Organization of the lipoprotein lipase gene of red sea bream Pagrus major

Lipoprotein lipase (LPL) is a key enzyme of lipid deposition and metabolism. To investigate the mechanism of lipid deposition in fish, as a first step, we have characterized the LPL gene of a marine teleost red sea bream Pagrus major by cDNA and genomic structure analysis. The red sea bream LPL gene encodes 511 amino acids and spans approximately 6.3 kb of the genome. The coding region is organized into ten exons and nine introns. In comparison with the LPL of other animals, the deduced amino acid sequence shows a high degree of similarity with a conservation of functional domains, e.g. catalytic triad, N-glycosylation sites, lipid and heparin binding regions. The 1.1 kb of 5′ flanking region contains two CCAAT, sequences homologous to Oct-I site and response elements for hormones including glucocorticoid, insulin and thyroid hormone. The results of the present study will facilitate further study of the function and regulation of the LPL in non-mammalian vertebrates.     

Chemoreception and vertical movement in planktonic yolk-sac larvae of red sea bream Pagrus major

The capability of planktonic yolk-sac larvae of red sea bream Pagrus major in detecting food was examined in the laboratory to ascertain basic knowledge on the early life history of this marine fish. After infrequent vertical burst swimming followed by slight rising or sinking, the larvae remained motionless within thin layers of concentrated food extract (rotifer, Brachionus plicatilis). At the moment of hatching, the larvae already have receptor cells with several cilia arranged radially in their open nostrils. Thus it is likely that by means of their vertical movement they are capable of sensing the thin food patch layer. We suggest that planktonic larvae of Pagrus major are capable of detecting and remaining within food patches even before the onset of feeding. The onset of food detection in the earlier stages may be, to some extent, the more efficient strategy for larval survival and growth because this ability could contribute to a reduction in energy consumption.     

Viability, growth and external morphology of meiotic- and mitotic-gynogenetic diploids in red sea bream, Pagrus major

Two types of gynogenetic diploids were artificially induced in the red sea bream ( Pagrus major Temminck et Schlegel), either by suppressing the first cell cleavage (mitotic-G2N) or by retaining the second polar body (meiotic-G2N). The eggs of red sea bream were inseminated with UV-irradiated (3000 erg mm⁻²) sperm of Japanese parrot fish ( Oplegnathus fasciatus Temminck et Schlegel), and hydrostatic pressure shock of 700 kg cm⁻² for 5.5 min at 46 min after insemination (mitotic-G2N) and cold shock of 1 °C for 30 min at 3 min after insemination (meiotic-G2N) were applied to the eggs, sequentially. The total hatching rate and hatching rate of normal larvae of the normal diploid, meiotic-G2N and mitotic-G2N were 86.5 and 94.9%, 38.1 and 45.8%, and 12.8 and 35.0%, respectively. The induction of mitotic-G2N was confirmed by isozyme marker analysis. The standard deviations, variances and coefficients of variation of the body weight, standard length and body depth in 91-day-old juveniles were always large in mitotic-G2N, small in normal-2N and intermediate in meiotic-G2N. The variances in the number of pectoral fin rays and caudal fin rays of mitotic-G2N were significantly higher than those of normal-2N. The incidences of deformities were highest in the mitotic-G2N group. The survival rates and growth performance of the meiotic- and mitotic-G2N were significantly lower than those of normal-2N. Both G2N survived for 3 years to the adult stage.     

Identification of the causative gene of a transparent phenotype of juvenile red sea bream Pagrus major

Deformities in cultured fish species may be genetic, and identifying causative genes is essential to expand production and maintain farmed animal welfare. We previously reported a genetic deformity in juvenile red sea bream, designated a transparent phenotype. To identify its causative gene, we conducted genome-wide linkage analysis and identified two single nucleotide polymorphisms (SNP) located on LG23 directly linked to the transparent phenotype. The scaffold on which the two SNPs were located contained two candidate genes, duox and duoxa, which are related to thyroid hormone synthesis. Four missense mutations were found in duox and one in duoxa, with that in duoxa showing perfect association with the transparent phenotype. The mutation of duoxa was suggested to affect the transmembrane structure and thyroid-related traits, including an enlarged thyroid gland and immature erythrocytes, and lower thyroxine (T₄) concentrations were observed in the transparent phenotype. The transparent phenotype was rescued by T₄ immersion. Loss-of-function of duoxa by CRISPR–Cas9 induced the transparent phenotype in zebrafish. Evidence suggests that the transparent phenotype of juvenile red sea bream is caused by the missense mutation of duoxa and that this mutation disrupts thyroid hormone synthesis. The newly identified missense mutation will contribute to effective selective breeding of red sea bream to purge the causative gene of the undesirable phenotype and improve seed production of red sea bream as well as provide basic information of the mechanisms of thyroid hormones and its related diseases in fish and humans.Subject terms: Agricultural genetics, Animal breeding     

