Methionine to homocysteine

The route from methionine to homocysteine is described in more detail in Figure 18-18 the conversion of homocysteine to a-ketobutyrate in Figure 22-14 the conversion of propionyl-CoA to succinyl-CoA in Figure 17-11. 

Figure 26-32 Biochemical pathways of the conversion of methionine to homocysteine and cysteine.

The conversion of methionine to homocysteine and homocysteine to cysteine is the major degradative route for these two amino acids. Because this is the only degradative route for homocysteine, vitamin B6 deficiency or congenital cystathi-none (3-synthase deficiency can result in homocystinemia, which is associated with cardiovascular disease. 

Table 47.4 Estimation of remethylation and transsulfuration activities. The ratio of methionine to homocysteine (M/H) was significantly decreased in patients with CKD stage V, but elevated after each supplementation regimen supplementation. On the other hand, the ratio of cysteine to homocysteine (C/H) did not deteriorate and increased considerably after treatment whether accompanied by vitamin Bg or not. M/H represents remethylation activity and C/H represents transsulfuration activity. Reproduced with permission from Koyama (2011).

Conversion of Methionine to Homocysteine. The conversion of methionine to the corresponding keto acid does not bring the thiomethyl group directly into action. On the contrary, the fact that this group plays the principal role in the demethylation of methionine has been demonstrated in the work of du Vigneaud and collaborators. Numerous observations have been carried out with living animals which have shown... 

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. 

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. 

Methionine synthase deficiency (cobalamin-E disease) produces homocystinuria without methylmalonic aciduria. This enzyme mediates the transfer of a methyl group from methyltetrahydrofolate to homocysteine to yield methionine (Fig. 40-4 reaction 4). A cobalamin group bound to the enzyme is converted to methylcobalamin prior to formation of methionine. 

The best characterized B 12-dependent methyltransferases is methionine synthase (Figure 15.11) from E. coli, which catalyses the transfer of a methyl group from methyltetrahydrofolate to homocysteine to form methionine and tetrahydrofolate. During the catalytic cycle, B12 cycles between CH3-Co(in) and Co(I). However, from time to time, Co(I) undergoes oxidative inactivation to Co(II), which requires reductive activation. During this process, the methyl donor is S-adenosylmethionine (AdoMet) and the electron donor is flavodoxin (Fid) in E. coli, or methionine synthase reductase (MSR) in humans. Methionine synthase... 

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. 

Important pathways requiring SAM include synthesis of epinephrine and of the 7-methylgua-nine cap on eukaryotic mRNA, Synthesis of SAM from methionine is shown in Figure T17-3. After donating the methyl group, SAM is converted to homocysteine and remethylated in a reaction catalyzed by N-methyl THF-homocysteine methyltransferase requirii both vitamin Bj2 and N-meth d-THF. The methionine produced is once again used to make SAM. 

Figure 15.5 Four reactions involved in methylatlon. The reactions are (1) formation of S-adenosylmethlonIne (SAM) (11) transfer of methyl group to an acceptor (111) conversion of S-adenosylmethlonIne to homocysteine (Iv) conversion of homocysteine to methionine using methyl tetrahydrofolate as the methyl donor with the formation of FH4.

Homocysteine is an intermediate in the metabolism of methionine and disturbances in metabolism of this amino acid can lead to an elevated plasma level of homocysteine. The risk is due not to homocysteine itself but to a thiolactone, to which homocysteine is converted spontaneously (Figure 22.7 Box 22.3). 

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. 

Enzymatic O-methylation of flavonoids, which is catalyzed by O-methyltransferases (E.C. 2.1.1.6-) involves the transfer of the methyl group of an activated methyl donor, S -adenosyl-L-methionine, to the hydroxyl group of a flavonoid acceptor with the formation of the corresponding methylether and S -adenosyl-L-homocysteine. The latter product is, in... 

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

Two essential enzymatic reactions in humans require vitamin B12 (Figure 33-2). In one, methylcobalamin serves as an intermediate in the transfer of a methyl group from /V5-methyltetrahydrofolate to homocysteine, forming methionine (Figure 33-2A Figure 33-3, section 1). Without vitamin B12, conversion of the major dietary and storage folate, N5-... 

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. 

