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Glycine catabolism

Primary hyperoxaluria type I is due to a deficiency of cytosolic a-ketoglutarate-glyoxylate carboligase, which catalyzes the following reaction  [Pg.348]


While Tetrahymena must have lipoic acid in its diet, we humans can make our own, and it is not considered a vitamin. Lipoic acid is present in tissues in extraordinarily small amounts. Its major function is to participate in the oxidative decarboxylation of a-oxoacids but it also plays an essential role in glycine catabolism in the human body as well as in plants.295 296 The structure is simple, and the functional group is clearly the cyclic disulfide which swings on the end of a long arm. Like biotin, which is also present in tissues in very small amounts, lipoic acid is bound in covalent amide linkage to lysine side chains in active sites of enzymes 2963... [Pg.795]

Glyeine cleavagi system Glycine catabolism In the milochondria... [Pg.543]

Glycine cleavage system Glycine catabolism in the mitochondria... [Pg.543]

The answer is d. (Murray, pp 238-249. Scriver, pp 2165-2194. Sack, pp 121-144. Wilson, pp 287-324.) Propionic acidemia (232000) results from a block in propionyl CoA carboxylase (PCC), which converts propionic to methylmalonic acid. Excess propionic acid in the blood produces metabolic acidosis with a decreased bicarbonate and increased anion gap (the serum cations sodium plus potassium minus the serum anions chloride plus bicarbonate). The usual values of sodium (-HO meq/L) plus potassium ( 4 meq/T) minus those for chloride (-105 meq/L) plus bicarbonate (—20 meq/L) thus yield a normal anion gap of -20 meq/L. A low bicarbonate of 6 to 8 meq/L yields an elevated gap of 32 to 34 meq/L, a gap of negative charge that is supplied by the hidden anion (propionate in propionic acidemia). Biotin is a cofactor for PCC and its deficiency causes some types of propionic acidemia. Vitamin B deficiency can cause methylmalonic aciduria because vitamin Bn is a cofactor for methylmalonyl coenzyme A mutase. Glycine is secondarily elevated in propionic acidemia, but no defect of glycine catabolism is present. [Pg.391]

THF and 5,10-methylenetetrahydrofolate can also be interconverted by the glycine catabolic reaction below... [Pg.1099]

The biochemical mechanism by which carbohydrates spare proteins is not known. Carbohydrate breakdown yields ATP, NADH, and amino acid precursors—all compounds needed for amino acid or protein synthesis, and each of them could alone be responsible for the sparing effect. To assume that in the presence of excess carbohydrates the cell selects carbohydrates rather than protein as an energy source is obviously an oversimplified interpretation of the sparing effect. Yet, glucose and fructose administration reverses urea formation and glycine catabolism. [Pg.589]

Fia. 1. Glycine catabolism pathway 1, via serine and pyruvate pathway 2, via glyoxylic acid and formate pathway 3, via the glycine-succinate cycle. [Pg.84]

In summary, the biochemical function of folate coenzymes is to transfer and use these one-carbon units in a variety of essential reactions (Figure 2), including de novo purine biosynthesis (formylation of glycinamide ribonucleotide and 5-amino-4-imidazole carboxamide ribonucleotide), pyrimidine nucleotide biosynthesis (methylation of deoxyuridylic acid to thy-midylic acid), amino-acid interconversions (the interconversion of serine to glycine, catabolism of histidine to glutamic acid, and conversion of homocysteine to methionine (which also requires vitamin B12)), and the generation and use of formate. [Pg.214]

Glycinuria results from a defect in renal tubular reabsorption. The defect in primary hyperoxaluria is the failure to catabolize glyoxylate formed by deamination of glycine. Subsequent oxidation of glyoxylate to oxalate results in urohthiasis, nephrocalcinosis, and early mortality from renal failure or hypertension. [Pg.250]

Serine. Following conversion to glycine, catalyzed by serine hydroxymethyltransferase (Figure 30—5), serine catabolism merges with that of glycine (Figure 30-6). [Pg.250]

Threonine. Threonine is cleaved to acetaldehyde and glycine. Oxidation of acetaldehyde to acetate is followed by formation of acetyl-CoA (Figure 30-10). Catabolism of glycine is discussed above. [Pg.255]

