22This study examined the effect of including different dietary proportions of starch, protein 23 and lipid, in diets balanced for digestible energy, on the utilisation efficiencies of dietary energy by 24 barramundi (Lates calcarifer). Each diet was fed at one of three ration levels (satiety, 80% of initial 25 satiety and 60% of initial satiety) for a 42-day period. Fish performance measures (weight gain, feed 26 intake, and feed conversion ratio) were all affected by dietary energy source. The efficiency of energy 27 utilisation was significantly reduced in fish fed the starch diet relative to the other diets, but there 28 were no significant effects between the other macronutrients. This reduction in the efficiency of Barramundi are an obligate carnivorous fish species that is the basis of a significant 40 aquaculture industry in Southeast Asia and Australia (1). The development of high-nutrient density 41 formulated extruded feeds has been underpinned by the development of both a series of factorial 42 bioenergetic nutritional models and foundation empirical studies (1, 2, 3, 4, 5). These nutritional 43 models have so far relied on the assumption that the dietary digestible energy (DE) source is 44 irrelevant; that is that the dietary DE derived from protein, lipid and starch is utilised with equal 45 efficiency, subject to key nutrients (e.g. protein) being provided at/or above minimum critical ratios to 46 energy supply (4, 5, 6, 7, 8, 9, 10). 47 Each of the different macronutrients (starch, protein and lipid) supplies energy by distinct 48 metabolic pathways. In aquatic animals it is recognised that there are different levels of efficiency in 49 the utilisation of each these macronutrients for energy (11, 12). It is now recognised that this 50 difference requires an amendment of the digestible nutritional values of each macronutrient to those 51 of metabolisable nutritional values and/or net energy nutritional values (9, 12, 13, 14). Recent work 52 by Schrama et al. (14) examined the utilisation of both starch and lipid for growth by the omnivorous respectively. These observations clearly indicated that this fish species used lipid as an energy source 57 for growth more efficiently. However, the third key macronutrient, protein, was not considered in this 58 study. In that same study, Schrama et al. (14) in reviewing the literature identified that there was a 59 wide variability (0.31 to 0.82) in the kgDE of different studies. It was suggested that the three primary 60 reasons for this variability were: different dietary macronutrient compositions; trophic level of the fish 61 species; and the composition of the growth. In addition, there is increasing evidence that the roles of 62 gluconeogenesis, glycolysis and -oxidation play substantially different relative roles in energy 63 provision in fish compared to other vertebrates (11, 14, 15, 16, 17). 64 The objective of this study was to determine the partial efficiencies of utilisation of each of 65 the d...
