Pierre-Yves Le Bail

Growth hormone axis as marker of nutritional status and growth performance in fish

The endocrine control of growth and metabolism is interrelated and many of the endocrine factors involved in the regulation of lipid and protein metabolism are also involved in nutrient utilization, immune system function and somatic growth. All these processes are impaired in catabolic states induced by fasting, protein deprivation and chronic liver diseases as a response to the consequential changes in the endocrine system. In this regard, it must be noted that concentrations of circulating metabolites may be quite different depending on the catabolic state. However, in all the metabolic disorders that shared an increased catabolism/anabolism balance, plasma insulin levels are depressed, whereas those of GH are elevated. This hypersomatotropism, linked to growth retardation, is accompanied by a reduction of plasma IGF-I concentration, which reflects some refractoriness of liver to the anabolic action of GH. Changes in GH availability and liver GH-responsiveness can also be established as a function of age, fish species, and environmental factors (photoperiod and temperature). In the present work, the regulation and mode of GH action is discussed in order to provide a useful tool to assess the nutritional status and growth performance of cultured fish.

Effects of environmental temperature on IGF1, IGF2, and IGF type I receptor expression in rainbow trout (Oncorhynchus mykiss).

Recently, we have demonstrated in rainbow trout that environmental temperature may, independently of nutritional status, directly stimulate plasma growth hormone (GH) that is recognised as being an insulin-like growth factor (IGF) system regulator. The aim of this study was to determine whether temperature may directly regulate the IGF system or indirectly regulate it through plasma GH or nutritional status. For this purpose, rainbow trout were reared at 8, 12, or 16 degrees C and fed either ad libitum (similar nutritional status) to evidence the global effect of temperature, or with the same ration (1.2% body weight/day), to determine the temperature effect in fish with the same growth rate. Endocrine and autocrine/paracrine regulations of the IGF system were determined by measuring plasma IGF1 and IGF2, liver and muscle IGF1 and IGF2 mRNA as well as IGFRIa, IGFRIb mRNA, and the quantity of IGF type I receptor in muscle. Our results show that neither rearing temperature nor the nutritional status of fish affected the expression of both IGF receptor genes in muscle. Nevertheless, the quantity of IGF type I receptor determined by a binding study, appeared to be inversely proportional (P<0.05) to the rearing temperature without any relationship with nutritional status, suggesting a direct effect of temperature on its turnover. After 2 weeks of treatment, the levels of IGF1 mRNA in muscle at 8 degrees C were 2-fold higher (P<0.05) than at 16 degrees C in both ad libitum and restricted feed fish, whereas after 6 weeks, this difference was no longer observed. In both experiments, the levels of plasma IGF2 were 10-fold higher than the levels of plasma IGF1 (mean 105+/-3.0 versus 13.5+/-0.6 ng/ml), and plasma levels were correlated with their respective mRNA liver concentrations (r2=0.14 and 0.25, respectively; P<0.01). In the ad libitum feeding experiment, plasma and mRNA levels of IGF1 were related to the rearing temperature (P<0.05), while for IGF2 no effect was seen. In contrast, in the restricted feeding experiment, plasma and IGF2 mRNA levels were inversely proportional to the rearing temperature (P<0.0001) while plasma IGF1 was unaltered. Levels of plasma IGF1 were related to the growth rate in both experiments, while levels of plasma IGF2 appeared to be associated with the nutritional status of the fish. Our results suggest that the autocrine/paracrine expression of IGF1 and IGF2 in muscle is not a key regulator of the growth promoting effect of temperature. Conversely, temperature seems to promote growth through IGF1 secretion by the liver following GH stimulation, and impairment of nutritional status would prevent the IGF1 stimulation by temperature. In addition, the growth-promoting effect of temperature did not affect plasma IGF2, which appeared to be more related to the metabolic status of the fish.

PRESENCE OF SPECIFIC GROWTH HORMONE BINDING SITES IN RAINBOW TROUT (ONCORHYNCHUS MYKISS) TISSUES : CHARACTERIZATION OF THE HEPATIC RECEPTOR

The present work outlines the presence of specific binding for chinook salmon growth hormone (sGH) in different tissue preparations of rainbow trout. Optimal incubation conditions (pH, Tris, MgCl2) were determined. Specific binding was very sensitive to salt concentration during incubation. The specific binding reached a plateau after 15 and 25 hr of incubation at 12 and 4 degrees. At 20 degrees, specific and nonspecific binding were not stable. Specific binding dissociation was slower than association and was only partial. The binding was saturable (Bmax = 187 +/- 167 pmol), of high affinity (Ka = 2.4 +/- 0.8 10(9) M-1), and very specific for GH, properties which are in agreement with the characteristics of hormonal receptors. Sea bream and mammalian GH appeared 2- and 30-fold, respectively, less potent than cold sGH2 for displacing 125I-sGH2. Tissue preparations from ovary, testis, fat, skin, cartilage, gill, blood pellet, brain, spleen, kidney, and muscle showed significant saturable binding.

