Gregory J. Crouch

Purification and Mechanism of Human Aldehyde Oxidase Expressed in Escherichia coli

Human aldehyde oxidase 1 (AOX1) has been subcloned into a vector suitable for expression in Escherichia coli, and the protein has been expressed. The resulting protein is active, with sulfur being incorporated in the molybdopterin cofactor. Expression levels are modest, but 1 liter of cells supplies enough protein for both biochemical and kinetic characterization. Partial purification is achieved by nickel affinity chromatography through the addition of six histidines to the amino-terminal end of the protein. Kinetic analysis, including kinetic isotope effects and comparison with xanthine oxidase, reveal similar mechanisms, with some subtle differences. This expression system will allow for the interrogation of human aldehyde oxidase structure/function relationships by site-directed mutagenesis and provide protein for characterizing the role of AOX1 in drug metabolism.

Cytochrome P450 2C9 Type II Binding Studies on Quinoline-4-Carboxamide Analogues

CYP2C9 is a significant P450 protein responsible for drug metabolism. With the increased use of heterocyclic compounds in drug design, a rapid and efficient predrug screening of these potential type II binding compounds is essential to avoid adverse drug reactions. To understand binding modes, we use quinoline-4-carboxamide analogues to study the factors that determine the structure-activity relationships. The results of this study suggest that the more accessible pyridine with the nitrogen para to the linkage can coordinate directly with the ferric heme iron, but this is not seen for the meta or ortho isomers. The pi-cation interaction of the naphthalene moiety and Arg 108 residue may also assist in stabilizing substrate binding within the active-site cavity. The type II substrate binding affinity is determined by the combination of steric, electrostatic, and hydrophobicity factors; meanwhile, it is enhanced by the strength of lone pair electrons coordination with the heme iron.

Synthesis of 2′-Deoxyuridine Nucleosides with Appended 5-Position Carbonyl Cross-Linking Groups

Abstract A simple modification of Stille type carbonylative coupling conditions resulted in high yield reactions giving new carbonyl appended 2′-deoxyuridine derivatives useful for chemical cross-linking.

Modeling and synthesis of novel tight-binding inhibitors of cytochrome P450 2C9

Cytochrome P450 2C9 (2C9) is one of the three major drug metabolizing cytochrome P450 enzymes in human liver. Although the crystal structure of 2C9 has been solved, the important physicochemical properties of substrate-enzyme interactions remain difficult to be determined. This is due in part to the conformational flexibility of mammalian P450 enzymes. Therefore, probing the active-site with high-affinity substrates is important in further understanding substrate-enzyme interactions. Three-dimensional quantitative structure-activity relationships (3D-QSAR) and docking experiments have been shown to be useful tools in correlating biological activity with structure. In particular we have previously reported that the very tight-binding inhibitor benzbromarone can provide important information about the active-site of 2C9. In this study we report the binding affinities and potential substrate-enzyme interactions of 4H-chromen-4-one analogs, which are structurally similar to benzbromarone. The chromenone structures are synthetically accessible inhibitors and give inhibition constants as low as 4.2 nM, comparable with the very tightest-binding inhibitors of 2C9. Adding these compounds to our previous 2C9 libraries for CoMFA models reinforces the important electrostatic and hydrophobic features of substrate binding. These compounds have also been docked in the 2C9 crystal structure and the results indicate that Arg 108 plays significant roles in the binding of chromenone substrates.