Catalysis involves the conserved aspartate-histidine-aspartate catalytic triad.¹⁵ The reaction cycles from the free enzyme, Michaelis complex (I), covalent ester intermediate (II), enzyme-product complex (III), and then back to the free enzyme. First, fluoride is displaced by the aspartate nucleophile in an S_N2 attack. The resulting covalent intermediate is then hydrolyzed by a water molecule activated by the histidine base. This step is assisted by the second aspartate residue.

The secondary structural elements of RPA1163 (grey) superpose well onto those of the Burkholderia FAcD (cyan). (A) At the active site entrance, the cap domain loop which carries Trp185 displays the largest conformational difference (curved arrow). (B) The active site cavity viewed along the access tunnel. The corresponding tryptophan side chain in the Burkholderia FAcD is located ~8 Å further away from the active site. (C) Superposition of seven catalytically important residues reveals a remarkably conserved active site architecture.

(A) The binding of FAc, BrAc and ClAc in the active site of the Asp110Asn mutant. FAc is bound at full occupancy, but only ~75% saturation for ClAc and BrAc are observed. The residual electron densities on O2 of ClAc and BrAc are both modelled as a chloride ion at ~25% occupancy (Supporting Information, Figure S3). The omit F_o−F_c electron density maps are contoured at 4.5 (FAc), 3.0 (ClAc) and 2.8 (BrAc) σ. (B) The superposition of the FAc, ClAc and BrAc complexes (in green, yellow and brown, respectively) using all Cα atoms of the protein subunits. Only His155 is displaced, albeit minimally, by the increasingly larger halide of the substrate (vertical arrow). The binding of the larger halogen atom forces a slight tilt to the entire haloacetate substrate thereby keeping the halogen atom further out of the active site (curved arrow).

The upper and lower domains are the α-helical cap and α/β/α core, respectively. The catalytic triad Asp110-His280-Asp134 protruding from the core domain is shown as sticks. The arrow indicates the opening of the 11 Å-long channel leading to the active site.

(A) Active site structure of the free WT FAcD. The cavity comprises the catalytic triad (Asp110-His280-Asp134), the carboxylate binding site (Arg111 and Arg114) and the fluoride pocket (His155, Trp156 and Tyr219). (B) The Asp110Asn/FAc Michaelis complex. The bound FAc reveals the key enzyme-substrate interactions (dashed lines with distances in Å). (C) The His280Asn/FAc covalent intermediate. The location where the displaced fluoride ion may be transiently bound is shown. (D) The WT/glycolate (GOA) product complex. (E) The initial S_N2 attack is deduced from the superposition of FAc as found in the Michaelis complex onto the structure of the covalent intermediate. The arrow shows the displacement of the substrate’s C2 atom as this occurs. The location where the expelled fluoride ion may be transiently bound is indicated. (F) The same structural comparison viewed down the line of the atoms involved in the nucleophilic attack (i.e. from fluorine to the substrate’s C2 to Asp110’s Oδ2). The halide stabilizing residues (His155, Trp156 and Tyr219) form a ‘claw’ reaching for the leaving fluoride. Phe40 and Trp185 are also sufficiently close to participate in catalysis. The ‘flapping’ motion of the indole side chain of Trp185 is indicated by the curved arrow. (G) The subsequent hydrolysis of the covalent intermediate is inferred from the superposition of the glycolyl-Asp110 residue as found in the covalent intermediate onto the enzyme-product complex. This step employs the catalytic water activated by His280. The arrow indicates how the product glycolate (GOA) detaches from its former covalent bonding partner. The omit F_o−F_c electron density maps are contoured at 3 δ.

The active sites residues from WT/apo (grey), Asp110Asn/FAc Michaelis complex (green), His280Asn/FAc covalent intermediate (red) and WT/GOA product complex (blue) are shown.