Folate is an essential one-carbon carrier cofactor required for essential biological reactions such as amino acid and DNA biosynthesis. Folates are comprised of three chemical moieties: a pteridine ring, p-aminobenzoate (pABA), and glutamate residues. Chlamydia trachomatis has been shown to synthesize folate de novo; however, it is missing several genes involved in the canonical folate biosynthesis pathway. Previous work has demonstrated that a single gene, ct610, functionally replaces the enzymes responsible for pABA production in the canonical biosynthesis pathway. However, CT610 does not use chorismate as the precursor to pABA as is used in the canonical pathway. Further experiments showed that isotopically labeled tyrosine was incorporated into the pABA molecule when synthesized by CT610 in vivo. However, in vitro experiments demonstrated that CT610 produces pABA in the presence of oxygen and a reducing agent without any added substrates, including tyrosine. This led to the hypothesis that CT610 is a self-sacrificing “suicide” enzyme that donates an active site tyrosine residue in synthesizing pABA. CT610 has low sequence similarity to non-heme diiron monooxygenases such as methane monooxygenase and class Ia ribonucleotide reductase, and the previously solved crystal structure of CT610 revealed a diiron active site. Here we describe our recent progress towards understanding this unique suicide mechanism for pABA biosynthesis. To determine the tyrosine residue sacrificed in the reaction, we generated five active site tyrosine to phenylalanine mutants and found that two of the variants completely abolished pABA production, suggesting that one of these residues is the precursor to pABA. Further, a conserved lysine residue is also essential for the reaction and may be a sacrificial amino group donor. We have confirmed the oxygenase activity of wild-type CT610, which requires only a reducing agent and is not stimulated by the presence of tyrosine or other possible substrates. Further, we developed an Fe(II) reconstitution procedure, where the reconstituted enzyme exhibits a drastic increase in oxygenase activity. However, surprisingly, the reconstituted enzyme does not exhibit increased pABA synthase activity, although EDTA treatment of the as-purified enzyme almost completely inhibits pABA production. This suggests that a metal other than iron is required for the reaction and thus current work is focused on testing other potential metal cofactors that may play a role in the novel suicide reaction.
