Effect of ammonium acetate-induced hyperammonemia on metabolism of guanidino compounds.

Guanidino compounds are synthesized from arginine in various tissues such as liver, kidney, brain, and skeletal muscle. Guanidino compounds such as arginine and creatine play an important role in nitrogen metabolism, whereas other guanidino compounds such as guanidinosuccinic acid and alpha-N-acetylarginine are known toxins. In order to understand the changes in the metabolism of guanidino compounds during ammonia toxicity, we investigated the effect of hyperammonemia induced by an ammonium acetate injection on the levels of guanidino compounds in plasma, liver, kidney, and brain of rats. Control animals were injected with an equal volume of saline. Blood and tissues were removed 1 h following ammonium acetate or saline injection and guanidino compounds were analyzed by high-performance liquid chromatography. Plasma and kidney levels of guanidinosuccinic acid were significantly elevated in rats challenged with ammonium acetate. Brain alpha-N-acetylarginine levels were also significantly higher in rats injected with ammonium acetate as compared to those in controls. Our results suggest that guanidinosuccinic acid and alpha-N-acetylarginine may play an important role in hyperammonemia.     

Effect of Urease-Induced Hyperammonemia on Metabolism of Guanidino Compounds

We previously reported that guanidino compounds produced by the catabolism of arginine play an important role in the pathophysiology of acute hyperammonemia. In order to understand the metabolism of guanidino compounds during sustained hyperammonemia, we investigated the effect of intraperitoneal urease injection (800 IU/kg) on the levels of guanidino compounds in blood, liver, kidney, and brain of rats. Control rats received an equal volume of saline. Eight hours following injection, rats were sacrificed and blood and tissues were removed. Ammonia and urea were determined by enzymatic and colorimetric assays, respectively. Guanidino compounds were analyzed by high-performance liquid chromatography. Blood and tissue ammonia were significantly increased and urea decreased in urease-treated animals. Blood and kidney arginine levels were significantly decreased although hepatic arginine was increased following urease injection. Elevated hepatic arginine may be due to the rapid conversion of urea to ammonia by urease and the development of a futile urea cycle. Catabolites produced by the transamidination of arginine were significantly decreased in the blood, liver, kidney, and brain of urease-treated rats, whereas acetylation of hepatic arginine to α-N-acetylarginine was increased. Blood and tissue guanidinosuccinic acid levels were not elevated during urease induced hyperammonemia, supporting the hypothesis that urea is a precursor for the synthesis of guanidinosuccinic acid.     

Effect of hyperammonemia on brain amino acids in young and adult ferrets

Summary Effects of arginine deficiency and hyperammonemia on the brain concentrations of amino acids and urea cycle enzyme activities in young and adult ferrets were investigated. Only young ferrets developed hyperammonemia and encephalopathy immediately after consuming the arginine-free diet. Brain ornithine and citrulline concentrations in young ferrets fed arginine containing diet were significantly lower than those in adult ferrets. Compared to rats and other animals, young and adult ferrets had lower concentrations of brain glutamic acid and glutamine. Unlike in other species, brain glutamine was not elevated in young, hyperammonemic ferrets. Brain arginase and glutamate dehydrogenase activities were significantly increased in young ferrets fed arginine-free diet. Young ferrets provide a useful animal model for investigating the neurotoxicity of acute hyperammonemia.Abbreviations ACD Arginine-containing diet - AFD Arginine-free diet This work was presented, in part, at the annual meeting of the Midwest Society for Pediatric Research, Chicago, IL, 1991.     

Effects of arginine-free diet on urea cycle enzymes in young and adult ferrets

Young ferrets develop hyperammonemia soon after eating an arginine-free diet, whereas adult ferrets do not develop hyperammonemia after an identical treatment. Earlier reports indicate that young or adult rats do not develop hyperammonemia and encephalopathy after a single meal of an arginine-free diet. The effects of a single feeding of an arginine-free diet on the urea cycle enzyme activities in the liver of young and adult ferrets is reported. Ornithine carbamyl transferase, carbamyl phosphate synthetase and ornithine aminotransferase activities in the livers of adult ferrets were significantly higher than those in the livers of young ferrets. A single meal of an arginine-free diet did not alter the urea cycle enzyme activities in the liver of young or adult ferrets. The levels of urea cycle enzymes in the liver and kidney of young ferrets were comparable to those in rat liver and kidney. The results suggest that the hyperammonemia observed in young ferrets following a single meal of an arginine-free diet may not be due to the deficiency of enzyme activities.     

