Pyridoxal phosphate-dependent reaction racemization

A number of decarboxylase enzymes have been described as catalysts for the preparation of chiral synthons, which are difficult to access chemically (see Chapter 2).264 The amino acid decarboxylases catalyze the pyridoxal phosphate (PLP)-dependent removal of C02 from their respective substrates. This reaction has found great industrial utility with one specific enzyme in particular, L-aspartate-P-decarboxylase (E.C. 4.1.1.12) from Pseudomonas dacunhae. This biocatalyst, most often used in immobilized whole cells, has been utilized by Tanabe to synthesize L-alanine on an industrial scale (multi-tons) since the mid-1960s (Scheme 19.33).242-265 Another use for this biocatalyst has been the resolution of racemic aspartic acid to produce L-alanine and D-aspartic acid (Scheme 19.34). The cloning of the L-aspartate-P-decarboxylase from Alcaligenes faecalis into E. coli offers additional potential to produce both of these amino acids.266... 

The ring nitrogen of pyridoxal phosphate exerts a strong electron withdrawing effect on the aldimine, and this leads to weakening of all three bonds about the a-carbon of the substrate. In nonenzymic reactions, all the possible pyridoxal-catalyzed reactions are observed - a-decarboxylation, aminotrans-fer, racemization and side-chain elimination, and replacement reactions. By contrast, enzymes show specificity for the reaction pathway followed which bond is cleaved will depend on the orientation of the Schiff base relative to reactive groups of the catalytic site. As discussed in Section 9.3.1.5, reaction specificity is not complete, and a number of decarboxylases also undergo transamination. 

Pyridoxal 5 -phosphate dependent enzymes constitute an important class of proteins involved predominately in amino acid metabolism. The PLP-cofactor is capable of catalyzing a variety of reactions at the a-, [3-, and/or y-carbons of amino acid substrates. These reactions include tranamination, racemization, decarboxylation, and aldoyltic cleavage reactions at the a-carbon and elimina-tion/substitution reactions at either the 3-, or y-position of the amino acid substrate (67-74) The chemical properties of the cofactor (67-71) are responsible for the great diversity of reactions catalyzed by PLP, while reaction specificity is ultimately determined by the active site environment imposed by the surrounding apo-protein to which the cofactor is covalendy bound (69). 

The pyridoxal phosphate (PLP)-dependent enzymes catalyze a diverse set of chemical transformations of amino acids. These include transamination, decarboxylation, and racemization reactions [Eqs. (41-43)],... 

Amino acid metabolism requires the participation of three important cofactors. Pyridoxal phosphate is the quintessential coenzyme of amino acid metabolism (see Chapter 38). All amino acid reactions requiring pyridoxal phosphate occur with the amino group of the amino acid covalently bound to the aldehyde carbon of the coenzyme (Fig. 39.3). The pyridoxal phosphate then pulls electrons away from the bonds around the a-carbon. The result is transamination, deamination, decarboxylation, P-elimination, racemization, and -elimination, depending on which enzyme and amino acid are involved. 

The general arguments about the antiquity of cofactors apply to PLP. The nonenzymatic synthesis of pyridoxal under prebiotic conditions is considered possible, whereas the presence of a 5 phosphate group could hint to an ancestral attachment of the cofactor to RNA molecules. " Furthermore, there are specific grounds to assume that PLP arrived on the evolutionary scene before the emergence of proteins. In fact, in current metabolism, PLP-dependent enzymes play a central role in the synthesis and interconversion of amino acids, and thus they are closely related to protein biosynthesis. In an early phase of biotic evolution, free PLP could have played many of the roles now fulfilled by PLP-dependent enzymes, since the cofactor by itself can catalyze (albeit at a low rate) reactions such as amino acid transaminations, racemizations, decarboxylations, and eliminations. " This suggests that the appearance of PLP may have preceded (and somehow eased) the transition from primitive RNA-based life forms to more modern organisms dependent on proteins. 

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