Zebrafish (Danio rerio) have been proposed as a possible model organism for nutritional physiology. However, this potential has not yet been realized and studies on the field remain scarce. In this work, we investigated in this species the effect of a single meal as well as that of an increase in the ratio of dietary carbohydrates/proteins on the postprandial expression of several hepatic and muscle metabolism-related genes and proteins. Fish were fed once either a commercial diet (experiment 1) or one of two experimental diets (experiment 2) containing different protein and carbohydrate levels after 72 h of starvation. Refeeding induced the postprandial expression of genes of glycolysis (GK, HK1) and lipogenesis (FAS, G6PDH, ACCa) and inhibited those of gluconeogenesis (cPEPCK) and beta-oxidation (CPT1b) in the viscera. In the muscle, refeeding increased transcript levels of myogenesis (Myf5, Myogenin), inhibited those of Ub-proteasomal proteolytic system (Atrogin1, Murf1a, Murf1b), and induced the activation of key signaling factors of protein synthesis (Akt, 4EBP1, S6K1, S6). However, diet composition had a low impact on the studied factors. Together, these results highlight some specificity of the zebrafish metabolism and demonstrate the interest and the limits of this species as a model organism for nutritional physiology studies.
A morphometric analysis of white axial muscle of common carp Cyprinus carpio was undertaken in order to quantify increase in fibre size, fibre nuclei and fibre number in relation to somatic growth rate during early life. In fast-growing carp larvae fed zooplankton, length and height of fibres from the central part of dorsolateral muscle increased at the same rate (0·75) relative to the total length of the larvae during the first 2 weeks of feeding. During this period, the number of nuclei per fibre increased threefold while the number of nuclei per unit fibre surface remained constant. In fast-growing larvae fed a formulated diet, the total cross-sectional area of one epaxial quadrant of white muscle and the total area of white fibres increased at almost the same rate (3·15; 3·23) relative to larval total length during the first 28 days of exogenous feeding. The total number of white fibres increased faster (2·07) relative to the total length of larvae than the mean area of white fibres (1·16). Hyperplasia accounted for 64% of muscle growth in these larvae. The proportion of fibres with a width <10 m decreased from 72% at first feeding to 14% 28 days later, while the proportion of fibres with a width >20 m which was 0% at first feeding increased up to 34% in the same time. The recruitment of new white fibres seemed to be almost the same in the whole muscle quadrant at first feeding and 18 or 28 days later but, 8 days after first feeding, a transient significant recruitment of new fibres was shown at the apex of the myotome. Comparisons between fast-and slow-growing groups of larvae showed that for a given larval total length: (1) the mean width of central white fibres was higher and the proportion of central fibres with a width <10 m was lower in slow-growing larvae than in fast-growing ones; (2) the total number of white fibres was lower for a higher total cross-sectional area of white muscle in slow-growing larvae than in fast-growing ones. These results suggest that, in Cyprinus carpio larvae, slow-growing conditions are related to a decreased contribution of hyperplasia to muscle growth. 1997 The Fisheries Society of the British Isles
The effect of early (embryonic and larval) thermal history on subsequent (juvenile) white muscle hyperplasia was studied in a teleost fish, the European sea bass (Dicentrarchus labrax L.). D. labrax, incubated and reared at constant temperatures of 13 degrees C, 15 degrees C or 20 degrees C from the embryonic stage of half epiboly up to 18-19 mm in total length, were transferred to ambient seawater temperature and reared for the subsequent 14 months on commercial feed. The somatic growth of juveniles was linked to annual variations of ambient seawater temperature and inversely related to early rearing temperature, so that, after 14 months, the juveniles originally reared at low temperatures had compensated for the growth retardation experienced during early life. The white muscle growth process of juveniles was quantified after two periods of growth opportunity at ambient seawater temperature (100 and 400 days post-transfer) as well as, in order to follow total-length-dependent effects of early temperature and to discriminate total-length-independent effects of early temperature, on juveniles from the three batches sampled at six successive equivalent total lengths (31-33, 84-88, 141-145, 166-172, 196-206 and 211-220 mm). Our data demonstrate the existence of a seasonal recruitment of new white muscle fibres when seawater temperature increases and of a shrinkage of the largest white muscle fibres during the winter months. The seasonal recruitment of new white muscle fibres occurring in juveniles is linked to their early rearing temperature. Juveniles originating from low temperatures have a higher and longer capacity to recruit new white muscle fibres when seawater temperature increases, supporting their better somatic growth. This finding is discussed in relation to the early (embryonic and larval) myogenic processes of the three populations and is related to their sex ratio.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.