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J. Biol. Chem., Vol. 282, Issue 19, 14348-14355, May 11, 2007

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Adaptations for the Oxidation of Polycyclic Aromatic Hydrocarbons Exhibited by the Structure of Human P450 1A2^*

Stefaan Sansen, Jason K. Yano¹, Rosamund L. Reynald, Guillaume A. Schoch², Keith J. Griffin, C. David Stout³, and Eric F. Johnson⁴

From the Department of Molecular and Experimental Medicine and the Department of Molecular Biology, The Scripps Research Institute, La Jolla, California 92037

Received for publication, December 21, 2006 , and in revised form, February 2, 2007.

	ABSTRACT

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS AND DISCUSSION REFERENCES

 
Microsomal cytochrome P450 family 1 enzymes play prominent roles in xenobiotic detoxication and procarcinogen activation. P450 1A2 is the principal cytochrome P450 family 1 enzyme expressed in human liver and participates extensively in drug oxidations. This enzyme is also of great importance in the bioactivation of mutagens, including the N-hydroxylation of arylamines. P450-catalyzed reactions involve a wide range of substrates, and this versatility is reflected in a structural diversity evident in the active sites of available P450 structures. Here, we present the structure of human P450 1A2 in complex with the inhibitor -naphthoflavone, determined to a resolution of 1.95 Å. -Naphthoflavone is bound in the active site above the distal surface of the heme prosthetic group. The structure reveals a compact, closed active site cavity that is highly adapted for the positioning and oxidation of relatively large, planar substrates. This unique topology is clearly distinct from known active site architectures of P450 family 2 and 3 enzymes and demonstrates how P450 family 1 enzymes have evolved to catalyze efficiently polycyclic aromatic hydrocarbon oxidation. This report provides the first structure of a microsomal P450 from family 1 and offers a template to study further structure-function relationships of alternative substrates and other cytochrome P450 family 1 members.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS AND DISCUSSION REFERENCES

 
Enzymes of the cytochrome P450 (CYP)⁵ superfamily play a significant physiologic role in the detoxication of foreign compounds and the biosynthesis of endogenous compounds, including steroid hormones, bile acids, and cholesterol. The enzymes comprising P450 families 1, 2, and 3 contribute most extensively to the biotransformation of xenobiotics to more polar metabolites that are more readily excreted. In humans and most mammals, family 1 contains three well characterized P450 monooxygenases; 1A1, 1A2, and 1B1. These enzymes are generally distinguished from P450s in other families by their capacity to oxidize a variety of polynuclear aromatic hydrocarbons (PAHs).⁶ Moreover, the expression levels of the three enzymes are induced by exposure to PAHs (1). The induction is mediated by a ligand-activated transcription factor, the aryl hydrocarbon receptor, which is a basic-loop-helix PAS domain protein that binds to enhancer elements flanking the CYP1A1, CYP1A2, and CYP1B1 genes and stimulates transcription.

The oxidation of PAHs is generally protective. However, some P450-catalyzed reactions can transform these relatively inert compounds into genotoxic metabolites that can initiate mutagenesis and cancer. Human P450 1A2 is notable among family 1 enzymes for the capacity to N-oxidize arylamines, the major metabolic process in the bioactivation of arylamines to potent mutagenic or carcinogenic compounds (2). -Naphthoflavone (ANF), a prototype flavonoid, is known to competitively inhibit P450s of family 1, albeit at different concentrations, and has been used to discriminate between P450 family 1 enzymes (3). Flavonoids have gained recent interest in view of their potential therapeutic and prophylactic effects on P450-mediated chemical carcinogenesis (4).

CYP1A2 is the principal family 1 enzyme expressed in human liver, and CYP1A2 contributes significantly to the hepatic metabolism of drugs, as recently reviewed (5). Among liver P450 drug-metabolizing enzymes, P450 1A2 plays a predominant role in the metabolic clearance of caffeine and melatonin as well as of marketed drugs such as flutamide, lidocaine, olanzapine, tacrine, theophylline, triamterene, and zolmitriptan. Large inter-individual differences in CYP1A2 expression levels and catalytic activity contribute to significant differences between individuals in drug clearance. The basis for this variation is only partially understood.

This report provides the first structural characterization of human CYP1A2 and is the first structure of a microsomal P450 from family 1. The structure reveals an enzyme that is highly adapted for the oxidation of relatively large, planar molecules such as (heterocyclic) arylamines and PAHs and provides a basis for understanding the unique roles this enzyme plays in the biotransformation of xenobiotics. CYP1A2 exhibits less than 40% amino acid sequence identity when compared with other structurally characterized mammalian microsomal P450s 2A6 (6), 2B4 (7), 2C5 (8), 2C8 (9), 2C9 (10, 11), 2D6 (12), and 3A4 (13, 14). The P450 1A2 active site cavity complements the sizes, shapes, and chemical properties of the substrate binding sites determined for other human drug-metabolizing P450s, contributing to the overall capacity of P450s to oxidize a vast array of structurally dissimilar substrates.

