Your search keyword '"Brosnan, John T."' showing total 15 results

1. Synthesis of guanidinoacetate and creatine from amino acids by rat pancreas.

Author

da Silva RP, Clow K, Brosnan JT, and Brosnan ME

Subjects

Animals, Creatine pharmacology, Creatinine metabolism, Diet, Dietary Supplements, Glycine biosynthesis, Kidney metabolism, Liver metabolism, Male, Pancreas enzymology, Phosphocreatine metabolism, RNA, Messenger metabolism, Rats, Rats, Sprague-Dawley, S-Adenosylhomocysteine metabolism, S-Adenosylmethionine metabolism, Amidinotransferases metabolism, Amino Acids metabolism, Creatine biosynthesis, Glycine analogs & derivatives, Guanidinoacetate N-Methyltransferase metabolism, Pancreas metabolism

Abstract

Creatine is an important molecule involved in cellular energy metabolism. Creatine is spontaneously converted to creatinine at a rate of 1·7% per d; creatinine is lost in the urine. Creatine can be obtained from the diet or synthesised from endogenous amino acids via the enzymes arginine:glycine amidinotransferase (AGAT) and guanidinoacetate N-methyltransferase (GAMT). The liver has high GAMT activity and the kidney has high AGAT activity. Although the pancreas has both AGAT and GAMT activities, its possible role in creatine synthesis has not been characterised. In the present study, we examined the enzymes involved in creatine synthesis in the pancreas as well as the synthesis of guanidinoacetate (GAA) and creatine by isolated pancreatic acini. We found significant AGAT activity and somewhat lower GAMT activity in the pancreas and that pancreatic acini had measurable activities of both AGAT and GAMT and the capacity to synthesise GAA and creatine from amino acids. Creatine supplementation led to a decrease in AGAT activity in the pancreas, though it did not affect its mRNA or protein abundance. This was in contrast with the reduction of AGAT activity and mRNA and protein abundance in the kidney, suggesting that the regulatory mechanisms that control the expression of this enzyme in the pancreas are different from those in the kidney. Dietary creatine increased the concentrations of GAA, creatine and phosphocreatine in the pancreas. Unexpectedly, creatine supplementation decreased the concentrations of S-adenosylmethionine, while those of S-adenosylhomocysteine were not altered significantly.

Published

2014

2. Creatine and guanidinoacetate content of human milk and infant formulas: implications for creatine deficiency syndromes and amino acid metabolism.

Author

Edison EE, Brosnan ME, Aziz K, and Brosnan JT

Subjects

Adult, Creatine metabolism, Creatine pharmacology, Female, Glycine chemistry, Humans, Infant, Infant Nutrition Disorders prevention & control, Infant Nutritional Physiological Phenomena, Amino Acids metabolism, Creatine chemistry, Creatine deficiency, Glycine analogs & derivatives, Infant Formula chemistry, Milk, Human chemistry

Abstract

Creatine is essential for normal neural development; children with inborn errors of creatine synthesis or transport exhibit neurological symptoms such as mental retardation, speech delay and epilepsy. Creatine accretion may occur through dietary intake or de novo creatine synthesis. The objective of the present study was to determine how much creatine an infant must synthesise de novo. We have calculated how much creatine an infant needs to account for urinary creatinine excretion (creatine's breakdown product) and new muscle lay-down. To measure an infant's dietary creatine intake, we measured creatine in mother's milk and in various commercially available infant formulas. Knowing the amount of milk/formula ingested, we calculated the amount of creatine ingested. We have found that a breast-fed infant receives about 9 % of the creatine needed in the diet and that infants fed cows' milk-based formula receive up to 36 % of the creatine needed. However, infants fed a soya-based infant formula receive negligible dietary creatine and must rely solely on de novo creatine synthesis. This is the first time that it has been shown that neonatal creatine accretion is largely due to de novo synthesis and not through dietary intake of creatine. This has important implications both for infants suffering from creatine deficiency syndromes and for neonatal amino acid metabolism.

