Aldol condensation aldolase-catalyzed

N-Acetvlneuraminic Acid Aldolase. A new procedure has also been developed for the synthesis of 9-0-acetyl-N-acetylneuraminic acid using the aldolase catalyzed reaction methodology. This compound is an unusual sialic acid found in a number of tumor cells and influenza virus C glycoproteins (4 ). The aldol acceptor, 6-0-acetyl-D-mannosamine was prepared in 70% isolated yield from isopropenyl acetate and N-acetyl-D-mannosamine catalyzed by protease N from Bacillus subtilis (from Amano). The 6-0-acetyl hexose was previously prepared by a complicated chemical procedure (42.) The target molecule was obtained in 90% yield via the condensation of the 6-0-acetyl sugar and pyruvate catalyzed by NANA aldolase (Figure 6). With similar procedures applied to KDO, 2-deoxy-NANA and 2-deoxy-2-fluoro-NANA were prepared from NANA. 

Figure 6. Synthesis of 9-0-acetyl-N-acetylneuraminic acid. The aldol acceptor was prepared from N-acetylmannosamine and isopropenyl acetate in DMF catalyzed by protease N obtained from Amano. The aldol condensation was carried out by using N-acetylneuraminic acid aldolase as catalyst.

Cleavage of Fructose 1,6-Bisphosphate The enzyme fructose 1,6-bisphosphate aldolase, often called simply aldolase, catalyzes a reversible aldol condensation (p. 485). Fructose 1,6-bisphosphate is cleaved to yield two different triose phosphates, glyceraldehyde 3-phosphate, an aldose, and dihydroxyacetone phosphate, a lcetose ... 

C.-H. Lin, T. Sugai, R. L. Halcomb, Y. Ichikawa, and C. H. Wong, Unusual stereoselectivity in sialic acid aldolase-catalyzed aldol condensations Synthesis of both enantiomers of high-carbon monosaccharides, J. Am. Chem. Soc. 774 10138 (1992). 

Cleavage of fructose-l,6-bisphosphate, an aldolase-catalyzed reaction. The aldolase reaction entails a reversal of the familiar aldol condensation. The first step involves abstraction of the hydrogen of the C-4 hydroxyl group, followed by elimination of an enolate anion. 

The transaldolase-catalyzed conversion of fructose-6-phosphate and erythrose-4-phosphate to glyceraldehyde-3-phosphate and sedoheptulose-7-phosphate. This is a two-step conversion. The first step is similar to the aldolase reaction except that the dihydroxyacetone produced is held at the catalytic site while the aldose product diffuses away and is replaced by another aldose molecule. The second step involves an aldol condensation. 

Transaldolase catalyzes a two-step conversion. The first step, an aldol cleavage of the bond between C-3 and C-4 of a ketose, is essentially identical to the reaction catalyzed by aldolase. However, the dihydroxyacetone that is produced in the transaldolase reaction from carbons 1, 2, and 3 is not released. Rather, it is held at the catalytic site while the glyceraldehyde-3-phosphate produced diffuses away and is replaced by erythrose-4-phosphate. An aldol condensation then generates the second product of the reaction, a ketose that contains the first three carbon atoms of the original ketose attached to C-1 of the acceptor aldose (fig. 12.32). 

Reymond and Chen88 have investigated the same set of antibodies for their ability to catalyze bimolecular aldol condensation reactions. The antibodies were assayed individually at pH 8.0 for the formation of aldol 111 from aldehyde 109 and acetone. None catalyzed the direct reaction, but in the presence of amine 110 three anti-52a and three anti-52b antibodies showed modest activity. In analogy with natural type I aldolase enzymes, the reaction is believed to occur by formation of an enamine from acetone and the amine, followed by rate-determining condensation of the enamine with the aldehyde. As in the previous example, the catalyst, which was characterized in detail, is not very efficient in absolute terms ( cat = 3 x 10-6 s 1 for the anti-52b antibody 72D4), but it is approximately 600 times more effective than amine alone. Moreover, the reactions with the antibody are stereoselective The enamine adds only to the si face of the aldehyde to give... 

The use of enzymes for the aldol reaction complements traditional chemical approaches. In the early twentieth century a class of enzymes was recognized that catalyzes, by an aldol condensation, the reversible formation of hexoses from their three carbon components.3 The lyases that catalyze the aldol reaction, are referred to as aldolases. More than 30 aldolases have been characterized to date. These aldolases are capable of stereospecifically catalyzing the reversible addition of a ketone or aldehyde donor to an aldehyde acceptor. Two distinct mechanistic classes of aldolases have been identified (Scheme 5.1).4... 

Aldol condensation reactions are catalyzed by amines and the active sites of many aldolases contain an essential lysine residue. Using a strategy of reactive immunization with a 1,3-diketone (18 in Fig. 5.8), Wagner et al. were able to generate antibodies with aldolase activity. These were shown to possess a highly reactive lysine residue in... 

