Differential effects of protein malnutrition and ascorbic acid deficiency on histidine metabolism in the brains of infant nonhuman primates

Abstract: Male infant nonhuman primates (M. nemes-trina) born in captivity were used in the study. They were divided into three groups. The first group of three animals was fed a 20% casein diet and the second group of six monkeys received a 2.0% casein diet. The third group of four monkeys received a 20% casein diet totally devoid of ascorbic acid for 3.5 weeks before the diet was supplemented with ascorbic acid (20 mg/kg diet). All the diets were given to the animals in two daily rations of 100 g/animal. The monkeys fed a 2% casein diet failed to grow, and after about 3.5 months showed variable degrees of edema, hypoalbuminemia, evidence of psychomotor disturbance, depressed plasma levels of many essential amino acids, and other features consistent with the diagnosis of protein-energy malnutrition. Examination of the brains revealed significant alterations in the levels of histidine (+ 172%) and homocarnosine (+ 146%) in comparison with the control well-fed monkeys. Associated with the increase in brain histidine was a marked elevation of brain histamine level. Protein deficiency also led to poor brain retention of ascorbic acid but not to the same degree observed in the ascorbic acid-deficient animals. The latter group of animals, after receiving their diet for about 8 months, demonstrated a modest elevation in the plasma levels of most amino acids in comparison with controls. Ascorbic acid deficiency elicited a significant reduction (p < 0.01) in brain level of histidine, with hardly any change in homocarnosine level. In addition, vitamin C deficiency produced elevation of brain histamine level comparable to findings in the protein-energy-deficient monkeys. The results suggested that protein deficiency raised brain histamine level mainly through increased availability of the precursor amino acid histidine, while defective degradation might account for the increased brain level of this amine in ascorbic acid-deficient monkeys. Histamine has been proposed to have a predominantly depressant action on relevant neurons, and has also been shown to participate with other neuro-transmitters in influencing the function of the pituitary gland by regulating release of the hypothalamic hormones into the portal vessels. The relevance of the findings of marked increases in brain histamine in experimental protein and ascorbic acid deficiencies to the behavioral and extensive endocrinological alterations seen in human malnutrition deserves some intensive investigation.     

Changes in cerebrospinal fluid and plasma amino acid concentrations with elevated dietary protein concentration in dogs with portacaval shunts

Effects of dietary protein concentration on plasma and cerebrospinal fluid (CSF) amino acids (AA) in dogs with portacaval shunts (PCS) were examined. An 18% protein purified diet (18P) was fed to 4 PCS dogs and 2 controls; at week 10, 2 of the PCS dogs were switched to 36% protein (36P) until week 28. Effects of the diet switch on plasma and CSF AA in 8 normal dogs were determined in another experiment. Neither surgery nor protein level significantly affected average food intake (weeks 10-28). Plasma amino acid patterns typical of PCS animals were observed: phenylalanine and tyrosine increased and branched chain AA decreased with shunting (p less than 0.05). Plasma phenylalanine increased further with 36P in PCS dogs (p less than 0.05), but was not affected by dietary protein concentration in controls. With 36P: CSF arginine, serine, histidine, tryptophan, phenylalanine, glutamate and glutamine increased in PCS dogs; but only arginine decreased in CSF of controls (p less than 0.05). In PCS dogs, significant CSF AA changes with elevated dietary protein were unrelated to plasma AA changes.     

Accumulation of histidine, 3-methylhistidine, and homocarnosine in the brains of protein-calorie deficient monkeys

Abstract— Seventeen monkeys (M. nemestrina and M. fascicularis) aged 10 months to about 5 yr were divided into two groups and fed either an adequate protein diet (20% casein) or a low-protein diet (2% casein). The diets were supplied to the animals in restricted amount (200 g/animal in two daily rations). In one experiment, the malnourished animals were initially fed a diet containiing 8 per cent protein and the protein content of the diet was gradually reduced over a period of 9 months, to 2 per cent. After about 3 months on the 2 per cent protein diet, the malnourished monkeys showed growth failure, severe anorexia, peri-ocular oedema, tremors of the head and limbs, atrophy of several visceral organs, fatty liver, hypoalbuminaemia, and depressed serum levels of many essential amino acids with an elevation of the ratio of non-essential to essential amino acids. These features are consistent with protein-calorie malnutrition. Examination of the brains revealed significant alterations in the levels of glycerophosphoethanolamine (—40 per cent), glutamic acid (—25 per cent), histidine (+230 per cent), homocamosine (+185 per cent), 3-methyl-histidine (+147 per cent), lysine (+55 per cent), phenylalanine (+33 per cent) and tyrosine (+26 per cent) in comparison to findings on the well-fed monkeys. The possible implications of elevated cerebral contents of homocarnosine in malnourished monkeys are discussed in the light of several reported human cases in whom neurological disorders are associated with increased histidine-containing dipeptides in the brain, CSF, blood and urine.     

