Pyridoxal phosphate catalysis studies

Lactobacillus delbrueckii. In 1953, Rodwell suggested that the histidine decarboxylase of Lactobacillus 30a was not dependent upon pyridoxal phosphate (11). Rodwell based his suggestion upon the fact that the organism lost its ability to decarboxylate ornithine but retained high histidine decarboxylase activity when grown in media deficient in pyridoxine. It was not until 1965 that E. E. Snell and coworkers (12) isolated the enzyme and showed that it was, indeed, free of pyridoxal phosphate. Further advances in characterization of the enzyme were made by Riley and Snell (13) and Recsei and Snell (14) who demonstrated the existence of a pyruvoyl residue and the participation of the pyruvoyl residue in histidine catalysis by forming a Schiff base intermediate in a manner similar to pyridoxal phosphate dependent enzymes. Recent studies by Hackert et al. (15) established the subunit structure of the enzyme which is similar to the subunit structure of a pyruvoyl decarboxylase of a Micrococcus species (16). 

Several coenzymes are involved in the biosynthesis of their own precursors. Thus, thiamine is the cofactor of the enzyme that converts 1-deoxy-D-xylulose 5-phosphate (43) (the precursor of thiamine pyrophosphate, pyridoxal 5 -phosphate and of iso-prenoids via the nomnevalonate pathway) into 2 C-methyl-D-erythritol 4-phosphate (90, Fig. 11). Similarly, two enzymes required for the biosynthesis of GTP, which is the precursor of tetrahydrofolate, require tetrahydrofolate derivatives as cofactors (Fig. 3). When a given coenzyme is involved in its own biosynthesis, we are faced with a hen and egg problem, namely how the biosynthesis could have evolved in the absence of the cmcially required final product. The answers to that question must remain speculative. The final product may have been formed via an alternative biosynthetic pathway that has been abandoned in later phases of evolution or that may persist in certain organisms but remains to be discovered. Alternatively, the coenzyme under study may have been accessible by a prebiotic sequence of spontaneous reactions. An interesting example in this respect is the biosynthesis of flavin coenzymes, in which several reaction steps can proceed without enzyme catalysis despite their mechanistic complexity. 

---