青鳉prdm14的原核表达、多克隆抗体制备及其应用

青鳉(Oryzias latipes)是研究遗传发育和细胞多能性的重要模式鱼类, 为探究prdm14同源基因的潜在作用, 实验将青鳉prmd14经原核表达后制备了兔抗Prdm14多克隆抗体。首先, 将prdm14基因的部分编码区连接到pET32a质粒中, 构建重组表达载体pET32a-prdm14?600。随后将重组载体转化至大肠杆菌(Escherichia coli)Rosetta(DE3), 经异丙基-β-d-硫代半乳糖苷(Isopropyl-β-d-thiogalactoside, IPTG)诱导表达, 获得分子量为60 kD的Prdm14重组蛋白。接着大量诱导蛋白表达并切胶纯化, 免疫家兔(Oryctolagus cuniculus), 6周后获得阳性抗体, 最后通过ELISA和Western blot检测抗体效价及其特异性。结果显示, 在37℃、0.6 mmol/L IPTG、诱导3h的条件下, 可获得Prdm14重组蛋白的高效表达; 制备的兔抗青鳉Prdm14多克隆抗体能够特异性识别青鳉组织中表达的Prdm14蛋白以及在HepG2细胞中过表达的青鳉Prdm14: EGFP融合蛋白。综上所述, 研究首次制备了一种能有效识别青鳉Prdm14的多克隆抗体, 该抗体的获得为后续研究prdm14基因在鱼类多能性干细胞中的作用提供了有力工具。     

Variation in juvenile growth rates among and within latitudinal populations of the medaka

In ectotherms, lower temperatures at high latitudes would theoretically reduce annual growth rates of individuals. If slower growth and resulting smaller body size reduce fitness, individuals at high latitudes may evolve compensatory growth. This study compares individual growth rates among and within 12 latitudinal populations of the medaka (Oryzias latipes). Growth rates during juvenile stage were measured in a common, temperature-controlled (28°C) environment. The results revealed that juvenile growth rates differed significantly among the populations. Growth rates were, moreover, significantly correlated with latitudes of source populations, such that higher-latitude individuals grew faster. Significant variation in growth rates among full-sib families within populations was also demonstrated. The results strongly suggest that higher-latitude O. latipes have acquired a greater capacity for growth as an adaptation to shorter growing seasons (which would reduce annual growth rates), thus refuting probability processes, i.e., genetic drift, founder, or bottleneck effects, as a cause of the among-population variation.     

Molecular Cloning and Bacterial Expression of the Catalytic Domain of the SENP1 Gene of Oryzias latipes

In this study, we cloned the catalytic domain of the Oryzias latipes sentrin/SUMO-specific protease 1 (OlSENP1-CD) gene and produced the recombinant OlSENP1-CD protein in Escherichia coli. Experimental procedures designed to reveal the ability of the recombinant protein to show deSUMOylating activity in vitro should be helpful in future studies of other SENPs and the SUMO pathway.     

Medaka dead end encodes a cytoplasmic protein and identifies embryonic and adult germ cells

dead end (dnd) was identified in zebrafish as a gene encoding an RNA-binding protein essential for primordial germ cell (PGC) development and gametogenesis in vertebrates. The adult dnd RNA expression has been restricted to the ovary in Xenopus or to the testis in mouse. Its protein product is nuclear in chicken germ cells but both cytosolic and nuclear in mouse cell cultures. Here we report the cloning and expression pattern of Odnd, the medakafish (Oryzias latipes) dnd gene. Sequence comparison, gene structure, linkage analysis and expression demonstrate that Odnd encodes the medaka Dnd orthologue. A systematic comparison of Dnd proteins from five fishes and tetrapod representatives led to the identification of five previously unidentified conserved regions besides the RNA recognition motif. The Odnd RNA is maternally supplied and preferentially segregated with PGCs. Its adult expression occurs in both sexes and is restricted to germ cells. In the testis, Odnd is abundant in spermatogonia and meiotic cells but absent in sperm. In the ovary, Odnd RNA persists throughout oogenesis. Furthermore, we developed a dual color fluorescent in situ hybridization procedure allowing for precise comparisons of expression and distribution patterns between two genes in medaka embryos and adult tissues. Importantly, this procedure co-localized Odnd and Ovasa in testicular germ cells and PGCs. Surprisingly, by cell transfection and embryo RNA injection we show that ODnd is cytoplasmic in cell cultures, cleavage embryos and PGCs. Therefore, medaka dnd encodes a cytoplasmic protein and identifies embryonic and adult germ cells of both sexes.     

Gonadal sex differentiation and expression of Sox9a2, Dmrt1, and Foxl2 in Oryzias luzonensis

Oryzias luzonensis is closely related to the medaka, O. latipes. The sex of both species is determined by an XX‐XY system. However, the testis determining gene (DMY/Dmrt1bY) found in O. latipes does not exist in O. luzonensis. Instead, a different gene is thought to act as a testis determining gene. In this study, we focused the gonadal sex differentiation process in O. luzonensis under different testis determining gene. First, we observed the gonadal development of O. luzonensis histologically. We then analyzed the expression of Sox9a2/Sox9b, Dmrt1, and Foxl2 during early development. Our results suggest that the sexual differentiation of germ cells in O. luzonensis is initiated later than in O. latipes. However, the timing of the sexual differentiation of the supporting cell linage is similar between the species. genesis 47:289–299, 2009. © 2009 Wiley‐Liss, Inc.     

