Evolution of aromatic biosynthesis and fine-tuned phylogenetic positioning of Azomonas, Azotobacter and rRNA group I pseudomonads

Abstract

The evolutionary history of biochemical pathways can be determined in microbial groupings for which phylogenetic trees have been established. This has been demonstrated best in Superfamily B, an assemblage of rRNA homology groups containing lineages that lead to genera such as Escherichia and other enteric microbes, Pseudomonas (Group I), Xanthomonas, Oceanospirillum, and Acinetobacter. The rRNA homology group that defines Group I pseudomonads also includes Azomonas and Azotobacter, but particular dendrogram points of evolutionary divergence for these genera within Superfamily B have not been established. Phylogenetic relationships at such intergeneric levels can be deduced by analysis of aromaticpathway enzyme arrangement and regulation in selected groupings where dynamic evolutionary changes have occurred. A case in point is illustrated by Axomonas insignis, Azotobacter paspali, and Azotobacter vinelandii — a grouping that appears to be homogeneous with respect to the evolutionary state of the aromatic pathway. The conclusion that this phylogenetic cluster diverges from an ancestor common to pseudomonad subgroup Ia (rather than to subgroup Ib) is based upon the absence of chorismate mutase-F and arogenate dehydratase, enzymes making up a twostep pathway of phenylalanine biosynthesis that is absent in subgroup Ia, but present in subgroup Ib. Of further interest, Azomonas insignis and Azotobacter sp. were found to comprise a distinctive and recently evolved sublineage, differing from subgroup Ia species in their loss of a regulatory isozyme of 3-deoxy-d-arabino-heptulosonate 7-phosphate synthase (ADHP synthase-trp) that is subject to feedback inhibition by l-tryptophan. DAHP synthase-trp is an ancient character state of Superfamily B that has been retained during the evolutionary history of most members of this Superfamily.