The Structure of Oxalate Decarboxylase at its Active pH

Oxalate decarboxylase catalyzes the redox-neutral unimolecular disproportionation reaction of oxalic acid. The pH maximum for catalysis is ~4.0 and activity is negligible above pH7. Here we report on the first crystal structure of the enzyme in its active pH range at pH4.6, and at a resolution of 1.45 Å, the highest to date. The fundamental tertiary and quaternary structure of the enzyme does not change with pH. However, the low pH crystals are heterogeneous containing both a closed and open conformation of a flexible loop region which gates access to the N-terminal active site cavity. Residue E162 in the closed conformation points away from the active-site Mn ion owing to the coordination of a buffer molecule, acetate. Since the quaternary structure of the enzyme appears unaffected by pH many conclusions drawn from the structures taken at high pH remain valid. Density functional theory calculations of the possible binding modes of oxalate to the N-terminal Mn ion demonstrate that both mono- and bi-dentate coordination modes are possible in the closed conformation with an energetic preference for the bidentate binding mode. The simulations suggest that R92 plays an important role as a guide for positioning the substrate in its catalytically competent orientation. A strong hydrogen bond is seen between the bi-dentate bound substrate and E101, one of the coordinating ligands for the N-terminal Mn ion. This suggests a more direct role of E101 as a transient base during the first step of catalysis.