Bitterness Reduction of Citrus Fruits by β-Cyclodextrin

The levels of free amino acid, ammonia nitrogen and guanidino compounds were examined in renal failure rats induced by adenine. Among the essential amino acids in the serum, the marked reduction of lysine, valine, leucine and isoleucine was confirmed in the adenine-fed group as compared with the control group. Tyrosine and ornithine were also significantly reduced in the adenine-fed rats, while glycine, arginine and aspartic acid were significantly elevated. The urinary excretion of leucine, isoleucine and non-essential amino acids (glutamic acid, histidine, aspartic acid, citrulline, tyrosine, ornithine) was found to be high. On the other hand, adenine administered orally caused hyperammonemia. Furthermore, the results of the present study show that intake of adenine increased extraordinarily the level of guanidinosuccinic acid and methylguanidine in the serum, while the value of serum guanidinosuccinic acid and methylguanidine in rats fed on a control diet was not detectable.     

Fluorometrical Analysis of Guanidino Compounds in Human Cerebrospinal Fluid

Abstract: Guanidino compounds in CSF of 57 human subjects were determined fluorometrically after reaction with phenanthrenequinone in alkali solution, using HPLC. Creatinine (65.2 ± 13.4 nmol/ml), arginine (24.7 ± 6.4 nmol/ml), and homoarginine (0.7 ± 0.3 nmol/ml) were found in all subjects. Trace amounts of guanidinosuccinic acid and guanidinoacetic acid were detected in some of the subjects. Brain guanidino compounds, taurocyamine, N -acetylarginine, and methylguanidine were not detected in CSF.     

Arginine deficiency, hyperammonemia and Reye's syndrome in ferrets

Young male ferrets developed hyperammonemia and encephalopathy shortly after eating a diet lacking in arginine. The dietary supplementation of arginine or intraperitoneal injection of ornithine prevented hyperammonemia and shortened the duration of encephalopathy. Therefore, young ferrets were assumed to be unable to meet their ornithine needs from sources other than arginine. Adult ferrets did not develop hyperammonemia and encephalopathy after eating arginine-free diet. Because young ferrets are also susceptible to human influenza infections, they were further tested as animal model of Reye's syndrome. Reye's syndrome is a serious childhood disorder that develops following influenza infections and is characterized in part by an encephalopathy, hyperammonemia and elevated serum transaminases. In young ferrets, concurrent administration of aspirin with human influenza inoculation and an arginine-free diet produced symptoms similar to those seen in humans with Reye's syndrome. The ferret model appears to be useful for studying the roles of various etiologic agents and their interactions in producing Reye's syndrome-like disorders. The ammonia metabolism in ferrets is reviewed and the ferret model for Reye's syndrome and its applications for the better understanding of this disorder in humans are discussed.     

Biochemistry and neurotoxicology of guanidino compounds. History and recent advances

Guanidino compounds are known to have important biological roles, such as the participation of arginine in ureagenesis, and of creatine in muscular contraction. On the other hand, the high toxicity of guanidino compounds, such as methylguanidine and guanidine, has been under study for quite a long time in the biochemical as well as clinical fields. In this review, the author summarizes the experimental results of neurophysiological and neurochemical studies on guanidino compound-induced seizures, conducted by his colleagues since 1966, and introduces several topics arising from their recent investigations on guanidino compounds and seizure mechanism, i.e., (1) alpha-guanidino-glutaric acid in the cobalt epileptic focus and its convulsive activity; (2) guanidino-ethanesulfonic acid and epilepsy; (3) delta-guanidinovaleric acid, and endogenous and specific GABA receptor antagonist; and (4) guanidino compounds as radical generators.     

A role for guanidino compounds in the brain

Guanidino compounds of guanidinoethanesulfonic acid, guanidinoacetic acid, guanidinosuccinic acid, N-acetylarginine, -guanidinopropionic acid, creatinine, -guanidinobutyric acid, arginine, guanidine, methylguanidine, homoarginine and -guanidinoglutaric acid are present in the mammalian brain. These guanidino compounds except for arginine and guanidine induce seizures and convulsions in rat, rabbit and cat by intracisternal injection.Hirudonine, audonine, -keto--guanidinovaleric acid, N,N-dibenzoylguanidine and phenylethylguanidine are also convulsants. Levels of creatinine, guanidinoethanesulfonic acid, creatinine, guanidinoacetic acid and methylguanidine in animal brain were changed at pre- and during convulsions induced by pentylentetrazol, amygdala kindling, iron-induced epileptogenesis and so on. These convulsions are thought to be due to depressed functions of serotonergic neurons and accumulated free radicals.Arginine is a substrate of nitric oxide production by nitric oxide synthase. -Guanidinoglutaric acid is a generator of superoxide, hydroxyl radicals and nitric oxide, and induced C6 glial cell death. On the other hand, aminoguanidine is a free radical scavenger. Energy formation by creatine metabolism may inhibit apoptosis induced by pathogenesis. Free radical generation/reaction and energy generation by guanidino compounds must be important key role in the brain.     