Published

2013

3. Creatine synthesis: hepatic metabolism of guanidinoacetate and creatine in the rat in vitro and in vivo.

Author

da Silva RP, Nissim I, Brosnan ME, and Brosnan JT

Subjects

Amidinotransferases metabolism, Animals, Cells, Cultured, Creatine blood, Creatine pharmacokinetics, Glycine blood, Glycine metabolism, Guanidinoacetate N-Methyltransferase metabolism, Hepatocytes metabolism, Liver enzymology, Male, Models, Biological, Nitrogen Isotopes pharmacokinetics, Rats, Rats, Sprague-Dawley, Creatine biosynthesis, Glycine analogs & derivatives, Liver metabolism

Abstract

Since creatinine excretion reflects a continuous loss of creatine and creatine phosphate, there is a need for creatine replacement, from the diet and/or by de novo synthesis. Creatine synthesis requires three amino acids, methionine, glycine, and arginine, and two enzymes, l-arginine:glycine amidinotransferase (AGAT), which produces guanidinoacetate acid (GAA), and guanidinoacetate methyltransferase (GAMT), which methylates GAA to produce creatine. In the rat, high activities of AGAT are found in the kidney, whereas high activities of GAMT occur in the liver. Rat hepatocytes readily convert GAA to creatine; this synthesis is stimulated by the addition of methionine, which increases cellular S-adenosylmethionine concentrations. These same hepatocytes are unable to produce creatine from methionine, arginine, and glycine. (15)N from (15)NH(4)Cl is readily incorporated into urea but not into creatine. Hepatic uptake of GAA is evident in vivo by livers of rats fed a creatine-free diet but not when rats were fed a creatine-supplemented diet. Rats fed the creatine-supplemented diet had greatly decreased renal AGAT activity and greatly decreased plasma [GAA] but no decrease in hepatic GAMT or in the capacity of hepatocytes to produce creatine from GAA. These studies indicate that hepatocytes are incapable of the entire synthesis of creatine but are capable of producing it from GAA. They also illustrate the interplay between the dietary provision of creatine and its de novo synthesis and point to the crucial role of renal AGAT expression in regulating creatine synthesis in the rat.

Published

2009

4. Creatine synthesis: production of guanidinoacetate by the rat and human kidney in vivo.

Author

Edison EE, Brosnan ME, Meyer C, and Brosnan JT

Subjects

Adult, Amino Acids analysis, Amino Acids blood, Amino Acids metabolism, Animals, Citrulline metabolism, Creatine pharmacology, Creatinine metabolism, Diet, Glycine biosynthesis, Glycine metabolism, Guanidinoacetate N-Methyltransferase metabolism, Humans, Male, RNA, Messenger biosynthesis, RNA, Messenger genetics, Rats, Rats, Sprague-Dawley, Reverse Transcriptase Polymerase Chain Reaction, Creatine biosynthesis, Glycine analogs & derivatives, Kidney metabolism

Abstract

A fraction of the body's creatine and creatine phosphate spontaneously degrades to creatinine, which is excreted by the kidneys. In humans, this amounts to approximately 1-2 g/day and demands a comparable rate of de novo creatine synthesis. This is a two-step process in which l-arginine:glycine amidinotransferase (AGAT) catalyzes the conversion of glycine and arginine to ornithine and guanidinoacetate (GAA); guanidinoacetate methyltransferase (GAMT) then catalyzes the S-adenosylmethionine-dependent methylation of GAA to creatine. AGAT is found in the kidney and GAMT in the liver, which implies an interorgan movement of GAA from the kidney to the liver. We studied the renal production of this metabolite in both rats and humans. In control rats, [GAA] was 5.9 microM in arterial plasma and 10.9 microM in renal venous plasma for a renal arteriovenous (A-V) difference of -5.0 microM. In the rat, infusion of arginine or citrulline markedly increased renal GAA production but infusion of glycine did not. Rats fed 0.4% creatine in their diet had decreased renal AGAT activity and mRNA, an arterial plasma [GAA] of 1.5 microM, and a decreased renal A-V difference for GAA of -0.9 microM. In humans, [GAA] was 2.4 microM in arterial plasma, with a renal A-V difference of -1.1 microM. These studies show, for the first time, that GAA is produced by both rat and human kidneys in vivo.

