Substrates are powerful modulators of amino acid and protein turnover in vivo (Table 4). Intravenous infusions of amino acids exert a protein-anabolic effect, because they directly inhibit endogenous protein degradation and stimulate protein synthesis at the whole-body level. A stimulation of protein synthesis has been observed also at the forearm level. These changes resulted in an improvement of body and tissue protein balance, which is the ultimate goal of any nutritional intervention aimed at preserving body protein stores. In humans acute intravenous infusions of carbohydrates do not appear to affect either protein degradation or leucine oxidation. However, animal studies support the view that glucose availability spares essential amino acids at least in the fetus. The effects of hypercaloric refeeding with high-carbohydrate diets may, however, result in increased protein turnover. Lipids, in the form of long-chain fatty acids, inhibit endogenous protein breakdown and may suppress leucine oxidation in the whole body. They do not affect protein synthesis. In contrast, medium-chain fatty acids apparently increased leucine oxidation, and therefore increased net protein catabolism. Ketone bodies may be anabolic provided that fatty acid concentrations are not concurrently decreased

The role of substrates in the regulation of protein metabolism.

BARAZZONI, ROCCO;ZANETTI, MICHELA;
1996-01-01

Abstract

Substrates are powerful modulators of amino acid and protein turnover in vivo (Table 4). Intravenous infusions of amino acids exert a protein-anabolic effect, because they directly inhibit endogenous protein degradation and stimulate protein synthesis at the whole-body level. A stimulation of protein synthesis has been observed also at the forearm level. These changes resulted in an improvement of body and tissue protein balance, which is the ultimate goal of any nutritional intervention aimed at preserving body protein stores. In humans acute intravenous infusions of carbohydrates do not appear to affect either protein degradation or leucine oxidation. However, animal studies support the view that glucose availability spares essential amino acids at least in the fetus. The effects of hypercaloric refeeding with high-carbohydrate diets may, however, result in increased protein turnover. Lipids, in the form of long-chain fatty acids, inhibit endogenous protein breakdown and may suppress leucine oxidation in the whole body. They do not affect protein synthesis. In contrast, medium-chain fatty acids apparently increased leucine oxidation, and therefore increased net protein catabolism. Ketone bodies may be anabolic provided that fatty acid concentrations are not concurrently decreased
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11368/2627040
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