1 research outputs found
1,2,3-Triazole–Heme Interactions in Cytochrome P450: Functionally Competent Triazole–Water–Heme Complexes
In comparison to imidazole (IMZ) and 1,2,4-triazole (1,2,4-TRZ),
the isosteric 1,2,3-triazole (1,2,3-TRZ) is unrepresented among cytochrome
P450 (CYP) inhibitors. This is surprising because 1,2,3-TRZs are easily
obtained via “click” chemistry. To understand this underrepresentation
of 1,2,3-TRZs among CYP inhibitors, thermodynamic and density functional
theory computational studies were performed with unsubstituted IMZ,
1,2,4-TRZ, and 1,2,3-TRZ. The results indicate that the lower affinity
of 1,2,3-TRZ for the heme iron includes a large unfavorable entropy
term likely originating in solvent–1,2,3-TRZ interactions;
the difference is not solely due to differences in the enthalpy of
heme–ligand interactions. In addition, the 1,2,3-TRZ fragment
was incorporated into a well-established CYP3A4 substrate and mechanism-based
inactivator, 17-α-ethynylestradiol (17EE), via click chemistry.
This derivative, 17-click, yielded optical spectra consistent with
low-spin ferric heme iron (type II) in contrast to 17EE, which yields
a high-spin complex (type I). Furthermore, the rate of CYP3A4-mediated
metabolism of 17-click was comparable to that of 17EE, with a different
regioselectivity. Surprisingly, continuous-wave electron paramagnetic
resonance (EPR) and HYSCORE EPR spectroscopy indicate that 17-click
does not displace water from the sixth axial ligand position of CYP3A4
as expected for a type II ligand. We propose a binding model in which
17-click pendant 1,2,3-TRZ hydrogen bonds with the sixth axial water
ligand. The results demonstrate the potential for 1,2,3-TRZ to form
metabolically labile water-bridged low-spin heme complexes, consistent
with recent evidence that nitrogenous type II ligands of CYPs can
be efficiently metabolized. The specific case of [CYP3A4·17-click]
highlights the risk of interpreting CYP–ligand complex structure
on the basis of optical spectra