Disordered branched chain amino acid catabolism in pancreatic islets is associated with postprandial hypersecretion of glucagon in diabetic mice

Dysregulation of glucagon is associated with the pathophysiology of type 2 diabetes. We previously reported that postprandial hyperglucagonemia is more obvious than fasting hyperglucagonemia in type 2 diabetes patients. However, which nutrient stimulates glucagon secretion in the diabetic state and the underlying mechanism after nutrient intake are unclear. To answer these questions, we measured plasma glucagon levels in diabetic mice after oral administration of various nutrients. The effects of nutrients on glucagon secretion were assessed using islets isolated from diabetic mice and palmitate-treated islets. In addition, we analyzed the expression levels of branched chain amino acid (BCAA) catabolism-related enzymes and their metabolites in diabetic islets. We found that protein, but not carbohydrate or lipid, increased plasma glucagon levels in diabetic mice. Among amino acids, BCAAs, but not the other essential or nonessential amino acids, increased plasma glucagon levels. BCAAs also directly increased the intracellular calcium concentration in α cells. When BCAAs transport was suppressed by an inhibitor of system L-amino acid transporters, glucagon secretion was reduced even in the presence of BCAAs. We also found that the expression levels of BCAA catabolism-related enzymes and their metabolite contents were altered in diabetic islets and palmitate-treated islets compared to control islets, indicating disordered BCAA catabolism in diabetic islets. Furthermore, BCKDK inhibitor BT2 suppressed BCAA-induced hypersecretion of glucagon in diabetic islets and palmitate-treated islets. Taken together, postprandial hypersecretion of glucagon in the diabetic state is attributable to disordered BCAA catabolism in pancreatic islet cells.     

CORRELATION OF PLASMA AND BRAIN AMINO ACID AND PUTATIVE NEUROTRANSMITTER ALTERATIONS DURING ACUTE HEPATIC COMA IN THE RAT

During acute hepatic coma following two-stage hepatic devascularization in the rat, profound changes occurred in plasma and whole-brain amino acids and putative neurotransmitters. Brain ammonia, glutamine and GABA were increased, aspartate was decreased, while glutamate was unchanged. An increase in brain tryptophan was accompanied by a similar increase in plasma unbound tryptophan but decreased plasma total tryptophan. These changes occurred in the presence of high plasma levels of the other neutral amino acids, including the branched chain amino acids. Plasma insulin was unchanged while glucagon levels rose, resulting in a decreased insulin to glucagon ratio. These results suggest that while plasma unbound tryptophan may influence brain tryptophan levels, altered plasma concentrations of neutral amino acids which compete with tryptophan for transport into the brain do not contribute to the increase in brain tryptophan observed during acute hepatic coma.     

Deleterious mutation V369M in the mouse GCGR gene causes abnormal plasma amino acid levels indicative of a possible liver–α-cell axis

Glucagon plays an important role in glucose homeostasis and amino acid metabolism. It regulates plasma amino acid levels which in turn modulate glucagon secretion from the pancreatic α-cell, thereby establishing a liver–α-cell axis described recently. We reported previously that the knock-in mice bearing homozygous V369M substitution (equivalent to a naturally occurring mutation V368M in the human glucagon receptor, GCGR) led to hypoglycemia with improved glucose tolerance. They also exhibited hyperglucagonemia, pancreas enlargement and α-cell hyperplasia. Here, we investigated the effect of V369M/V368M mutation on glucagon-mediated amino acid metabolism. It was found that Gcgr^V369M+/+ mice displayed increased plasma amino acid levels in general, but significant accumulation of the ketogenic/glucogenic amino acids was observed in animals fed with a high-fat diet (HFD), resulting in deleterious metabolic consequence characteristic of α-cell proliferation and hyperglucagonemia.     

Plasma amino acids of lean and obese Zucker rats subjected to a cafeteria diet after weaning.

