Changes in the exercise-induced hormone response to branched chain amino acid administration.

It was the aim of the present experiment to detect possible effects of branched-chain amino acids (BCAA) on the endocrine response to 1 h of continuous running. Blood samples were collected from 14 long-distance runners (age 24-42 years) in two different trials performed at 1-week intervals. In both trials (E and P) blood samples were collected at the following times: 9 a.m. (basal values sample), 10.30 a.m. (sample 90), 11.30 a.m. (sample 150), 12.30 p.m. (sample 210); the athletes performed 1 h of running at a constant predetermined speed between samples 90 and 150. Following the basal sample a mixture containing BCAA (E trial), or not containing BCAA (P trial) was ingested. In both trials no hormone basal concentrations, except insulin, were changed before exercise. In P trial, following exercise (sample 150), human growth hormone (HGH), prolactin (PRL), adrenocorticotropic hormone (ACTH) and cortisol (C) increased, while testosterone (T) decreased. In sample 210, after 1 h of rest, while ACTH, PRL and HGH had recovered to basal concentrations, C remained elevated and T displayed a further decrease. In the E trial a similar pattern of change was observed in sample 150 for HGH, PRL, ACTH and C; in sample 210 HGH and PRL displayed significantly lower values than in the corresponding P trial samples. The T was not modified by the running exercise and increased during the recovery period. It is, therefore, suggested that BCAA administration before exercise affects the response of some anabolic hormones, mainly HGH and T.     

Measurement of branched chain amino acids in blood plasma by high performance liquid chromatography

A simple and rapid high performance liquid chromatographic technique is described for the separation and quantitation of plasma branched chain amino acids. After addition of a norleucine internal standard, plasma samples are acidified with acetic acid, and amino acids are separated from proteins and other plasma components by passage of the acidified plasma through an ion exchange resin. The ammonium hydroxide eluate from the resin is dried, phenylisothiocyanate derivatives are prepared, and the amino acids are separated on a Waters reverse-phase "Pico-Tag" column with an ultraviolet detector set at 254 nm. In addition to the branched chain amino acids (leucine, valine, and isoleucine), aspartate, glutamate, serine, threonine, alanine, and methionine are quantitated with high precision and accuracy, as verified by quantitative recovery and comparison with an automatic amino acid analyzer. The advantages of the method are its simplicity, speed, stability of derivatives, high reproducibility, low per-sample cost, and the use of a simple fixed-wavelength ultraviolet detector.     

Fermentative production of branched chain amino acids: a focus on metabolic engineering

The branched chain amino acids (BCAAs), l-valine, l-leucine, and l-isoleucine, have recently been attracting much attention as their potential to be applied in various fields, including animal feed additive, cosmetics, and pharmaceuticals, increased. Strategies for developing microbial strains efficiently producing BCAAs are now in transition toward systems metabolic engineering from random mutagenesis. The metabolism and regulatory circuits of BCAA biosynthesis need to be thoroughly understood for designing system-wide metabolic engineering strategies. Here we review the current knowledge on BCAAs including their biosynthetic pathways, regulations, and export and transport systems. Recent advances in the development of BCAA production strains are also reviewed with a particular focus on l-valine production strain. At the end, the general strategies for developing BCAA overproducers by systems metabolic engineering are suggested.     

The induction of a dehydrogenase activity for branched chain amino acids in Bacillus subtilis

Summary In Bacillus subtilis a dehydrogenase activity for branched chain amino acids was induced twelvefold in glucose medium by isoleucine. To a lesser degree this activity was induced by metabolically related amino acids with the exception of leucine which hardly induced. The induced enzyme actvity is different from alanine dehydrogenase. The presumable role of this inducible enzyme in anteiso fatty acid biosynthesis is discussed.     

Failure of a branched chain amino acid-enriched diet to reverse ethanol inhibition of cardiac protein synthesis in the rat

The fractional rate of protein synthesis was determined in the hearts of rats in vivo fed on diets containing 27% of energy as ethanol or on this diet supplemented with 5% of equimolar amounts of branched chain amino acids (BCAA). Administration of ethanol significantly decreased the fractional synthetic rate of mixed cardiac proteins and this depression was not ameliorated by concomitant feeding of BCAA. These data are discussed in relation to the stimulation of cardiac protein synthesis by BCAA observed in vitro.     

Effect of the composition of branched chain amino acids, taurine, and tryptophan on the amino acid metabolism in experimental models of alcoholism

Ethanol withdrawal after forced alcoholization of rats according to Majchrowicz led to the development of amino acid imbalance in the pool of free amino acids in the liver (increasing levels of alanine, aspartate, glutamate, glutamine and histidine, decreasing levels of glycine, lysine, threonine and taurine) and blood plasma (increasing levels of tyrosine and alanine, decreasing levels of most glycogen aminoacids, branched-chain aminoacids and Lys). Less profound changes were observed after prolonged alcohol intoxication (decreasing levels of alanine, ornitine, citrulline and increasing level of Glu in liver, increasing levels of sulfur-containing compounds, Asp and Lys in blood plasma). Amino acid mixture which contained branched-chain amino acids, taurine and tryptophan administered intragastrically was found to correct levels of sulfur-containing amino acids, threonine, lysine and isoleucine after ethanol withdrawal and to eliminate disorders in urea cycle, exchange of threonine, glycine and phenylalanine after prolonged alcohol intoxication.     