Regional distribution of homocarnosine and other ninhydrin-positive substances in brains of malnourished monkeys

—Eight male monkeys (Macaca nemestrina) aged 6–9 months were divided into two groups and fed either an adequate protein diet (20% casein) or a protein deficient diet (2% casein). After 3- 5 months of receiving the low protein diet, the malnourished monkeys showed extensive fatty metamorphosis of the liver cells, distorted patterns of plasma and hepatic free amino acid pools, and other features consistent with the diagnosis of protein-calorie malnutrition. Examination of the cerebrum, cerebellum and brain stem in the malnourished animals revealed profound accumulation of 3-methylhistidine, histidine and homocarnosine in all three regions. For histidine, the cerebral, cerebellar and brain stem levels in the protein deficient animals increased by 145, 104 and 101 per cent over levels observed in corresponding regions of the brain in well-fed monkeys. Similarly, there were significant elevations in homocarnosine contents of the cerebrum (+ 99 per cent), cerebellum (+ 140 per cent) and brain stem (+ 146 per cent) in comparison to levels in control animals. In contrast, the levels of valine, serine and aspartic acid were markedly reduced in all three brain areas in the malnourished animals. Protein-calorie deficiency also produced reductions in the brain levels of taurine, glutamic acid, isoleucine, leucine and threonine which varied in magnitude in the three major regions of the brain examined. These biochemical alterations which may in part underlie some of the psychomotor changes often observed in protein-calorie malnutrition, were discussed not only in relation to the role of amino acids as precursors for the synthesis of neuroregulatory substances but also with due regard to the possibility that some of these ninhydrin-positive substances such as GABA, homocarnosine, glycine and the dicarboxylic amino acids may possess neuroexcitatory or inhibitory properties in various parts of the central nervous system.     

Elevation of brain histamine content in protein-deficient rats.

—Male rats of the Sprague-Dawley strain (80–250 g body wt) were fed either an adequate protein diet (18% lactalbumin) or a protein-deficient diet (0.5% lactalbumin). After 5–8 weeks of receiving the low protein diet, some of the malnourished rats were rehabilitated with an adequate protein diet. The malnourished rats exhibited significant elevations in brain levels of histidine (+415%) and homocarnosine (+100%) in comparison to findings in the control animals of similar age. Associated with the elevated brain levels of histidine in malnutrition was a prominent increase in brain content of histamine (+ 150-+ 238%). The mean brain histamine levels (ng/g) in the control rats varied from 45.96 to 56.15 in several experiments. In the protein-deficient rats, values ranged from 115 to 190. Refeeding the malnourished rats with adequate protein diet elicited reversal of histidine and histamine levels to near normal values within 1 week. The increased brain content of histamine in malnutrition was attributed to enhanced rate of production resulting from increased availability of the precursor amino acid, a conclusion consistent with elevation also of the brain content of homocarnosine (γ-aminobutyryl-l -histidine) which is another major route of disposal of histidine in the brain. The relevance of these neurochemical alterations to the behavioural changes often associated with protein malnutrition, deserves some intensive examination.     

Eliminating tyrosine sequence variants in CHO cell lines producing recombinant monoclonal antibodies

Amino acid sequence variants are defined as unintended amino acid sequence changes that contribute to product variation with potential impact to product safety, immunogenicity, and efficacy. Therefore, it is important to understand the propensity for sequence variant (SV) formation during the production of recombinant proteins for therapeutic use. During the development of clinical therapeutic products, several monoclonal antibodies (mAbs) produced from Chinese Hamster Ovary (CHO) cells exhibited SVs at low levels (≤3%) in multiple locations throughout the mAbs. In these examples, the cell culture process depleted tyrosine, and the tyrosine residues in the recombinant mAbs were replaced with phenylalanine or histidine. In this work, it is demonstrated that tyrosine supplementation eliminated the tyrosine SVs, while early tyrosine starvation significantly increased the SV level in all mAbs tested. Additionally, it was determined that phenylalanine is the amino acid preferentially misincorporated in the absence of tyrosine over histidine, with no other amino acid misincorporated in the absence of tyrosine, phenylalanine, and histidine. The data support that the tyrosine SVs are due to mistranslation and not DNA mutation, most likely due to tRNA^Tyr mischarging due to the structural similarities between tyrosine and phenylalanine. Biotechnol. Bioeng. 2013; 110: 1087–1097. © 2012 Wiley Periodicals, Inc.     

