Coenzyme transferases

The primary transporter of cholesterol in the blood is low density Hpoprotein (LDL). Once transported intraceUularly, cholesterol homeostasis is controlled primarily by suppressing cholesterol synthesis through inhibition of P-hydroxy-P-methyl gluterate-coenzyme A (HMG—CoA) reductase, acyl CoA—acyl transferase (ACAT), and down-regulation of LDL receptors. An important dmg in the regulation of cholesterol metaboHsm is lovastatin, also known as mevinolin, MK-803, and Mevacor, which is an HMG—CoA reductase inhibitor (Table 5). 

Histone Acetylation. Figure 1 Histone acetylation is a posttranslational modification of lysine residues of histones. This modification is catalyzed by histone actyl transferases (HATs), which transfer an acetyl group (yellow) from acetyl-Coenzyme A onto the E-amino group of the lysine residue. Histone deacetylation is catalyzed by histone deacetylases (HDACs), which hydrolyze the lysine bound acetyl group. HDAC inhibitors like Trichostatin A (TSA) are known to inhibit the deacetylation reaction in vivo and in vitro. 

Pyridoxamine phosphate serves as a coenzyme of transaminases, e.g., lysyl oxidase (collagen biosynthesis), serine hydroxymethyl transferase (Cl-metabolism), S-aminolevulinate synthase (porphyrin biosynthesis), glycogen phosphoiylase (mobilization of glycogen), aspartate aminotransferase (transamination), alanine aminotransferase (transamination), kynureninase (biosynthesis of niacin), glutamate decarboxylase (biosynthesis of GABA), tyrosine decarboxylase (biosynthesis of tyramine), serine dehydratase ((3-elimination), cystathionine 3-synthase (metabolism of methionine), and cystathionine y-lyase (y-elimination). 

Tocotrienols present in rice bran inhibit the liver microsomal enzyme HMGCoA reductase (Qureshi and Qureshi, 1992), the key enzyme involved in the endogenous synthesis of cholesterol, and this helps to lower the circulating cholesterol. Inhibition of another enzyme, ACAT (Acyl coenzyme A acyl transferase), by y-oryzanol results in lowered LDL-C synthesis and enrichment... 

Coleman NV, JC Spain (2003) Epoxyalkane coenzyme M transferase in the ethene and vinyl chloride biodegradation pathways of Mycobacterium strain JS60. J Bacterial 185 5536-5546. 

In mammals and in the majority of bacteria, cobalamin regulates DNA synthesis indirectly through its effect on a step in folate metabolism, catalyzing the synthesis of methionine from homocysteine and 5-methyltetrahydrofolate via two methyl transfer reactions. This cytoplasmic reaction is catalyzed by methionine synthase (5-methyltetrahydrofolate-homocysteine methyl-transferase), which requires methyl cobalamin (MeCbl) (253), one of the two known coenzyme forms of the complex, as its cofactor. 5 -Deoxyadenosyl cobalamin (AdoCbl) (254), the other coenzyme form of cobalamin, occurs within mitochondria. This compound is a cofactor for the enzyme methylmalonyl-CoA mutase, which is responsible for the conversion of T-methylmalonyl CoA to succinyl CoA. This reaction is involved in the metabolism of odd chain fatty acids via propionic acid, as well as amino acids isoleucine, methionine, threonine, and valine. 

Sulzenbacher, G., Gal, L., Peneff, C., Fassy, F., and Bourne, Y. (2001). Crystal structure of Streptococcus pneumoniae N-acetylglucosamine-1-phosphate uridyl transferase bound to acetyl-coenzyme A reveals a novel active site architecture. J. Biol. Chem. 276, 11844-11851. 

Serine hydroxymethyl transferase catalyzes the decarboxylation reaction of a-amino-a-methylmalonic acid to give (J )-a-aminopropionic acid with retention of configuration [1]. The reaction of methylmalonyl-CoA catalyzed by malonyl-coenzyme A decarboxylase also proceeds with perfect retention of configuration, but the notation of the absolute configuration is reversed in accordance with the CIP-priority rule [2]. Of course, water is a good proton source and, if it comes in contact with these reactants, the product of decarboxylation should be a one-to-one mixture of the two enantiomers. Thus, the stereoselectivity of the reaction indicates that the reaction environment is highly hydro-phobic, so that no free water molecule attacks the intermediate. Even if some water molecules are present in the active site of the enzyme, they are entirely under the control of the enzyme. If this type of reaction can be realized using synthetic substrates, a new method will be developed for the preparation of optically active carboxylic acids that have a chiral center at the a-position. 

The transferases (class 2) catalyze the transfer of other groups from one molecule to another. Oxidoreductases and transferases generally require coenzymes (see pp.l04ff). 

This enzyme [EC 2.3.1.26], also known as sterol O-acyl-transferase, sterol-ester synthase, and cholesterol acyl-transferase, catalyzes the reaction of an acyl-coenzyme A derivative with cholesterol to produce coenzyme A and the cholesterol ester. The animal enzyme is highly specific for transfer of acyl groups having a single cis double bond at C9. 