	EXPERIMENTAL PROCEDURES

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS AND DISCUSSION REFERENCES

 
Expression and Purification of hP450 1A2—Plasmid vectors were constructed to express modified forms of human P450 1A2 in Escherichia coli. The modifications were designed to facilitate crystallization by removing the N-terminal transmembrane helical domain to reduce aggregation, increase solubility, and eliminate a flexible appendage that is not part of the catalytic domain. In the expression construct, the native sequence upstream of the polyproline motif at residue 42 was modified to correspond to a modified, truncated N-terminal sequence successfully employed for crystallization of P450s 2C5/3LVdH (8, 15), 2C8dH (9), 2B4dH (16), and 2A6dH (6). This was achieved using a forward PCR primer that encoded a 5'-NdeI restriction site, the modified N-terminal sequence MAKKTSSKGKL, and sequence encoding the native protein beginning at codon 42. The reverse primer encoded a HindIII restriction site, a stop codon, four histidine codons, and seven C-terminal codons of the protein. Following PCR amplification from a plasmid template containing the human CYP1A2 cDNA (17) kindly provided by Robert Tukey, University of California San Diego (UCSD), using high fidelity Platinum Taq polymerase (Invitrogen), the PCR fragment was isolated and digested with the appropriate endonucleases for ligation into the pCWori vector. A series of alternative constructs was also generated that deleted the transmembrane helical domain but retained different portions of the native linker region preceding the proline-rich motif at the beginning of the catalytic domain. For the D24 construct used in this study, double-stranded oligonucleotides with appropriate overhangs were ligated into the initial expression vector designated G1, which had been digested with the endonucleases NdeI and NcoI. The D24 construct encodes residues 26-515 of the protein, preceded by codons for Met and Ala. Sequences of the primer pairs used in the design of the G1 and D24 constructs are provided in supplemental Table S1. Sequence analysis verified the construction of each expression vector for the predominant allelic variant CYP1A2^*1A (GenBank^TM: P05177 [GenBank] ).

E. coli strain DH5 was transformed with a CYP1A2 expression plasmid together with an expression plasmid for the chaperones GroEL and GroES (pGro7, Takara Bio Inc., Shiga, Japan) to further improve the yield and stability of the proteins. Transformants were selected based on ampicillin and chloramphenicol resistance. Conditions for the growth, harvest, and purification of the proteins by metal ion affinity chromatography and CM-Sepharose chromatography in the presence of the detergent CYMAL-5 (Anatrace) closely followed procedures described previously (18). All buffers used for purification, storage, and crystallization of the protein contained 10 µM ANF to stabilize the modified human P450 1A2 constructs (19). The concentration of the protein was estimated by UV-visible difference spectroscopy for the CO-complex of the dithionite-reduced enzyme versus the reduced enzyme.

Protein Crystallization—The modified CYP1A2 proteins were crystallized by hanging drop vapor diffusion. The vapor diffusion experiments were conducted at 298 K over a standard well solution (0.5 ml) composed of 10% PEG 3350, 20% glycerol, 100 mM NaCl in a Hepes buffer, pH 7.4. Protein drops were set up in a ratio of 1:1 protein detergent solution to precipitant solution. The setup allowed us to fine-tune the equilibration rate by only changing the precipitant solution in the experiment while holding the well solution constant. The protein detergent solution contained 1.25 µl of a concentrated protein solution mixed with detergent solution to contain 7.5 mM CYMAL-6 and 0.01 mM C12E8 (Anatrace). A precipitant solution containing 100 mM Tris-HCl buffer (pH 8.5), 10% PEG 3350, and 50 mM ammonium iodide yielded crystals for the G1 construct from a protein solution at a concentration of 390 µM in 50 mM potassium phosphate buffer (pH 7.4) containing 10 µM ANF, 500 mM NaCl, and 20% glycerol. Crystals of the D24 construct were obtained by mixing a protein solution (400 µM) in N-(2-acetamido)-iminodiacetic acid buffer (pH 6.5) containing 10 µM ANF, 600 mM NaCl, and 20% glycerol with precipitant solution composed of 11% PEG 3350 and 75 mM ammonium nitrate in 100 mM Tris-HCl buffer (pH 8.5).