Plasma amino acids in four models of experimental liver injury in rats

Summary We studied the plasma amino acid profiles in four models of hepatic injury in rats. In partially hepatectomized rats (65% of liver was removed) we observed significant increase of aromatic amino acids (AAA; i.e. tyrosine and phenylalanine), taurine, aspartate, threonine, serine, asparagine, methionine, ornithine and histidine. Branched-chain amino acids (BCAA; i.e. valine, leucine and isoleucine) concentrations were unchanged. In ischemic and carbon tetrachloride acute liver damage we observed extreme elevation of most of amino acids (BCAA included) and very low concentration of arginine. In carbon tetrachloride induced liver cirrhosis we observed increased levels of AAA, aspartate, asparagine, methionine, ornithine and histidine and decrease of BCAA, threonine and cystine. BCAA/AAA ratio decreased significantly in partially hepatectomized and cirrhotic rats and was unchanged in ischemic and acute carbon tetrachloride liver damage. We conclude that a high increase of most of amino acids is characteristic of fulminant hepatic necrosis; decreased BCAA/AAA ratio is characteristic of liver cirrhosis; and decrease of BCAA/AAA ratio may not be used as an indicator of the severity of hepatic parenchymal damage.Abbreviations BCAA branched-chain amino acids (i.e. valine, leucine and isoleucine) - AAA aromatic amino acids (i.e. tyrosine and phenylalanine)     

Changes in plasma amino acid concentrations with increasing age in patients with propionic acidemia

The objective of the study is to analyze plasma amino acid concentrations in propionic acidemia (PA) for the purpose of elucidating possible correlations between propionyl-CoA carboxylase deficiency and distinct amino acid behavior. Plasma concentrations of 19 amino acids were measured in 240 random samples from 11 patients (6 families) with enzymatically and/or genetically proven propionic acidemia (sampling period, January 2001–December 2007). They were compared with reference values from the literature and correlated with age using the Pearson correlation coefficient test. Decreased plasma concentrations were observed for glutamine, histidine, threonine, valine, isoleucine, leucine, phenylalanine and arginine. Levels of glycine, alanine and aspartate were elevated, while values of serine, asparagine, ornithine and glutamate were normal. For lysine, proline and methionine a clear association was not possible. Significant correlations with age were observed for 13 amino acids (positive correlation: asparagine, glutamine, proline, alanine, histidine, threonine, methionine, arginine; negative correlation: leucine, phenylalanine, ornithine, glutamate and aspartate). This study gives new insight over long-term changes in plasma amino acid concentrations and may provide options for future therapies (e.g., substitution of anaplerotic substances) in PA patients.     

Effect of cypermethrin on the free amino acids pool in an organophosphorus-insecticide-resistant and a susceptible strain of Tribolium castaneum

1. Proline was found to be the major component of CTC-12 (44%) and FSS II (45%) strain.2. The cypermethrin treatment resulted in an increase in most of the amino acids of sixth instar larvae and all amino acids of adult beetles of CTC 12 strain.3. In the susceptible strain (FSS II), however, the tyrosine, phenylalanine and arginine increased, whereas serine, proline, glycine, alanine, valine, isoleucine, leucine and lysine were decreased significantly in the sixth instar larvae.4. In the FSS II adult beetles, only aspartic acid increased, while other amino acids either decreased (threonine, proline, glycine, alanine, valine, methionine, isoleucine, tyrososine, lysine, arginine) or remained unaffected (serine, glutamic acid, leucine, phenylalanine, histidine).     

THE INFLUENCE OF HIGH PHENYLALANINE AND TYROSINE ON THE CONCENTRATIONS OF ESSENTIAL AMINO ACIDS IN BRAIN

—High circulating levels of phenylalanine caused depletions of threonine, valine, methionine, isoleucine, leucine, histidine, tryptophan, and tyrosine in immature and adult rat brains. The branched-chain amino acids were most affected. Their reductions ranged between 38–64 per cent of control values when phenylalanine was administered either parenterally or in the diet. The pattern of cerebral amino acid depletions found in phenylalanine-injected infant rats was similar to that of the adults. Phenylalanine loading caused depletions in serum amino acid levels in adult rats, but in infant rats the serum levels were either unchanged or somewhat elevated. Tyrosine, when administered to adult rats either parenterally or via the diet, caused cerebral depletions in essential amino acids, but the depletions were not as striking as with phenylalanine. In both the infant and adult rat, brain-blood ratios of most of the essential amino acids were significantly reduced by phenylalanine loading.     