Abundant and constant expression of uncoupling protein 2 in the liver of red sea bream Pagrus major

Four overlapping cDNA fragments encoding a partial sequence for uncoupling protein 2 (UCP2) were amplified by PCR using degenerate primers from the liver of a marine teleost fish, red sea bream (Pagrus major). The partial sequence was 674 bp long, encoding 224 amino acids. The deduced amino acid sequence from the cDNA partial sequence contained the signature motifs for mitochondrial transporter protein and revealed positional identity higher than 72.8% with UCP2 from mammals. The fish UCP2 gene was highly expressed in the liver but almost undetectable in the visceral mesenteric adipose tissue. Using beta-actin as control, the UCP2 mRNA level was determined to be at least 20-fold higher in the liver than in the visceral mesenteric adipose tissues. Neither 48 h starvation nor high lipid diet had any significant effect on liver UCP2 gene expression, indicating that the abundant UCP2 gene expression was stable and might have some basic function in a fish liver that always contains high lipid content. The striking contrast of UCP2 gene expression in the two fish fat-depot organs is consistent with their large differences in oxidative capacity. We suggest that the fish liver may adapt to a constantly high fat deposit by maintaining high UCP2 expression to constrain reactive oxygen species (ROS) production and protect hepatocytes from apoptosis.     

Size-dependent mortality of red sea bream, Pagrus major, juveniles released with fluorescent otolith-tags in News Bay, Japan

Totals of 2^.67 x 10⁵ and 7^.56 x 10⁵ juvenile red sea bream of three size groups (10, 20 and 40 mm t.l.) marked with a fluorescent substance in the otolith were released in News Bay, Oita Prefecture, Japan, in July 1987 and June 1988, respectively; the aim was to estimate growth and mortality of different developmental stages.
Of fish released in 1987 and 1988, 10 618 and 4413, respectively were recaptured during those two years. Released fish remained in the bay until the end of summer, and afterwards migrated out towards open waters. Fish of the 40-mm group released in 1987 grew to over 200 mm t.l. in one year. Mean growth rate for 19 days after release was higher in the 40-mm group (0^.87 mm day⁻¹) than in the 20-mm group (0^.74mm day⁻¹). Survival rates over 19 days were 59^.0 and 10^.1 % for 40-mm and 20-mm fish, respectively, in 1987, and those over 30 days were 69^.2, 3^.3 and 0^.0% for 40-mm, 20-mm and 10-mm fish, respectively, in 1988.
Cannibalism was indicated by the presence of marked otoliths for 20-mm fish in the stomachs of a few 40-mm individuals recaptured 2 days after release. Size-dependent growth and size-selective mortality were both noted in juvenile red sea bream, i.e. the relative size differential between larger and smaller individuals was maintained in the period between marking and recapture, and mortality was inversely proportional to size.     

Molecular cloning and characterization of alpha-class glutathione S-transferase genes from the hepatopancreas of red sea bream, Pagrus major

Two distinct cDNAs corresponding to GSTA1 and GSTA2 genes encoding glutathione S-transferases (GSTs) from the hepatopancreas of red sea bream, Pagrus major were cloned and sequenced. A comparison of the nucleotide sequences of GSTA1 and GSTA2 revealed 98% identity and their derived amino acid sequences had 96% similarity. Both genes could be classified as alpha-class GSTs on the basis of their amino acid sequence identity with other species. Genomic DNA cloning showed that both GSTA1 and GSTA2 genes consisted of six exons and five introns. In a comparison of genomic DNAs, the structures of GSTA1 and GSTA2 differed. In addition, Southern-blot analysis indicated that at least two kinds of alpha-class GSTs existed in the P. major genome. In order to biochemically characterize the recombinant enzymes (pmGSTA1-1 and pmGSTA2-2), both clones were highly expressed in Escherichia coli. The purified pmGSTA1-1 and pmGSTA2-2 exhibited glutathione conjugating activity toward 1-chloro-2,4-dinitrobenzene and glutathione peroxidase activity toward cumene hydroperoxide, while neither pmGSTs show detectable activity toward 1,2-dichloro-4-nitrobenzene, ethacrynic acid, 4-hydroxynonenal, or p-nitrobenzyl chloride. Despite their high level of amino acid sequence identity, the pmGSTs had quite different enzyme-kinetic parameters.     

