OBJECTIVE: Maternal high-fat intake during pregnancy may have long-term consequences in the offspring. Since this might relate to the capacity of mitochondrial metabolic adaptation and hepatic lipid metabolism, we investigated how maternal high-fat intake affected mitochondrial function and hepatic steatosis in the offspring. DESIGN: Sprague-Dawley rats were fed a high-fat (20% w/w) or a control diet (chow, C) from 10 days before pregnancy and throughout lactation. At weaning the litters were split into two groups; one was continued on the maternal diet and the other was fed low-fat chow. SAMPLE: Skeletal muscle mitochondria and liver lipids. METHODS: Mitochondrial respiration and hepatic lipid content were determined during and after weaning, on days 20 and 70 postpartum. MAIN OUTCOME MEASURES: Mitochondrial function and hepatic lipids. RESULTS: At 20 days, maternal high-fat diet caused increased Vo2max with pyruvate as substrate (p=0.047), at 70 days, pups born by C-dams, but not those born by high-fat-dams, showed increased oxidation of palmitoylcarnitine in the absence of ADP (p=0.018). Rates of ADP-stimulated oxygen consumption, maximal respiratory capacity and mitochondrial respiratory control ratio with pyruvate, increased post weaning (p<0.001), whereas respiratory control ratio with palmitoylcarnitine decreased (p=0.013). The increase in respiratory control ratio was most pronounced in pups from C-dams (p=0.05). The high-fat-diet caused pronounced hepatic steatosis in pups at weaning (p<0.001), without concomitant ceramide accumulation, while high-fat-feeding after weaning induced triacylglycerol and ceramide accumulation (p<0.01), regardless of maternal diet. CONCLUSION: Intake of a fat-rich diet during pregnancy and lactation reduced the age-induced increases in un-coupled fat oxidation.
OBJECTIVE: Maternal high-fat intake during pregnancy may have long-term consequences in the offspring. Since this might relate to the capacity of mitochondrial metabolic adaptation and hepatic lipid metabolism, we investigated how maternal high-fat intake affected mitochondrial function and hepatic steatosis in the offspring. DESIGN:Sprague-Dawley rats were fed a high-fat (20% w/w) or a control diet (chow, C) from 10 days before pregnancy and throughout lactation. At weaning the litters were split into two groups; one was continued on the maternal diet and the other was fed low-fat chow. SAMPLE: Skeletal muscle mitochondria and liver lipids. METHODS: Mitochondrial respiration and hepatic lipid content were determined during and after weaning, on days 20 and 70 postpartum. MAIN OUTCOME MEASURES: Mitochondrial function and hepatic lipids. RESULTS: At 20 days, maternal high-fat diet caused increased Vo2max with pyruvate as substrate (p=0.047), at 70 days, pups born by C-dams, but not those born by high-fat-dams, showed increased oxidation of palmitoylcarnitine in the absence of ADP (p=0.018). Rates of ADP-stimulated oxygen consumption, maximal respiratory capacity and mitochondrial respiratory control ratio with pyruvate, increased post weaning (p<0.001), whereas respiratory control ratio with palmitoylcarnitine decreased (p=0.013). The increase in respiratory control ratio was most pronounced in pups from C-dams (p=0.05). The high-fat-diet caused pronounced hepatic steatosis in pups at weaning (p<0.001), without concomitant ceramide accumulation, while high-fat-feeding after weaning induced triacylglycerol and ceramide accumulation (p<0.01), regardless of maternal diet. CONCLUSION: Intake of a fat-rich diet during pregnancy and lactation reduced the age-induced increases in un-coupled fat oxidation.
Authors: Janne Boone-Heinonen; Lynne C Messer; Stephen P Fortmann; Lawrence Wallack; Kent L Thornburg Journal: Prev Med Date: 2015-10-30 Impact factor: 4.018