Interaction of Mycobacterium tuberculosis CYP130 with Heterocyclic Arylamines

The Mycobacterium tuberculosis P450 enzymes are of interest for their pharmacological development potential, as evidenced by their susceptibility to inhibition by antifungal azole drugs that normally target sterol 14α-demethylase (CYP51). Although antifungal azoles show promise, direct screening of compounds against M. tuberculosis P450 enzymes may identify novel, more potent, and selective inhibitory scaffolds. Here we report that CYP130 from M. tuberculosis has a natural propensity to bind primary arylamines with particular chemical architectures. These compounds were identified via a high throughput screen of CYP130 with a library of synthetic organic molecules. As revealed by subsequent x-ray structure analysis, selected compounds bind in the active site by Fe-coordination and hydrogen bonding of the arylamine group to the carbonyl oxygen of Gly²⁴³. As evidenced by the binding of structural analogs, the primary arylamine group is indispensable, but synergism due to hydrophobic contacts between the rest of the molecule and protein amino acid residues is responsible for a binding affinity comparable with that of the antifungal azole drugs. The topology of the CYP130 active site favors angular coordination of the arylamine group over the orthogonal coordination of azoles. Upon substitution of Gly²⁴³ by an alanine, the binding mode of azoles and some arylamines reverted from type II to type I because of hydrophobic and steric interactions with the alanine side chain. We suggest a role for the conserved Ala(Gly)²⁴³-Gly²⁴⁴ motif in the I-helix in modulating both the binding affinity of the axial water ligand and the ligand selectivity of cytochrome P450 enzymes.CYP130 is one of the 20 Mycobacterium tuberculosis cytochrome P450 (P450, CYP)² enzymes and is one of three (CYP51, CYP121, and CYP130) that have been studied as individually expressed proteins at the structural level. Evidence has accumulated for the importance of M. tuberculosis P450 enzymes in virulence (CYP132) (1), host infection (CYP125) (2), and pathogen viability (CYP128, CYP121) (3, 4), although neither their exact biological functions nor any of the endogenous substrates upon which these enzymes operate have yet been established. However, it has recently been shown in vitro that CYP121 catalyzes a C–C coupling reaction between two tyrosine groups (5). CYP130 is absent from the genome of Mycobacterium bovis, suggesting that it might play specific role(s) in the infection of the human host and thus constitute a potential therapeutic target.The potential of M. tuberculosis P450 enzymes for pharmacologic development was initially suggested by their susceptibility to inhibition by antifungal azole drugs such as fluconazole, econazole, and clotrimazole. These drugs block sterol 14α-demethylase CYP51 in fungi (6), tightly bind to M. tuberculosis P450 proteins (7, 8), and display inhibitory potential against latent and multidrug-resistant forms of tuberculosis both in vitro and in tuberculosis-infected mice (9–14).The substantial differences between fungal CYP51 and the potential P450 targets in microbial pathogens, including M. tuberculosis, suggest that the direct screening of compounds against M. tuberculosis CYP enzymes could identify novel inhibitory scaffolds that are more potent and selective than antifungal drugs. Structurally characterized screening targets are advantageous, as the already defined purification and crystallization protocols can be applied to obtain co-crystal structures and to elucidate the binding modes of screening hits. This approach has been successfully applied to CYP51, resulting in identification of novel inhibitory scaffolds for CYP51 therapeutic targets (15, 16).Toward this goal, the property of P450 enzymes to shift the ferric heme iron Soret band on ligand binding (17) provides an experimental platform for high throughput screening of compound libraries to select chemotypes with high binding affinities for the target. Expulsion of the heme iron axial water ligand from the Fe-coordination sphere by the incoming substrate followed by transition of the ferric heme from the low-spin hexacoordinated to the high-spin pentacoordinated state characterize type I spectral shifts and are a prerequisite for P450 catalytic activity. Replacement of a weak axial ligand, the water molecule, with a stronger one possessing a nitrogen-containing aliphatic or aromatic group coordinating to the heme iron characterizes type II spectral shifts.To find new high affinity ligands of CYP130, a commercial library of 20,000 small organic molecules comprising a large selection of molecular scaffolds was screened against the enzyme. In contrast to the results with CYP51, no type I binding hits were identified. Screening produced about a dozen structurally diverse type II hits that were unexpectedly devoid of the usual aromatic nitrogen atoms readily accessible for axial coordination of the heme iron, suggesting an alternative coordination mode. High resolution x-ray structure analysis determined that two compounds coordinated to the heme iron via a primary arylamine group, providing the first structural evidence on P450-heterocyclic arylamine interactions.