Plasma guanidino compounds are altered by oral creatine supplementation in healthy humans.

Although creatine is one of the most widely used nutritional supplements for athletes as well as for patients with neuromuscular disorders, the effects of oral creatine supplementation on endogenous creatine synthesis in humans remains largely unexplored. The aim of the present study was to investigate the metabolic consequences of a frequently used, long-term creatine ingestion protocol on the circulating creatine synthesis precursor molecules, guanidinoacetate and arginine, and their related guanidino compounds. For this purpose, 16 healthy young volunteers were randomly divided to ingest in a double-blind fashion either creatine monohydrate or placebo (maltodextrine) at a dosage of 20 g/day for the first week (loading phase) and 5 g/day for 19 subsequent wk (maintenance phase). Fasting plasma samples were taken at baseline and at 1, 10, and 20 wk of supplementation, and guanidino compounds were determined. Plasma guanidinoacetate levels were reduced by 50% after creatine loading and remained approximately 30% reduced throughout the maintenance phase. Several circulating guanidino compound levels were significantly altered after creatine loading but not during the maintenance phase: homoarginine (+35%), alpha-keto-delta-guanidinovaleric acid (+45%), and argininic acid (+75%) were increased, whereas guanidinosuccinate was reduced (-25%). The decrease in circulating guanidinoacetate levels suggests that exogenous supply of creatine chronically inhibits endogenous synthesis at the transamidinase step in humans, supporting earlier animal studies showing a powerful repressive effect of creatine on l-arginine:glycine amidinotransferase. Furthermore, these data suggest that this leads to enhanced utilization of arginine as a substrate for secondary pathways.     

Changes in Creatine and Urea Formation in Rats Fasted and Fed Low Protein Diets

Changes in the time course of the urinary excretion of creatinine, creatine and urea, and the activities of kidney transamidinase and liver urea-cycle enzymes were investigated in rats fasted and fed on a 10% casein diet and 10% casein diets supplemented with 10% glycine and/or 1.4% arginine.

The urinary total-creatinine of the fasted rats increased extremely during fasting for 7 days, while that of the animals given the 10% casein diet supplemented with glycine and arginine rose exceedingly on the 3rd day and thereafter no significant change was observed. Most of the increase of total-creatinine could be accounted for by the increase of creatine. The activity of kidney transamidinase in the fasted rats decreased in the 3rd day and thereafter kept nearly constant. The transamidinase activity of rats fed on the 10% casein diet after giving a protein-free diet for 5 days increased in the 3rd day. An inverse relation was observed between the urinary creatine and the transamidinase activity. The urinary urea increased in the rats fasted or fed on the 10% casein diets with the supplement of glycine and/or arginine. In fasting, the activities of liver urea-cycle enzymes, except arginase, had a tendency of increasing with the lapse of time. The arginase activity remained more or less constant. The reason of the extreme increase of urinary creatine during starvation was discussed.     

Effect of age and dietary protein level on tissue mineral levels in female rats

Mineral (phosphorus, sulfur, potassium, calcium, magnesium, iron, zinc, copper, and manganese) concentrations were measured in plasma, and several tissues from female Wistar rats (young: 3-wk-old; mature: 6-mo-old) were fed on a dietary regimen designed to study the combined or singular effects of age and dietary protein on mineral status. Three diets, respectively, contained 5, 15, and 20% of bovine milk casein. Nephrocalcinosis chemically diagnosed by increased calcium and phosphorus in kidney was prevented in rats fed a 5% protein diet. Renal calcium and phosphorus were more accumulated in young rats than mature rats. A 5% protein diet decreased hemoglobin and blood iron. The hepatic and splenic iron was increased by a 5% protein diet in mature rats but was not altered in young rats. Mature rats had higher iron in brain, lung, heart, liver, spleen, kidney, muscle, and tibia than young rats. A 5% protein diet decreased zinc in plasma and liver. Zinc in tibia was increased with dietary protein level in young rats but was not changed in mature rats. A 5% protein diet decreased copper concentration in plasma of young rats but not in mature rats. Mature rats had higher copper in plasma, blood, brain, lung, heart, liver, spleen, and kidney than young rats. With age, manganese concentration was increased in brain but decreased in lung, heart, liver, kidney, and muscle. These results suggest that the response to dietary protein regarding mineral status varies with age.     

