Methionine cobalamins

Cobalamin is a complex molecule containing a Co atom. In the mamalian synthesis of methionine, cobalamin acts as a coenzyme by accepting the methyl group from N5-methyltetrahydrofolate and transferring it to homocysteine. The reaction is catalyzed by cobalamin-N%-methyl-THF homocysteine methyltransferase. The overall reaction is... 

Mechanistic aspects of the action of folate-requiring enzymes involve one-carbon unit transfer at the oxidation level of formaldehyde, formate and methyl (78ACR314, 8OMI2I6OO) and are exemplified in pyrimidine and purine biosynthesis. A more complex mechanism has to be suggested for the methyl transfer from 5-methyl-THF (322) to homocysteine, since this transmethylation reaction is cobalamine-dependent to form methionine in E. coli. 

Enzymatic methylation of homocysteine (HSCHjCHjCHNHjCOOH) by methylcobalamin to give methionine (CH3SCH2CH2CHNH2COOH) was discovered in 1962 by Woods and co-workers, who also noticed the occurrence of a much slower, nonenzymatic reaction giving the same products. Methylcobinamide showed the same activity as the cobalamin in both the enzymatic and nonenzymatic reactions (72, 7/). It was subsequently discovered that HS, MeS , PhS , and w-BuS will dealkylate a variety of methyl complexes [DMG, DMG-BF2, DPG, G, salen, (DO)(DOH)pn, cobalamin] and even ethyl-Co(DMG)2 complexes to give the thioethers, and it was suggested that the reaction involved transfer of the carbonium ion to the attacking thiolate 161, 164), e.g.,... 

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. 

Zinc is the active metal in the largest group of metalloproteins found in the nature. Recently a new class of zinc enzymes with a sulfur-rich environment has emerged the thiolate-alkylating enzimes, the most prominent of which is the cobalamine-independent methionine synthase.126 For these reasons several monothiolate zinc complexes have been prepared for the modelling of these enzymes with different N2S as (13),127 130 N20,13° 132 N3,132,133 S3,134 tripod ligands, or with Cd because of the favourable spectroscopic properties with an S3 tripod ligand.135... 

Methionine synthase deficiency (cobalamin-E disease) produces homocystinuria without methylmalonic aciduria 677 Cobalamin-c disease remethylation of homocysteine to methionine also requires an activated form of vitamin B12 677 Hereditary folate malabsorption presents with megaloblastic anemia, seizures and neurological deterioration 678... 

A relatively large number of agents have been utilized to treat this intractable disorder folinic acid (5-formyl-tetrahydrofolic acid), folic acid, methyltetrahydrofolic acid, betaine, methionine, pyridoxine, cobalamin and carnitine. Betaine, which provides methyl groups to the beta i ne ho mocystei ne methyltransferase reaction, is a safe treatment that lowers blood homocysteine and increases methionine. 

In cobalamin-E (cblE) disease there is a failure of methyl-B12 to bind to methionine synthase. It is not known if this reflects a primary defect of methionine synthase or the absence of a separate enzyme activity. Patients manifest megaloblastic changes with a pancytopenia, homocystinuria and hypomethioninemia. There is no methylmalonic aciduria. Patients usually become clinically manifest during infancy with vomiting, developmental retardation and lethargy. They respond well to injections of hydroxocobalamin. 

Cobalamin-c disease remethylation of homocysteine to methionine also requires an activated form of vitamin B12. In the absence of normal B12 activation, homocystinuria results from a failure of normal vitamin B12 metabolism. Complementation analysis classifies defects in vitamin B12 metabolism into three groups cblC (most common), cblD and cblF. Most individuals become ill in the first few months or weeks of life with hypotonia, lethargy and growth failure. Optic atrophy and retinal changes can occur. Methylmalonate excretion is excessive, but less than in methylmalonyl-CoA mutase deficiency, and without ketoaciduria or metabolic acidosis. 

