Susumu Uji

Identification of cDNA coding for a homologue to mammalian leptin from pufferfish, Takifugu rubripes

We identified cDNA coding for a homologue to mammalian leptin in puffer, Takifugu rubripes, using genomic synteny around the human leptin gene. In addition to significant sequence homologies, the puffer leptin (pLEP) displays characteristic structural features in common with mammalian leptin. The pLEP mRNA was expressed mostly in the liver that contained abundant lipids. In addition, homologues to pLEP were found in the databanks for three fish species (salmon, medaka, and Tetraodon) and two amphibians (salamander and Xenopus). The phylogenetic analysis shows rapid rates of molecular divergence among leptins from different vertebrate classes, but not between mammals and avians.

Production of recombinant leptin and its effects on food intake in rainbow trout (Oncorhynchus mykiss)

Leptin is a key factor for the regulation of food intake and energy homeostasis in mammals, but information regarding its role in teleosts is still limited. There are large differences between mammalian and teleost leptin at both gene and protein levels, and in order to characterize the function of leptin in fish, preparation of species-specific leptin is therefore a key step. In this study, full-length cDNA coding for rainbow trout leptin was identified. In spite of low amino acid sequence similarity with other animals, leptin is highly conserved between trout and salmon (98.7%). Based on the cDNA, we produced pure recombinant trout leptin (rt-leptin) in E. coli, with a final yield of 20 mg/L culture medium. We then examined the effects of intraperitoneal (IP) injection of rt-leptin on feeding behavior and gene expression of hypothalamic NPY and POMCs (POMC A1, A2 and B) in a short-term (8 h) experiment. The rt-leptin suppressed food intake and led to transient reduction of NPY mRNA levels, while the expression of POMCs A1 and A2, was elevated compared with vehicle-injected controls. These results for rainbow trout are the first that describe a physiological role of leptin using a species-specific orthologue in teleosts, and they suggest that leptin suppresses food intake mediated by hypothalamic regulation. This anorexic effect is similar to that observed in mammals and frogs and supports that the neuroendocrine pathways that control feeding by leptin are ancient and have been conserved through evolution.

Genomic characterization and tissue distribution of leptin receptor and leptin receptor overlapping transcript genes in the pufferfish, Takifugu rubripes

Full-length cDNAs encoding the leptin receptor (tfLEPR), leptin receptor overlapping transcript (tfLEPROT) and leptin receptor overlapping transcript-like 1 (tfLEPROTL1) were cloned and sequenced from the pufferfish, Takifugurubripes. The tfLEPR gene encoded an 1116-amino acid protein that includes almost all functionally important domains conserved among vertebrate LEPR such as three fibronectin type III domains, the immunoglobulin (Ig) C2-like domain and a pair of repeated tryptophan/serine motifs. The tfLEPR mRNA was abundantly expressed in the pituitary and ovary and moderately expressed in brain, eye, heart, kidney, liver and testis. Both tfLEPROT and tfLEPROTL1 genes encoded a 130-amino acid protein. Human LEPR gene shares the first and second exons with the LEPROT gene, and they are continuously located on chromosome 1p31. In contrast, TakifuguLEPR and LEPROT were located at different regions of the chromosome. However, both Takifugu regions showed genomic synteny with the human genome around LEPR gene on chromosome 1p31. This result could mean that the Takifugu chromosomes around LEPR and LEPROT genes are paralogous genomic regions derived from genome duplication early in the teleost lineage and the overlapping LEPR and LEPROT genes were subsequently lost.

Overexpression of the dominant-negative form of myostatin results in doubling of muscle-fiber number in transgenic medaka (Oryzias latipes)

In addition to altering the phenotypes of gene-modified animals, transgenesis also has the potential to facilitate access to the various mechanisms underlying the development and functioning of specific phenotypes and genes, respectively. Myostatin (MSTN) is implicated in double-muscling when mutated in mammals, indicating that MSTN is a negative regulator of skeletal muscle formation. In order to elucidate the role of an MSTN equivalent in fish muscle formation, we created a transgenic medaka strain that expresses dominant-negative MSTN exclusively in skeletal muscle, d-rR-Tg(OlMA1-C315Y-MSTN-hrGFPII-FLAG). The transgenic fish exhibited increased production of skeletal muscle fibers at the adult stage (hyperplasia), although gross muscle mass was not altered. During embryogenesis, ectopic accumulation and misalignment of muscle fibers, possibly due to muscle-fiber hypertrophy, were observed in the transgenic medaka. Our findings suggest that MSTN function is required for regulating the appropriate growth of skeletal muscle in medaka. Unlike in mammals, MSTN loss-of-function failed to induce double-muscling in medaka, despite the highly conserved nature of MSTN function among taxa.