Plasma amino acids of Zucker obese (fa/fa) and lean (Fa/?) rats fed either a reference nonpurified pellet or a cafeteria diet have been studied from 30 to 60 days after birth. Obese rats showed higher plasma branched chain amino acid levels but similar total amino acids, urea and glucose concentrations. The ingestion of a cafeteria diet induced higher levels in many amino acids, as well as in the composite figure in lean rats, but failed to alter total 2-amino nitrogen concentrations in obese rats, despite high levels in several non-essential amino acids and lower values in essential amino acids; urea levels were much lower in rats fed the cafeteria diet. The results are consistent with an impairment of amino acid nitrogen elimination via urea cycle in cafeteria diet-fed rats. This is independent of the hyperinsulinemia-driven plasma accumulation of several essential amino acids induced by genetic obesity. The effects were, then additive.     

Accumulation of large neutral amino acids in the brain of sparse-fur mice at hyperammonemic state

Sparse-fur mice which are deficient in ornithine transcarbamylase, the second-step enzyme in the urea cycle, were examined for hyperammonemia and its relationship with encephalopathy. We compared amino acid concentrations in the serum and brain of spf mice with those of control mice. Unlike hepatic encephalopathy we could not find marked amino acid changes in the serum of spf mice besides low levels of citrulline and arginine. But in the brain of spf mice, glutamine was increased strikingly during hyperammonemia, and a concomitant accumulation of large neutral amino acids such as tyrosine, phenylalanine, methionine, and histidine was observed. The accumulation of these large neutral amino acids in the brain was not influenced by 24-hr fasting which caused increases in branched chain amino acids in the serum. From these results, we conclude that the accumulation of the large neutral amino acid in the brain of hyperammonemic state is caused by uptake of ammonia in the brain and the subsequent accumulation of glutamine, but is not influenced by a decreased ratio of branched chain amino acids to aromatic amino acids in the serum.     

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.     

肝硬化与肝癌患者血浆游离氨基酸水平分析

采用高效液相色谱法分析了２５例肝硬化和１５例肝癌患者空腹血浆游离氨基酸水平的变化。结果表明,二者支链氨基酸（ＢＣＡＡ）如Ｖａｌ、Ｉｌｅ呈下降趋势,而芳香族氨基酸（ＡＡＡ）如Ｔｙｒ、Ｐｈｅ则呈上升趋势,ＢＣＡＡ／ＡＡＡ分子比值下降。丙氨酸（Ａｌａ）、蛋氨酸（Ｍｅｔ）、谷氨酰胺（Ｇｌｎ）及天门冬氨酸（Ａｓｐ）明显上升。其变化趋势二者存在差别。     

FREE AMINO ACIDS OF FETAL BRAIN

Abstract— Injection of each of the branched chain amino acids into maternal rats from the 14th to 21st day of pregnancy resulted in increased levels of these compounds in fetal serum. Furthermore, these amino acids were found in high concentration in fetal brain. The elevated levels of the branched chain amino acids were associated with a disturbance of the free amino acid pool in the brain. Isoleucine appeared to have the greatest effect in depressing the other amino acids.     

Relative importance of physiological precursors for ketogenesis in the nutritional homeostasis of the development of the embryonic chick

This paper investigates the relative importances of specific amino acids, and, in particular, branched chain amino acids and their keto derivatives as possible ketogenic precursors in suspensions of liver cells isolated from chick embryos. Addition of the branched chain keto acids stimulated ketogenesis. The order of potency was α-ketoisocaproic acid >α-ketoisovaleric acid >DL- α-keto-β-methyl-n-valeric acid. The relative order of effectiveness for branched chain keto acids was maintained at all comparable concentrations, and in each case maximum rates were observed with concentrations of 1–2 mM. In contrast to the stimulation of ketogenesis by their keto derivatives, branched chain amino acids were ineffective as precursors for ketogenesis. Of the other amino acids (utilised at concentrations present in chick embryo plasma) only Tyr, Lys, Phe and Arg produced significant increases in ketone body formation above the endogenous rate. At these physiological concentrations, the effectiveness of the amino acids were in the order of Tyr > Lys = Phe > Arg. The interactions between three groups of ketogenic precursor (fatty acids, amino acids and keto amino acids, all at physiological concentrations), produced rates of ketogenesis that were purely additive. These results indicate that high concentrations of hydroxybutyrate and acetoacetate found in plasma of developing chick embryos may arise from hepatic metabolism of several distinct precursors. The relative importance of each category of precursor may vary with the precise developmental status of animals.     