Variation in the free amino acid content of skeletal muscle of Ophicephalus punctatus (Bloch)

The skeletal muscle of Ophicephalus punctatus contains nine essential free amino acids, arginine, histidine, isoleucine, leucine, methionine, phenylalanine, threonine, valine and lysine, and eight non-essential amino acids, alanine, aspartic acid, cystine, glutamic acid, glycine, tyrosine, proline and serine. Histidine and lysine dominated the free amino acids pool. Seasonal variation was detected in the levels of histidine, arginine, leucine, phenylalanine, glycine, cystine and serine with highest values occurring in April and again in November. Changes were also detected in the concentrations of certain amino acids as the fish grew in size. Levels of free amino acids did not significantly differ between sexes. Factors effecting variation are discussed.     

Changes in catecholamine metabolism by ascorbic acid deficiency in spontaneously hypertensive rats unable to synthesize ascorbic acid

We have previously reported the establishment of a novel rat strain, SHR-od, with both spontaneous hypertension and a defect of ascorbic acid biosynthesis. Blood pressure in mature SHR-od fed an ascorbic acid-supplemented diet is over 190-200 mmHg, while it decreased to around 120 mmHg at 4-5 weeks after the cessation of ascorbic acid supplementation. With regard to possible mechanisms of blood pressure lowering, we focused on catecholamine synthesis in adrenal glands, since catecholamine is a major factor for blood pressure regulation and ascorbic acid is a co-factor of dopamine beta-hydroxylase (DBH) in catecholamine biosynthesis. Male SHR-od (25-week-old) and normotensive ODS rats with a defect in ascorbic acid biosynthesis (25-week-old) were fed a Funabashi-SP diet with or without ascorbic acid (300 mg/kg diet) for 28 days or 35 days. In SHR-od, systolic blood pressure (191 +/- 6 mmHg) began to decrease from day 21 in the ascorbic acid-deficient group, whereas no significant difference was found in ODS rats. In spite of significant lowering of blood pressure, no significant differences were found in catecholamine levels in serum, adrenal glands and brain on day 28. On day 35, however, urinary excretion of norepinephrine and epinephrine in the ascorbic acid-deficient SHR-od were higher at 490% (P < 0.05) and 460% (P < 0.05) of the respective control. Serum catecholamine concentrations and the adrenal catecholamine content tended to be higher in the ascorbic acid-deficient SHR-od than the control of SHR-od and reached to similar level in ODS rats. The administration of ascorbic acid (intraperitoneal injection, 60 mg ascorbic acid/kg body weight, once a day) to the ascorbic acid-deficient SHR-od restored blood pressure to the range 180-190 mmHg within two days. These findings indicate that ascorbic acid deficiency affects catecholamine metabolism in the adrenal glands of SHR-od in response to blood pressure lowering, suggesting catecholamines are not involved in the mechanism for the remarkable reduction in blood pressure in response to ascorbic acid deficiency.     

Plasma-free amino acid profiling of cervical cancer and cervical intraepithelial neoplasia patients and its application for early detection

In this study, plasma-free amino acid profiles were used to investigate pre-cancerous cervical intraepithelial neoplasia (CIN) and cervical squamous cell carcinoma (CSCC) metabolic signatures in plasma. Additionally, the diagnostic potential of these profiles was assessed, as well as their ability to provide novel insight into CSCC metabolism and systemic effects. Plasma samples from CIN patients (n = 26), CSCC patients (n = 22), and a control healthy group (n = 35) were analyzed by high-performance liquid chromatography, and their spectral profiles were subjected to the t test for statistical significance. Potential metabolic biomarkers were identified using database comparisons that examine the significance of metabolites. Compared with healthy controls, patients with CIN and CSCC demonstrated lower levels of plasma amino acids; plasma levels of arginine and threonine were increased in CIN patients but were decreased in cervical cancer patients. Additionally, the levels of a larger group of amino acids (aspartate, glutamate, asparagine, serine, glycine, histidine, taurine, tyrosine, valine, methionine, lysine, isoleucine, leucine, and phenylalanine) were gradually reduced from CIN to invasive cancer. These findings suggest that plasma-free amino acid profiling has great potential for improving cancer screening and diagnosis and for understanding disease pathogenesis. Plasma-free amino acid profiles may have the potential be used to determine cancer diagnoses in the early stage from a single blood sample and may enhance our understanding of its mechanisms.     