Measurement of beta-guanidinopropionate and phosphorylated beta-guanidinopropionate in tissues.

The Sakaguchi color reaction for monosubstituted guanidino compounds was applied to the measurement of β-guanidinopropionate and phosphorylated β-guanidinopropionate. The phosphorylated derivative was measured as an increase in β-guanidinopropionate following incubation with 0.1n HCl in a boiling-water bath for 10 min. After feeding rats 1% of β-guanidinopropionic acid in their diet for 69 days, skeletal muscle, heart, liver, kidney, and spleen contained 5–10 μmoles of a monosubstituted guanidino compound per gram wet weight of tissue. No β-guanidinopropionate was detected in brain or testes. Phosphorylated β-guanidinopropionate was found only in skeletal muscle (27 μmoles/g) and in heart (7 μmoles/g). Creatine hydrate (2%) added to the diet containing β-guanidinopropionic acid inhibited the accumulation of phosphorylated β-guanidinopropionate in the heart and partially inhibited its accumulation in skeletal muscle.     

Mitochondrial intermembrane inclusion bodies: The common denominator between human mitochondrial myopathies and creatine depletion due to impairment of cellular energetics

Mitochondrial inclusion bodies are often described in skeletal muscle of patients suffering diseases termed mitochondrial myopathies. A major component of these structures was discovered as being creatine kinase. Similar creatine kinase enriched inclusion bodies in the mitochondria of creatine depleted adult rat cardiomyocytes have been demonstrated. Structurally similar inclusion bodies are observed in mitochondria of ischemic and creatine depleted rat skeletal muscle. This paper describes the various methods for inducing mitochondrial inclusion bodies in rodent skeletal muscle, and compares their effects on muscle metabolism to the metabolic defects of mitochondrial myopathy muscle. We fed rats with a creatine analogue guanidino propionic acid and checked their soled for mitochondrial inclusion bodies, with the electron microscope. The activity of creatine kinase was analysed by measuring creatine stimulated oxidative phosphorylation in soleus skinned fibres using an oxygen electrode . The guanidino propionic acid-rat soleus mitochondria displayed no creatine stimulation, whereas control soleus did, even though the GPA soled had a five fold increase in creatine kinase protein per mitochondrial protein. The significance of these results in light of their relevance to human mitochondrial myopathies and the importance of altered muscle metabolism in the formation of these crystalline structures are discussed. (Mol Cell Biochem 174: 283–289, 1997)     

Effects of retinoic acid on the concentrations of radioactive metabolites of retinol in tissues of rats maintained on a retinol-deficient diet

The effects of feeding retinoic acid for 2 and 6 days on the metabolism of labeled retinol in tissues of rats maintained on a vitamin A deficient diet was studied. The metabolites of retinol were analyzed by high performance liquid chromatography. Feeding retinoic acid for 2 days significantly reduced the blood retinol and retinyl ester levels without affecting the vitamin A content of the liver. In intestine and testis the content of labeled retinoic acid was decreased significantly by dietary retinoic acid. Addition of retinoic acid to the diet for 6 days resulted, in addition to decreased blood retinol and retinyl ester values, in an increase in the retinyl ester values in the liver. The accumulation of retinyl ester in the retinoic acid fed rat liver was accompanied by an absence of labeled retinoic acid. Kidney tissue was found to contain the highest levels of labeled retinoic acid, retinol, and retinyl esters; dietary retinoic acid did not alter the concentrations of these retinoids in the kidney during the experimental period. Since kidney retained more vitamin A when the liver vitamin A was low and also dietary retinoic acid did not affect the concentrations of radioactive retinoic acid in the kidney, it is suggested that the kidney may play a major role in the production of retinoic acid from retinol in the body.     