Published

2007

5. Hyperglycinemia due to folate deficiency in rats: evidence for the lack of involvement of the hepatic glycine cleavage system.

Author

Dickson TM, Edison E, Brosnan JT, and House JD

Subjects

Animals, Diet, Eating, Folic Acid administration & dosage, Folic Acid blood, Homocysteine blood, Male, Rats, Rats, Sprague-Dawley, Weight Gain, Amino Acid Oxidoreductases metabolism, Carrier Proteins metabolism, Folic Acid Deficiency complications, Glycine blood, Liver enzymology, Multienzyme Complexes metabolism, Transferases metabolism

Abstract

In addition to a well-recognized hyperhomocysteinemic state, folate deficiency also leads to profound hyperglycinemia. To further characterize the latter observation, two trials were conducted using a folate-deficient rat model to (1) determine the sensitivity of plasma glycine to folate repletion and (2) test the hypothesis that hyperglycinemia results from a reduced flux through the folate-dependent glycine cleavage system (GCS). Weanling male Sprague-Dawley rats were used, and they consumed an amino acid-defined diet with either 0 (FD) or 1 (FA) mg/kg of crystalline folic acid. In Trial 1, 30 rats consumed the FD diet for 28 days. Rats then consumed diets containing 0.1, 0.2, 0.3 or 0.4 mg/kg of folic acid for 14 days before termination. In Trial 2, 16 rats were allocated to receive either the FA (n=8) or FD (n=8) diet for 30 days before termination. Liver mitochondria were isolated and flux through the GCS (measured as 14CO2 production from 1-14C-glycine) was determined. Plasma from blood collected at termination was analyzed for folate, homocysteine and glycine. In Trial 1, both homocysteine and glycine responded linearly to increased dietary folic acid (milligrams per kilogram) levels (P<.05). In Trial 2, plasma folate (FA=25.85 vs. FD=0.66; S.E.M.=1.4 microM), homocysteine (FA=11.1 vs. FD=55.3; S.E.M.=1.7 microM) and glycine (FA=564 vs. FD=1983; S.E.M.=114 microM) were significantly affected by folate deficiency (P<.0001). However, glycine flux through hepatic GCS was not affected by folate deficiency (P>.05). These results provide evidence that in a folate-deficient rat model, both homocysteine and glycine are sensitive to dietary folic acid levels; however, the observed hyperglycinemia does not appear to be related to a reduced flux through the hepatic GCS.

Published

2005

6. An isotope-dilution, GC–MS assay for formate and its application to human and animal metabolism

Author

Lamarre, Simon G., MacMillan, Luke, Morrow, Gregory P., Randell, Edward, Pongnopparat, Theerawat, Brosnan, Margaret E., and Brosnan, John T.

Published

2014

7. The metabolic burden of creatine synthesis

Author

Brosnan, John T., da Silva, Robin P., and Brosnan, Margaret E.

