Structural basis of bidirectional allostery across the heme in a cytochrome P450 enzyme

Pleiotropy of Progesterone Receptor Membrane Component 1 in Modulation of Cytochrome P450 Activity

Progesterone receptor membrane component 1 (PGRMC1) is one of few proteins that have been recently described as direct modulators of the activity of human cytochrome P450 enzymes (CYP)s. These enzymes form a superfamily of membrane-bound hemoproteins that metabolize a wide variety of physiological, dietary, environmental, and pharmacological compounds. Modulation of CYP activity impacts the detoxification of xenobiotics as well as endogenous pathways such as steroid and fatty acid metabolism, thus playing a central role in homeostasis. This review is focused on nine main topics that include the most relevant aspects of past and current PGRMC1 research, focusing on its role in CYP-mediated drug metabolism. Firstly, a general overview of the main aspects of xenobiotic metabolism is presented (I), followed by an overview of the role of the CYP enzymatic complex (IIa), a section on human disorders associated with defects in CYP enzyme complex activity (IIb), and a brief account of cytochrome b5 (cyt b5)'s effect on CYP activity (IIc). Subsequently, we present a background overview of the history of the molecular characterization of PGRMC1 (III), regarding its structure, expression, and intracellular location (IIIa), and its heme-binding capability and dimerization (IIIb). The next section reflects the different effects PGRMC1 may have on CYP activity (IV), presenting a description of studies on the direct effects on CYP activity (IVa), and a summary of pathways in which PGRMC1's involvement may indirectly affect CYP activity (IVb). The last section of the review is focused on the current challenges of research on the effect of PGRMC1 on CYP activity (V), presenting some future perspectives of research in the field (VI).

Asparagine-85 Stabilizes a Structural Active Site Water Network in CYP121A1 of Mycobacterium tuberculosis

The cytochrome P450 enzyme CYP121A1 endogenously catalyzes the formation of a carbon-carbon bond between the two phenol groups of dicyclotyrosine (cYY) in Mycobacterium tuberculosis (Mtb). One of 20 CYP enzymes in Mtb, CYP121A1 continues to garner significant interest as a potential drug target. The accompanying reports the use of 19F NMR spectroscopy, reconstituted activity assays, and molecular dynamics simulations to investigate the significance of hydrogen bonding interactions that were theorized to stabilize a static active site water network. The active site residue Asn-85, whose hydrogen bonds with the diketopiperazine ring of cYY contributes to a contiguous active site water network in the absence of cYY, was mutated to a serine (N85S) and to a glutamine (N85Q). These conservative changes in the hydrogen bond donor side chain result in inactivation of the enzyme. Moreover, the N85S mutation induces reverse type-I binding as measured by absorbance difference spectra. NMR spectra monitoring the ligand-adaptive FG-loop and the active site Trp-182 side chain confirm that disruption of the active site water network also significantly alters the structure of the active site. These data were consistent with dynamics simulations of N85S and N85Q that demonstrate that a compromised water network is responsible for remodeling of the active site B-helix and a repositioning of cYY toward the heme. These findings implicate a slowly exchanging water network as a critical factor in CYP121A1 function and a likely contributor to the unusual rigidity of the structure.

Single Mutations in Cytochrome P450 Oxidoreductase Can Alter the Specificity of Human Cytochrome P450 1A2-Mediated Caffeine Metabolism

A unique cytochrome P450 (CYP) oxidoreductase (CPR) sustains activities of human microsomal CYPs. Its function requires toggling between a closed conformation enabling electron transfers from NADPH to FAD and then FMN cofactors and open conformations forming complexes and transferring electrons to CYPs. We previously demonstrated that distinct features of the hinge region linking the FAD and FMN domain (FD) modulate conformer poses and their interactions with CYPs. Specific FD residues contribute in a CYP isoform-dependent manner to the recognition and electron transfer mechanisms that are additionally modulated by the structure of CYP-bound substrate. To obtain insights into the underlying mechanisms, we analyzed how hinge region and FD mutations influence CYP1A2-mediated caffeine metabolism. Activities, metabolite profiles, regiospecificity and coupling efficiencies were evaluated in regard to the structural features and molecular dynamics of complexes bearing alternate substrate poses at the CYP active site. Studies reveal that FD variants not only modulate CYP activities but surprisingly the regiospecificity of reactions. Computational approaches evidenced that the considered mutations are generally in close contact with residues at the FD-CYP interface, exhibiting induced fits during complexation and modified dynamics depending on caffeine presence and orientation. It was concluded that dynamic coupling between FD mutations, the complex interface and CYP active site exist consistently with the observed regiospecific alterations.