Adenosylcobalamin

It is recognized that there are several important forms of vitamin The active coenzyme forms are adenosylcobalamin [13870-90-1] (coenzyme... 

Methylcobalamin and adenosylcobalamin are the two coen2yme forms of vitamin B 2 in animals and humans. Each is involved in the catalysis of a specific... 

Adenosylcobalamin (coenzyme B 2) is required in a number of rearrangement reactions that occurring in humans is the methylmalonyl-Co A mutase-mediated conversion of (R)-methylmalonyl-Co A (6) to succinjl-CoA (7) (eq. 1). The mechanism of this reaction is poorly understood, although probably free radical in nature (29). The reaction is involved in the cataboHsm of valine and isoleucine. In bacterial systems, adenosylcobalamin drives many 1,2-migrations of the type exemplified by equation 1 (30). 

Metabolism and Mobilization. On entry of vitamin B 2 into the cell, considerable metaboHsm of the vitamin takes place. Co(III)cobalamin is reduced to Co(I)cobalamin, which is either methylated to form methylcobalamin or converted to adenosylcobalamin (coenzyme B>22)- The methylation requires methyl tetrahydrofolate. 

The total syntheses have yielded cobyric acid and thence cyanocobalamin. Routes to other cobalamins, eg, methylcobalamin and adenosylcobalamin, are known (76—79). One approach to such compounds involves the oxidative addition of the appropriate alkyl haUde (eg, CH I to give methylcobalamin) or tosylate (eg, 5 -A-tosyladenosine to yield adenosylcobalamine) to cobalt(I)alamine. 

Methylmalonyl-CoA mutase (MCM) catalyzes a radical-based transformation of methylmalonyl-CoA (MCA) to succinyl-CoA. The cofactor adenosylcobalamin (AdoCbl) serves as a radical reservoir that generates the S -deoxyadenosine radical (dAdo ) via homolysis of the Co—C5 bond [67], The mechanisms by which the enzyme stabilizes the homolysis products and achieve an observed 1012-fold rate acceleration are yet not fully understood. Co—C bond homolysis is directly kineti-cally coupled to the proceeding hydrogen atom transfer step and the products of the bond homolysis step have therefore not been experimentally characterized. 

See also ATP entries hydrolysis of, 16 553 20 641 production of, 13 288 Adenosylcobalamin, 25 804 Adenoviruses, 3 136 Adequate Intake (AI), 25 784, 785t Adern, E., 11 8 Adherends, 1 501, 524 Adhesion, 1 501-524. See also Adhesive entries Pressure-sensitive adhesives (PSAs)... 

Adenosylcobalamin (coenzyme 812) carries a covalently bound adenosyl residue at the metal atom. This is a coenzyme of various isomerases, which catalyze rearrangements following a radical mechanism. The radical arises here through homolytic cleavage of the bond between the metal and the adenosyl group. The most important reaction of this type in animal metabolism is the rearrangement of methylmalonyl-CoAto form succinyl-CoA, which completes the breakdown of odd-numbered fatty acids and of the branched amino acids valine and isoleucine (see pp. 166 and 414). 

This enzyme [EC 2.5.1.17], also referred to as cob(I)-alamin adenosyltransferase or aquacob(I)alamin adeno-syltransferase, catalyzes the reaction of cob(I)alamin with ATP and water to produce adenosylcobalamin, orthophosphate, and pyrophosphate (or, diphosphate). A cofactor for this enzyme is manganese ion. 

The name vitamin B12 indicates a group of cobalt-containing corrinoids, also described as cobala-mins. Hydroxycobalamin (HOCbl), adenosylcobalamin (AdoCbl), and methylcobalamin (MeCbl) are the natural occurring forms. Instead, cyanocobalamin (Figure 19.20) is the commercially available form used for supplements and food fortification, thanks to its greater relative stability. Occasionally, sulfitocobalmin can occur in processed foods. Vitamin B,2 functions as a coenzyme and it is linked to human growth, cell development, and is involved in metabolism of certain amino acids. Vitamin B12 is present mainly in meat and diary foods, therefore a deficiency can occur in... 

The structure of the E. coli enzyme (Fig. 16-24) shows methylcobalamin bound in a base-off conformation, with histidine 759 of the protein replacing dimethylbenzimidazole in the distal coordination position on the cobalt. This histidine is part of a sequence Asp-X-His-X-X-Gly that is found not only in methionine synthase but also in methylmalonyl-CoA mutase, glutamate mutase, and 2-methyleneglutarate mutase. However, diol dehydratase lacks this sequence and binds adenosylcobalamin with the dimethylbenz-imidazole-cobalt bond intact.417... 

The Bj2 vitamers consist of a group of organometallic compounds that have a common cor-rinoid structure and vary in the substituent bound to the central cobalt atom (Fig. 7) (167,168). The principal naturally occurring Bl2 vitamers are hydroxocobalamin (HOCbl), methylcobal-amin (MeCbl), and adenosylcobalamin (AdoCbl). Cyanocobalamin (CNCbl) is the form commonly used for clinical, pharmaceutical, and food fortification purposes, due to its greater relative stability. 

CNCbl = cyanocobalamin HOCbl = hydroxocobalamin MeCbl = methylcobalamin AdoCbl = adenosylcobalamin. Column specifications expressed as (length X ID, particle size manufacturer) when reported in original publication. n = number of determinations. 

Coordination Compounds in Biology Table 19 Adenosylcobalamin-dependent Enzymes... 

H. Kajiura, K. Mori, T. Tobimatsu, and T. Toraya, Characterization and mechanism of action of a reactivating factor for adenosylcobalamin-dependent glycerol dehydratase, J. Biol. Chem. 2001, 276, 36514-36519. 

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