Fructose-6-phosphate formed from the isomerization discussed above is further phos-phorylated during glycolysis to fructose-1,6-diphosphate (108), which is then cleaved by fructose-1,6-bisphosphate aldolase to afford dihydroxy acetone phosphate (109) and glyceraldehyde-3-phosphate (110). This cleavage reaction is the reverse of an aldol condensation discussed in Section II.C and during gluconeogenesis. In the latter case, fructose-1,6-bisphosphate aldolase catalyzes the reverse reaction herein via aldol condensation of the ketose 109 and the aldose 110 to form linear fructose-1,6-bisphosphate (108) . 

This reaction is catalyzed by aldolase. This enzyme derives its name from the nature of the reverse reaction, an aldol condensation. The reaction catalyzed by aldolase is readily reversible under intracellular conditions. 

We will consider the mechanism of transketolase when we meet it again in the pentose phosphate pathway (Section 20.3.2). Aldolase, which we have already encountered in glycolysis (Section 16.1.3). catalyzes an aldol condensation between dihydroxyacetone phosphate and an aldehyde. This enzyme is highly specific for dihydroxyacetone phosphate, but it accepts a wide variety of aldehydes. 

Enzymes turned out to be very helpful in the de novo synthesis of certain monosaccharides. Generally, two chiral carbonyl compounds are combined in an aldol-type reaction. In carbohydrate metabolism, aldolases catalyze the condensation of dihydroxyacetone phosphate (DHAP) and aldehydes to higher sugar components. To date, about thirty aldolases have been classified, but only... 

The enzymatic aldol reaction represents a useful method for the synthesis of various sugars and sugar-like structures. More than 20 different aldolases have been isolated (see Table 13.1 for examples) and several of these have been cloned and overexpressed. They catalyze the stereospecific aldol condensation of an aldehyde with a ketone donor. Two types of aldolases are known. Type I aldolases, found primarily in animals and higher plants, do not require any cofactor. The x-ray structure of rabbit muscle aldolase (RAMA) indicates that Lys-229 is responsible for Schiff-base formation with dihydroxyacetone phosphate (DHAP) (Scheme 13.7a). Type II aldolases, found primarily in micro-organisms, use Zn as a cofactor, which acts as a Lewis acid enhancing the electrophilicity of the ketone (Scheme 13.7b). In both cases, the aldolases accept a variety of natural (Table 13.1) and non-natural acceptor substrates (Scheme 13.8). 

One of the most efficient methods for the generation of 2,5-dideoxy-2,5-iminogalactitol 16 relies on the fuculose-1-phosphate aldolase-catalyzed aldol condensation of 2-azido-3-hydroxypropanal with dihydroxyacetone monophosphate (Scheme 13.17). The same method, applied to (2/ )-2-azidopropanal R)-V7 and to (25 )-2-azido-propanal (5 )-17, allows for the preparation of 2,5,6-trideoxy-2,5-imino-D-allitol 18 and 2,5,6-trideoxy-2,5-imino-L-talitol 19, respectively [22]. 

R, = OH, Rj = H, R2 = OH, R4 = CHjOH in Table 3), the enantiomeric compound of the one just reported could be easily prepared. Aldol condensation products were obtained as diastereomeric mixtures from L-sugars, such as L-fucose, L-xylose, L-lyxose, and o-sugars epimeric to o-mannose relative to the 3-position, such as D-allose and o-gulose [46-48]. Table 4 lists the corresponding aldol condensation products isolated as diastereomeric mixtures. Also, 3-deoxy-D-mannose by condensation with pyruvate gave a diastereomeric mixture of 6-deoxy-KDN furanose derivatives [43]. All these results confirm that sialic acid aldolase, similar to other aldolases, exhibits broad specificity toward the electrophilic acceptor on the other hand, only pyruvate was reported acceptable as the donor [10]. But very recently, in contradiction to that, 3-fluoro-Neu5Ac and 3-fluoro-KDN could be prepared by the sialic acid aldolase-catalyzed condensation of 3-fluoropyruvate and Af-acetylmannosamine or o-mannose (Scheme 5) [47]. 

Fructose 1-phosphate is further metabolized to dihydroxyacetone phosphate (DHAP) and glyceraldehyde by the hepatic isoform of the enzyme aldolase, which catalyzes a reversible aldol condensation reaction. Aldolase is present in three different isoforms. Aldolase A is present in greatest concentrations in the skeletal muscle, whereas the B isoform predominates in the liver, kidney, and intestine. Aldolase C is the brain isoform. Aldolase B has similar activity for either fructose 1,6-bisphosphate (F16BP) or FIP however, the A or C isoforms are only slightly active when FIP is the substrate. 

A very important naturally occuring thiazole derivative is thiamine pyrophosphate (473). It is the prosthetic group in a variety of enzymes which catalyze decarboxylation (decarboxylase) and aldol-type condensation (aldolase) reactions. The catalytic active site of the molecule is at C-2 of the thiazole ring . The same activity of (473) is shown by other thiazolium salts and therefore these compounds have been widely exploited as catalysts in reactions of importance such as the benzoin condensation (see Section 3.06.12.2). 

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