Published

2011

8. Plasma Formate Is Greater in Fetal and Neonatal Rats Compared with Their Mothers.

Author

Brosnan, Margaret E, Tingley, Garrett, MacMillan, Luke, Harnett, Brian, Pongnopparat, Theerawat, Marshall, Jenika D, and Brosnan, John T

Subjects

RATS, AMNIOTIC liquid, AMINO acids, NAD (Coenzyme), MOTHERS, GLYCINE, GLYCINE receptors, METABOLISM, ANIMAL experimentation, ANIMAL populations, COMPARATIVE studies, LIVER, MATERNAL-fetal exchange, RESEARCH methodology, MEDICAL cooperation, PLACENTA, RESEARCH, EVALUATION research, ACYCLIC acids

Abstract

Background: Formate can be incorporated into 10-formyl-tetrahydrofolate (10-formyl-THF), which is a substrate for purine synthesis, and after further reduction of the one-carbon group, may be used as a substrate for thymidylate synthesis and for homocysteine remethylation.Objective: We examined plasma formate concentrations and the expression of genes involved in the production and utilization of formate in fetal and neonatal rats and in pregnant and virgin female rats.Methods: In 1 experiment, plasma formate was measured by GC-MS in rats aged 1-56 d. In a second experiment, virgin female (adult) rats, 19-d pregnant rats (P) and their male and female fetuses (F), and 3-d-old (N) and 7-d-old (J) offspring had plasma and amniotic fluid analyzed for formate by GC-MS, mRNA abundance in liver and placenta by qPCR, and several plasma amino acids by HPLC.Results: The plasma formate concentration was significantly higher in fetuses at embryonic day 19 than in the mothers. It was also significantly higher in neonatal rats but slowly returned to adult concentrations by ∼3 wk. The abundance of mitochondrial monofunctional 10-formyl-tetrahydrofolate synthetase (Mthfd1l) mRNA was significantly higher in placenta (PP) and F liver than in liver of N or J. Expression of mitochondrial bifunctional NAD-dependent methylene-tetrahydrofolate dehydrogenase/methenyl-tetrahydrofolate cyclohydrolase (Mthfd2) was significantly enriched in PP and liver of P, intermediate in F liver, and much lower in liver of N and J, relative to PP. Serine hydroxymethyltransferase 2 (Shmt2), methylenetetrahydrofolate dehydrogenase 1 (Mthfd1), and glycine decarboxylase protein of the glycine cleavage system (Gldc) mRNA expression was significantly lower in PP compared with other groups. Cytoplasmic NAD(P)-dependent 10-formyl-tetrahydrofolate dehydrogenase (Aldh1/1) and mitochondrial NAD(P)-dependent 10-formyl-tetrahydrofolate dehydrogenase (Aldh1/2) , genes responsible for the catabolism of 10-formylTHF, were very weakly expressed in PP, low in livers of F and N, and reached the significantly higher adult levels in J. Serine, glycine, and methionine concentrations in plasma of F were significantly higher than in plasma of P.Conclusions: Formate metabolism is highly active in fetuses and in placenta of pregnant rats. [ABSTRACT FROM AUTHOR]

Published

2020

9. Glycine decarboxylase deficiency causes neural tube defects and features of non-ketotic hyperglycinemia in mice

Author

Pai, Yun Jin, Leung, Kit-Yi, Savery, Dawn, Hutchin, Tim, Prunty, Helen, Heales, Simon, Brosnan, Margaret E., Brosnan, John T., Copp, Andrew J., and Greene, Nicholas D.E.

Subjects

congenital, hereditary, and neonatal diseases and abnormalities, Indoles, Base Sequence, Formates, Genotype, Hyperglycinemia, Nonketotic, Molecular Sequence Data, Glycine, Galactosides, Sequence Analysis, DNA, Glycine Dehydrogenase (Decarboxylating), Real-Time Polymerase Chain Reaction, Immunohistochemistry, Article, Gas Chromatography-Mass Spectrometry, Mice, Folic Acid, Animals, Neural Tube Defects, In Situ Hybridization, DNA Primers

