Identification of free glycan chain liberated by de-N-glycosylation of the cortical alveolar glycopolyprotein (hyosophorin) during early embryogenesis of the Medaka fish, Oryzias latipes

In Medaka embryos (at the stages of blastulation to organogenesis), we found the presence of free glycan of which structure is identical with the multiantennary N-linked sugar chain of L-hyosophorin molecules which were originally present in the cortical alveoli of the unfertilized eggs in their precursor high molecular form. The free glycan-enriched fraction was separated from L-hyosophorin by chromatography on DEAE-Sephadex A-25 and Sephadex G-50 after removal of the sialic acid residues with exo-sialidase. Composition analysis, 400-MHz 1H NMR spectroscopy, and pyridylamination-hydrazinolysis-nitrous acid deamination of the free glycan showed the presence of di-N-acetylchitobiosyl structure at the reducing end, suggesting that the free glycan chain was derived from L-hyosophorin by the action of a specific peptide:N-glycosidase (PNGase). When we combine the previous finding of the hyosophorin-derived unique pentaantennary free glycan chain in the flounder embryos [A. Seko et al. (1989) J. Biol. Chem. 264, 15922-15929], it is anticipated that PNGase-catalyzed de-N-glycosylation of L-hyosophorin would be required at a certain stage of embryogenesis for L-hyosophorin to play a yet undefined functional role during early development.     

Immunocytochemical localization of epidermal growth factor receptor in early embryos of the Japanese medaka fish (Oryzias latipes)

This study was undertaken to localize epidermal growth factor receptor (EGFR) during early development of Japanese medaka embryos using immunocytochemistry. Specific staining was observed in all stages studied. All of the cells of the embryonic disc from the germinal disc (1 cell) through the late high blastula stages stained moderately for EGFR. Beginning with the flat blastula stage, the surface and lateral cells of the embryonic disc and the cells migrating around the yolk stained intensely for EGFR, and this continued throughout the study period. The presence of the keel at the late gastrula stage did not affect the moderate staining of the majority of the embryonic disc cells. When somites first appeared, the keel region stained less intensely than before, but scattered individual cells stained intensely for EGFR. Embryos with 12 somites had a neural tube that was lightly stained except for a few intensely stained individual cells. The neural tube, notochord and somites in 24-somite embryos lacked immunostaining. However, the surface epithelium, aorta, intestinal epithelium and pronephric duct demonstrated EGFR immunostaining. This study demonstrates that EGFR is present during medaka development and supports the hypothesis that EGFR ligands are important during cleavage, gastrulation and early organogenesis.     

Gravity influences the position of the dorsoventral axis in medaka fish embryos (Oryzias latipes)

To determine whether gravity influences the plane of bilateral symmetry in medaka embryos, zygotes were placed with their animal-vegetal axis orientated vertically and with their vegetal pole elevated. Then, at regular intervals during the first cell cycle, the zygotes were tilted 90° for about 10 min and subsequently returned to their original orientation. In embryos tilted during the first half of the first cell cycle, the embryonic shield formed on the side that had been lowermost when the zygote was tilted. In embryos that were tilted twice, first in one direction and then in the opposite direction, the embryonic shield formed on the side that was lowermost the first time. When zygotes were centrifuged at 5 g , the embryonic shield formed on the outwardly radial (centrifugal) side of the embryo. The orientation of the array of parallel microtubules in the vegetal pole region was also influenced by tilting or centrifuging zygotes. No correlation was found between the positions of the polar body and the micropyle and the plane of bilateral symmetry. It was concluded that gravity influences both the plane of bilateral symmetry and the orientation of microtubules in the vegetal pole region of medaka embryos.     

Nitrate toxicity on visceral organs of Medaka fish, Oryzias latipes: aiming to raise fish from egg to egg in space.

