Thiamine-pyrophosphate-aldehyde

Thiamine (Bj) Thiamine pyrophosphate Aldehyde transfer Beriberi (weight loss, heart problems, neurological dysfunction)... 

Thiamin Thiamin pyrophosphate Aldehyde group transfer... 

A number of lyases are known which, unlike the aldolases, require thiamine pyrophosphate as a cofactor in the transfer of acyl anion equivalents, but mechanistically act via enolate-type additions. The commercially available transketolase (EC 2.2.1.1) stems from the pentose phosphate pathway where it catalyzes the transfer of a hydroxyacetyl fragment from a ketose phosphate to an aldehyde phosphate. For synthetic purposes, the donor component can be replaced by hydroxypyruvate, which forms the reactive intermediate by an irreversible, spontaneous decarboxylation. 

Fermenting baker s yeast also catalyzes the 1,4-addition of a formal trifluoroethanol-d1-synthon to a,/i-unsaturated aldehydes, to give optically active l,l,l-trifluoro-2-hydroxy-5-alka-nones52. Presumably, the mechanism involves oxidation of the alcohol to the corresponding aldehyde followed by an umpolung step with thiamine pyrophosphate and Michael addition to the a,/i-unsaturated aldehyde. For example, l,l,l-trifluoro-2-hydroxy-5-hexanone (yield 26%, ee 93%) is thus obtained from trifluoroethanol and l-bnten-3-one. 

Group-transfer reactions often involve vitamins3, which humans need to have in then-diet, since we are incapable of realizing their synthesis. These include nicotinamide (derived from the vitamin nicotinic acid) and riboflavin (vitamin B2) derivatives, required for electron transfer reactions, biotin for the transfer of C02, pantothenate for acyl group transfer, thiamine (vitamin as thiamine pyrophosphate) for transfer of aldehyde groups and folic acid (as tetrahydrofolate) for exchange of one-carbon fragments. Lipoic acid (not a vitamin) is both an acyl and an electron carrier. In addition, vitamins such as pyridoxine (vitamin B6, as pyridoxal phosphate), vitamin B12 and vitamin C (ascorbic acid) participate as cofactors in an important number of metabolic reactions. 

However, cyanide ion is not suitable for inducing a benzoin-type condensation between two aliphatic aldehydes, since the basic character of this ion induces an aldol condensation between them. In Nature, nevertheless, condensations of this type take place easily. As Breslow proposed in 1958 [8], such condensations are catalysed by thiamine pyrophosphate 6 (or cocarboxylase), the active part of which is the conjugate base of the "thiazolium cation present in it. According to Breslow [8a], the mechanism is, in fact, identical to that described for the cyanide ion (see Scheme 5.7) that is to say, the conjugate base of thiamine (TPP ) reacts with an "aldehyde equivalent -such as an a-ketoacid 2- to generate the corresponding "active aldehyde" 8 with umpoled reactivity, which then reacts with the electrophile to give finally, after elimination of "thiamine anion", a 1,2-D system (9). 

This thiamin pyrophosphate-dependent enzyme [EC 4.1.1.1] catalyzes the conversion of an a-keto acid (or, a 2-0X0 acid) to an aldehyde and carbon dioxide. This enzyme will also catalyze acyloin formation. 

Thiamin itself (in the absence of enzyme) had previously been shown to catalyse the formation of acetoin from acetaldehyde, albeit in very poor yield (Ukai et al., 1943 Mizuhara et al., 1951 Mizuhara and Handler, 1954). The reaction parallels the formation of benzoin from benzaldehyde, catalysed by cyanide ion. The mechanism of the latter reaction had been suggested in 1903 by Arthur Lapworth, who had shown how an aldehyde, R—CHO, could be converted into the equivalent of the anion R—C=0- (Lapworth, 1903). It is this idea that Breslow carried over to thiamin pyrophosphate and used to... 

Nearly all the water-soluble vitamins are heterocyclic compounds. Among the first to be isolated was thiamine (vitamin Bi) (62), deficiency of which causes degenerative changes in the nervous system, including the multiple peripheral neuritis characteristic of beriberi. Thiamine deficiency can arise from decomposition of the vitamin by bacteria in the gut. In mammalian metabolism the hydroxy group of thiamine is esterified to give cocarboxylase (thiamine pyrophosphate) which catalyzes the decarboxylation of a-keto acids to aldehydes, acyloins or acids, and their transformation into acyl phosphates. 

Transketolase is one of several enzymes that catalyze reactions of intermediates with a negative charge on what was initially a carbonyl carbon atom. All such enzymes require thiamine pyrophosphate (TPP) as a cofactor (chapter 10). The transketolase reaction is initiated by addition of the thiamine pyrophosphate anion to the carbonyl of a ketose phosphate, for example xylulose-5-phosphate (fig. 12.33). The adduct next undergoes an aldol-like cleavage. Carbons 1 and 2 are retained on the enzyme in the form of the glycol-aldehyde derivative of TPP. This intermediate condenses with the carbonyl of another aldolase. If the reactants are xylulose-5-phosphate and ribose-5-phosphate, the products are glyceraldehyde-3-phosphate and the seven-carbon ketose, sedoheptulose-7-phosphate (see fig. 12.33). 

