Abstract
Modern aquaculture feeds tend to contain lower levels of fish based ingredients, while increasing the content of plant ingredients. However, this may alter the vitamin profile of the feeds, leading to unbalanced vitamin supply. Requirements for several vitamins have been established for species such as carps and salmonids, but adequate levels for gilthead sea bream are yet unknown.Vitamin D is mainly involved in Ca homeostasis by regulating Ca uptake and liberation from bone intervening in bone remodeling. Fish are unable to synthesize vitamin D and so require absorbing it directly from the diet, thus, it is considered essential for fish. A practical plant-based diet containing 10% fish meal and 6% fish oil containing five levels of vitamin D3 (0.15, 0.43, 0.50, 0.55 and 0.65 mg kg−1 or 5.8, 17.0, 20.0, 22.0 and 26.0 IU g−1) were formulated to identify the optimum levels for gilthead seabream juveniles. Feeding juveniles of gilthead seabream with a range of vitamin D3 levels between 5.8 and 26.0 IU g−1 for 70 days did not markedly alter growth. Increase dietary vitamin D3 significantly raised the liver contents in vitamin D3 in a dose-dependent manner following a potential regression. Increased dietary vitamin D3 levels up to 11.6 IU g−1 may reduce the incidence of skeletal anomalies, particularly caudal and maxillary anomalies, whereas further elevation of dietary vitamin D3 levels increased the concentration of vitamin D3 in liver as well as skeletal anomalies in association to the up-regulation of alp and bmp2 gene expression. The occurrence of myocarditis signs in fish fed vitamin D3 levels of 20.0 IU g−1 or more denote the toxic effects of these dietary levels. These results, together with the increased occurrence of skeletal anomalies in seabream fed the highest dietary vitamin D3 levels, suggest initial signs of hypervitaminosis D. Thus, the recommended level for vitamin D3 for gilthead seabream juveniles fed diets containing high levels of plant ingredients was suggested to be 11.6 IU g−1.
Highlights
The current trend in substituting marine based ingredients for alternative ingredients in aquaculture feeds translates in changes in their nutritional profile, and can cause an unbalanced vitamin supply (Hansen et al, 2015)
Vitamin D is mainly involved in Ca homeostasis by regulating Ca uptake and liberation from bone intervening in bone remodeling
Increased dietary vitamin D3 levels up to 11.6 IU g− 1 may reduce the incidence of skeletal anomalies, caudal and maxillary anomalies, whereas further elevation of dietary vitamin D3 levels increased the concentration of vitamin D3 in liver as well as skeletal anomalies in association to the up-regulation of alp and bmp2 gene expression
Summary
The current trend in substituting marine based ingredients for alternative ingredients in aquaculture feeds translates in changes in their nutritional profile, and can cause an unbalanced vitamin supply (Hansen et al, 2015). Bone formation is tightly regulated by a series of genes and proteins that affect cell differentiation and mineralization, especially at early devel opmental stages. These markers include runx, bone morphogenic pro teins (bmp), alkaline phosphatase (alp) or osteocalcin (oc) (Fleming et al, 2005; Darias et al, 2010; Saleh et al, 2014). Besides its relevance for bone formation, vitamin D plays important roles in muscle function and cardiovascular physiology (Lock et al, 2010)
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