Histological survey was made to determine nitrate toxicity on the Medaka fish, Oryzias latipes. In order to investigate the effects of short-term exposure to nitrate, one-month-old Medaka fish was exposed to NaNO3 at concentrations of 100 and 125 mg NO3-N l-1 for 96 hours. At the end of the exposure period, survival rate was found to be 30% and 10%, for the 100 and 125 mg NO3-N l-1 exposure concentrations, respectively. Histological examination of the organs showed that disruption of cell alignment was a common feature in the gills, intestinal ampulla, liver and kidney. A long-term exposure experiment was also carried out, whereby Medaka fish was exposed to NaNO3 (100 and 125 mg NO3-N l-1) for three months from its egg stage. Eggs treated with NaNO3 hatched within 10 days after fertilization. At the end of the exposure period, survival rate in the 100 and 125 mg NO3-N l-1 treatments were 40% and 30%, respectively. Fibrosis of the hepatic cells and curved spinal column were observed in the juveniles subjected to long-term nitrate exposure. The results of our experiments suggest that the high mortality resulting from short-term acute exposure to nitrate is caused by general dysfunction throughout the whole body. The chronic toxic effects attributed to nitrate, following long-term exposure, were likely to have resulted from nutrient deficiency caused by hepatic dysfunction.     

Change in the radiation responses of oogonia in the embryos and fry of the fish Oryzias latipes.

Embryos of the fish Oryzias latipes were irradiated with 1000 R of X-rays 1 day before hatching,and the post-irradiation change in the female germ-cell population was observed. Scarcely any reduction in the number of oogonia was observed, but their proliferation was inhibited. Repopulation occurred between 12 and 20 days after hatching. These responses were quite different from those of germ cells in the irradiated fry (Hamaguchi and Egami 1975). Embryos and/or fry were also exposed to 1000 R of X-rays 1 day before hatching and 0, 1, 2, and 3 days after hatching. A comparison of their responses suggested that the change in the radiation responses of oogonia is correlated with the initiation of meiosis.     

Evolution of acetylcholinesterase and butyrylcholinesterase in the vertebrates: an atypical butyrylcholinesterase from the Medaka Oryzias latipes

Acetylcholinesterase (AChE) and butyrylcholinesterase (BChE) are thought to be the result of a gene duplication event early in vertebrate evolution. To learn more about the evolution of these enzymes, we expressed in vitro, characterized, and modeled a recombinant cholinesterase (ChE) from a teleost, the medaka Oryzias latipes. In addition to AChE, O. latipes has a ChE that is different from either vertebrate AChE or BChE, which we are classifying as an atypical BChE, and which may resemble a transitional form between the two. Of the fourteen aromatic amino acids in the catalytic gorge of vertebrate AChE, ten are conserved in the atypical BChE of O. latipes; by contrast, only eight are conserved in vertebrate BChE. Notably, the atypical BChE has one phenylalanine in its acyl pocket, while AChE has two and BChE none. These substitutions could account for the intermediate nature of this atypical BChE. Molecular modeling supports this proposal. The atypical BChE hydrolyzes acetylthiocholine (ATCh) and propionylthiocholine (PTCh) preferentially but butyrylthiocholine (BTCh) to a considerable extent, which is different from the substrate specificity of AChE or BChE. The enzyme shows substrate inhibition with the two smaller substrates but not with the larger substrate BTCh. In comparison, AChE exhibits substrate inhibition, while BChE does not, but may instead show substrate activation. The atypical BChE from O. latipes also shows a mixed pattern of inhibition. It is effectively inhibited by physostigmine, typical of all ChEs. However, although the atypical BChE is efficiently inhibited by the BChE-specific inhibitor ethopropazine, it is not by another BChE inhibitor, iso-OMPA, nor by the AChE-specific inhibitor BW284c51. The atypical BChE is found as a glycophosphatidylinositol-anchored (GPI-anchored) amphiphilic dimer (G(2) (a)), which is unusual for any BChE. We classify the enzyme as an atypical BChE and discuss its implications for the evolution of AChE and BChE and for ecotoxicology.     