Characterization and tissue distribution of multiple agouti-family genes in pufferfish, Takifugu rubripes

Four types of agouti-family genes (AGRP1, AGRP2, ASIP1 and ASIP2) were obtained from torafugu, Takifugu rubripes. Their characterization and structure were analyzed to elucidate the relationship among the torafugu agouti-family genes. Both AGRP1 and AGRP2 showed genomic synteny with the human AGRP gene. Phylogenetic tree analysis showed that AGRP1 formed a cluster with human AGRP. We inferred that torafugu AGRP1 and AGRP2 are orthologs of human AGRP and that they are paralogous genes derived from genome duplication occurred in the teleost phylogeny. Torafugu ASIP1 showed genomic synteny with the human ASIP, but ASIP2 did not. The ASIP1 expression level was about five times higher in the white ventral skin than in the black dorsal skin. Therefore, we concluded that torafugu ASIP1 is an ortholog of human ASIP, nevertheless, we are unable to determine if torafugu ASIP2 is a paralog of ASIP1 or not.

Metamorphic pitx2 expression in the left habenula correlated with lateralization of eye-sidedness in flounder

The bilateral symmetry of flounder larvae changes through the process of morphogenesis to produce external asymmetry at metamorphosis. The process is characterized by the lateral migration of one eye and pigmentation at the ocular side. Migration of the left or right eye to produce either dextral or sinistral forms, respectively, is usually fixed within a species. Here we propose a mechanism for the mediation of lateralization by the nodal‐lefty‐pitx2 (NLP) pathway in flounders, in which pitx2, the final left‐right determinant of the NLP pathway, is re‐expressed in the left habenula at pre‐metamorphosis. After the initiation of left‐sided pitx2 re‐expression, the eye commences migration, when the habenulae shift their position on the ventral diencephalon rightwards in sinistral flounder (Paralichthys olivaceus) and leftwards in dextral flounder (Verasper variegatus). In addition, the right habenula increases in size relative to the left habenula in both species. Loss of pitx2 re‐expression induces randomization of eye‐sidedness, manifesting as normal, reversed or bilateral symmetry, with laterality of the structural asymmetry of habenulae being entirely inverted in reversed flounders compared with normal ones. Thus, flounder pitx2 appears to be re‐expressed in the left habenula at metamorphosis to direct eye‐sidedness by lateralizing the morphological asymmetry of the habenulae.

Circadian pacemaker in the suprachiasmatic nuclei of teleost fish revealed by rhythmic period2 expression.

In mammals, the role of the suprachiasmatic nucleus (SCN) as the primary circadian clock that coordinates the biological rhythms of peripheral oscillators is well known. However, in teleosts, it remains unclear whether the SCN also functions as a circadian pacemaker. We used in situ hybridization (ISH) techniques to demonstrate that the molecular clock gene, per2, is expressed in the SCN of flounder (Paralichthys olivaceus) larvae during the day and down-regulated at night, demonstrating that a circadian pacemaker exists in the SCN of this teleost. The finding that per2 expression in the SCN was also observed in the amberjack (Seriola dumerili), but not in medaka (Oryzias latipes), implies that interspecific variation exists in the extent to which the SCN controls the circadian rhythms of fish species, presumably reflecting their lifestyle. Rhythmic per2 expression was also detected in the pineal gland and pituitary, and aperiodic per2 expression was observed in the habenula, which is known to exhibit circadian rhythms in rodents. Since the ontogeny of per2 expression in the brain of early flounder larvae can be monitored by whole mount ISH, it is possible to investigate the effects of drugs and environmental conditions on the functional development of circadian clocks in the brain of fish larvae. In addition, flounder would be a good model for understanding the rhythmicity of marine fish. Our findings open a new frontier for investigating the role of the SCN in teleost circadian rhythms.

