Supplementation with branched-chain amino acids to a low-protein diet regulates intestinal expression of amino acid and peptide transporters in weanling pigs

This study determined the effects of dietary branched-chain amino acids (AA) (BCAA) on growth performance, expression of jejunal AA and peptide transporters, and the colonic microflora of weanling piglets fed a low-protein (LP) diet. One hundred and eight Large White × Landrace × Duroc piglets (weaned at 28 days of age) were fed a normal protein diet (NP, 20.9 % crude protein), an LP diet (LP, 17.1 % crude protein), or an LP diet supplemented with BCAA (LP + BCAA, 17.9 % crude protein) for 14 days. Dietary protein restriction reduced piglet growth performance and small-intestinal villous height, which were restored by BCAA supplementation to the LP diet to values for the NP diet. Serum concentrations of BCAA were reduced in piglets fed the LP diet while those in piglets fed the LP + BCAA diet were similar to values for the NP group. mRNA levels for Na⁺-neutral AA exchanger-2, cationic AA transporter-1, b^0,+ AA transporter, and 4F2 heavy chain were more abundant in piglets fed the LP + BCAA diet than the LP diet. However, mRNA and protein levels for peptide transporter-1 were lower in piglets fed the LP + BCAA diet as compared to the LP diet. The colonic microflora did not differ among the three groups of pigs. In conclusion, growth performance, intestinal development, and intestinal expression of AA transporters in weanling piglets are enhanced by BCAA supplementation to LP diets. Our findings provide a new molecular basis for further understanding of BCAA as functional AA in animal nutrition.     

Effect of diet and essential amino acids gavage on young rat amino acid metabolism enzymes

• 1.1. The effects of a high-fat, high-energy diet and essential plus semi-essential amino acid gavage on pup rats have been studied (60–65 animals).
• 2.2. The activities of alanine transaminase, adenylate deaminase, glutamine synthetase and serine dehydratase have been tested in liver and muscle.
• 3.3. Plasma was used for the estimation of proteins, urea, amino acids, glucose, lactate, 3-hydroxy-butyrate and acetoacetate.
• 4.4. Liver and muscle glutamine synthetase activities are increased by diet and gavage administered. Hepatic serine dehydratase is inhibited by a cafeteria diet but activated by amino acid gavage. Adenylate deaminase is inhibited by diet and gavage in the liver, but gavage does not affect this enzyme activity in muscle. Liver alanine transaminase is increased by the diet; in the muscle, cafeteria diet and amino acid gavage showed the highest values for this enzyme.
• 5.5. In the plasma, the increase in lactate produced by the diet is inhibited by the amino acids provided. Cafeteria-fed pups showed lower urea levels and higher 3-hydroxybutyrate concentrations in the plasma.
• 6.6. Intracellular glucose is diminished by cafeteria diet. In contrast, the blood cell amino acid concentration increases with diet and gavage supplied.

     

Effect of a diet containing calcium pantothenate on urinary vitamin excretion and on the liver and kidney total pantothenic acid level in rats

Four groups of five adult rats weighing 310 g received during 20 days a diet containing 0, 1.68, 16.8 or 168 mumol of pantothenic acid per kg of diet. The daily urinary vitamin excretion was, in nmol per day: 32 +/- 8, 32 +/- 4, 180 +/- 23 and 2,100 +/- 91, respectively (mean +/- SEM). Liver and kidney pantothenic acid content was the same in all groups, in nmol per g of fresh tissue: 300 +/- 36 and 190 +/- 6, respectively (mean +/- SEM, n = 20).     