Figure 15.11 Reactions catalysed by cobalamin-dependent methionine synthase. (From Banneijee and Ragsdale, 2003. Reprinted with permission from Annual Reviews.)...

It is the role of jV5-methyl THF which is key to understanding the involvement of cobalamin in megaloblastic anaemia. The metabolic requirement for N-methyl THF is to maintain a supply of the amino acid methionine, the precursor of S-adenosyl methionine (SAM), which is required for a number of methylation reactions. The transfer of the methyl group from jV5-methyl THF to homocysteine is cobalamin-dependent, so in B12 deficiency states, the production of SAM is reduced. Furthermore, the reaction which brings about the formation of Ns-methyl THF from N5,N10-methylene THF is irreversible and controlled by feedback inhibition by SAM. Thus, if B12 is unavailable, SAM concentration falls and Ah -methyl THF accumulates and THF cannot be re-formed. The accumulation of AT-methyl THF is sometimes referred to as the methyl trap because a functional deficiency of folate is created. 

Researchers studying the metalloenzyme hydrogenase would like to design small compounds that mimic this enzyme s ability to reversibly reduce protons to H2 and H2 to 2H+, using an active center that contains iron and nickel. Cobalamins (vitamin and its derivatives) contain an easily activated Co-C bond that has a number of biological functions, one of which is as a methyl transferase, 5-methyltetrahydrofolate-homocysteine methyltransferase (MTR). This enzyme converts homocysteine (an amino acid that has one more CH2 group in its alkyl side chain than cysteine see Figure 2.2) to methionine as methylcobalamin is converted to cobalamin. 

The structure of cobalamin is more complex than that of folic acid (Figure 15.2 and 15.3). At its heart is a porphyrin ring containing the metal ion cobalt at its centre. In catalytic reactions the cobalt ion forms a bond with the one-carbon group, which is then transferred from one compound to another. Vitamin B12 is the prosthetic group of only two enzymes, methylmalonyl-CoAmutase and methionine synthase. The latter enzyme is particularly important, as it is essential for the synthesis of nucleotides which indicates the importance of vitamin B12 in maintenance of good health. 

In animal metabolism, derivatives of cobalamine are mainly involved in rearrangement reactions. For example, they act as coenzymes in the conversion of methylmalonyl-CoA to succinyl-CoA (see p. 166), and in the formation of methionine from homocysteine (see p. 418). In prokaryotes, cobalamine derivatives also play a part in the reduction of ribonucleotides. 

This cobalamin-dependent enzyme [EC 2.1.1.13], also known as methionine synthase and tetrahydropteroyl-glutamate methyltransferase, catalyzes the reaction of 5-methyltetrahydrofolate with L-homocysteine to produce tetrahydrofolate and L-methionine. Interestingly, the bacterial enzyme is reported to require 5-adenosyl-L-methionine and FADH2. See also Tetrahydropteroyl-triglutamate Methyltransferase... 

Cobalamin compounds Tight Cobalamin (B12) Transfer of methyl group to homocysteine during synthesis of methionine metabolism of methylmalonyl coenzyme A... 

Vitamin Bjj (8.50, cobalamin) is an extremely complex molecule consisting of a corrin ring system similar to heme. The central metal atom is cobalt, coordinated with a ribofuranosyl-dimethylbenzimidazole. Vitamin Bjj occurs in liver, but is also produced by many bacteria and is therefore obtained commercially by fermentation. The vitamin is a catalyst for the rearrangement of methylmalonyl-CoA to the succinyl derivative in the degradation of some amino acids and the oxidation of fatty acids with an odd number of carbon atoms. It is also necessary for the methylation of homocysteine to methionine. 

Homocyst(e)ine CBS deficiency Cobalamin defects/defi-ciency MTHFR deficiency Methionine adenosyltrans-ferase deficiency Hyperhomocysteinemia Sulfite oxidase deficiency... 

Methionine Methionine adenosyltrans-ferase deficiency Cobalamin defects... 