The carbon skeletons of six amino acids are converted in whole or in part to pyruvate. The pyruvate can then be converted to either acetyl-CoA (a ketone body precursor) or oxaloacetate (a precursor for gluconeogenesis). Thus amino acids catabolized to pyruvate are both ke-togenic and glucogenic. The six are alanine, tryptophan, cysteine, serine, glycine, and threonine (Fig. 18-19). Alanine yields pyruvate directly on transamination with... [Pg.674]

In the biosynthesis of serine from glycine, (25) serves as the methylene donor. The reverse of this reaction is important in the catabolism of serine and provides a major source of the one-carbon units needed in biosynthesis (80MI11003). In addition to tetrahydrofolate, pyridoxal phosphate is required as a coenzyme in this transformation. The topic will be taken up again in the next section. [Pg.263]

In addition to these major processes, many other chemical events also occur. Mitochondria concentrate Ca2+ ions and control the entrance and exit of Na+, K+, dicarboxylates, amino acids, ADP, P and ATP, and many other substances.16 Thus, they exert regulatory functions both on catabolic and biosynthetic sequences. The glycine decarboxylase system (Fig. 15-20) is found in the mitochondrial matrix and is especially active in plant mitochondria (Fig. 23-37). Several cytochrome P450-dependent hydroxylation reactions, important to the biosynthesis and catabolism of steroid hormones and... [Pg.1015]

Figure 25-5 shows the principal catabolic pathways, as well as a few biosynthetic reactions, of phenylalanine and tyrosine in animals. Transamination to phenylpyruvate (reaction a) occurs readily, and the product may be oxidatively decarboxylated to phen-ylacetate. The latter may be excreted after conjugation with glycine (as in Knoop s experiments in which phenylacetate was excreted by dogs after conjugation with glycine, Box 10-A). Although it does exist, this degradative pathway for phenylalanine must be of limited importance in humans, for an excess of phenylalanine is toxic unless it can be oxidized to tyrosine (reaction b, Fig. 25-5). Formation of phenylpyruvate may have some function in animals. The enzyme phenylpyruvate tautomerase, which catalyzes interconversion of enol and oxo isomers of its substrate, is also an important immunoregulatory cytokine known as macrophage migration inhibitory factor.863... Figure 25-5 shows the principal catabolic pathways, as well as a few biosynthetic reactions, of phenylalanine and tyrosine in animals. Transamination to phenylpyruvate (reaction a) occurs readily, and the product may be oxidatively decarboxylated to phen-ylacetate. The latter may be excreted after conjugation with glycine (as in Knoop s experiments in which phenylacetate was excreted by dogs after conjugation with glycine, Box 10-A). Although it does exist, this degradative pathway for phenylalanine must be of limited importance in humans, for an excess of phenylalanine is toxic unless it can be oxidized to tyrosine (reaction b, Fig. 25-5). Formation of phenylpyruvate may have some function in animals. The enzyme phenylpyruvate tautomerase, which catalyzes interconversion of enol and oxo isomers of its substrate, is also an important immunoregulatory cytokine known as macrophage migration inhibitory factor.863...

See other pages where Glycine catabolism is mentioned: [Pg.1119]    [Pg.673]    [Pg.559]    [Pg.1119]    [Pg.506]    [Pg.506]    [Pg.348]    [Pg.366]    [Pg.505]    [Pg.9]    [Pg.1119]    [Pg.673]    [Pg.559]    [Pg.1119]    [Pg.506]    [Pg.506]    [Pg.348]    [Pg.366]    [Pg.505]    [Pg.9]    [Pg.246]    [Pg.20]    [Pg.202]    [Pg.882]    [Pg.7]    [Pg.189]    [Pg.140]    [Pg.1]    [Pg.415]    [Pg.83]    [Pg.675]    [Pg.272]    [Pg.492]    [Pg.1391]    [Pg.1397]    [Pg.1399]    [Pg.530]    [Pg.184]    [Pg.230]    [Pg.89]    [Pg.186]   
See also in sourсe #XX -- [ Pg.502 , Pg.506 ]




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