Refinement of 3D models of horseradish peroxidase isoenzyme C: Predictions of 2D NMR assignments and substrate binding sites

In this study, two alternative three-dimensional (3D) models of horseradish peroxidase (HRP-C)—differing mainly in the structure of a long untemplated insertion—were refined, systematically assessed, and used to make predictions that can both guide and be tested by future experimental studies. A key first step in the model-building process was a procedure for multiple sequence alignment based on structurally conserved regions and key conserved residues, including those side chains providing ligands to the two Ca2+ binding sites. The model refinements reported here include (1) optimization of side-chain conformations; (3) addition of structural waters using a template-independent procedure; (2) structural refinement of the untemplated 34 amino acid insertion located between the F and G helices, using both energy criteria and NMR data; (4) unconstrained energy optimization of the refined models. Using these procedures, two refined structures of HRP-C were obtained, differing mainly in the conformation of this long insertion. The presence of residues in this insertion that could potentially interact with bound substrates suggests a functional role that may be related to the general ability of class III peroxidases to form stable 1:1 complexes with a variety of substrates. The structural validity of the models was systematically assessed by a variety of criteria. Most notably, the ProsaII z scores and Profiles 3D scores of the two HRP-C models indicated that they are significantly better than would be obtained by simple amino acid replacement, using any of the known structures as a template. These two 3D HRP-C models, were then used to predict candidate residues for the assignment of NOESY cross-peaks previously noted in 2D-NMR studies. Specifically, the residues known as Ile X, Phe A, Phe B, aliphatic residue Q, and Ile T. Candidate substrate binding sites were also identified and compared with experimentally based predictions. This work is timely because new X-ray structures are anticipated that will facilitate the validation of these procedures. © 1996 Wiley-Liss, Inc.