The loss of a methyl group from AdoMet in each of the reactions yields S-ad-enosylhomocysteine (AdoHcy) and this is subsequently hydrolysed to adenosine and Hey by AdoHcy-hydrolase. Hey sits at a metabolic branch point and can be remethylated to methionine by way of two reactions. One is the 5-methyltetrahydrofo-late dependent reaction catalysed by methionine synthase, which itself is reductively methylated by cobalamin (vitamin B12) and AdoMet, requiring methionine synthase reductase. 5-Methyltetrahydrofolate is generated from 5,10-methylenetetrahydrofo-late (MTHF) by MTHF reductase. The second remethylation reaction is catalysed by betaine methyltransferase, which is restricted to the liver, kidney and brain, while methionine synthase is widely distributed. 

Fig. 2.2.1 Outline of homocysteine metabolism in man. BMT Betaine methyltransferase, cblC cobalamin defect type C, cblD cobalamin defect type D, GNMT def glycine N-methyltransferase deficiency, MAT methionine adenosyl transferase, MeCbl methylcobalamin, Met Synth methionine synthase, MTHFR methylenetetrahydrofolate reductase, SAH Hyd dc/S-adenosylhomocys-...

A large elevation of Hey in body fluids and tissues is found in several genetic enzyme deficiencies, the homocystinurias. These include cystathionine /3-synlhase deficiency [9], the remethylation defects due to deficiency of MTHF reductase [10], methionine synthase and methionine synthase reductase deficiencies, as well as defects of intracellular cobalamin metabolism [11], namely the cblF, cblC and cblD defects. It is noteworthy that low levels of total Hey (tHcy) have been described in sulphite oxidase deficiency [12]. 

Vitamin B12 consists of a porphyrin-like ring structure, with an atom of Co chelated at its centre, linked to a nucleotide base, ribose and phosphoric acid (6.34). A number of different groups can be attached to the free ligand site on the cobalt. Cyanocobalamin has -CN at this position and is the commercial and therapeutic form of the vitamin, although the principal dietary forms of B12 are 5 -deoxyadenosylcobalamin (with 5 -deoxyadeno-sine at the R position), methylcobalamin (-CH3) and hydroxocobalamin (-OH). Vitamin B12 acts as a co-factor for methionine synthetase and methylmalonyl CoA mutase. The former enzyme catalyses the transfer of the methyl group of 5-methyl-H4 folate to cobalamin and thence to homocysteine, forming methionine. Methylmalonyl CoA mutase catalyses the conversion of methylmalonyl CoA to succinyl CoA in the mitochondrion. 

Vitamin B12 Cobalamin Methylcobalamin Deoxyadenosyl cobalamin Cofactor for reactions Homocysteine > Methionine I Methylmalonyl CoA -> Succinyl CoA j... 

Vitamin B12 (cobalamin) has as its active forms, methylcobalamin and deoxyadenosyl cobalamin. It serves as a cofactor for the conversion of homocysteine to methionine, and methylmalonyl CoA to succinyl CoA. A deficiency of cobalamin results in pernicious (megaloblastic) anemia, dementia, and spinal degeneration. The anemia is treated with IM or high oral doses of vitamin B12. There is no known toxicity for this vitamin. 

Although numerous enzymatic reactions requiring vitamin B12 have been described, and 10 reactions for adenosylcobalamin alone have been identified, only three pathways in man have so far been recognized, one of which has only recently been identified (PI). Two of these require the vitamin in the adenosyl form and the other in the methyl form. These cobalamin coenzymes are formed by a complex reaction sequence which results in the formation of a covalent carbon-cobalt bond between the cobalt nucleus of the vitamin and the methyl or 5 -deoxy-5 -adenosyl ligand, with resulting coenzyme specificity. Adenosylcobalamin is required in the conversion of methylmalonate to succinate (Fig. 2), while methylcobalamin is required by a B12-dependent methionine synthetase that enables the methyl group to be transferred from 5-methyltetrahydrofolate to homocysteine to form methionine (Fig. 3). 

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