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Beyond pharmaceutical screening activity developed on aminothiazoles derivatives, some studies at the molecular level were performed. Thus 2-aminothiazole was shown to inhibit thiamine biosynthesis (941). Nrridazole (419) affects iron metabohsm (850). The dehydrase for 5-aminolevulinic acid of mouse liver is inhibited by 2-amino-4-(iS-hydroxy-ethyl)thiazole (420) (942) (Scheme 239). l-Phenyl-3-(2-thiazolyl)thiourea (421) is a dopamine fS-hydroxylase inhibitor (943). Compound 422 inhibits the enzyme activity of 3, 5 -nucleotide phosphodiesterase (944). The oxalate salt of 423, an analog of levamisole 424 (945) (Scheme 240),... [Pg.152]

The pentose phosphate pathway is an alternative route for the metabolism of glucose. It does not generate ATP but has two major functions (1) The formation of NADPH for synthesis of fatty acids and steroids and (2) the synthesis of ribose for nucleotide and nucleic acid formation. Glucose, fructose, and galactose are the main hexoses absorbed from the gastrointestinal tract, derived principally from dietary starch, sucrose, and lactose, respectively. Fructose and galactose are converted to glucose, mainly in the liver. [Pg.163]

Liver, the major site of purine nucleotide biosynthesis, provides purines and purine nucleosides for salvage and utilization by tissues incapable of their biosynthesis. For example, human brain has a low level of PRPP amidotransferase (reaction 2, Figure 34-2) and hence depends in part on exogenous purines. Erythrocytes and polymorphonuclear leukocytes cannot synthesize 5-phosphoribosylamine (strucmre III, Figure 34-2)... [Pg.294]

Adenylate kinase (AK) is a ubiquitous monomeric enzyme that catalyzes the interconversion of AMP, ADP, and ATP. This interconversion of the adenine nucleotides seems to be of particular importance in regulating the equilibrium of adenine nucleotides in tissues, especially in red blood cells. AK has three isozymes (AK 1,2, and 3). AK 1 is present in the cytosol of skeletal muscle, brain, and red blood cells, and AK 2 is found in the intermembrane space of mitochondria of liver, kidney, spleen, and heart. AK 3, also called GTP AMP phosphotransferase, exists in the mitochondrial matrix of liver and heart. [Pg.13]

G5. Gipp, J. J., Chang, C., and Mulcahy, R. T Cloning and nucleotide sequence of a full length cDNA for human liver -y-glutamylcysteine synthetase. Biochem Biophys. Res. Commun. 185, 29-35 (1992). [Pg.41]

Sakakibara, M., Mukai, T and Hori, K., Nucleotide sequence of a cDNA clone for human aldolase A messenger RNA in the liver. Biochem. Biophys. Res. Commun. 131,413-420(1985). [Pg.50]

ADH6 was discovered by nucleotide cross-hybridization, and has not yet been demonstrated as a functional protein. The mRNA is found in liver (both adult and fetal) and stomach. ADH6 has a fully functional promoter, active in both hepatoma cells and fibroblasts [37]. There are several positive cis-acting elements in the proximal promoter, several of which are bound by C/EBP. There is a compound cell-specific regulatory element about 2 kb upstream, that is a positive element in the hepatoma cells and a negative element in fibroblasts [23]. [Pg.427]

Indicine IV-oxide (169) (Scheme 36) is a clinically important pyrrolizidine alkaloid being used in the treatment of neoplasms. The compound is an attractive drug candidate because it does not have the acute toxicity observed in other pyrrolizidine alkaloids. Indicine IV-oxide apparently demonstrates increased biological activity and toxicity after reduction to the tertiary amine. Duffel and Gillespie (90) demonstrated that horseradish peroxidase catalyzes the reduction of indicine IV-oxide to indicine in an anaerobic reaction requiring a reduced pyridine nucleotide (either NADH or NADPH) and a flavin coenzyme (FMN or FAD). Rat liver microsomes and the 100,000 x g supernatant fraction also catalyze the reduction of the IV-oxide, and cofactor requirements and inhibition characteristics with these enzyme systems are similar to those exhibited by horseradish peroxidase. Sodium azide inhibited the TV-oxide reduction reaction, while aminotriazole did not. With rat liver microsomes, IV-octylamine decreased... [Pg.397]

Al. Anderson, E. P., Kalckar, H. M., and Isselbacher, K. J., Defect in uptake of galactose-l-phosphate into liver nucleotides in congenital galactosemia. Science 125, 113-114 (1957). [Pg.74]

Both the enzymes were prepared by a special technique from the insoluble portion of guinea pig liver mitochondria, and they are quite specific with respect to the requirement of pyridine nucleotide (H9, Hll). However, dehydrogenases catalyzing reaction (25) with NAD as coenzyme have been reported (Mil, S13, T3), thus confirming the importance of the source of the enzyme and the purification procedure employed. [Pg.290]