Sex reversal in the medaka Oryzias latipes by brief exposure of early embryos to estradiol-17beta

To induce sex reversal of male to female, freshly-fertilized eggs of the S-rR strain medaka (Oryzias latipes) were immersed in saline containing estradiol-17beta (E2) in different concentrations for various durations until hatching. Results of the present experiment showed that the immersion duration in 1 microg/ml E2 to induce 100% reversal of sex differentiation in the genotypic males was enough only for one day (24 hr) post-fertilization (dpf) and that treatment with E2 for 1 dpf resulted in a dose-dependent manner with the maximum sex reversal of 100% at 1 microg/ml. To ascertain early developmental periods efficacious for inducing sex reversal, additional brief immersion treatments of eggs with E2 were further performed individually for four different early developmental periods (Stages 4-9, 10-12, 13-15 and 16-18) within 1 dpf. As a result, induction of sex reversal was observed in all these short immersion periods without any restricted efficacy. Between both experimental and control groups treated with or without E2 for 1 dpf, differences in the number of germ cells in a gonad were compared in newly-hatched fry. It was found that gonads of the genotypic males (XY) treated with E2 revealed the female type which contained many germ cells with much dividing activity. These data suggest that a possible switch mechanism that exogenous E2 could trigger to change the genetic cascades involved in sex determination upon fertilization exists in early developmental stages.     

Expression of the congenital heart disease 5/tryptophan rich basic protein homologue gene during heart development in Medaka fish,Oryzias latipes

The congenital heart disease 5 (CHD5)/tryptophan rich basic protein (WRB) is a protein containing a tryptophan‐rich carboxy‐terminal region, which was discovered in the human fetal heart. In humans, this CHD5/WRB is located between the markers ACTL5‐D21S268 within the Down syndrome (DS) Region‐2 at chromosome 21. Congenital heart disease is commonly linked to DS patients. The functions of this gene product are unknown. To identify the functions of CHD5/WRB in heart formation during embryogenesis, the medaka CHD5 cDNA (mCHD5) was isolated and its gene expression pattern and the localization of its gene product were investigated. The obtained mCHD5 belongs to the CHD5 superfamily, whose members include coiled‐coil proteins. The mCHD5 gene was found to be expressed in the developing heart after stage 28 at which the chamber (ventricle and atrium) differentiation in the heart tube is initiated in the embryo. Its gene product was also detected in the developing heart at embryonic stage 28 and 35. Knocking‐down of mCHD5 function caused severe cardiac disorder, including abnormal chamber differentiation, abnormal looping and ocular abnormality such as Cyclops. Our results provide the mCHD5 gene expression pattern as well as its physiological role during heart formation in a vertebrate model system.     

Deficiency of the Gene B Impairs Differentiation of Melanophores in the Medaka Fish,Oryzias latipes: Fine Structure Studies

In an orange-colored variant of the medaka fish, Oryzias latipes, which is homozygous for b allele, the melanophores represent a tissue-specific differentiation, manifesting an amelanotic appearance in the skin, an incomplete melanogenesis in the choroid and the peritoneum, and mosaic phenotype-like melano-iridophores in the peritoneum. In a wild-type strain of this species carrying the B gene, all melanophores are terminally differentiated irrespective of the tissues in which they are located. This indicates that the deficiency of B gene impairs the differentiation of melanophores in the medaka. Electron microscopy disclosed that the deficiency of B gene causes deterioration of melanogenesis to occur inside the melanosomes and that the manner of deterioration in the melanophores in the skin, the choroid and the peritoneum is different. The ubiquitous occurrence of reflecting platelet-laden melanophores in the peritoneum of this variant and the total absence of a mosaicism in pigment cells of the wild-type strain indicate that the deficiency of B gene predestines melanoblasts distributed in this tissue to an ambiguous state with regard to their differentiation. Little difference is observed between melanosomes maturation in pigment epithelial cells of the orange-colored variant and the wild-type strain, indicating an innocent role of the B gene in their differentiation.     