In the first step of the conversion catalyzed by pyruvate decarboxylase, a carbon atom from thiamine pyrophosphate adds to the carbonyl carbon of pyruvate. Decarboxylation produces the key reactive intermediate, hydroxyethyl thiamine pyrophosphate (HETPP). As shown in figure 13.5, the ionized ylid form of HETPP is resonance-stabilized by the existence of a form without charge separation. The next enzyme, dihydrolipoyltransacetylase, catalyzes the transfer of the two-carbon moiety to lipoic acid. A nucleophilic attack by HETPP on the sulfur atom attached to carbon 8 of oxidized lipoic acid displaces the electrons of the disulfide bond to the sulfur atom attached to carbon 6. The sulfur then picks up a proton from the environment as shown in figure 13.5. This simple displacement reaction is also an oxidation-reduction reaction, in which the attacking carbon atom is oxidized from the aldehyde level in HETPP to the carboxyl level in the lipoic acid derivative. The oxidized (disulfide) form of lipoic acid is converted to the reduced (mer-capto) form. The fact that the two-carbon moiety has become an acyl group is shown more clearly after dissocia-... 

In both reactions cyanide has usually been employed as catalyst [231, 232], Under these conditions, the acyl anion equivalent is represented by the tautomeric form XIX of the cyanohydrin anion which results from addition of cyanide to an aldehyde (Scheme 6.104). In nature, this type of Umpolung is performed enzymatically, with the aid of the cofactor thiamine pyrophosphate 226 (vitamin Bl, Scheme 6.105) [232, 233]. 

G3P) and D-sedoheptulose 7-P as illustrated in Scheme 5.53. In addition D-erythrose 4-phosphate can function as the ketol acceptor thus producing D-fructose-6-P and G3P (Scheme 5.53). The enzyme relies on two cofactors for activity — thiamin pyrophosphate (TPP) and Mg2+—and utilizes the nucleophilic catalysis mechanism outlined in (Scheme 5.54).83 When TPP is used as a cofactor for nucleophilic catalysis, an activated aldehyde intermediate is formed. This intermediate functions as a nucleophile, and thus TK employs a strategy that is similar to the umpolung strategy exploited in synthetic organic chemistry. 

Scheme 5.54. Thiamine pyrophosphate (TPP) addition to D-xylulose-5-phosphate provides an electron sink to stabilize the incipient carbanion, which in turn reacts with the incoming aldehyde acceptor. P = PO .

Pyruvate decarboxylase catalyzes the nonoxidative decarboxylation of pyruvate to acetaldehyde and carbon dioxide. When an aldehyde is present with pyruvate, the enzyme promotes an acyloin condensation reaction. The mechanistic reason for this fortuitous reaction is well understood and involves the aldehyde outcompeting a proton for bond formation with a reactive thiamine pyrophosphate-bound intermediate (90,91). When acetaldehyde is present, the product formed is acetoin. Benzalde-hyde results in the production of phenylacetylcarbinol (Fig. 26). Both of these condensations are enantioselective, forming the R enantiomer preferentially in both cases. 

The answer is c. (Murray, pp 627—661. Scriver, pp 3897—3964. Sack, pp 121-138. Wilson, pp 287-320.1 In the Far East, rice is a staple of the diet. When rice is unsupplemented, beriberi can be manifest, since rice is low in vitamin Bi (thiamine). Thiamine pyrophosphate is the necessary prosthetic group of enzymes that transfers activated aldehyde units. Such enzymes... 

Bi) is converted to thiamine pyrophosphate simply by the addition of pyrophosphate. It is involved in aldehyde group transfer. Niacin (nicotinic acid) is esterified to adenine dinucleotide and its two phosphates to form nicotinamide adenine dinucleotide. Pyridoxine (vitamin B ) is converted to either pyridoxal phosphate or pyridoxamine phosphate before complexing with enzymes. Riboflavin becomes flavin mononucleotide by obtaining one phosphate (riboflavin 5 -phosphate). If it complexes with adenine dinucleotide via a pyrophosphate ester linkage, it becomes flavin adenine dinucleotide. 

Thiamine (vitamin Bj) is an important water-soluble vitamin that, in its active form of thiamine pyrophosphate, is used as a cofactor in enzymatic reactions that involve the transfer of an aldehyde group. Thiamine can be synthesized by plants and some microorganisms, but not usually by animals. Hence, humans must obtain thiamine from the diet, though small amounts may be obtained from synthesis by intestinal bacteria. Because of its importance in metabolic reactions, it is present in large amounts in skeletal muscle, heart, liver, kidney, and brain. Thus, it has a widespread distribution in foods, but there can be a substantial loss of thiamine during cooking above 100°C (212°F). 

Thiamine (vitamin Bj) is an important water-soluble vitamin that, in its active form of thiamine pyrophosphate, is used as a cofactor in enzymatic reactions that involve the transfer of an aldehyde group. 

Water-Soluble Vitamins Thiamine (B,) Thiamine pyrophosphate Decarboxylation, aldehyde group transfer... 

This enzyme catalyzes the reversible transfer of the hydroxyketo group of a ketose phosphate to an aldose phosphate. The cofactor thiamine pyrophosphate (TPP) is associated with the enzyme and activates the ketose (Scheme 7). Most known donor ketoses (xylulose 5-phosphate, sedoheptulose 7-phosphate, fructose 6-phosphate, L-erythrose) have a trans arrangement of hydroxy groups at C-3 and C-4 hydroxypyruvate is an exception. A range of aldehydes (such as o-glyceraldehyde 3-phosphate, D-ribose 5-phosphate, o-erythrose 4-phosphate, glycoaldehyde) are acceptors. Transketolase has been... 

The usefulness of thiamine pyrophosphate in carbon-carbon-bond-forming reactions is exemplified by the condensation of aldehydes and ketones to give a-hydroxy ketones (Scheme 3), and the mechanistically similar a-ketol transfers (Scheme 4). 

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