Volume 8, Issue 2, Pages (February 2000)

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Volume 8, Issue 2, Pages 111-122 (February 2000) Structure of Aspergillus niger epoxide hydrolase at 1.8 Å resolution: implications for the structure and function of the mammalian microsomal class of epoxide hydrolases Jinyu Zou, B Martin Hallberg, Terese Bergfors, Franz Oesch, Michael Arand, Sherry L Mowbray, T Alwyn Jones Structure Volume 8, Issue 2, Pages 111-122 (February 2000) DOI: 10.1016/S0969-2126(00)00087-3

Figure 1 Structure of AnEH. (a) Cα trace, with colors going through the rainbow from red at the N terminus to blue at the C terminus. The sidechains of the catalytic triad (Asp192, His374 and Asp348), Tyr251, Tyr314, and Glu123 are shown in red. The approximate placement of residues 320–328 (omitted from the final model) is indicated by dotted lines. (b) Topology diagram colored using the same rainbow scheme. Secondary-structure descriptors for the α/β domain follow earlier nomenclature [7], whereas the N-terminal meander and lid domains use separate systems, prefixed with N and L, respectively. Residues of the catalytic triad are indicated by red stars, and the two active-site tyrosine residues of the lid by magenta stars. Structure 2000 8, 111-122DOI: (10.1016/S0969-2126(00)00087-3)

Figure 2 Stereo ribbon drawing showing the interface and symmetry of the AnEH dimer interaction. Both subunits are colored in the rainbow scheme used in Figure 1. Sidechains of the dimer interface are shown, as well as a series of interactions (Trp276, His255, and Tyr314) that leads from the dimer interface to the active site. Structure 2000 8, 111-122DOI: (10.1016/S0969-2126(00)00087-3)

Figure 3 Catalytic site residues (Asp192, His374 and Asp348), with the most important hydrogen-bonding interactions displayed. The water molecule (red) interacting with Tyr251 and Tyr314 is believed to indicate the position of the oxirane ring oxygen. Additional water molecules near the charge-relay residues (His374 and Asp348) and Glu123 are thought to provide a reservoir of water close to the active site. The series of interactions leading via the rings of Trp276 and His255 to the active-site residue Tyr314 is also shown. Colors for the backbone use the same rainbow scheme found in earlier figures. Structure 2000 8, 111-122DOI: (10.1016/S0969-2126(00)00087-3)

Figure 4 Mechanism of 4-nitrostyrene oxide hydrolysis by AnEH; residues are shown as close as possible to their actual relative orientation and position. Initial binding and positioning of the substrate in the active center of the enzyme is thought to be directed by hydrogen bonding between the epoxide ring oxygen and the hydroxyl groups of Tyr251 and Tyr314. In the first step of the enzymatic reaction, the carboxylate sidechain of the catalytic nucleophile Asp192 attacks the unsubstituted carbon atom of the oxirane ring, forming an ester bond and opening the ring. The process is facilitated through simultaneous proton donation by one of the tyrosine residues (the series of hydrogen bonds between the π system of Tyr314 and His255/Trp276 discussed in the main text favors Tyr314, as it is expected to result in a lower pKa). The two parts together comprise a classic push–pull mechanism. The second step of the reaction consists of the hydrolysis of the ester intermediate via the attack of a water molecule. This water is activated through proton abstraction by the His374/Asp348 charge-relay system, possibly further assisted by Glu123 (not shown). Structure 2000 8, 111-122DOI: (10.1016/S0969-2126(00)00087-3)

Figure 5 Substrate 4-nitrostyrene oxide docked into the active site of the apo enzyme, shown with a solvent accessible surface. The site is complementary to the R enantiomer (green carbon atoms), and a poorer fit for the S enantiomer (yellow carbon atoms). The close contact (< 3 Å) expected between C7 of the S isomer and the hydroxyl group of Tyr251 is shown. Structure 2000 8, 111-122DOI: (10.1016/S0969-2126(00)00087-3)

Figure 6 Superposition of the agrobacterial EH (black) on AnEH (rainbow coloring), showing similarity of the active-site region and lid. The known residues of catalysis are included; dashed lines indicate the location of the disordered regions of the two proteins. Structure 2000 8, 111-122DOI: (10.1016/S0969-2126(00)00087-3)

Figure 7 Structural alignments of the proteins listed in Table 3, showing the similarity of the α/β domains and the different construction of the lids. AnEH is shown in black, the bacterial EH in red, bromoperoxidase A2 in magenta, chloroperoxidase F in gold, chloroperoxidase L in green, bromoperoxidase A1 in cyan, haloalkane dehalogenase in yellow, hydroxynitrile lyase in blue, proline iminopeptidase in maroon, and the lipase in lime green. Structure 2000 8, 111-122DOI: (10.1016/S0969-2126(00)00087-3)