This is another example of the generalization that enzyme reactions of the same type have the same stereospecificity for the pyridine nucleotide, no matter what their cellular origin. There is another mevaldic reductase in the cytosol of liver, which catalyzes the reduction of mevaldic acid to mevalonic acid by NAD or NADP, and this enzyme also has A (or pro R) stereospecificity for the pyridine nucleotide but the hydrogen transfer occurs to the pro R position on C—5. This latter enzyme can use either 3R or 3S mevaldic acid that is, it is indifferent to... [Pg.54]

The true biological function of liver mevaldic reductase is not clear. It is not thought to be involved in cholesterol synthesis, and because of the difference in its stereospecificity for the substrate, it is thought to be only a distant relative of the hydroxymethylglutaryl CoA reductases. But all of these enzymes have the same A stereospecifidty for the pyridine nucleotide. [Pg.55]

The liver alcohol dehydrogenase mentioned in the preceding section has the same pro-R stereospecificity for NAD and ethanol as yeast alcohol dehydrogenase. Furthermore, the oxidation of ethanol by a microsomal oxidizing system, or by catalase and H2O2, likewise proceeds with pro-R stereospecificity for the ethanol77>. The catalase-H2C>2 system is so very different, however, from the pyridine nucleotide dehydrogenase, that one wonders whether the similarity in stereospecificity for ethanol is fortuitous. [Pg.55]

The stereospecificity of hydrogen transfer for estradiol-17 and estradiol-17(3 dehydrogenases has been examined by George et a/.84>. These enzymes are both present in chicken liver, and have substrates which differ only in the chirality of their substituents at C—17. Both of these enzymes were shown to use the 4-pro-S or 4B proton of the NADPH. Since the steroid is a bulky substrate, the authors argue that the steric fit between pyridine nucleotide and steroid cannot be as important as the role played by the enzyme in directing the fit. This paper contains an interesting summary of other recent work on the stereospecificity of pyridine nucleotide dependent-steroid dehydrogenases. [Pg.56]

Liver cells contain two different but closely related enzymes glycerol phosphate dehydrogenase which is specific for NAD, and acylglycerol phosphate dehydrogenase, which is NADP specific. Both enzymes have B stereospecificity for the pyridine nucleotide 93. They apparently have different metabolic functions. [Pg.59]

The generalization that the same dehydrogenase has the same stereospecificity, no matter what the source of the enzyme, has been tested now particularly well for malic and lactic dehydrogenases. In fact, one can venture a guess, that pyridine nucleotide dehydrogenases which oxidize a-hydroxycarb oxylic acids at the a-position, all have A stereospecificity for the pyridine nucleotide, regardless of their stereo-specificity for the substrate. Biellman and Rosenheimer 88> have assembled the data. One can add liver malic enzyme 90> to their list. [Pg.59]

Mueller, G.C. and Miller, J.A. The reductive cleavage of l+-dimethylaminoazobenzene by rat liver the intracellular distribution of the enzyme system and its requirement for triphosphopyridine nucleotide. J. Biol. Chem. (191+9) 180, 1125-1136. [Pg.293]

Williams, C. H. and Kamin, H. Microsomal triphosphopyridine nucleotide-cytochrome "c" reductase of liver. J. Biol. Chem. (1962) 237 587-595. [Pg.317]

Figure 8.29 The initial reactions of glutamine metabolism in kidney, intestine and cells of the immune system. The initial reaction in all these tissues is the same, glutamine conversion to glutamate catalysed by glutaminase the next reactions are different depending on the function of the tissue or organ. In the kidney, glutamate dehydrogenase produces ammonia to buffer protons. In the intestine, the transamination produces alanine for release and then uptake and formation of glucose in the liver. In the immune cells, transamination produces aspartate which is essential for synthesis of pyrimidine nucleotides required for DNA synthesis otherwise it is released into the blood to be removed by the enterocytes in the small intestine or by cells in the liver. Figure 8.29 The initial reactions of glutamine metabolism in kidney, intestine and cells of the immune system. The initial reaction in all these tissues is the same, glutamine conversion to glutamate catalysed by glutaminase the next reactions are different depending on the function of the tissue or organ. In the kidney, glutamate dehydrogenase produces ammonia to buffer protons. In the intestine, the transamination produces alanine for release and then uptake and formation of glucose in the liver. In the immune cells, transamination produces aspartate which is essential for synthesis of pyrimidine nucleotides required for DNA synthesis otherwise it is released into the blood to be removed by the enterocytes in the small intestine or by cells in the liver.
Folates Yeast, liver, fresh green vegetables Nucleotide metabolism... [Pg.333]

See other pages where Nucleotides liver is mentioned: [Pg.538]    [Pg.32]    [Pg.170]    [Pg.56]    [Pg.694]    [Pg.123]    [Pg.145]    [Pg.231]    [Pg.111]    [Pg.154]    [Pg.257]    [Pg.185]    [Pg.31]    [Pg.301]    [Pg.198]    [Pg.239]    [Pg.294]    [Pg.708]    [Pg.966]    [Pg.523]    [Pg.30]    [Pg.33]    [Pg.309]    [Pg.59]    [Pg.137]    [Pg.153]    [Pg.565]    [Pg.118]    [Pg.265]    [Pg.397]    [Pg.398]   
See also in sourсe #XX -- [ Pg.487 , Pg.490 , Pg.493 ]



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