Intake of diet enriched fish oil increases energy expenditure by a UCP1-independent mechanism and protects mice from obesity induced by lard-rich diet.

We have previously shown that diet-induced obesity is prevented by increasing N3 fatty acids content in the body of mice through genetic modification. Aim: In the present study, we investigated the mechanisms by which the fish oil control the energy balance protecting mice from diet-induced obesity, with emphasis at shivering and non-shivering thermogenesis. Materials and Methods: Protocol 1- C57BL6/J mice were fed during 8 weeks with normal diet (DN) containing 10% of lipids from soy oil and lard, normal diet N3 (DNN3) containing 10% of lipids from soy and fish oils, high fat diet (HFD) 60% of lipids from soy oil and lard and high fat diet (HFDN3) containing 60% of lipids from soy and fish oils. The evaluated parameters were body weight, energy efficiency, food intake, indirect calorimetry, adiposity, glucose and insulin tolerance, tissue oxygen consumption and lipidomic analysis of the white adipose tissue (WAT) and brown adipose tissue (BAT). Protocol 2- Wild type (WT) and UCP1 knockout (KO) mice were fed during 8 weeks with HFD and HFDN3. In Protocol 2, body weight, energy efficiency, food intake, indirect calorimetry, adiposity, glucose tolerance and tissue oxygen consumption were evaluated. Results: Protocol 1- No significant differences were observed in body weight, adiposity, food intake, oxygen consumption and glucose tolerance between mice fed with DN and DNN3. Mice fed with HFDN3, however, displayed reduced body weight gain, epididimal, inguinal and retroperitoneal adipose tissue masses, and energy efficiency when compared to mice fed with HFD. These effects occurred in the absence of significant alterations in food intake measured in grams and Kcal. Corroborating the decrease in energy efficiency, C57BL6/J mice fed with HFDN3 have increased oxygen consumption, but similar spontaneous locomotor activity when compared to mice fed with HFD. We show that oxygen consumption in the WAT in mice fed with HFDN3 was higher than in mice fed with HFD. Finally, the lipidomics analysis in both WAT and BAT revealed an enrichment of the triacylglycerol (TAG) linked to highly unsaturated fatty acids (HUFA, 46 double bonds) in mice fed with HFDN3. Protocol 2- The HFDN3 protects both WT and UCP1 KO groups from body weight gain, increases energy expenditure, and improves glucose tolerance. Moreover, we observe that UCP1 KO HFD group increased the weight of the TAM relative to the other groups. Conclusion: Our results indicate that replacement of lard by fish oil in the diet of mice increases energy expenditure independently of UCP1, decreasing the gain in body weight and adiposity in both protocols. To account for these findings, a model based on the higher mobilization of TAG linked to HUFA for beta-oxidation (relative to less unsaturated moieties) and activation of alternative mechanisms of energy expenditure are proposed to explain the lean phenotype of mice fed with HFDN3. This and other mechanisms of energy expenditure, however, require further investigations. (AU)