The Nutritional Value of D-Amino Acid in the Chick Nutrition

The nutritional values of 16 D-amino acids in chick growth were studied on the purified diets containing crystalline amino acids as a sole source of nitrogen. Growth rate, feed consumption and nitrogen retention were measured. The nutritional values of D-amino acids were studied by comparing individually with the control groups fed on the diet containing all L-amino acids and negative control groups fed with the diet omitted the corresponding L-isomer. The following results were obtained. Essential amino acids: 1. Equal or almost equal nutritional value to the corresponding L-isomer; methionine, phenylalanine, leucine, proline. 2. Half nutritional value compared with L-isomer; valine. 3. Small nutritional value compared with L-isomer; tryptophan, isoleucine, histidine. 4. No nutritional value; lysine, threonine, arginine. Non-essential amino acid: 1. Equal or almost equal nutritional value to the corresponding L-isomer; serine, tyrosine, cystine. 2. There is a possibility that it has a slight growth retardation effect; alanine. 3. The growth retardation effect was found; aspartic acid.     

Genetic analysis of amino acid content in wheat grain

Complete diallel crosses with five parents of common wheat (Triticum aestivum L.) were conducted to analyse inheritance of 17 amino acid contents by using the genetic model including seed, cytoplasmic, maternal and environment interaction effects on quantitative traits of seeds in cereal crops. The results showed that inheritance of 17 amino acid contents, except tyrosine, was controlled by several genetic systems including seed, cytoplasmic, and maternal effects, and by significant gene × environment interaction effects. Seed-direct additive and maternal effects constituted a major part of genetic effects for lysine, tyrosine, arginine, methionine, and glutamic acid content. Seed-direct additive effect formed main part in inheritance of isoleucine and serine contents. Threonine content was mainly governed by maternal additive effect. The other nine amino acid contents were almost entirely controlled by dominance effects. High general heritability of tyrosine (36.3%), arginine (45.8%), lysine (24.7%) and threonine (21.4%) contents, revealed that it could be effective to improve them by direct selection in progenies from appropriate crosses. Interaction heritability for phenylalanine, proline, and histidine content, which was 36.1%, 39.5% and 25.7%, respectively, was higher than for the other amino acids.     

烧伤狗浆血游离氨基酸的动态变化

烧伤狗浆血游离氨基酸的动态变化黎君友,周幼勤,赖业馥,赵有,伊少杰ＳｅｑｕｅｎｔｉａｌＣｈａｎｇｅｓｉｎＰｌａｓｍａＦｒｅｅＡｍｉｎｏＡｃｉｄＣｏｎｃｅｎｔｒａｔｉｏｎｉｎＢｕｒｎｅｄＤｏｇｓ￥Ｌｉｊｕｎｙｏｎ;Ｚｈｏｕｙｏｕｑｉｎ;Ｌａｉｙｅｆｕ;...     

Substrate specificities of active transport systems for amino acids in vacuolar-membrane vesicles of Saccharomyces cerevisiae. Evidence of seven independent proton/amino acid antiport systems

The substrate specificities of the amino acid transport systems of vacuoles of the yeast, Saccharomyces cerevisiae, were investigated using purified vacuolar-membrane vesicles (Ohsumi, Y., and Anraku, Y. (1981) J. Biol. Chem. 256, 2079-2082). Ten amino acids: arginine, lysine, histidine, phenylalanine, tryptophan, tyrosine, glutamine, asparagine, isoleucine, and leucine, were taken up actively into the vesicles. Kinetic studies indicated the presence of seven independent H+/amino acid antiport systems with narrow substrate specificity, which were all driven by a proton motive force established by ATP hydrolysis. The Kt and Vmax values, and the specific inhibitors for the arginine, arginine-lysine, histidine, phenylalanine-tryptophan, tyrosine, glutamine-asparagine, and isoleucine-leucine transport systems were determined.     

pH Dependence of Histidine Affinity for Blood-Brain Barrier Carrier Transport Systems for Neutral and Cationic Amino Acids