Abstract

Glycine decarboxylase (GLDC) acts in the glycine cleavage system to decarboxylate glycine and transfer a one-carbon unit into folate one-carbon metabolism. GLDC mutations cause a rare recessive disease non-ketotic hyperglycinemia (NKH). Mutations have also been identified in patients with neural tube defects (NTDs); however, the relationship between NKH and NTDs is unclear. We show that reduced expression of Gldc in mice suppresses glycine cleavage system activity and causes two distinct disease phenotypes. Mutant embryos develop partially penetrant NTDs while surviving mice exhibit post-natal features of NKH including glycine accumulation, early lethality and hydrocephalus. In addition to elevated glycine, Gldc disruption also results in abnormal tissue folate profiles, with depletion of one-carbon-carrying folates, as well as growth retardation and reduced cellular proliferation. Formate treatment normalizes the folate profile, restores embryonic growth and prevents NTDs, suggesting that Gldc deficiency causes NTDs through limiting supply of one-carbon units from mitochondrial folate metabolism., Mutations in the enzyme glycine decarboxylase (GLDC) are associated with neural tube closure defects and non-ketotic hyperglycinemia in humans. Here the authors generate a mouse model with reduced Gldc expression and activity and study the direct effect of the enzyme in these diseases and the mechanisms responsible for neural tube closure defects.

Published

2015

10. Formate concentrations in maternal plasma during pregnancy and in cord blood in a cohort of pregnant Canadian women: relations to genetic polymorphisms and plasma metabolites.

Author

Brosnan, John T, Plumptre, Lesley, Brosnan, Margaret E, Pongnopparat, Theerawat, Masih, Shannon P, Visentin, Carly E, Berger, Howard, Lamers, Yvonne, Caudill, Marie A, Malysheva, Olga V, O'Connor, Deborah L, and Kim, Young-In

Subjects

CARBON metabolism, METHIONINE metabolism, PURINE metabolism, AMINO acids, CHILD health services, DELIVERY (Obstetrics), CORD blood, GENETIC polymorphisms, GLYCINE, LONGITUDINAL method, METHIONINE, TRYPTOPHAN, SERINE, ACYCLIC acids, GENOTYPES, PREGNANCY

Abstract

Background One-carbon metabolism, responsible for purine and thymidylate synthesis and transmethylation reactions, plays a critical role in embryonic and fetal development. Formate is a key player in one-carbon metabolism. In contrast to other one-carbon metabolites, it is not linked to tetrahydrofolate, is present in plasma at appreciable concentrations, and may therefore be distributed to different tissues. Objective The study was designed to determine the concentration of formate in cord blood in comparison with maternal blood taken earlier in pregnancy and at delivery and to relate formate concentrations to potential precursors and key fetal genotypes. Methods Formate and amino acids were measured in plasma during early pregnancy (12–16 wk), at delivery (37–42 wk), and in cord blood samples from 215 mothers, of a prospective cohort study. Three fetal genetic variants in one-carbon metabolism were assessed for their association with cord plasma concentrations of formate. Results The formate concentration was ∼60% higher in the cord blood samples than in mothers' plasma. The maternal formate concentrations did not differ between the early pregnancy samples and those taken at delivery. Plasma concentrations of 4 formate precursors (serine, glycine, tryptophan, and methionine) were increased in cord blood compared with the maternal samples. Cord blood formate was influenced by fetal genotype, being ∼12% higher in infants harboring the MTHFR A1298C (rs1801131) AC or CC genotypes and 10% lower in infants harboring the MTHFD1 G1958A (rs2236225) GA or AA genotypes. Conclusions The increased formate concentrations in cord blood may support the increased activity of one-carbon metabolism in infants. As such, it would support increased rates of purine and thymidylate synthesis and the provision of methionine for methylation reactions. [ABSTRACT FROM AUTHOR]

Published

2019

11. Riboflavin Deficiency in Rats Decreases de novo Formate Production but Does Not Affect Plasma Formate Concentration.

Author

MacMillan, Luke, Lamarre, Simon G., daSilva, Robin P., Jacobs, René L., Brosnan, Margaret E., and Brosnan, John T.