Insulin-like growth factor (IGF-I) mRNA and IGF-I receptor in trout testis and in isolated spermatogenic and Sertoli cells.

Few data exist concerning the occurrence and potential role of an insulin‐like growth factor (IGF) system in fish gonads. Using Northern and slot blot hybridization with a specific salmon IGF‐I cDNA, we confirmed that IGF‐I transcription occurs in trout testis. Testicular IGF‐I mRNA abundance may be increased by long‐term GH treatment in juvenile fish, while shorter treatment with growth hormone (GH) or a gonadotropin (GTH‐II) in maturing males had no statistically significant effect. Radiolabelled recombinant human IGF‐I binds with high affinity to crude trout testis preparation, to cultured isolated testicular cells, and to a membrane fraction of these cells (Ka = 0.2 to 0.7 × 1010 M1; Bmax = 10 to 20 fmol/107 cells, and 68 fmol/mg protein of membrane). The binding site was identified as type 1 IGF receptor by its binding specificity (IGF‐I > IGF‐II ⋙ insulin) and the molecular size of its α‐subunit labelled with 125HGF‐I (Mr125 ‐ 140 kDa). 125HGF‐II also bound to the type 1 receptor whereas IGF‐II/mannose 6 phosphate receptors could not be detected.

Comparative analysis of reproductive traits in 65 freshwater fish species: application to the domestication of new fish species

Based on an extensive literature search (1,000 references), the objectives of the present study were to establish a numerical clustering of temperate freshwater fish based on their reproductive traits and to evaluate whether it was possible to extrapolate zootechnical knowledge among species belonging to the same cluster. About 65 species were classified into ten homogeneous clusters from the analysis of 29 reproductive traits, among which the most important were temperature during spawning, egg incubation and larval rearing, degree-days for incubation, larval size upon hatching, spawning season, and parental care. From this typology, a rather regular continuum of reproductive clusters emerges with two obvious endpoints. Between these two extremes, species could be ordered chiefly according to temperature requirement, spawning season and parental care. In conclusion, this new typology, differing significantly from all others proposed earlier, may now serve as a possible framework to help enhancing the domestication of new species by comparison to species belonging to the same cluster.

Environmental temperature increases plasma GH levels independently of nutritional status in rainbow trout (Oncorhynchus mykiss)

Like many poecilotherms, salmonids exhibit seasonal variations of growth rate in relation with seasonal temperatures and plasma GH level. However, temperature alters other parameters like food intake, which may directly modify the level of plasma GH. In order to determine whether temperature regulates plasma GH levels independently of nutritional status, fish were reared at 8, 12, or 16 degrees C and either fed ad libitum (fish with different food intake) to determine the global effect of temperature, or with the same ration (1.2%/body weight) to observe the temperature effect in fish with the same growth rate. Plasma insulin level was inversely proportional to the temperature (8, 12, and 16 degrees C) in fish fed ad libitum (12.1+/-0.3 ng/ml, 10.9+/-0.3 ng/ml, 9.5+/-0.4 ng/ml; P<0.001) and in restricted fish (14.0+/-0.3 ng/ml, 11.3+/-0.3 ng/ml, 10.0+/-0.2 ng/ml; P<0.0001), probably due to a prolonged nutrient absorption, and delayed recovery of basal insulin level at low temperature. Conversely, temperature did not affect plasma T3 level of fish fed ad libitum (2.5+/-0.2 ng/ml, 2.4+/-0.1 ng/ml, 2.5+/-0.1 ng/ml at 8, 12, and 16 degrees C) while fish fed with the same ration present less T3 at 16 degrees C than at 8 degrees C (1.83+/-0.1 ng/ml versus 1.2+/-0.1 ng/ml; P<0.001) throughout the experiment; these observations indicate that different plasma T3 levels reflect the different nutritional status of the fish. The levels of GH1 and GH2 mRNA, and GH1/GH2 ratio were not different for whatever the temperature or the nutritional status. Pituitary GH content, of fish fed ad libitum did not exhibit obvious differences at 8, 12, or 16 degrees C (254+/-9 ng/g bw, 237+/-18 ng/g bw, 236+/-18 ng/g bw), while fish fed with the same ration have higher pituitary GH contents at 16 degrees C than at 8 degrees C (401+/-30 ng/g bw versus 285+/-25 ng/g bw; P<0.0001). Interestingly, high temperature strongly increases plasma GH levels (2.5+/-0.3 ng/ml at 8 degrees C versus 4.8+/-0.6 ng/ml at 16 degrees C; P<0.0001) to the same extent in both experiments, since at a given temperature average plasma GH was similar between fish fed ad libitum or a restricted diet. Our results, demonstrate that temperature regulates plasma GH levels specifically but not pituitary GH content, nor the levels of GH1 and GH2 mRNA. In addition no differential regulation of both GH genes was evidenced whatever the temperature.