The effects of pH (3.5-7.5) on the brain uptake of histidine by the blood-brain barrier (BBB) carriers for neutral and cationic amino acids were tested, in competition with unlabeled histidine, arginine, or phenylalanine, with the single-pass carotid injection technique. Cationic amino acid ( [14C]arginine) uptake was increasingly inhibited by unlabeled histidine as the pH of the injection solution decreased. In contrast, the inhibitory effect of unlabeled histidine on neutral amino acid ( [14C]phenylalanine) uptake decreased with decreasing pH. Brain uptake indices with varying histidine concentrations indicated that the neutral form of histidine inhibited phenylalanine uptake whereas the cationic form competed with arginine uptake. Since phenylalanine decreased [14C]histidine uptake at all pH values whereas arginine did not, it was concluded that the cationic form of histidine had an affinity for the cationic carrier, but was not transported by it. We propose that the saturable entry of histidine into brain is, under normal physiological circumstances, mediated solely by the carrier for neutral amino acids.     

Inhibition of phenylalanine hydroxylase activity by alpha-methyl tyrosine, a potent inhibitor of tyrosine hydroxylase.

Inhibitors of phenylalanine hydroxylase and tyrosine hydroxylase were used in the assay of phenylalanine hydroxylase in liver and kidney of rats and mice. Parachlorophenylalanine (PCPA), methyl tyrosine methyl ester and dimethyl tyrosine methyl ester showed 5–15% inhibition while α-methyl tyrosine seemed to inhibit phenylalanine hydroxylase to the extent of 95–98% at concentrations of 5 × 10 ⁻⁵M –1 × 10 ⁻⁴M. After a phenylketonuric diet (0.12% PCPA + 3% excess phenylalanine), the liver showed 60% phenylalanine hydroxylase activity and kidney 82% that present in pair-fed normals. Hepatic activity was normal after 8 days refeeding normal diet whereas kidney showed 63% of normal activity. The PCPA-fed animals showed 34% in liver and 38% in kidney as compared to normals; in both cases normal activity was noticed after refeeding. The phenylalanine-fed animals showed activity similar to that seen in phenylketonuric animals. The temporary inducement of phenylketonuria in these animals may be due to a slight change in conformation of the phenylalanine hydroxylase molecule; once the normal diet is resumed, the enzyme reverts back to its active form. This paper also suggests that α-methyl tyrosine when fed in conjunction with the phenylketonuric diet may suppress phenylalanine hydroxylase activity completely in the experimental animals thus yielding normal tyrosine levels as seen in human phenylketonurics.     

Feeding and arginine deficient diets differentially alter free amino acid concentrations of hindlimb muscle in young rats

Summary The objective of these experiments was to examine short- and long-term (7 d) effects of arginine-deficient diets on free amino acid concentrations in hindlimb muscle of rats. In rats fed the control diet containing arginine (+Arg), muscle alanine and methionine concentrations were higher 1 and 2h after feeding compared to food-deprived rats, whereas branched-chain amino acids, arginine and asparagine concentrations were lower postprandially. In Experiment 1, rats were fed an arginine-deficient (–Arg) diet with glutamate (+Glu) substituted for arginine; alanine (+Ala), ornithine (+Orn) or citrulline (+Cit) were substituted for arginine in Experiment 2. In Experiment 1, arginine concentrations decreased in blood but not in muscle. This contrasts with rats fed –Arg/+Ala or –Arg/+Orn diets which had muscle arginine concentrations less than half the concentrations in controls or in rats fed the –Arg/+Cit diet. Muscle essential amino acids in Experiment 2 did not differ by diet, but muscle branched-chain amino acids were elevated relative to controls in the rats fed –Arg/+Ala or –Arg/+Orn diets; however, rats fed the –Arg/+Cit diet had levels similar to the controls. Also, muscle branched-chain amino acids were correlated with glutamine concentrations in both blood and muscle. The measurements in the post-meal period suggest that muscle amino acid concentrations may more closely reflect dietary amino acid patterns than do blood amino concentrations.Abbreviations BCAA branched-chain amino acids - BCKADH branched-chain ketoacid dehydrogenase - EAA essential amino acids - LNAA large neutral amino acids - NEAA nonessential amino acids - PDV portal-drained viscera - SELSM standard error of least squares means - SSA 5-sulfosalicylic acid - TAA total amino acids Mention of a trade name, proprietary product or specific equipment does not constitute a guarantee by the US Department of Agriculture and does not imply its approval to the exclusion of other products that may be suitable.