Sex determination in fish: Lessons from the sex-determining gene of the teleost medaka, Oryzias latipes

Although sex determination systems in animals are diverse, sex-determining genes have been identified only in mammals and some invertebrates. Recently, DMY (DM domain gene on the Y chromosome) has been found in the sex-determining region on the Y chromosome of the teleost medaka fish, Oryzias latipes. Functional and expression analyses of DMY show it to be the leading candidate for the male-determining master gene of the medaka. Although some work is required to define DMY as the master sex-determining gene, medaka is expected to be a good experimental animal for investigating the precise mechanisms involved in primary sex determination in non-mammalian vertebrates. In this article, the process of identification of DMY and is summarized and the origins of DMY and sexual development of the medaka's gonads are reviewed. In addition, putative functions of DMY are discussed.     

Four synonymous genes encode calmodulin in the teleost fish, medaka (Oryzias latipes): conservation of the multigene one-protein principle.

We cloned four distinct calmodulin (CaM)-encoding cDNAs from a small teleost fish, medaka (Oryzias latipes). The deduced amino acid (aa) sequences were exactly the same in these four genes and identical to the aa sequence of mammalian CaM, because of synonymous codon usages. The four cDNAs from medaka, termed CaM-A, -B, -C and -D, corresponded to mRNAs of 1.8, 1.4, 2.5 and 1.8 kb, respectively, in Northern blot analysis. Our results demonstrated that the 'multigene one-protein' principle of CaM synthesis is applicable to medaka, as well as to mammals whose CaM is encoded by at least three different genes.     

Chromophoric peptide substrates for activity determination of animal aspartic proteinases in the presence of their zymogens: A novel assay

Solid-phase synthesis was used for the preparation of pyroglutamyl-histidyl-p-nitrophenylalanyl-phenylalanyl-alanyl-leucine amide (I) and glycyl-glycyl-histidyl-p-nitrophenylalanyl-phenylalanyl-alanyl-leucine amide (II), two water-soluble and sensitive chromophoric substrates of chicken pepsin, hog pepsin A, and bovine spleen cathepsin D. The kinetic constants of hydrolysis of the p-nitrophenylalanyl-phenylalanyl bond of the substrates were measured by difference spectrophotometry at 308 nm (Δ? = 860 m^?1 cm^?1) and by ninhydrin colorimetry (substrate I, ?₅₇₀ = 2.31 × 10⁴m^?1 cm^?1). The pH optimum of cleavage is 5 for the pepsins and 3.7 for cathepsin D. Since all three proteinases still have a significant activity at pH 5.5–6 a new, simple assay was designed for submicrogram quantities of pepsins in the presence of pepsinogens without interference of the latter. The method is particularly suitable for the analyses of the zymogen activation mixtures.     

Novel method for the nuclear transfer of adult somatic cells in medaka fish (Oryzias latipes): use of diploidized eggs as recipients

Until recently, the nuclear transfer of adult somatic cell nuclei in fish has been unsuccessful. This is primarily because of chromosomal aberrations in nuclear transplants, which are thought to arise due to asynchrony between the cell cycles of the recipient egg and donor nucleus. We recently succeeded in circumventing this difficulty by using a new nuclear transfer method in medaka fish ( Oryzias latipes ). Instead of enucleated eggs, the method uses non-enucleated and diploidized eggs, obtained by retention of the second polar body release, as recipients in the nuclear transfer of primary culture cells from the caudal fin of an adult green fluorescent protein gene ( GFP )-transgenic strain. We found that 2.7% of the reconstructed embryos grew into diploid and fertile adults exhibiting donor expression characteristics and transmission of the GFP marker gene to progeny. The mechanism underlying the generation of nuclear transplants using this method is unknown at present; however, analyses of donor and recipient nuclei behavior and the cytoskeletal mechanisms involved in the early developmental stages, as well as the special ability of diploidized eggs to facilitate reprogramming of the donor nuclei will result in elucidation of the mechanism.