Branched chain amino acid aminotransferase isoenzymes of Pseudomonas cepacia

Pseudomonas cepacia grew rapidly using a mixture of all three branched chain amino acids as carbon source, but failed to use individual branched chain amino acids as sole carbon source. Extracts of bacteria grown on branched chain amino acids had between 2- and 3-fold higher levels of -ketoglutarate-dependent branched chain amino acid aminotransferase activity than extracts of glucose-grown bacteria. The increase in enzyme activity was due to the presence of a second aminotransferase not detected in extracts of glucose-grown bacteria. The enzyme, which presumably plays a role in branched chain amino acid degradation, had an apparent molecular weight (mol. wt.) of 75,000. The other aminotransferase was formed constitutively and apparently functions in synthesis of branched chain amino acids. It was more stable than the 75,000 mol.wt. enzyme, and was purified to homogeneity and found to be a 180,000 mol.wt. oligomer containing 6 subunits of approximately 30,000 mol.wt. Antiserum prepared against the purified enzyme inhibited its activity but failed to influence the activity of the 75,000 mol.wt. aminotransferase, suggesting that the two isoenzymes are encoded by different genes.     

Tentative identification of the toxohormones of cancer cachexia: roles of vasopressin, prostaglandin E2 and cachectin-TNF

A proposed role for the hypothesized toxohormone/s (Vasopressin, Prostaglandin E2 and TNF-Cachectin) in the development and maintenance of cancer cachexia was investigated in rats bearing the Walker 256 carcinosarcoma. Elevated levels of arginine vasopressin and prostaglandin E2 in the plasma and urine were associated with reduced hepatic ketogenesis, fatty acid oxidation and increased fatty acid esterification. The oxidation of branched chain amino acids by the muscle tissue of tumour bearing rats was increased and attributed to the enhanced activity of muscle branched chain keto-acid dehydrogenase. Concerted actions by the triology of factors (AVP, PGE2, Cachectin-TNF) are proposed to instigate a sequence of reactivities that lead to the clinical symptoms of muscle and adipose tissue wasting, together with the negative nitrogen balance characteristic of the cachectic state.     

Branched Chain Amino Acid Metabolism in the Biosynthesis of Lycopersicon pennellii Glucose Esters

Lycopersicon pennellii Corr. (D'Arcy) an insect-resistant, wild tomato possesses high densities of glandular trichomes which exude a mixture of 2,3,4-tri-O-acylated glucose esters that function as a physical impediment and feeding deterrent to small arthropod pests. The acyl moieties are branched C₄ and C₅ acids, and branched and straight chain C₁₀, C₁₁, and C₁₂ acids. The structure of the branched acyl constituents suggests that the branched chain amino acid biosynthetic pathway participates in their biosynthesis. [¹⁴C]Valine and deuterated branched chain amino acids (and their oxo-acid derivatives) were incorporated into branched C₄ and C₅ acid groups of glucose esters by a process of transamination, oxidative decarboxylation and subsequent acylation. C₄ and C₅ branched acids were elongated by two carbon units to produce the branched C₁₀-C₁₂ groups. Norvaline, norleucine, allylglycine, and methionine also were processed into acyl moieties and secreted from the trichomes as glucose esters. Changes in the acyl composition of the glucose esters following sulfonylurea herbicide administration support the participation of acetohydroxyacid synthetase and the other enzymes of branched amino acid biosynthesis in the production of glucose esters.     

