The enterobactin biosynthetic enzyme EntA forms a complex with EntE, the next enzyme in the pathway, to enhance activation of the enterobactin precursor 2,3-dihydroxybenzoate. Here we used phage display to identify an EntE-interacting region on the surface of EntA. Upon panning immobilized EntE with a random peptide phage library, we recovered 47 unique EntE-binding dodecamer peptide sequences that aligned to a region of the EntA primary sequence corresponding to helix alpha 4. In order to further investigate this region, we mutagenized EntA Q64, a hydrogen-bonding residue found on the surface-exposed face alpha 4. Far-UV circular dichroism, thermal denaturation experiments, and enzymatic assays showed that mutation of EntA residue Gln 64 to alanine (Q64A) had no deleterious effect on EntA structure or function. By following near-UV CD spectral changes, we found that the spectrum of wild-type EntA was altered in the presence of EntE, indicative of conformational changes in EntA aromatic chromophores upon formation of the EntA-EntE complex. However, EntE did not affect the CD spectrum of EntA variant Q64A, demonstrating that this variant did not interact with EntE in a manner similar to wild-type EntA. Analytical ultracentrifugation of wild-type and variant EntA proteins showed that EntA Q64A was predominantly dimeric at 2011M, unlike wild-type EntA which was predominantly tetrameric. Taken together, our findings establish that EntA alpha 4 is required for efficient formation of the EntA-EntE as well as for EntA oligomerization. (C) 2014 Elsevier Inc. All rights reserved.