Transfer of the methyl group from 5,-adenosylmethi-onine to an acceptor yields S -adenosylhomocysteine (Fig. 18-18, step (2)), which is subsequently broken down to homocysteine and adenosine (step (3)). Methionine is regenerated by transfer of a methyl group to homocysteine in a reaction catalyzed by methionine synthase (step (4)), and methionine is reconverted to 5-adenosyl-methionine to complete an activated-methyl cycle. 

Hydrolysis of SAM After donation of the methyl group, S-adenosylhomocysteine is hydrolyzed to homocysteine aid adenosine. Homocysteine has two fates. If there is a deficiency of methionine, homocysteine may be remethylated to methionine (see Figure 20.8). If methionine stores are adequate, homocysteine rmty enter the transsulfuration pathway, where it is converted to cysteine. 

When present in excess methionine is toxic and must be removed. Transamination to the corresponding 2-oxoacid (Fig. 24-16, step c) occurs in both animals and plants. Oxidative decarboxylation of this oxoacid initiates a major catabolic pathway,305 which probably involves (3 oxidation of the resulting acyl-CoA. In bacteria another catabolic reaction of methionine is y-elimination of methanethiol and deamination to 2-oxobutyrate (reaction d, Fig. 24-16 Fig. 14-7).306 Conversion to homocysteine, via the transmethylation pathway, is also a major catabolic route which is especially important because of the toxicity of excess homocysteine. A hereditary deficiency of cystathionine (3-synthase is associated with greatly elevated homocysteine concentrations in blood and urine and often disastrous early cardiovascular disease.299,307 309b About 5-7% of the general population has an increased level of homocysteine and is also at increased risk of artery disease. An adequate intake of vitamin B6 and especially of folic acid, which is needed for recycling of homocysteine to methionine, is helpful. However, if methionine is in excess it must be removed via the previously discussed transsulfuration pathway (Fig. 24-16, steps h and z ).310 The products are cysteine and 2-oxobutyrate. The latter can be oxidatively decarboxylated to propionyl-CoA and further metabolized, or it can be converted into leucine (Fig. 24-17) and cysteine may be converted to glutathione.2993... 

Cysteine is formed in plants and in bacteria from sulfide and serine after the latter has been acetylated by transfer of an acetyl group from acetyl-CoA (Fig. 24-25, step f). This standard PLP-dependent (3 replacement (Chapter 14) is catalyzed by cysteine synthase (O-acetylserine sulfhydrase).446 447 A similar enzyme is used by some cells to introduce sulfide ion directly into homocysteine, via either O-succinyl homoserine or O-acetyl homoserine (Fig. 24-13). In E. coli cysteine can be converted to methionine, as outlined in Eq. lb-22 and as indicated on the right side of Fig. 24-13 by the green arrows. In animals the converse process, the conversion of methionine to cysteine (gray arrows in Fig. 24-13, also Fig. 24-16), is important. Animals are unable to incorporate sulfide directly into cysteine, and this amino acid must be either provided in the diet or formed from dietary methionine. The latter process is limited, and cysteine is an essential dietary constituent for infants. The formation of cysteine from methionine occurs via the same transsulfuration pathway as in methionine synthesis in autotrophic organisms. However, the latter use cystathionine y-synthase and P-lyase while cysteine synthesis in animals uses cystathionine P-synthase and y-lyase. 

Vitamin B12 is a biologically active corrinoid, a group of cobalt-containing compounds with macrocyclic pyrrol rings. Vitamin B12 functions as a cofactor for two enzymes, methionine synthase and L-methylmalonyl coenzyme A (CoA) mutase. Methionine synthase requires methylcobalamin for the methyl transfer from methyltetrahydrofolate to homocysteine to form methionine tetrahy-drofolate. L-methylmalonyl-CoA mutase requires adenosylcobalamin to convert L-methylmalonyl-CoA to succinyl-CoA in an isomerization reaction. An inadequate supply of vitamin B12 results in neuropathy, megaloblastic anemia, and gastrointestinal symptoms (Baik and Russell, 1999). 

Homocysteine is formed as an intermediary amino acid in the methionine cycle (Fig. I). Methionine is metabolized to s-adenosylmethionine (SAM), the methyl donor in most methylation reactions and essential for the synthesis of creatinine, DNA, RNA, proteins, and phospholipids. SAM is converted by methyl donation to s-adenosylhomocysteine (SAH), which is then hydrolyzed to homocysteine. SAH is an inhibitor of methyl group donation from SAM. 

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