α-亚麻酸对高脂模型大鼠组织脂肪酸代谢的影响

研究不同ALA含量油脂对高脂模型大鼠组织脂肪酸代谢的影响.60只雄性Wistar大鼠分为正常组、高脂组、花生油组、13％、27％和55％ ALA含量油脂组,除正常组和高脂组外,其余各组在饲喂高脂饲料的同时采用灌胃方式连续给予2 mL/kg.bw剂量的受试油.试验6周后分别测定大鼠各组织脂肪酸组成.结果表明,高脂饮食能够降低大鼠各组织n-3脂肪酸含量,但摄入不同ALA油脂可显著增加组织n-3脂肪酸含量,并具有一定的剂量效应关系;但ALA及其代谢产物EPA、DPA和DHA的累积具有组织特异性,其中肾和心组织中ALA累积高于血浆、脑及肝组织,肝和脑组织中EPA和DPA含量增加较显著,而肾和心组织中EPA含量不变,各组织DHA含量增加不显著.不同ALA油脂组C18:3(n-6)和C20:3 (n-6)差异不显著,但与花生油组相比,其血浆、脑和肾组织C20:4含量显著降低.因此,富含ALA含量的油脂能够增加组织中ALA及其代谢产物在组织中的含量,提高其在脑组织中的分布比例,这可能是ALA具有心血管保护作用和促进脑生长发育的作用机制之一.     

The effect of high protein diet on urea and guanidino compound levels in renal insufficient mice

Summary. Nephrectomy in mice provokes a decrease in creatinine clearance (CTN_Cl) and an increase in urea and specific guanidino compound (GC) concentrations in blood and other tissues. Our purpose was to investigate the influence of high protein diet (HPD) on CTN_Cl, urea and GC levels in NX mice. Mice were nephrectomized or sham-operated and subdivided in groups to study five diet conditions. At the end of each experiment, 10 days and 30 days postsurgery, urine and blood were collected for determination of urea and GCs, including creatinine. HPD resulted in significantly higher CTN_Cl values in sham-operated mice than those observed in mice under normal protein diet, 10 days as well as 30 days postnephrectomy. HPD induced significant increases in plasma urea, guanidinosuccinic acid, argininic acid and α-keto-δ-guanidinovaleric acid concentration 10 days postsurgery but not 30 days postsurgery. HPD coincided with significantly higher excretion of urea, guanidinosuccinic acid, α-keto-δ-guanidinovaleric acid, creatine, argininic acid and γ-guanidinobutyric acid in sham-operated and nephrectomized mice 10 days postsurgery. Our results show that HPD induces supplementary (to nephrectomy) increases of urea and GCs in the early postsurgery period but not in the later phase. Received June 13, 2000 Accepted January 9, 2001     

α-Guanidinoglutaric Acid in Cobalt-Induced Epileptogenic Cerebral Cortex of Cats

: Guanidino compounds in the cobalt-induced epileptogenic cerebral cortex of cats were fluorometrically analysed by a JASCO G-520 guanidino compounds analyser, and an unknown high peak was observed in the chromatogram that was identical to the peak of authentic α-guanidinoglutaric acid. In another experiment, the substance was extracted from the cobalt focus tissue, converted into dimethylpyrimidyl derivative-butylester, and analysed by a GC/MS technique. The mass spectrum of the substance was identical to the dimethylpyrimidyl derivative of α-guanidinoglutaric acid butylester (M⁺= 365).     

Liver composition and lipid metabolism in NZB/W F1 female mice fed dehydroisoandrosterone

The beneficial effects obtained with dehydroisoandrosterone (DHA) feeding in the treatment of murine systemic lupus erythematosus are similar to those obtained with caloric restriction or with dietary manipulation of essential fatty acid availability. In this study, the fatty acid composition of selected tissues was examined in NZB/W F1 mice fed a diet containing 0.4% DHA. The effect of the DHA diet on liver composition and the activity of key hepatic enzymes involved in fatty acid synthesis and glucose metabolism was also investigated. The content of the essential fatty acid, arachidonate, was decreased in plasma cholesteryl esters and liver and kidney phospholipids in mice fed the DHA diet, yet no significant decrease in arachidonate content was observed in plasma phospholipid. The most striking change in both plasma and liver phospholipid was an increase in palmitic acid and a decrease in stearic acid, which could result from a decreased ability for fatty acid elongation. The liver mass was dramatically increased in the mice fed DHA, primarily from parenchymal cell hypertrophy, and contained little lipid. Significant changes in the activities of malic enzyme, glucose-6-phosphate dehydrogenase and pyruvate kinase, similar to those changes which occur with fasting, were observed during the initial adaptation to the DHA diet. The pyruvate kinase activity remained low, suggesting a decrease in liver glycolysis. These results are consistent with the concept that diets containing DHA result in an altered metabolism with a decreased dependence on carbohydrate metabolism and an increased metabolism of lipids.