Browsing by Author "Fladmark, K. E."
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- Dietary lysine imbalance affects muscle proteome in zebrafish (Danio rerio): a comparative 2D-DIGE studyPublication . Vareilles, Mahaut; Conceição, L. E. C.; Gómez-Requeni, Pedro; Kousoulaki, Katerina; Richard, Nadège; Rodrigues, Pedro; Fladmark, K. E.; Rønnestad, I.Lysine (Lys) is an indispensable amino acid (AA) and generally the first limiting AA in vegetable protein sources in fish feeds. Inadequate dietary Lys availability may limit protein synthesis, accretion and growth of fish. This experiment aimed to further elucidate the role of Lys imbalance on growth by examining the myotomal muscle proteome of juvenile zebrafish (Danio rerio). Quadruplicate groups of 8 fish were fed either a low-Lys [Lys(−), 1.34 gkg−1], medium/control (Lys, 2.47 gkg−1) or high-Lys [Lys(+), 4.63 gkg−1] diet. Fish growth was monitored from 33 to 49 days postfertilization (dpf) and trunk myotomal muscle proteome of Lys(−) and Lys(+) treatments were screened by 2D-DIGE and MALDI ToF tandem mass spectrometry. Growth rate was negatively affected by diet Lys(−). Out of 527±11 (mean±S.E.M.) protein spots detected (∼10–150 kDa and 4–7 pI value), 30 were over-expressed and 22 under-expressed in Lys(−) fish (|fold-change|>1.2, p value <0.05). Higher myosin light chains abundance and other myofibrillar proteins in Lys (−) fish pointed to increased sarcomeric degradation, indicating a higher protein turnover for supplying basal energysaving metabolism rather than growth and muscle protein accretion. The Lys deficiency also possibly induced a higher feeding activity, reflected in the over-expression of beta enolase and mitochondrial ATP synthase. Contrarily, in the faster growing fish [Lys(+)], over-expression of apolipoprotein A-I, F-actin capping protein and Pdlim7 point to increased energy storage as fat and enhanced muscle growth, particularly by mosaic hyperplasia. Thus using an exploratory approach, this study pinpoints interesting candidates for further elucidating the role of dietary Lys on growth of juvenile fish.
- Impact of dietary protein hydrolysates on skeleton quality and proteome in Diplodus sargus larvaePublication . Vareilles, Mahaut; Richard, Nadège; Gavaia, Paulo J.; Silva, Tomé S.; Cordeiro, O.; Guerreiro, Inês; Yúfera, M.; Batista, I.; Pires, C.; Pousão-Ferreira, P.; Rodrigues, Pedro; Rønnestad, I.; Fladmark, K. E.; Conceição, L. E. C.In order to investigate the effects of dietary protein hydrolysates (PH) on larval growth performance, skeleton quality and proteome expression, triplicate groups of white seabream (Diplodus sargus) larvae were co-fed from first-feeding with live feed and three microencapsulated diets differing in the molecular weight of their PH fraction (Control – inclusion of CPSP-90; H – inclusion of a high amount in 0.5–30 kDa hydrolysates; L – inclusion of a high amount in <0.5 kDa hydrolysates). At 15 days after hatching (DAH), proteome expression changes were assessed in entire larvae by twodimensional gel electrophoresis and the quality of larval skeleton was analysed at 28 DAH through double staining of cartilage and bone. Dietary PH fractions tested affected growth, the larvae fed diet L being significantly larger than those fed diet H, but it did not affect the incidence of deformed larvae, nor the number of deformities per fish. Two-dimensional analysis of larvae proteome allowed the detection and the comparative quantification of a total of 709 protein spots having a pI between 4 and 7, around half of which had an expression significantly affected by dietary treatment, the main difference being between proteome of Control larvae with those of both groups L and H. From these spots, 52 proteins involved in diverse processes such as cytoskeletal dynamics, energetic, lipoprotein, amino acid (AA), and nucleotide metabolisms, protein chaperoning and degradation, and signal transduction, were identified. This study revealed that the molecular weight of the dietary protein hydrolysate fraction had a minor impact on skeletal deformities in white seabream larvae, but affected growth performance and had a strong impact on larvae whole body proteome.