THE EFFECT OF HIGH CONCENTRATIONS OF HISTIDINE ON THE LEVEL OF OTHER AMINO ACIDS IN PLASMA AND BRAIN OF THE MATURE RAT

—Changes in plasma and brain amino acids have been observed in adult rats 1 h after intraperitoneal injections of histidine and in others maintained on high histidine diets for 8 days. In the injection studies the compounds most consistently affected were the aromatic and branched chain amino acids and methionine. Reductions in their concentrations in the brain were explained by a competition with histidine for uptake into the tissue. There was little change in plasma amino acid levels. In the animals fed the highest concentration of histidine there was a generalized increase in brain, and a reduction in plasma, amino acid concentrations. A decrease in protein synthesis is postulated to explain this effect in brain.     

Infusion of amino acids decreases the hyperglycaemic effect of per- and postoperative glucose infusion: an experimental study in the rabbit

The effects on blood glucose concentration of 10% glucose with amino acid solution at low (18%) and high (25%) concentration of branched chain amino acids were studied, two days after laparotomy in fasted rabbits. During the whole study period, saline infusion was associated with normoglycaemia. Among the other infusion combinations peroperative infusion of amino acid solution high in branched chain amino acids with 10% glucose was the least hyperglycaemic. An amino acid solution low in branched chain amino acids with 10% glucose had the lowest hyperglycaemic effect 24 hours postoperatively. After 48 hours an infusion of 10% glucose produced the weakest hyperglycaemia. In preoperatively and 24 hours postoperatively 10% glucose was more hyperglycaemic than 10% glucose with the two amino acid solutions. After 24 and 48 hours, infusion of 10% glucose with amino acids high in branched chain amino acids was more hyperglycaemic than 10% glucose with amino acids low in branched chain amino acids.     

复方高支链氨基酸对肝硬化大鼠肝功能及营养状况的影响

将SD雄性大鼠用四氯化碳处理建立肝硬化大鼠模型,并随机分为A、B、C三组,A组大鼠给予静脉输注生理盐水,B组、C组大鼠分别给予输注等量的普通氨基酸注射液和复方高支链氨基酸注射液,分别于实验第0d、第14d测定大鼠体质量、肝功能指标及营养学指标水平。实验结束后,B、C两组大鼠体质量明显增加,与A组相比,B、C两组大鼠肝功能各指标水平显著降低,血清蛋白水平显著升高,且C组相比,B组大鼠肝功能水平与血清蛋白水平改善作用更为明显(p<0.05)。说明复方高支链氨基酸能改善肝硬化大鼠的肝功能指标,抑制血浆蛋白分解,有效控制肝硬化病症的进一步恶化。     

Beyond lipids, pharmacological PPARalpha activation has important effects on amino acid metabolism as studied in the rat

PPARalpha agonists have been characterized largely in terms of their effects on lipids and glucose metabolism, whereas little has been reported about effects on amino acid metabolism. We studied responses to the PPARalpha agonist WY 14,643 (30 micromol x kg(-1) x day(-1) for 4 wk) in rats fed a saturated fat diet. Plasma and urine were analyzed with proton NMR. Plasma amino acids were measured using HPLC, and hepatic gene expression was assessed with DNA arrays. The high-fat diet elevated plasma levels of insulin and triglycerides (TG), and WY 14,643 treatment ameliorated this insulin resistance and dyslipidemia, lowering plasma insulin and TG levels. In addition, treatment decreased body weight gain, without altering cumulative food intake, and increased liver mass. WY 14,643 increased plasma levels of 12 of 22 amino acids, including glucogenic and some ketogenic amino acids, whereas arginine was significantly decreased. There was no alteration in branched-chain amino acid levels. Compared with the fat-fed control animals, WY 14,643-treated animals had raised plasma urea and ammonia levels as well as raised urine levels of N-methylnicotinamide and dimethylglycine. WY 14,643 induced changes in a number of key genes involved in amino acid metabolism in addition to expected effects on hepatic genes involved in lipid catabolism and ketone body formation. In conclusion, the present results suggest that, in rodents, effects of pharmacological PPARalpha activation extend beyond control of lipid metabolism to include important effects on whole body amino acid mobilization and hepatic amino acid metabolism.     