This enzyme [EC 2.3.1.23], also called lysolecithin acyl-transferase and lysophosphatidylcholine acyltransferase, catalyzes the reaction of an acyl-CoA derivative with 1-acyl-5 n-glycero-3-phosphocholine to yield coenzyme A and l,2-diacyl-5 n-glycero-3-phosphocholine. The enzyme preferentially acts on unsaturated acyl-CoA derivatives, but l-acyl-5 n-glycero-3-phosphoinositol can also act as the acceptor. 

Glycine A-benzoyltransferase [EC 2.3.1.71] catalyzes the reaction of benzoyl-CoA with glycine to produce coenzyme A and A-benzoylglycine. This enzyme is not identical with glycine A-acyltransferase or glutamine A-acyl-transferase [EC 2.3.1.68]. 

Inskeep, P. B., K. M. Davis, and A. E. Ree. Pharmacokinetics of the acyl coenzyme A cholesterol acyl transferase inhibitor CP-105,191 in dogs-the effect of food and sesame oil on systemic exposure following oral dosing. J Pharm Sci 1995 84(2) 131-133. Satchithanandam, S., M. Reicks, R. J. Calvert, M. M. Cassidy, and D. Kritchevsky. Coconut oil and sesame... 

Leaver, M.J., Scott, K., George, S.G. (1993). Cloning and characterization of the major hepatic glutathione S-transferase from a marine teleost flatfish, the plaice Pleuronectes platessa), with structural similarities to plant, insect and mammalian theta-class coenzymes. Journal of Biochemistry, 292 189-195. 

Diabetes - insulin dependent Methyl malonic, propionic or isovaleric acidaemias Pyruvate carboxylase and multiple carboxylase deficiency Gluconeogenesis enzyme deficiency glucose-6-phosphatase, fructose-1,6-diphosphatase or abnormality of glycogen synthesis (glycogen synthase) Ketolysis defects Succinyl coenzyme A 3-keto acid transferase ACAC coenzyme A thiolase... 

Table 1.4.15 Data from a acid transferase deficiency patient affected with succinyl coenzyme A 3-oxo ... 

Succinyl coenzyme A 3-oxo acid transferase catalyses the transformation of ACAC into acetoacetyl coenzyme A in the mitochondria of extra-hepatic tissues. This enzyme defect may be suggested in cases of severe ketoacidosis often associated with neurologic dysfunction [16]. 

Acetylcholine is an ester composed of acetate (from acetyl coenzyme A) and choline (either synthesized de novo or taken in the diet as lecithin). The enzyme choline acetyl transferase catalyzes the reaction to form Ach. The breakdown of Ach back to acetate and choline, which will terminate its activity, is catalyzed by the enzyme acetylcholineesterase (Achase). 

CoA, the coenzyme A derivative of acetoacetate, reduces its reactivity as a substrate for /3-ketoacyl-CoA transferase (an enzyme of lipid metabolism) by a factor of 106. Although this requirement for adenosine has not been investigated in detail, it must involve the binding energy between enzyme and substrate (or cofactor) that is used both in catalysis and in stabilizing the initial enzyme-substrate complex (Chapter 6). In the case of /3-ketoacyl-CoA transferase, the nucleotide moiety of coenzyme A appears to be a binding handle that helps to pull the substrate (acetoacetyl-CoA) into the active site. Similar roles may be found for the nucleoside portion of other nucleotide cofactors. 

In extraliepatic tissues, d-/3-hydroxybutyrate is oxidized to acetoacetate by o-/3-hydroxybutyrate dehydrogenase (Fig. 17-19). The acetoacetate is activated to its coenzyme A ester by transfer of CoA from suc-cinyl-CoA, an intermediate of the citric acid cycle (see Fig. 16-7), in a reaction catalyzed by P-ketoacyl-CoA transferase. The acetoacetyl-CoA is then cleaved by thiolase to yield two acetyl-CoAs, which enter the citric acid cycle. Thus the ketone bodies are used as fuels. 

Much of the cholesterol synthesis in vertebrates takes place in the liver. A small fraction of the cholesterol made there is incorporated into the membranes of he-patocytes, but most of it is exported in one of three forms biliary cholesterol, bile acids, or cholesteryl esters. Bile acids and their salts are relatively hydrophilic cholesterol derivatives that are synthesized in the liver and aid in lipid digestion (see Fig. 17-1). Cholesteryl esters are formed in the liver through the action of acyl-CoA-cholesterol acyl transferase (ACAT). This enzyme catalyzes the transfer of a fatty acid from coenzyme A to the hydroxyl group of cholesterol (Fig. 21-38), converting the cholesterol to a more hydrophobic form. Cholesteryl esters are transported in secreted lipoprotein particles to other tissues that use cholesterol, or they are stored in the liver. 

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