Subjects

VITAMIN B2 deficiency, LABORATORY rats, THYMIDYLATE synthase, FLAVOPROTEINS, METABOLITE synthesis, ANIMAL experimentation, DIET, FOOD, ISOTOPES, RATS, RESEARCH funding, ACYCLIC acids

Abstract

Background: The one-carbon metabolism pathway is highly dependent on a number of B vitamins in order to provide one-carbon units for purine and thymidylate biosynthesis as well as homocysteine remethylation. Previous studies have examined folate and vitamin B-12 deficiency and their effects on formate metabolism; as of yet, to our knowledge, no studies on the effects of riboflavin deficiency on formate metabolism have been published.Objective: Our objective was to determine the effects of riboflavin deficiency on formate metabolism.Methods: Weanling male rats were randomly assigned either to control, riboflavin-replete (RR) or to experimental, riboflavin-deficient (RD) versions of the AIN-93G diet for 13 d, at which time a constant infusion of [13C]-formate was carried out to ascertain the effects of deficiency on formate production. Gas chromatography-mass spectrometry was used to measure plasma formate concentration and [13C]-formate enrichment. HPLC, LC-mass spectrometry (MS)/MS, and enzymatic assays were used for the measurement of one-carbon precursors and other metabolites.Results: RD rats had significantly lower rates of formate production (15%) as well as significantly reduced hepatic methylenetetrahydrofolate reductase activity (69%) and protein concentration (54%) compared with RR rats. There was no difference in plasma formate concentrations between the groups. Plasma serine, a potential one-carbon precursor, was significantly higher in RD rats (467 ± 73 μM) than in RR rats (368 ± 52 μM).Conclusions: Although deficiencies in folate and vitamin B-12 lead to major changes in plasma formate concentrations, riboflavin deficiency results in no significant difference; this disagrees with the prediction of a published mathematical model. Our observation of a lower rate of formate production is consistent with a role for flavoproteins in this process. [ABSTRACT FROM AUTHOR]

Published

2017

12. Choline and dimethylglycine produce superoxide/hydrogen peroxide from the electron transport chain in liver mitochondria.

Author

Mailloux, Ryan J., Young, Adrian, Chalker, Julia, Gardiner, Danielle, O'Brien, Marisa, Slade, Liam, and Brosnan, John T.

Subjects

CHOLINE, GLYCINE, HYDROGEN peroxide, ELECTRON transport, LIVER mitochondria

Abstract

Here, we report that choline and dimethylglycine can stimulate reactive oxygen species ( ROS) production in liver mitochondria. Choline stimulated O2˙−/H2O2 formation at a concentration of 5 μ m. We also observed that Complex II and III inhibitors, atpenin A5 and myxothiazol, collectively induced a 95% decrease in O2˙−/H2O2 production indicating both sites serve as the main sources of ROS during choline oxidation. Dimethylglycine, an intermediate of choline oxidation, was a more effective ROS generator. Rates of production were ~ 43% higher than choline-mediated O2˙−/H2O2 production. The main site for dimethylglycine-mediated ROS production was via reverse electron transfer to Complex I. Our results demonstrate that metabolism of essential metabolites involved in methionine and folic acid biosynthesis can stimulate mitochondrial ROS production. [ABSTRACT FROM AUTHOR]

Published

2016

13. Creatine Supplementation Prevents the Accumulation of Fat in the Livers of Rats Fed a High-Fat Diet.

Author

Deminice, Rafael, da Silva, Robin P., Lamarre, Simon G., Brown, Colin, Furey, George N., McCarter, Shannon A., Jordao, Alceu Afonso, Kelly, Karen B., King-Jones, Kirst, Jacobs, René L., Brosnan, Margaret E., and Brosnan, John T.

