1H NMR characterization of the solution active site structure of substrate-bound, cyanide-inhibited heme oxygenase from Neisseria meningitidis: comparison to crystal structures

Heme oxygenase, HO, from the pathogenic bacterium Neisseria meningitidis catabolizes heme for the iron necessary for infection. The enzyme, labeled HemO, exhibits less sequence homology to mammalian HO than another studied HO from Corynebacterium diphtheriae. Solution 1H NMR has been utilized to define the active site molecular and electronic structure of the cyanide-inhibited, substrate-bound complex for comparison with those provided by several crystal structures. Extensive assignments by solely 1H NMR 2D methods reveal a structure that is very strongly conserved with respect to the crystal structure, although 1H/2H exchange indicates dynamically much more stable distal and proximal helices than those for other HOs. Several residues found with alternate orientations in crystal structures of water- and NO-ligated complexes were shown to occupy positions found solely in the NO complex, confirming that there are structural accommodations in response to ligating the substrate complex with a diatomic, H-bond acceptor ligand. The observed dipolar shifts allow the determination of the magnetic axes that show that the Fe-CN unit is tilted approximately 10 degrees toward the alpha-meso position, thereby facilitating the alpha-stereoselectivity of the enzyme. Numerous labile protons with larger than usual low-field bias are identified and, in common with the other HO complexes, shown to participate in an extended, distal side H-bond network. This H-bond network orders several water molecules, most, but not all, of which have been detected crystallographically. A series of three C-terminal residues, His207-Arg208-His209, are not detected in crystal structures. However, 1H NMR finds two residues, His207 and likely Arg208 in contact with pyrrole D, which in crystal structures is exposed to solvent. The nature of the NOEs leads us to propose a H-bond between the proximally oriented His207 ring and the carboxylate of Asp27 and a salt-bridge between the terminus of Arg208 and the reoriented 7-propionyl carboxylate. While numerous ordered water molecules are found near both propionates in the crystal structure, we find much larger water NOEs to the 6- than 7-propionate, suggesting that water molecules near the 7-propionate have been expelled from the cavity by the insertion of Arg208 into the distal pocket. The conversion of the 7-propionate link from the N-terminal region (Lys16) to the C-terminal region (Arg208) in the ligated substrate complex both closes the heme cavity more tightly and may facilitate product exit, the rate-limiting step in the enzyme activity.