Quantitative contributions of diet and liver synthesis to docosahexaenoic acid homeostasis

Dietary requirements for maintaining brain and heart docosahexaenoic acid (DHA, 22:6n-3) homeostasis are not agreed on, in part because rates of liver DHA synthesis from circulating α-linolenic acid (α-LNA, 18:3n-3) have not been quantified. These rates can be estimated using intravenous radiotracer- or heavy isotope-labeled α-LNA infusion. In adult unanesthetized male rats, such infusion shows that liver synthesis–secretion rates of DHA from α-LNA markedly exceed brain and heart DHA synthesis rates and the brain DHA consumption rate, and that liver but not heart or brain synthesis is upregulated when dietary n-3 PUFA content is reduced. These rate differences reflect much higher expression of DHA-synthesizing enzymes in liver, and upregulation of liver but not heart or brain enzyme expression by reduced dietary n-3 PUFA content. A noninvasive intravenous [U?¹³C]α-LNA infusion method that produces steady-state liver tracer metabolism gives exact liver DHA synthesis–secretion rates and could be extended for human studies.     

Effect of glucosamine on amino acid transport and intensity of protein synthesis in liver cells in an inflammation model

The effect of glucosamine on the transport of amino acids and protein synthesis in hepatocytes when modelling inflammation was studied. It was found the considerable decrease of the amino acid transport via hepatocyte membranes. The protein synthesis intensity was displayed as also significantly reduced. Administration of glucosamine to the rats normalized both studied processes.     

The effect on macromolecular synthesis of amino acid deprivation of hamster kidney cells

Since asparagine has been found to inhibit growth of some tumors and to inhibit or delay mitotic activity in other cells, we have studied the effect of asparaginase and of deprivation of some essential amino acids (Arg, Asn, Leu, Ile, Trp) on nucleic acid and protein synthesis in an asparagine-requiring strain of BHK/21 cells. We find that: (1) there is no essential difference in the pattern of synthesis following deprivation of any of the amino acids we tested; (2) that the effect of asparaginase is similar to that of amino acid deprivation; (3) that RNA synthesis is inhibited more rapidly than DNA or protein synthesis; (4) that after 10 hr of amino acid starvation, DNA synthesis is almost totally (reversibly) inhibited while RAN synthesis continues at about 30-50% and protein at about 100% of the initial value.     

Thermophilic anaerobic amino acid degradation: deamination rates and end-product formation

Anaerobic thermophilic degradation of several amino acids was studied in batch cultures using an inoculum from a steady-state semicontinuous enrichment culture. Experiments were done in the presence and absence of methanogenesis and known electron acceptors in the Stickland reaction. Methanogenesis was found to be crucial for the degradation of amino acids known to be oxidatively deaminated (leucine, valine and alanine). Other amino acids (serine, threonine, cysteine and methionine) were degraded under both methanogenic and non-methanogenic conditions. Degradation rates for these four amino acids were 1.3 to 2.2 times higher in cases where methanogenesis was active. The degradation rates of serine, threonine, cysteine and methionine were about twice as high as the rates of leucine, valine and alanine under methanogenic conditions. Inclusion of different electron acceptors, known to work in the Stickland reaction, did not enhance the degradation rates of any amino acid used nor did they alter the degradation patterns. Glycine was oxidatively deaminated to acetate, carbon dioxide, hydrogen and ammonium.     

Non-enzymatic PLP-dependent oxidative deamination of amino acids induces higher alcohol synthesis

Pyridoxal phosphate (PLP) is an organic cofactor found in all transaminase enzymes. In this study PLP was used to replace the enzymatic deamination step in the Ehrlich pathway, for the oxidative conversion of amino acids into 2-keto acids. PLP functions in an enzymeindependent manner. It was further used in the synthesis of higher alcohols through a sequential enzymatic reduction in vitro and in vivo. PLP-dependent oxidation was investigated against five representative amino acids: valine, leucine, isoleucine, norvaline, and phenylalanine. In vitro amino acid oxidation resulted in approximately 45 ~ 75% [mole/mole] of each 2-keto acid conversion and in vitro ammonia formation was less than 2-keto acid formation, with 20% of conversion yields. Whole cell E. coli expressing reduction enzymes KivD/ADH with both single amino acid and amino acid mixture (4% yeast extract) gave the highest yield (30 ~ 55%) in the presence of the PLP-Cu complex and following enzymatic reactions.