Spectroscopic evidence of the effect of hydrogen peroxide excess on the coproheme decarboxylase from actinobacterial Corynebacterium diphtheriae.

The actinobacterial coproheme decarboxylase from Corynebacterium diphtheriae catalyzes the final reaction to generate heme b via the "coproporphyrin-dependent" heme biosynthesis pathway in the presence of hydrogen peroxide. The enzyme has a high reactivity toward H2O2 used for the catalytic reaction and in the presence of an excess of H2O2 new species are generated. Resonance Raman data, together with electronic absorption spectroscopy and mass spectrometry, indicate that an excess of hydrogen peroxide for both the substrate (coproheme) and product (heme b) complexes of this enzyme causes a porphyrin hydroxylation of ring C or D, which is compatible with the formation of an iron chlorin-type heme d species. A similar effect has been previously observed for other heme-containing proteins, but this is the first time that a similar mechanism is reported for a coproheme enzyme. The hydroxylation determines a symmetry lowering of the porphyrin macrocycle, which causes the activation of A2g modes upon Soret excitation with a significant change in their polarization ratios, the enhancement and splitting into two components of many Eu bands, and an intensity decrease of the non-totally symmetric modes B1g, which become polarized. This latter effect is clearly observed for the isolated ν10 mode upon either Soret or Q-band excitations. The distal His118 is shown to be an absolute requirement for the conversion to heme d. This residue also plays an important role in the oxidative decarboxylation, because it acts as a base for deprotonation and subsequent heterolytic cleavage of hydrogen peroxide.

An active site at work - the role of key residues in C. diphteriae coproheme decarboxylase.

Coproheme decarboxylases (ChdCs) are utilized by monoderm bacteria to produce heme b by a stepwise oxidative decarboxylation of the 2- and 4-propionate groups of iron coproporphyrin III (coproheme) to vinyl groups. This work compares the effect of hemin reconstitution versus the hydrogen peroxide-mediated conversion of coproheme to heme b in the actinobacterial ChdC from Corynebacterium diphtheriae (CdChdC) and selected variants. Both ferric and ferrous forms of wild-type (WT) CdChdC and its H118A, H118F, and A207E variants were characterized by resonance Raman and UV-vis spectroscopies. The heme b ligand assumes the same conformation in the WT active site for both the reconstituted and H2O2-mediated product, maintaining the same vinyl and propionate interactions with the protein. Nevertheless, it is important to note that the distal His118, which serves as a distal base, plays an important role in the stabilization of the cavity and for the heme b reconstitution. In fact, while the access of heme b is prevented by steric hindrance in the H118F variant, the substitution of His with the small apolar Ala residue favors the insertion of the heme b in the reversed conformation. The overall data strongly support that during decarboxylation, the intermediate product, a monovinyl-monopropionyl deuteroheme, rotates by 90o within the active site. Moreover, in the ferrous forms the frequency of the ν(Fe-Nδ(His)) stretching mode provides information on the strength of the proximal Fe-His bond and allows us to follow its variation during the two oxidative decarboxylation steps.