Abstract
Cytochromes P450 (CYP) from the 2A subfamily are known for their roles in the metabolism of nicotine, the addictive agent in tobacco, and activation of the tobacco procarcinogen 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK). Although both the hepatic CYP2A6 and respiratory CYP2A13 enzymes metabolize these compounds, CYP2A13 does so with much higher catalytic efficiency, but the structural basis for this has been unclear. X-ray structures of nicotine complexes with CYP2A13 (2.5 Å) and CYP2A6 (2.3 Å) yield a structural rationale for the preferential binding of nicotine to CYP2A13. Additional structures of CYP2A13 with NNK reveal either a single NNK molecule in the active site with orientations corresponding to metabolites known to form DNA adducts and initiate lung cancer (2.35 Å) or with two molecules of NNK bound (2.1 Å): one in the active site and one in a more distal staging site. Finally, in contrast to prior CYP2A structures with enclosed active sites, CYP2A13 conformations were solved that adopt both open and intermediate conformations resulting from an ∼2.5 Å movement of the F to G helices. This channel occurs in the same region where the second, distal NNK molecule is bound, suggesting that the channel may be used for ligand entry and/or exit from the active site. Altogether these structures provide multiple new snapshots of CYP2A13 conformations that assist in understanding the binding and activation of an important human carcinogen, as well as critical comparisons in the binding of nicotine, one of the most widely used and highly addictive drugs in human use.
Highlights
Cytochromes P450 2A13 and 2A6 are involved in nicotine metabolism and tobacco-related lung cancer initiation
Because a subset of active site residue substitutions between these two CYP2A enzymes have proved key in controlling the differential binding and metabolism of other CYP2A ligands [19, 29], we subsequently explored the effects of selected mutations on nicotine affinity
Simultaneous substitution of four of the ten active site residues differing between the two wild type enzymes (CYP2A6 I208S/I300F/G301A/S369G) resulted in a Kd of 196 M, or ϳ3.6-fold higher than that observed for wild type CYP2A13
Summary
Cytochromes P450 2A13 and 2A6 are involved in nicotine metabolism and tobacco-related lung cancer initiation. Cytochromes P450 (CYP) from the 2A subfamily are known for their roles in the metabolism of nicotine, the addictive agent in tobacco, and activation of the tobacco procarcinogen 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) Both the hepatic CYP2A6 and respiratory CYP2A13 enzymes metabolize these compounds, CYP2A13 does so with much higher catalytic efficiency, but the structural basis for this has been unclear. Four new crystal structures with these ligands identify amino acid residues important for the functional differences between these two enzymes in the binding and metabolism of nicotine and biotransformation of NNK into a carcinogen, but they provide unexpected evidence for multiple ligand binding modes and the location of a channel in CYP2A13 that may allow ligand access/egress The compilation of these structural vignettes is a stop motion perspective on CYP2A enzyme conformational changes controlling the binding and metabolism of nicotine and NNK, two substrates responsible for human tobacco addiction and lung cancer
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