Metabolic Effects of Dietary Glycerol Supplementation in Muscle and Liver of European Seabass and Rainbow Trout by 1H NMR Metabolomics.

Mariana Palma,Luís Henriques,Rodrigo Ozório,Miguel Pardal,Ludgero Tavares,Ivan Viegas,João Silva,Leonardo Magnoni,João Rito

doi:10.3390/metabo9100202

Mariana Palma, Luís Henriques + Show 7 more

Open Access

https://doi.org/10.3390/metabo9100202

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Journal: Metabolites	Publication Date: Sep 27, 2019
Citations: 18	License type: CC BY 4.0

Affiliation: University of Coimbra, University of Porto

Abstract

The sustainable growth of fish aquaculture will require the procurement of non-marine feed sources. Glycerol is a potential feed supplement whose metabolism may spare the catabolism of dietary amino acids, thereby extending the use of the feed protein to other physiological functions such as growth. In the present study, the effects of dietary glycerol supplementation on the muscle and liver metabolomes of rainbow trout (Oncorhynchus mykiss) and European seabass (Dicentrarchus labrax) were evaluated. Fish juveniles were fed diets with 0%, 2.5%, and 5% glycerol. Muscle and liver aqueous fractions were extracted and 1H NMR spectra were acquired. Metabolite profiles derived from the 1H NMR signals were assessed using univariate and multivariate statistical analyses. The adenylate energy charge was determined in the muscle. For both species, the muscle metabolite profile showed more variability compared to that of the liver and was most perturbed by the 5.0% glycerol diet. For the liver metabolite profile, rainbow trout showed fewer differences compared to European seabass. No differences were observed in energy charge between experimental groups for either species. Thus, rainbow trout appeared to be less susceptible to tissue metabolite perturbations, compared to seabass, when the diet was supplemented with up to 5% glycerol.

Highlights

Aquaculture is an important source of animal protein for human consumption
Due to a presumptive technical error during grinding or tissue extraction, out of the 72 samples taken, two muscle samples from the T0 group, two muscle samples from the T2.5 group, one muscle sample from the T5.0 group, and one liver sample from the T0 group were removed from the analysis
The principal component analysis (PCA) models revealed no separation between the three groups in either the muscle or liver samples

Summary

Introduction

Aquaculture is an important source of animal protein for human consumption. It is recognized as a way to generate food products with high safety and nutritional levels, while ensuring sustainable economic, social, and environmental development [1]. Aquaculture is still dependent on ingredients from wild sources, especially for carnivorous fish that have high protein requirements [2]. Improving the sustainability of aquaculture will increasingly rely on the substitution of marine-derived ingredients with alternative components. These alternative substrates should be readily available, incorporated into aquafeed, and highly digestible. On the other hand, aquafeeds that incorporate these new substrates need to fulfil fish nutritional and metabolic

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