Recognition of Ferric Catecholates by FepA

Abstract

Escherichia coli FepA transports certain catecholate ferric siderophores, but not others, nor any noncatecholate compounds. Direct binding and competition experiments demonstrated that this selectivity originates during the adsorption stage. The synthetic tricatecholate Fe-TRENCAM bound to FepA with 50- to 100-fold-lower affinity than Fe-enterobactin (FeEnt), despite an identical metal center, and Fe-corynebactin only bound at much higher concentrations. Neither Fe-agrobactin nor ferrichrome bound at all, even at concentrations 10⁶-fold above the K_d. Thus, FepA only adsorbs catecholate iron complexes, and it selects FeEnt among even its close homologs. We used alanine scanning mutagenesis to study the contributions of surface aromatic residues to FeEnt recognition. Although not apparent from crystallography, aromatic residues in L3, L5, L7, L8, and L10 affected FepA9s interaction with FeEnt. Among 10 substitutions that eliminated aromatic residues, K_d increased as much as 20-fold (Y481A and Y638A) and K_m increased as much as 400-fold (Y478), showing the importance of aromaticity around the pore entrance. Although many mutations equally reduced binding and transport, others caused greater deficiencies in the latter. Y638A and Y478A increased K_m 10- and 200-fold more, respectively, than K_d. N-domain loop deletions created the same phenotype: Δ60-67 (in NL1) and Δ98-105 (in NL2) increased K_d 10- to 20-fold but raised K_m 500- to 700-fold. W101A (in NL2) had little effect on K_d but increased K_m 1,000-fold. These data suggested that the primary role of the N terminus is in ligand uptake. Fluorescence and radioisotopic experiments showed biphasic release of FeEnt from FepA. In spectroscopic determinations, k_off1 was 0.03/s and k_off2 was 0.003/s. However, FepAY272AF329A did not manifest the rapid dissociation phase, corroborating the role of aromatic residues in the initial binding of FeEnt. Thus, the β-barrel loops contain the principal ligand recognition determinants, and the N-domain loops perform a role in ligand transport.