真鲷仔鱼用微粒子饲料中肽酶与大豆卵磷脂添加效果的研究

本研究以酪蛋白分解物为蛋白源配制三种微粒子饲料MD-S、MD-T和MD-U对真鲷开口仔鱼进行饲养试验。以MD-S的配方为基准,MD-T采用粉状大豆卵磷脂和麸质代替液状大豆卵磷脂;MD-U则另外添加0.1%的肽酶。结果表明,微粒子饲料在水中浸泡15min后,MD-T的溶出率(35.5%)低于MD-S(46.8%)和MD-U(45.8%);实验结束时(20日龄),仔鱼的成活率以生物饵料(轮虫)组为最高(86.3%),其次是MD-T组为20.7%,显著高于(P<0.05)MD-S组(13.3%)和MD-U组(13.6%);生物饵料组的仔鱼全长(6.14±0.49mm)显著大于微粒子饲料组(4.23±0.30mm~4.46±0.30mm),各微粒子饲料组之间仔鱼的全长并不存在显著差异(P>0.05)。在孵化后第12d,微粒子饲料组的仔鱼肠上皮细胞发育良好,但至孵化后第18d,仔鱼肠上皮细胞大部分萎缩、并发生脱落。鱼体的蛋白质、DNA与RNA日间增长率微粒子饲料MD-T组高于MD-S和MD-U组,但都低于生物饵料组。由此可见,微粒子饲料中添加肽酶并无助真鲷仔鱼对其消化吸收;可是,使用粉状大豆卵磷脂与麸质代替液状卵磷脂能增强微粒子饲料的黏合性,可减少其营养成分的溶出率,从而提高微粒子饲料的饲育效果。     

Exposure of eggs to solar UV‐B leads to reduced hatching rates in two sparid fishes,red sea bream Pagrus major and black sea bream Acanthopagrus schlegeli

Hatching success was examined under exposure to solar ultraviolet radiation (UVR) using filters to give three different light conditions [C1: UV‐B, UV‐A and photosynthetically active radiation (PAR), C2: UV‐A and PAR, C3: PAR] in red Pagrus major and black Acanthopagrus schlegeli sea bream. Hatching rate of both species was reduced by an exposure over a 2 day period to UVR and was not significantly different between two species under the three light conditions.     

Localization of group IB phospholipase A(2) isoform in the gills of the red sea bream,Pagrus (Chrysophrys) major

We previously reported that PLA(2) activity in the gills is higher than that in other tissues in red sea bream and purified PLA(2) from the gills belongs to the group IB PLA(2) as well as other red sea bream PLA(2)s. In this study, we reconfirmed that the level of PLA(2) activity is extremely high in the gills compared with other tissues, and gill PLA(2) was detected only in the gills by immunoblotting and inhibition test using anti-gill PLA(2) monoclonal antibody. The level of PLA(2) activity and protein expression in the gills are well correlated. Fish can be roughly divided into high and low groups based on the level of PLA(2) activity. Gill PLA(2) was detected in the gills of the high group, but not the low group by immunoblotting. In the gills of the high group, gill PLA(2) was detected in the mucous cells and pavement cells located on the surface of gill epithelia by immunohistochemistry. On the other hand, positive signals were observed only in the mucous cells by in situ hybridization. We also isolated inactive proPLA(2), having AR propeptide, preceding the mature enzyme from the gill extract. These results suggest that gill PLA(2) is synthesized as an inactive proPLA(2) in the mucous cells and is secreted to the surface of gill epithelia.     