Differentiation of chondrocytes and scleroblasts during dorsal fin skeletogenesis in flounder larvae

In teleosts, the embryonic fin fold consists of a peridermis, an underlying epidermis and a small number of mesenchymal cells. Beginning from such a simple structure, the fin skeletons, including the proximal and distal radials and lepidotrichia (finrays), develop in the dorsal fin fold at the larval stage. Their process of skeletogenesis and embryonic origin are unclear. Using flounder larvae, we report the differentiation process for chondrocytes and scleroblasts prior to fin skeletogenesis and the effects of retinoic acid (RA) on it. In early larvae, the mesenchymal cells grow between the epidermis and spinal cord to form a line of periodical condensations, which are proximal radial primordia, to produce chondrocytes. The prescleroblasts, which ossify the proximal radial cartilages, differentiate in the mesenchymal cells remaining between the cartilages. Then, mesenchymal condensations occur between the distal ends of the proximal radials, forming distal radial primordia, to produce chondrocytes. Simultaneously, condensations occur between the distal radial primordia and peridermis, which are lepidotrichia primordia, to produce prescleroblasts. Exogenous RA specifically inhibits the mesenchymal condensation prior to the proximal radial formation together with the down‐regulation of sonic hedgehog (shh) and patched (pta) expression, resulting in the loss of proximal radials. Thus, it was indicated that differentiation of the precursor cells of radials and lepidotrichia begins in the proximal part of the fin fold and that the initial mesenchymal condensation prior to the proximal radial formation is highly susceptible to the effects of RA. Lepidotrichia formation does not occur where proximal radials are absent, indicating that lepidotrichia differentiation requires interaction with the radial cartilages. To examine the suggestion that neural crest cells contribute to the medial fin skeletons, we localized the HNK‐1 positive cells in flounder embryos and slug and msxb‐positive cells in pufferfish, Fugu rubripes, embryos. That the positive cells commonly arrive at the proximal part of the fin fold does not contradict the suggestion, but their final destiny as radial chondrocytes or lepidotrichia scleroblasts, should be further investigated.

Adult-type pigment cells, which color the ocular sides of flounders at metamorphosis, localize as precursor cells at the proximal parts of the dorsal and anal fins in early larvae

Flounders form left‐right asymmetry in body coloration during metamorphosis through differentiation of adult‐type melanophores and xanthophores on the ocular side. As the first step in investigating the formation of flounder body coloration asymmetry, in this study, we aimed to determine where the precursors of adult‐type chromatophores distribute in larvae before metamorphosis. In Paralichthys olivaceus and Verasper variegatus, GTP cyclohydrolase 2 (gch2), a common marker of melanoblasts and xanthoblasts, was found to be transiently expressed in cells located along the bilateral skeletal muscles at the basal parts of the dorsal and anal fins of premetamorphic larvae. When V. variegatus larvae were fed with a strain of Artemia collected in Brazil, this gch2 expression was abolished and the differentiation of adult‐type melanophores was completely inhibited, while the density of larval melanophores was not affected. In a cell trace test in which the cells at the basal part of the dorsal fin were labeled with DiI at the premetamorphic stage, adult‐type melanophores labeled with DiI were found in the skin on the ocular side after metamorphosis. These data suggest that, in flounder larvae, adult‐type melanophores are distributed at the basal parts of the dorsal and anal fins as unpigmented precursor cells.

Molecular cloning of endogenous β-glucosidase from common Japanese brackish water clam Corbicula japonica

Studies on the cellulose utilization by animals have been conducted in keeping with the recent developments in molecular biology. In mollusks, endogenous cellulases have been reported from blue mussel, abalone, and freshwater snail. We previously reported the possibility of cellulose assimilation by Corbicula japonica, a representative bivalve dominant in brackish water environments in Japan, and the cloning of its endogenous cellulase (beta-1,4-glucanase) gene (Sakamoto, K., Touhata, K., Yamashita, M., Kasai, A. and Toyohara, H., 2007. Cellulose digestion by common Japanese freshwater clam Corbicula japonica. Fish. Sci. 73, 675-683). However, the gene of beta-glucosidase, another enzyme essential for the complete cellulose decomposition to glucose units, has not yet been isolated from the mollusk. Therefore, we attempted the molecular cloning of endogenous beta-glucosidase from C. japonica and succeeded in the isolation of a cDNA with a 2832-bp open reading frame (ORF) encoding 943 amino acid residues (CjCel1A). CjCEL1A has 2 repeated GHF-1(Glycosyl Hydrolase family 1)-like domains and showed high similarity with known insect beta-glucosidases and mammalian lactase-phlorizin-hydrolases. Reverse transcription (RT)-PCR analysis and in situ hybridization revealed that CjCEL1A is likely to be produced in the secretory cells in the digestive gland, suggesting that CjCEL1A is a digestive beta-glucosidase of C. japonica and is not derived from symbionts.