Effect of branched chain amino acids on liver regeneration after partial hepatectomy

The authors investigated the effect of the enrichment of commercial amino acid solutions with branched chain amino acids on the development of liver regeneration. Partial (65-70%) hepatectomy was performed on male Wistar rats (140-160 g body weight). Starting with the day of the operation, amino acid solutions normally used in clinical practice and the same solutions enriched with branched chain amino acids were administered by stomach tube; 24, 48 and 96 h after the operation the animals were decapitated. The onset of DNA synthesis was found to be more rapid in animals given the enriched solutions. Once regeneration had started, the stimulant effect of an increased supply of branched chain amino acid on liver regeneration was smaller. Nevertheless, even in the later phase after partial hepatectomy branched chain amino acids had a stronger stimulant effect on liver regeneration after partial hepatectomy than an energy supply in the form of sorbitol.     

Branched chain amino acids as source of specific branched chain volatile fatty acids during the fermentation process of fish sauce

Summary.  The source of the formation of branched chain volatile fatty acids (VFA) in fish sauce was investigated. Certain branched VFA were derived from the degradation of specific amino acids as iso-butyric acid from valine and iso-valeric acid from leucine. Short and long straight chain VFA were significantly higher in the linoleic acid added sample than in the control but did not significantly bring changes to the branched chain VFA. It is suggested that straight chain VFA developed from fish fats. Alanine and isoleucine did not have a clear influence on the production of volatile fatty acids. Received November 23, 2001 Accepted June 20, 2002 Published online December 18, 2002 RID="*" ID="*" Part of this paper was presented in the 7th International Congress on Amino Acids and Proteins in Vienna, Austria from August 6–10, 2001. Authors' address: Norlita G. Sanceda, Ph.D., Institute of Environmental Science for Human Life, 2-1-1 Otsuka, Bunkyo-ku, Tokyo 112, Japan, Fax: + 81-3-5978-5805, E-mail: lita@cc.ocha.ac.jp     

Effect of leucine and metabolites of branched chain amino acids on protein turnover in heart.

Leucine, but not isoleucine or valine, inhibited protein degradation and accelerated protein synthesis in hearts perfused with buffer that contained glucose (15 mM) and normal plasma levels of other amino acids, except for the branched chain compounds. Products of leucine, isoleucine, and valine metabolism also inhibited protein degradation and stimulated protein synthesis. These compounds included the transamination and decarboxylation products, as well as acetate, acetoacetate, and propionate. In some, but not all instances, inhibition of degradation and acceleration of synthesis were accompanied by an increase in intracellular leucine. When insulin was added to the perfusate, the rate of degradation was reduced by 40%, but addition of leucine was ineffective in the presence of the hormone. Insulin, leucine (2 mM) and a mixture of branched chain amino acids at normal plasma levels increased latency of cathepsin D in hearts that were perfused with buffer containing glucose. A combination of leucine and insulin increased latency more than either substance alone. These studies indicate that leucine as well as a variety of substrates that are oxidized in the citric acid cycle are involved in regulation of protein turnover in heart muscle.     

Elevation of transamination of branched chain amino acids in brain in acute ammonia toxicity

The activity levels of leucine, isoleucine and valine aminotransferases were determined in various cerebral regions, liver and muscle of rats injected with a large dose of ammonium acetate and were compared with those of normal animals. In brain the activity levels of both leucine and isoleucine aminotransferases were elevated in both preconvulsive and convulsive states. Valine aminotransferase activity was suppressed in brain stem and corpus striatum and was elevated in cerebellum and hippocampus in preconvulsive states. During convulsions its activity was suppressed in cerebral cortex and hippocampus. Under these conditions, there was a suppression of both leucine and valine aminotransferases in muscle. In liver, however, the activities of these enzymes were elevated. The results suggested that the glutamate required for glutamine formation in hyperammonaemic states in brain might be obtained from branched chain amino acids, especially leucine and isoleucine.     

In vitro effect of branched chain amino acids on the ribosomal cycle in muscles of fasted rats.

1) The effect of a single i.p injection of branched chain amino acids on ribosomal profiles of psoas muscles was studied in rats after a 48--96 hour fast. Experimental and control animals received glucose and insulin 1--2 hours before killing. 2) The ratio of polysomes to subunits and monomers decreased progressively during the fast. 3) The administration of the three branched chain amino acids together or leucine alone significantly increased the proportion of polysomes. 4) This effect was not observed in rats fed ad libitum. 5) It is suggested that the branched chain amino acids and specifically leucine may be required for the full protein anabolic response of muscles to insulin during a prolonged fast.     

Significance of branched chain amino acids as possible stimulators of hepatocyte growth factor

Amino acids can serve as regulatory molecules that modulate numerous cellular functions. Branched chain amino acids (BCAAs) are known to exert influences on cellular metabolism, amino acid transport, protein turn over, and gene expression. However, the mechanisms involved in the specific effect of BCAAs have not been clarified. BCAA supplementation therapy is a current treatment for patients with liver cirrhosis, therefore, specific BCAA activities should be examined. Hepatocyte growth factor (HGF) is considered to be a pleiotropic factor, and is reported to modulate gene expression and to stimulate the proliferation and functions of many cell types, including hepatocytes. A potential application of HGF for several types of diseases has been postulated. Here, we describe the potential of BCAAs as a therapeutic agent that acts through the induction of HGF production in the liver.