真鲷肝脏解偶联蛋白2(UCP2)基因及其功能的探讨

从真鲷(Pagrus major)肝脏通过简并引物PCR克隆解偶联蛋白2(UCP2)cDNA部分序列。该片段长674bp,编码224个氨基酸残基。推测的此部分氨基酸序列包含线粒体载体蛋白的特征结构,并与其它脊椎动物UCP2氨基酸序列同源性在72．8％以上。对变温动物色类UCP2组织表达调控研究表明：与哺乳类UCP2基因不同,真鲷UCP2基因在肝脏大量表达,而在腹腔肠系膜脂肪组织则仅有痕迹量表达,两者表达水平相差20倍以上。饲料中添加10％绿鳕油或48h饥饿对真鲷肝脏UCP2基因的表达水平均无显著影响,表明UCP2基因在脂肪含量高的鱼类肝脏表达十分稳定,为维持其基本功能所必需。真鲷肝脏和腹腔肠系膜脂肪组织UCP2基因表达水平的强烈反差,与鱼类这两种贮脂器官完全不同的氧化活性相一致[动物学报49(1)：110—117,2003]。     

Effects of insulin, triiodothyronine and fat soluble vitamins on adipocyte differentiation and LPL gene expression in the stromal-vascular cells of red sea bream, Pagrus major

Various kinds of hormones including insulin, triiodothyronine (T(3)) and fat-soluble vitamins have been proposed as mediators of adipocyte differentiation in mammals. To investigate the factors which are responsible for fish adipocyte differentiation, we developed a serum-free culture system of stromal-vascular cells of red sea bream adipose tissue and examined the effects of bovine insulin, T(3), and fat-soluble vitamins (all-trans retinoic acid, retinyl acetate and 1,25-dihydroxyvitamin D(3)) on the differentiation-linked expression of the lipoprotein lipase (LPL) gene. As assessed by the increase in LPL gene expression after 3 day cultivation, like in mammalian adipocytes, insulin enhanced the adipocyte differentiation in a concentration-dependent manner. During 2 week cultivation, bovine insulin promoted lipid accumulation in differentiating adipocytes concentration-dependently until the terminal differentiation. These results indicate that the differentiation of fish adipocytes is inducible by insulin alone. T(3) alone had no effect but enhanced the differentiation-linked LPL gene expression in the presence of insulin. Fat-soluble vitamins, unlike in mammalian adipocytes, did not show any significant effects. The method developed in this study should be of interest for the characterization of factors involved in fish adipocyte differentiation.     

Molecular characterization of peroxisome proliferator-activated receptors (PPARs) and their gene expression in the differentiating adipocytes of red sea bream Pagrus major

To investigate the molecular mechanism of fish adipocyte differentiation, the three subtypes of PPAR genes (alpha, beta and gamma) were characterized in a marine teleost red sea bream (Pagrus major). The primary structures of red sea bream PPARs exhibited high degrees of similarities to their mammalian counterparts, and their gene expression was detected in various tissues including adipose tissue, heart and hepatopancreas. During the differentiation of primary cultured red sea bream adipocytes, three PPARs showed distinct expression patterns: The alpha subtype showed a transient increase and the beta gene expression tended to increase during adipocyte differentiation whereas the gene expression level of PPARgamma did not change. These results suggest that they play distinct roles in adipocyte differentiation in red sea bream. In the differentiating red sea bream adipocytes, mammalian PPAR agonists, 15-deoxy-Delta(12,14)-prostaglandin J(2), ciglitazone and fenofibrate did not show clear effects on the adipogenic gene expression. However, 2-bromopalmitate increased the PPARgamma and related adipogenic gene expression levels, suggesting the gamma subtype plays a central role in red sea bream adipocyte differentiation and in addition, fatty acid metabolites can be used as modulators of adipocyte function. Thus our study highlighted the roles of PPARs in fish adipocyte differentiation and provided information on the molecular mechanisms of fish adipocyte development.     

Patterns of haemolymph vitellogenin and ovarian vitellin in the German cockroach, and the role of Juvenile Hormone

Abstract. The concentrations of fat body and haemolymph vitellogenin and ovarian vitellin during the first gonadotropic cycle of the cockroach Blattella germanica (L.) (Dictyoptera, Blattellidae) have been studied. For these purposes, a polyclonal antibody against B. germanica vitellogenin and vitellin has been obtained, and an ELISA to quantify these proteins has been developed. Ovarian vitellin levels follow a pattern which parallels those of basal oocyte growth and Juvenile Hormone production by the corpora allata. This suggests that Juvenile Hormone regulates vitellogenin uptake into oocytes. Fat body and haemolymph vitellogenin levels give cyclic and parallel patterns. However, the cycle of Juvenile Hormone appears delayed with respect to that of vitellogenin. We suggest that the production of Juvenile Hormone, although cyclic in profile, does not modulate alone the cycle of vitellogenin. At least a supplementary mechanism, apparently independent of Juvenile Hormone, may be involved in the decline of vitellogenin production at the end of the vitellogenic cycle.