postprandial use of dietary amino acids as an energy substrate is delayed after the deamination process in rats adapted for 2 weeks to a high protein diet

The aim of this study was to determine the contribution of dietary amino acids (AA) to energy metabolism under high protein (HP) diets, using a double tracer method to follow simultaneously the metabolic fate of α-amino groups and carbon skeletons. Sixty-seven male Wistar rats were fed a normal (NP)...

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Bibliographic Details
Published in:Amino acids 2011-05, Vol.40 (5), p.1461-1472
Main Authors: Fromentin, Claire, Azzout-Marniche, Dalila, Tomé, Daniel, Even, Patrick, Luengo, Catherine, Piedcoq, Julien, Fromentin, Gilles, Gaudichon, Claire
Format: Article
Language:English
Subjects:
adenosine triphosphate
Adenosine Triphosphate - biosynthesis
Agricultural sciences
Amino acids
Amino Acids - administration & dosage
Analytical Chemistry
Animals
Biochemical Engineering
Biochemistry
Biomedical and Life Sciences
blood glucose
Carbon
Deamination
Decarboxylation
Diet
Dietary Proteins - administration & dosage
Dietary Supplements
Diets
energy
Energy Intake
Energy Metabolism
Energy use
fasting
glycogen
Glycogens
high protein diet
Kinetics
Life Sciences
Liver
Liver - metabolism
liver protein
Male
males
Neurobiology
nitrogen
Original Article
oxidation
Postprandial Period
Proteins
Proteomics
Rats
Rats, Wistar
stable isotopes
tracer techniques
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Summary:The aim of this study was to determine the contribution of dietary amino acids (AA) to energy metabolism under high protein (HP) diets, using a double tracer method to follow simultaneously the metabolic fate of α-amino groups and carbon skeletons. Sixty-seven male Wistar rats were fed a normal (NP) or HP diet for 14 days. Fifteen of them were equipped with a permanent catheter. On day 15, after fasting overnight, they received a 4-g meal extrinsically labeled with a mixture of 20 U-[¹⁵N]-[¹³C] AA. Energy metabolism, dietary AA deamination and oxidation and their transfer to plasma glucose were measured kinetically for 4 h in the catheterized rats. The transfer of dietary AA to liver glycogen was determined at 4 h. The digestive kinetics of dietary AA, their transfer into liver AA and proteins and the liver glycogen content were measured in the 52 other rats that were killed sequentially hourly over a 4-h period. [¹⁵N] and [¹³C] kinetics in the splanchnic protein pools were perfectly similar. Deamination increased fivefold in HP rats compared to NP rats. In the latter, all deaminated AA were oxidized. In HP rats, the oxidation rate was slower than deamination, so that half of the deaminated AA was non-oxidized within 4 h. Non-oxidized carbon skeletons were poorly sequestrated in glycogen, although there was a significant postprandial production of hepatic glycogen. Our results strongly suggest that excess dietary AA-derived carbon skeletons above the ATP production capacity, are temporarily retained in intermediate metabolic pools until the oxidative capacities of the liver are no longer overwhelmed by an excess of substrates.
ISSN:0939-4451
1438-2199
DOI:10.1007/s00726-010-0756-3