causal relation to axis formation in the early embryo. We compared the quantity of mRNAs among four blastomeres of Xenopus 8-cell-stage embryos by the differential display method. A novel gene, Xbub3, was cloned by screening the oocyte cDNA library with an animal blastomere-enriched PCR product. Xbub3 is a homolog of the human mitotic checkpoint gene hBub3. A transcript of Xbub3 was 2940 bp and encoded a predicted protein of 330 amino acids with six WD repeats. Expression of Xbub3 was observed from oocyte to tadpole. Whole-mount in situ hybridization showed that Xbub3 mRNAs were uniformly distributed in the early stages of oogenesis but gradually localized to the animal hemisphere, especially in the perinuclear cytoplasm of full-grown oocytes. In the cleavage-stage embryos, the maternal transcripts of Xbub3 were recruited into each blastomere, associating closely with chromosomes. Zygotic expression of Xbub3 was widely detected in gastrula ectoderm and was gradually restricted to the central nervous systems, eyes, and branchial arches by the tadpole stage. This evidence contributes to understanding of the regulatory mechanism of the cell cycle and cell differentiation in the early embryo.

Xoom is maternally stored and functions as a transmembrane protein for gastrulation movement in Xenopus embryos

Xoom has been identified as a novel gene that plays an important role in gastrulation of Xenopus laevis embryo. Although Xoom is actively transcribed during oogenesis, distribution and function of its translation product have not yet been clarified. In the present study, the polyclonal antibody raised against Xoom was generated to investigate a behavior of Xoom protein. Anti‐Xoom antibodies revealed that there are two forms of Xoom protein in Xenopus embryos: (i) a 45 kDa soluble cytoplasmic form; and (ii) a 44 kDa membrane‐associated form. Two forms of Xoom protein were ubiquitously detected from unfertilized egg to tadpole stage, with a qualitative peak during blastula and gastrula stages. Immunohistochemical examination showed that Xoom protein is maternally stored in the animal subcortical layer and divided into presumptive ectodermal cells during cleavage stages. Enzymatic digestion of membrane protein and immunologic detection of Xoom showed that Xoom exists as a membrane‐associated protein. To examine a function of Xoom protein, anti‐Xoom antibodies were injected into blastocoele of stage 7 blastula embryo. Anti‐Xoom antibodies caused gastrulation defect in a dose‐ dependent manner. These results suggest that maternally prepared Xoom protein is involved in gastrulation movement on ectodermal cells.

Expression and characterization of Xenopus type I collagen alpha 1 (COL1A1) during embryonic development.

A cDNA encoding Xenopus type I collagen alpha 1 (Xenopus COL1A1) has been isolated from an ovary cDNA library. The COL1A1 cDNA is approximately 5.7 kb pairs and encodes 1447 amino acids. The putative COL1A1 polypeptide shares high identities of amino acid sequence with other vertebrate COL1A1 proteins. The level of Xenopus COL1A1 transcripts was increased markedly in the posterior region of the embryo at the tail‐bud stage, then gradually spread to the anterior region. Histological observations of the tail‐bud embryos showed that COL1A1 was mainly expressed in the inner layer of the posterior dorsal epidermis exposed to the somite mesoderm, except for in the dorsal fin. Less intense signals were also detected in the outer layer of the dorsal epidermis and dermatome. The expression of COL1A1 was increased in posteriorized embryos resulting from treatment with retinoic acid but decreased in hyper‐dorsalized embryos resulting from lithium chloride treatment. These results suggest that COL1A1 is a major component of the dorsal dermis exposed to the somite in Xenopus embryos, but its expression is not related to the temporal sequence of somite segregation.

A novel POZ/zinc finger protein, champignon, interferes with gastrulation movements in Xenopus.

We have cloned a novel krüppel‐like transcription factor of Xenopus that encodes POZ/zinc finger protein by expression cloning. Overexpression of mRNA resulted in interference with gastrulation. Because the injected embryo looks like a mushroom in appearance at the neurula stage, we have named this gene champignon (cpg). In cpg‐injected embryos, the blastopore appeared normally, but regressed thereafter. The injected embryos then elongated along the primary dorsoventral axis during the tailbud stage. Histologic sections and reverse transcription‐polymerase chain reaction analysis showed that cpg had no effect on the cell differentiation. The animal pole region of cpg‐injected embryos was thick during the gastrula stage, and mesodermal cells remained in the marginal zone. Furthermore, neither Keller‐sandwich explants nor activin‐treated animal cap explants excised from cpg‐injected embryos elongated. These results suggest that cpg acts as a potent inhibitor of cell migration and cell intercalation during gastrulation.

Xoom is required for epibolic movement of animal ectodermal cells in Xenopus laevis gastrulation

Gastrulation is the most dynamic cell movement and initiates the body plan in amphibian development. In contrast to numerous molecular studies on mesodermal induction, the driving force of gastrulation is as yet poorly understood. A novel transmembrane protein, Xoom, was previously reported, which is required for Xenopus gastrulation. In the present study, the role of Xoom during Xenopus gastrulation was further examined in detail. Overexpression and misexpression of Xoom induced overproduction of Xoom protein, but not a changed phenotype. However, Xoom antisense ribonucleic acid (RNA) injection reduced the Xoom protein and caused gastrulation defects without any influence on the involution and translation levels of mesodermal marker genes. Normal migrating activity of dorsal mesodermal cells was recognized in the antisense RNA‐injected explant. Morphological examination using artificial exogastrulation showed that convergent extension of mesodermal cells occurred normally, but the ectodermal cell layer significantly shrank in the antisense RNA‐injected embryo. Comparison of cell shape among various experimental conditions showed that inhibition of cell spreading occurs specifically in the outer ectodermal layer of the antisense RNA‐injected embryo. Cytochemical examination indicated disorganization of F‐actin in the ectodermal cells of the antisense RNA‐injected embryo. These results suggest that Xoom plays an important role in the epibolic movement of ectodermal cells through some regulation of actin filament organization.