Molecular insights into the enzymatic diversity of flavin‐trafficking protein (Ftp; formerly ApbE) in flavoprotein biogenesis in the bacterial periplasm

We recently reported a flavin‐trafficking protein (Ftp) in the syphilis spirochete Treponema pallidum (Ftp_Tp) as the first bacterial metal‐dependent FAD pyrophosphatase that hydrolyzes FAD into AMP and FMN in the periplasm. Orthologs of Ftp_Tp in other bacteria (formerly ApbE) appear to lack this hydrolytic activity; rather, they flavinylate the redox subunit, NqrC, via their metal‐dependent FMN transferase activity. However, nothing has been known about the nature or mechanism of metal‐dependent Ftp catalysis in either Nqr‐ or Rnf‐redox‐containing bacteria. In the current study, we identified a bimetal center in the crystal structure of Escherichia coli Ftp (Ftp_Ec) and show via mutagenesis that a single amino acid substitution converts it from an FAD‐binding protein to a Mg(2+)‐dependent FAD pyrophosphatase (Ftp_Tp‐like). Furthermore, in the presence of protein substrates, both types of Ftps are capable of flavinylating periplasmic redox‐carrying proteins (e.g., RnfG_Ec) via the metal‐dependent covalent attachment of FMN. A high‐resolution structure of the Ftp‐mediated flavinylated protein of Shewanella oneidensis NqrC identified an essential lysine in phosphoester‐threonyl‐FMN bond formation in the posttranslationally modified flavoproteins. Together, these discoveries broaden our understanding of the physiological capabilities of the bacterial periplasm, and they also clarify a possible mechanism by which flavoproteins are generated.