Effects of intravenous injection of butyrate, valerate and their isomers on endocrine pancreatic responses in conscious sheep (Ovis aries)

1. The effects of intravenous injection of n-butyrate, iso-butyrate, n-valerate and iso-valerate on insulin and glucagon secretion was examined in conscious sheep. 2. Each sodium salt of the short chain fatty acids increased plasma insulin and glucagon concentrations in a dose-dependent manner (312-1250 mumol/kg body wt). 3. Both butyrate and valerate isomers with branched carbon chains had larger insulin releasing activity than isomers with straight carbon chains. 4. The glucagon responses to butyrate or valerate did not differ between the isomers with straight carbon chains and those with branched carbon chains. 5. Our results suggest that the receptive mechanism to short chain fatty acids, which may involve the nervous system, differs between the A cell and the B cell in sheep in vivo.     

The effect of insulin deficiency, dietary protein intake, and plasma amino acid concentrations on brain amino acid levels in rats

The effect of diabetes (streptozotocin, 65 mg/kg ip), dietary protein intake (15-60%), and plasma amino acid concentrations on brain large neutral amino acid levels in rats was examined. After 20 days, the plasma concentrations of methionine and the branched chain amino acids (BCAA), valine, isoleucine, and leucine were increased in diabetic rats. In brain tissue, methionine and valine levels were increased but threonine, tyrosine, and tryptophan concentrations were depressed. Increased protein consumption promoted a diabetic-like plasma amino acid pattern in normal rats while enhancing that of diabetic animals. However, with the exception of threonine, glycine, valine, and tyrosine, there was little effect on brain amino acid levels. A good association was found between the calculated brain influx rate and the actual brain concentration of threonine, methionine, tyrosine, and tryptophan in diabetic animals. There was no correlation, however, between brain influx rate and brain BCAA levels. Thus, the brain amino acid pattern in diabetes represents the combined effects of insulin insufficiency and composition of the diet ingested on plasma amino acid levels as well as metabolic adaptation within the brain itself.     

Influence of glucogenic amino acids on the hepatic metabolism of threonine.

The supplementation of a low-protein diet with L-threonine leads to a marked accumulation of threonine in plasma and liver, whereas increasing dietary protein generally leads to an induction of threonine dehydratase in the liver, hence depressed availability for extrasplanchnic tissues. The aim of the present study was, thus, to further investigate the factors which control the utilization of threonine by the liver. Increasing the dietary supply of threonine led to parallel increases in the afferent and hepatic concentrations and in the rate of utilization by the liver; however, the fractional extraction tended to decrease. It appears that the addition of a mixture of glucogenic amino acids to the diet prevented the accumulation of threonine in plasma induced by exogenous threonine. The glucogenic amino acids increased the fractional hepatic uptake of threonine, and counteracted its accumulation in the liver. These effects reflect the fact that the glucogenic amino acids elicited a potent induction of the threonine dehydratase, whereas threonine alone was uneffective. Our results suggest that, besides the well-established effect of glucogenic conditions, the availability of some glucogenic amino acids is an important factor in the control of threonine catabolism.     

Effect of cold-temperature exposure and acclimation on amino acid pool changes and enzyme activities of rat brown adipose tissue

The amino acid pool composition and its concentration ratios with respect to blood and plasma, as well as the activities of alanine, aspartate and branched chain amino acid transaminases, glutamine synthetase, adenylate deaminase and glutamate dehydrogenase have been studied in the interscapular brown adipose tissue of control, 12-h cold-exposed and 15-day cold-acclimated rats. Cold temperature affected the amino acid metabolism and pool composition more intensely after 15 days than after 12-h cold-exposure, even though the patterns of change were very similar in both groups. Cold temperatures induced a decrease in glutamine and an increase in glutamate concentration in the tissue. This probably increased the metabolism of branched chain amino acids and caused a decrease in adenylate deaminase activity. It also seemed to increase alanine utilization. We concluded that amino acid metabolism in brown adipose tissue is enhanced by cold temperature acclimation.