Amino acid racemases cell wall biosynthesis

Amino acid racemases are important for bacteria because they need D-alanine in the biosynthesis of cell walls. These enzymes require pyridoxal as the active cofactor. A racemization reaction starts with the aldimine complex between pyridoxal and an a-amino acid (Scheme 2.4). Deprotonation occurs at the a-carbon of amino acid, due to the electron-sink effect of pyridoxal. Reprotonation of the quinonoid intermediate at the opposite side provides the desired product (pathway a in Scheme 2.4). However, reprotonation may also take place at the C4 of pyridoxal (pathway b in Scheme 2.4). This kills the catalyst because one of its product, pyridoxamine, can no longer racemize an amino acid. 

Amino acid racemases catalyse the formation of a racemic mixture from either l- or D-amino acids. The enzymes of this class have only been detected in bacteria where they are involved in the formation of D-amino acids required for cell-wall biosynthesis. A crucial step in the racemase catalysed reactions must involve the cleavage of C -H bond to give a quinonoid intermediate of type 2 (Fig. 10) which is then protonated in a non-stereospecific fashion. Detailed mechanistic studies on these... 

Cycloserine (Fig- 4) is produced by several species of Streptomyces. One of the basic glycosyl components of the bacterial cell wall, n-acetyl-muramic acid (the product of Mur A and MurB), is modified by the addition of the first three amino acids sequentially by MurC, MurD and MurE enzymes. A dipeptide, D-alanyl-D-alanine is then added to make the pentapeptide. In bacteria, L-alanine is the native form and it is converted to D-alanine form by alanine racemase (Air). Two D-alanines are joined by D-ala-D-ala ligase (DdlA) to synthesize the dipeptide. Cycloserine resembles the substrate for Air and Ddl and inhibits their respective reactions in stage I of the peptidoglycan biosynthesis (Fig. 2). 

Fluoro amino acids have been incorporated into peptides, in order to ease the transport or reduce the systemic toxicity. Thus, trifluoroalanine, a powerful inhibitor of alanine racemase, is an essential enzyme for the biosynthesis of the cell wall of bacteria. It has a low antibiotic activity because of its very poor transport. In order to facilitate this transport, the amino acid has been incorporated into a peptide. This delivery allows a reduction of the doses, and thus the toxicity of the treatment is lowered.3-FIuorophenylaIanine (3-F-Phe) is a substrate of phenylalanine hydroxylase, which transforms it into 3-F-Tyr. 3-F-Tyr has a high toxicity for animals, due to its ultimate metabolization into fluorocitrate, a powerful inhibitor of the Krebs cycle (cf. Chapter 7). 3-F-Phe has a low toxicicity toward fungus cells, but when delivered as a tripeptide 3-F-Phe becomes an efficient inhibitor of the growth of Candida albicans. This tripeptide goes into the cell by means of the active transport system of peptides, where the peptidases set free the 3-F-Phe. ... 

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