Subjects

CREATINE, LABORATORY rats, FATTY liver, ADENOSYLMETHIONINE, ARGININE, GLYCINE

Abstract

The aim of the present study was to examine the effects of creatine supplementation on liver fat accumulation induced by a high-fat diet in rats. Rats were fed 1 of 3 different diets for 3 wk: a control liquid diet (C), a high-fat liquid diet (HF), or a high-fat liquid diet supplemented with creatine (HFC). The C and HF diets contained, respectively, 35 and 71% of energy derived from fat. Creatine supplementation involved the addition of 1% (wt:v) of creatine monohydrate to the liquid diet. The HF diet increased total liver fat concentration, liver 1G. and liver TBARS and decreased the hepatic S-adenosylmethionine (SAM) concentration. Creatine supplementation normalized all of these perturbations. Creatine supplementation significantly decreased the renal activity of L-arginine:glycine amidinotransferase and plasma guanidi- noacetate and prevented the decrease in hepatic SAM concentration in rats fed the HF diet. However, there was no change in either the phosphatidylcholine:phosphatidylethanolamine (PE) ratio or PE N-methyltransferase activity. The HF diet decreased mRNA for PPARcY as well as 2 of its targets, carnitine palmitoyltransferase and long-chain acylCoA dehydrogenase. Creatine supplementation normalized these mRNA levels. In conclusion, creatine supplementation prevented the fatty liver induced by feeding rats a HF diet, probably by normalization of the expression of key genes of β-oxidation. [ABSTRACT FROM AUTHOR]

Published

2011

14. Creatine Synthesis Is a Major Metabolic Process in Neonatal Piglets and Has Important Implications for Amino Acid Metabolism and Methyl Balance.

Author

Brosnan, John T., Wijekoon, Enoka P., Warford-Woolgar, Lori, Trottier, Nathalie L, Brosnan, Margaret E., Brunton, Janet A., and Bertolo, Robert F. P.

Subjects

*METABOLISM, *AMINO acids, *ORGANIC acids, *PEPTIDES, *GLYCINE, *ARGININE, *METHIONINE, *SULFUR amino acids, *PHOSPHATES

Abstract

Our objectives in this study were as follows: 1) to determine the rate of creatine accretion by the neonatal piglet; 2) identify the sources of this creatine; 3) measure the activities of the enzymes of creatine synthesis; and 4) to estimate the burden that endogenous creatine synthesis places on the metabolism of the 3 amino acids required for this synthesis: glycine, arginine, and methionine. We found that piglets acquire 12.5 mmol of total creatine (creatine plus creatine phosphate) between 4 and 11 d of age. As much as one-quarter of creatine accretion in neonatal piglets may be provided by sow milk and three-quarters by de novo synthesis by piglets. This rate of creatine synthesis makes very large demands on arginine and methionine metabolism, although the magnitude of the demand depends on the rate of remethylation of homocysteine and of reamidination of ornithine. Of the 2 enzymes of creatine synthesis, we found high activity of L-arginine:glycine amidinotransferase in piglet kidneys and pancreas and of guanidinoacetate methyltransferase in piglet livers. Piglet livers also had appreciable activities of methionine adenosyltransferase, which synthesizes S-adenosylmethionine, and of betaine:homocysteine methyltransferase, methionine synthase, and methylene tetrahydrofolate reductase, which are required for the remethylation of homocysteine to methionine. Creatine synthesis is a quantitatively major metabolic process in piglets. [ABSTRACT FROM AUTHOR]

Published

2009

15. Threonine metabolism in isolated rat hepatocytes.

Author

House, James D., Hall, Beatrice N., and Brosnan, John T.

Subjects

*DEHYDROGENASES, *LIVER cells, *GLYCINE

Abstract

Examines the metabolism of threonine dehydrogenase of aldolase in rat hepatocytes. Removal of glycine from the mitochondrial glycine cleavage system; Oxidation of alpha-ketobutyrate in the mitochondria to carbon dioxide; Suppression of threonine oxidation.

Published

2001