Molecular cloning and biochemical characterization of two novel Neu3 sialidases, neu3a and neu3b, from medaka (Oryzias latipes)

Mammalian Neu3 sialidases are involved in various biological processes, such as cell death and differentiation, through desialylation of gangliosides. The enzymatic profile of Neu3 seems to be highly conserved from birds to mammals. In fish, the functional properties of Neu3 sialidase are not clearly understood, with the partial exception of the zebrafish form. To cast further light on the molecular evolution of Neu3 sialidase, we identified the encoding genes in the medaka Oryzias latipes and investigated the properties of the enzyme. PCR amplification using medaka brain cDNA allowed identification of two novel medaka Neu3 genes, neu3a and neu3b. The YRIP, VGPG motif and Asp-Box, characteristic of consensus motifs of sialidases, were well conserved in the both medaka Neu3 sialidases. When each gene was transfected into HEK293 to allow cell lysates for the use of enzymatic characterization, two Neu3 sialidases showed strict substrate specificity toward gangliosides, similar to mammalian Neu3. The optimal pH values were at pH 4.2 and pH 4.0, respectively, and neu3b in particular showed a broad optimum. Immunofluorescence assays indicated neu3a localization at plasma membranes, while neu3b was found in cytosol. The tissue distribution of two genes was then investigated by estimation of mRNA expression and sialidase activity, both being dominantly expressed in the brain. In neu3a gene-transfected neuroblastoma cells, the enzyme was found to positively regulate retinoic acid-induced differentiation with the elongation of axon length. On the other hand, neu3b did not affect neurite formation. These results and phylogenetic analysis suggested that the medaka neu3a is an evolutionally conserved sialidase with regard to enzymatic properties, whereas neu3b is likely to have originally evolved in medaka.     

Heritability and genetic correlation of abdominal versus caudal vertebral number in the medaka (Actinopterygii: Adrianichthyidae): genetic constraints on evolution of axial patterning?

Variation in the number of abdominal vs. caudal vertebrae is an important source of morphological diversification of fish. It is not clear, however, whether abdominal and caudal regions evolve independently. Regressions of offspring on parents demonstrated substantial additive genetic variation within populations, i.e. heritability, in both abdominal and caudal vertebral numbers of the medaka ( Oryzias latipes ). However, the heritability of caudal vertebrae tended to be smaller than that of abdominal vertebrae in some estimations, suggesting that abdominal and caudal regions are controlled by separate developmental modules. Furthermore, genetic correlation between abdominal and caudal vertebral numbers, estimated using full-sib family means, was negative but weak, supporting independent evolution. In addition, substantial genetic differentiation among populations was demonstrated in abdominal vertebral numbers, but not in caudal numbers. These results support our view that Jordan's rule, a geographical tendency for fish from higher latitudes to have more vertebrae, in this fish reflects local adaptations of abdominal vertebral numbers. In contrast, the low heritability of caudal vertebrae may reflect the intrinsic invariability of genes associated with a change in caudal vertebral numbers. This genetic constraint may have restricted morphological diversification of not only the medaka, but also the Order Beloniformes as a whole.  © 2009 The Linnean Society of London, Biological Journal of the Linnean Society , 2009, 96 , 867–874.     

Functional lysophosphatidic acid receptors expressed in Oryzias latipes

Lysophosphatidic acid (LPA) signaling is known to play biological and pathophysiological roles in many types of animals. Medaka (Oryzias latipes) is an experimental fish that can be easily maintained, propagated, and analyzed, and whose genome has been completely sequenced. However, there is limited information available regarding medaka LPA receptors. Here, using information from the medaka genome database, we examine the genomic structures, expression, and functions of six LPA receptor genes, Lpar1–Lpar6. Our analyses reveal that the genomic structures of Lpar1 and Lpar4 are different from those deduced from the database. Functional analyses using a heterologous expression system demonstrate that all medaka LPA receptors except for LPA_5b respond to LPA treatment with cytoskeletal changes. These findings provide useful information on the structure and function of medaka LPA receptor genes, and identify medaka as a useful experimental model for exploration of the biological significance of LPA signaling.     

The goldfish hAT-family transposon Tgf2 is capable of autonomous excision in zebrafish embryos

The goldfish (Carassius auratus) Tgf2 transposon is a vertebrate DNA transposon that belongs to the hAT transposon family. In this study, we constructed plasmids containing either the full-length Tgf2 transposon (pTgf2 plasmid) or a partially-deleted Tgf2 transposon (ΔpTgf2 plasmid), and microinjected these plasmids into fertilized zebrafish (Danio rerio) eggs at the one- to two-cell stage. DNA extracted from the embryos was analyzed by PCR to assess transient excision, if any, of the exogenous plasmid and to verify whether Tgf2 is an autonomous transposon. The results showed that excision-specific bands were not detected in embryos injected with the ΔpTgf2 plasmid, while bands of 300–500 bp were detected in embryos injected with pTgf2, which indicated that the full-length Tgf2-containing plasmid could undergo autonomous excision in zebrafish embryos. DNA cloned from 24 embryos injected with pTgf2 was sequenced, and the results suggested that Tgf2 underwent self-excision in zebrafish embryos. Cloning and PCR analysis of DNA extracted from embryos co-injected with ΔpTgf2 and in vitro-transcribed transposase mRNA indicated that partially-deleted-Tgf2-containing ΔpTgf2 plasmid also underwent excision, in the presence of functional transposase mRNA. DNA cloned from 25 embryos co-injected with ΔpTgf2 and transposase mRNA was sequenced, and the results suggested that partially-deleted Tgf2 transposons plasmids were excised. These results demonstrated that excisions of Tgf2 transposons were mediated by the Tgf2 transposase, which in turn confirmed that Tgf2 is an autonomous transposon.