Cytochrome P450 CYP101A1 (P450cam) hydroxylates camphor by receiving two distinct electrons from its unique reductase, putidaredoxin (Pdx). Upon binding ferric P450cam, Pdx is now known to trigger a conformational change in the enzyme. This Pdx-induced conversion may provide the trigger to coordinate enzyme turnover and protect the enzyme from oxidative damage, so the interactions responsible for this conversion are of significant interest at present. This proposed role for Pdx requires that its interactions with P450cam be different for the open and closed conformations. In this study, we show that the binding thermodynamics of Pdx does indeed differ in the predicted way when the conformation of P450cam is held in different states. However, double electron–electron resonance measurements of intermolecular distances in the Pdx/P450cam complex show that the geometry of the complex is nearly identical for the open and closed states of P450cam. These studies show that Pdx appears to make a single distinct interaction with its binding site on the enzyme and triggers the conformational change through very subtle structural interactions.

In this study, the effector role of Pdx (putidaredoxin) on cytochrome P450cam conformation is refined by attaching two different spin labels, MTSL or BSL (bifunctional spin-label) onto the F or G helices and using DEER (double electron–electron resonance) to measure the distance between labels. Recent EPR and crystallographic studies have observed that oxidized Pdx induces substrate-bound P450cam to change from the closed to the open state. However, this change was not observed by DEER in the reduced Pdx complex with carbon-monoxide-bound P450cam (Fe2+CO). In addition, recent NMR studies have failed to observe a change in P450cam conformation upon binding Pdx. Hence, resolving these issues is important for a full understanding the effector role of Pdx. Here we show that oxidized Pdx induces camphor-bound P450cam to shift from the closed to the open conformation when labeled on either the F or G helices with MTSL. BSL at these sites can either narrow the distance distribution widths dramatically or alter the extent of the conformational change. In addition, we report DEER spectra on a mixed oxidation state containing oxidized Pdx and ferrous CO-bound P450cam, showing that P450cam remains closed. This indicates that CO binding to the heme prevents P450cam from opening, overriding the influence exerted by Pdx binding. Finally, we report the open form P450cam crystal structure with substrate bound, which suggests that crystal packing effects may prevent conformational conversion. Using multiple labeling approaches, DEER provides a unique perspective to resolve how the conformation of P450cam depends on Pdx and ligand states.

Double electron–electron resonance (DEER) spectroscopy was used to determine the conformational state in solution for the heme monooxygenase P450cam when bound to its natural redox partner, putidaredoxin (Pdx). When oxidized Pdx was titrated into substrate-bound ferric P450cam, the enzyme shifted from the closed to the open conformation. In sharp contrast, however, the enzyme remained in the closed conformation when ferrous-CO P450cam was titrated with reduced Pdx. This result fully supports the proposal that binding of oxidized Pdx to P450cam opposes the open-to-closed transition induced by substrate binding. However, the data strongly suggest that in solution, binding of reduced Pdx to P450cam does not favor the open conformation. This supports a model in which substrate recognition is associated with the open-to-closed transition and electron transfer from Pdx occurs in the closed conformation. The opening of the enzyme in the ferric-hydroperoxo state following electron transfer from Pdx would provide for efficient O2 bond activation, substrate oxidation, and product release.

Although cytochrome P450cam from Pseudomonas putida, the archetype for all heme monooxygenases, has long been known to have a closed active site, recent reports show that the enzyme can also be crystallized in at least two clusters of open conformations. This suggests that the enzyme may undergo significant conformational changes during substrate binding and catalytic turnover. However, these conformations were observed in the crystalline state, and information is needed about the conformations that are populated in solution. In this study, double electron–electron resonance experiments were performed to observe substrate-induced changes in distance as measured by the dipolar coupling between spin labels introduced onto the surface of the enzyme on opposite sides of the substrate access channel. The double electron–electron resonance data show a decrease of 0.8 nm in the distance between spin labels placed at S48C and S190C upon binding the substrate camphor. A rotamer distribution model based on the crystal structures adequately describes the observed distance distributions. These results demonstrate conclusively that, in the physiologically relevant solution state, the substrate-free enzyme exists in the open P450cam-O conformation and that camphor binding results in conversion to the closed P450cam-C form. This approach should be useful for investigating many other P450s, including mammalian forms, in which the role of conformational change is of central importance but not well understood.