Enzyme-linked immunosorbent assay (Elisa) for rainbow trout (Oncorhynchus mykiss) vitellogenin

1. A specific and simple enzyme-linked immunoassay for rainbow trout (Onchorynchus mykiss) vitellogenin (Vtg) is described. This assay is performed using a rabbit antiserum for Vtg purified from trout plasma. 2. This assay is based upon the competition between soluble Vtg and Vtg adsorbed on microtiter plates, for the rabbit anti-Vtg antibody binding sites. 3. The adsorbed Vtg-antibody complexes are revealed through the peroxidase-antiperoxidase antibody, which is colored by o-phenylendiamin. This assay can be performed in a day and a night. 4. Under our conditions, 90-20% of binding gave a sensibility range of 33-1473 ng/ml. With almost a 50% binding yield (335 ng/ml) the intra-assay coefficient of variation (CV) was 5.2% (n = 26) and the inter-assay CV was 12.5% (n = 5). 5. There was low immunological cross-reactivity with sera from other salmonids and with ovary extracts. Extracts of liver from oestrogenized male rainbow trout yielded displacements parallel to the vitellogenin standard and to mature female serum or oestrogenized male serum. 6. This enzyme immunoassay is simple and easy to use. Its great specificity allows its use only for the rainbow trout species.

Optimization of somatic cell injection in the perspective of nuclear transfer in goldfish.

BackgroundNuclear transfer has the potential to become one strategy for fish genetic resources management, by allowing fish reconstruction from cryopreserved somatic cells. Survival rates after nuclear transfer are still low however. The part played by unsuitable handling conditions is often questioned, but the different steps in the procedure are difficult to address separately. In this work led on goldfish (Carassius auratus), the step of somatic cells injection was explored. Non-enucleated metaphase II oocytes were used as a template to explore the toxicity of the injection medium, to estimate the best location where the cell should be injected, and to assess the delay necessary between cell injection and oocyte activation.ResultsTrout coelomic fluid was the most suitable medium to maintain freshly spawned oocytes at the metaphase II stage during oocyte manipulation. Oocytes were then injected with several media to test their toxicity on embryo development after fertilization. Trout coelomic fluid was the least toxic medium after injection, and the smallest injected volume (10 pL) allowed the same hatching rates as the non injected controls (84.8% ± 23). In somatic cell transfer experiments using non enucleated metaphase II oocytes as recipient, cell plasma membrane was ruptured within one minute after injection. Cell injection at the top of the animal pole in the oocyte allowed higher development rates than cell injection deeper within the oocyte (respectively 59% and 23% at mid-blastula stage). Embryo development rates were also higher when oocyte activation was delayed for 30 min after cell injection than when activation was induced without delay (respectively 72% and 48% at mid-blastula stage).ConclusionsThe best ability of goldfish oocytes to sustain embryo development was obtained when the carrier medium was trout coelomic fluid, when the cell was injected close to the animal pole, and when oocyte activation was induced 30 min after somatic cell injection. Although the experiments were not designed to produce characterized clones, application of these parameters to somatic cell nuclear transfer experiments in enucleated metaphase II oocytes is expected to improve the quality of the reconstructed embryos.

Purification of chinook salmon (Oncorhynchus tshawytscha) GH for receptor study

A method for the purification of chinook Salmon (Oncorhynchus tshawytscha) GH, which retains its biological activity, is described. The biological activity was investigated with an established radioreceptor assay using liver membranes from pregnant rabbits and bovine GH as standard and labelled hormone. The enrichment of the preparation was checked with electrophoresis (SDS-PAGE). Extraction and further steps were carried out using low molarity alkaline buffer (pH 8–10, M = 100 mM). Three chromatography steps were performed (Concanavalin-A sepharose, Bio-gel P60, DEAE). Ion exchange chromatography was performed under isocratic conditions (using a 50 cm column). Two isoforms (sGH1 and sGH2) were isolated. The purification yield is 0.7% compared to lyophilized pituitaries. The molecule is homogeneous in SDS-PAGE. Contamination by prolactin, gonadotrophin and corticotrophin is negligible (< 0.5%). It could be demonstrated that the biological activity of the preparation is maintained since this preparation stimulates the growth of juvenile trout (Salmo gairdneri) and binds specifically (35%) to trout liver membranes.

ATOL: The Multi-species Livestock Trait Ontology

This paper presents the multi-species Animal Trait Ontology for Livestock (ATOL) and the methodology used for its design. ATOL has been designed as a reference source for indexing phenotype databases and scientific papers. It covers five major topics related to animal productions: growth and meat quality, animal nutrition, milk production, reproduction and welfare. It is composed of species-independent concepts subsuming species-specific ones so that cross-species and species-specific reasoning can be performed consistently. In order to ensure a large consensus, three complementary approaches have successively been applied to its design: reuse of existing ontologies, integration of production-specific livestock traits by a large team of domain experts and curators and terminology analysis of scientific papers. It resulted in a detailed taxonomy of 1,654 traits that is available at http://www.atol-ontology.com