The Axial Tyrosinate Fe3+ Ligand in Protocatechuate 3,4-Dioxygenase Influences Substrate Binding and Product Release: Evidence for New Reaction Cycle Intermediates,

Abstract

The essential active site Fe³⁺ of protocatechuate 3,4-dioxygenase [3,4-PCD, subunit structure (αβFe³⁺)₁₂] is bound by axial ligands, Tyr447 (147β) and His462 (162β), and equatorial ligands, Tyr408 (108β), His460 (160β), and a solvent OH^- (Wat827). Recent X-ray crystallographic studies have shown that Tyr447 is dissociated from the Fe³⁺ in the anaerobic 3,4-PCD complex with protocatechuate (PCA) [Orville, A. M., Lipscomb, J. D., and Ohlendorf, D. H. (1997) Biochemistry 36, 10052−10066]. The importance of Tyr447 to catalysis is investigated here by site-directed mutation of this residue to His (Y447H), the first such mutation reported for an aromatic ring cleavage dioxygenase containing Fe³⁺. The crystal structure of Y447H (2.1 Å resolution, R-factor of 0.181) is essentially unchanged from that of the native enzyme outside of the active site region. The side chain position of His447 is stabilized by a His447^Nδ1−Pro448^O hydrogen bond, placing the Nε2 atom of His447 out of bonding distance of the iron (∼4.3 Å). Wat827 appears to be replaced by a CO₃^2-, thereby retaining the overall charge neutrality and coordination number of the Fe³⁺ center. Quantitative metal and amino acid analysis shows that Y447H binds Fe³⁺ in ∼10 of the 12 active sites of 3,4-PCD, but its k_cat is nearly 600-fold lower than that of the native enzyme. Single-turnover kinetic analysis of the Y447H-catalyzed reaction reveals that slow substrate binding accounts for the decreased k_cat. Three new kinetically competent intermediates in this process are revealed. Similarly, the product dissociation from Y447H is slow and occurs in two resolved steps, including a previously unreported intermediate. The final E·PCA complex (ES₄) and the putative E·product complex (ESO₂*) are found to have optical spectra that are indistinguishable from those of the analogous intermediates of the wild-type enzyme cycle, while all of the other observed intermediates have novel spectra. Once the E·S complex is formed, reaction with O₂ is fast. These results suggest that dissociation of Tyr447 occurs during turnover of 3,4-PCD and is important in the substrate binding and product release processes. Once Tyr447 is removed from the Fe³⁺ in the final E·PCA complex by either dissociation or mutagenesis, the O₂ attack and insertion steps proceed efficiently, suggesting that Tyr447 does not have a large role in this phase of the reaction. This study demonstrates a novel role for Tyr in a biological system and allows evaluation and refinement of the proposed Fe³⁺ dioxygenase mechanism.