Structure Determination—The G1 construct was crystallized initially. A complete data set to 2.9 Å resolution was collected on a single crystal, using synchrotron radiation at the Stanford Synchrotron Radiation Laboratory beamline 9-1. Prior to x-ray exposure, the crystal was short-soaked in a cryoprotectant solution containing 0.05 M NaCl, 0.08 M NH₄I, 0.1 M potassium phosphate buffer (pH 7.4), 8% PEG 3350, 5% glycerol, and 25% ethylene glycol before being flash-frozen in liquid nitrogen. Data integration and scaling employed HKL2000 (20), MOS-FLM, and SCALA (21). A molecular replacement solution in space group P1 could be obtained with Phaser (22) using the structure of CYP2A6 (PDB accession number 1Z10) as a probe. Four CYP1A2 molecules were independently positioned in the unit cell. Model building and comparison with electron density maps was done with the computer program O (23) and iterated with refinement of the atomic coordinates and grouped B-factors by simulated annealing and/or minimization using CNS (24) with the application of non-crystallographic symmetry restraints. This allowed construction of an initial CYP1A2 model for residues 42-513 of the native protein with the exception of an exterior loop encompassing residues 294-305. Statistics on data collection, processing, and refinement are provided in Table 1. Although the G1 construct produced crystals that exhibited higher symmetry, the diffraction quality could not be extended to higher resolution.

	RESULTS AND DISCUSSION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS AND DISCUSSION REFERENCES

 
Protein Design and Structure Determination—CYP1A2 was modified to remove the N-terminal transmembrane domain to improve solubility and to reduce aggregation as described previously for the crystallization of other microsomal P450s (6, 9, 15, 16). Expression of CYP1A2 as a conditional membrane protein suitable for crystallization was achieved in two ways. In the G1 construct, a short hydrophilic sequence that has been successfully employed previously for the crystallization of other human P450 enzymes was substituted for the native N-terminal sequence upstream of the proline-rich motif at the beginning of the catalytic domain (18). The alternative D24 construct employed a truncation of the wild-type CYP1A2 sequence (GenBank^TM P05177 [GenBank] ) for which residues 3-26, including the transmembrane signal anchor domain, were deleted. Both proteins crystallized under similar conditions but produced crystals that belonged to three different space groups. This appears to reflect shifts in the crystal packing to accommodate the longer N-terminal sequence of the D24 construct, resulting in denser intermolecular packing interactions, a lower crystal solvent content, and a better diffraction quality. Nevertheless, conformational differences in the catalytic domain were not evident for structures obtained from crystals belonging to space groups I222 or P2₁2₁2₁ for the D24 construct and space group P1 for the G1 construct. Root mean square deviation values for the pairwise superimposition of C traces of the three respective models do not exceed 0.55 Å. The final model was refined against data to a resolution of 1.95 Å obtained for a single crystal in space group I222 and encompasses residues 34-513 of the native protein (PDB: 2HI4). Data collection and refinement statistics are shown in Table 1.

Human P450 1A2 Structure—The structure of P450 1A2 exhibits the 12 -helices and 4 -sheets designated A-L and 1-4, respectively, which are generally seen for the canonical P450 fold (Fig. 1). Several additional helices, some of which are also seen in other P450 structures, are present and indicated by prime or double prime designations. When compared with mammalian P450s of known structure, the most conserved regions are the core of the protein forming the heme binding site and the proximal surface that is thought to provide binding sites for the redox partners, NADPH cytochrome P450 oxidoreductase and cytochrome b₅ (25). The most divergent regions between known P450 structures are the portions that form the distal surfaces of the substrate binding cavity, the helix B-C and F-G regions and the C-terminal loop following helix L. Mammalian microsomal P450 enzymes generally have a large insertion between helices F and G, which exhibits a reverse amphipathicity that constitutes part of a hydrophobic surface on the tip of the protein close to the transmembrane domain. This hydrophobic surface forms part of the juxtamembrane surface of the catalytic domain of eukaryotic P450s (8, 26). Two short -helices, F' and G', are generally observed in this region for other mammalian P450 structures. In the P450 1A2 structure, both helix F' and G' are 3¹⁰ helical fragments rather than -helices. Nevertheless, a reverse amphipathicity is maintained. This insertion and hydrophobic surface are not generally seen in soluble prokaryotic P450 structures.

View larger version (46K): [in this window] [in a new window]   FIGURE 1. The secondary and tertiary structure of human P450 1A2 is shown in two views. The -helices are colored blue, and the -strands are colored brown. These secondary structure elements are designated A-L and 1-4, respectively, and are sequentially identified from the N terminus. The heme prosthetic group is represented in sticks and is colored red. The substrate binding cavity is illustrated as a red mesh surface.

View larger version (29K): [in this window] [in a new window]   FIGURE 2. Comparison between the active site cavity volumes for human P450 1A2 (A) (PDB: 2HI4), P450 2A6 (B) (PDB: 1Z10 (6)), and P450 3A4 (C) (PDB: 1TQN (14)). The overall size of the P450 1A2 cavity is 375 Å3, which is about 50% larger than that of P450 2A6 (260 Å3) but considerably smaller than that of P450 3A4 (1385 Å3). Volumes of the substrate binding cavities were calculated using a 1.4 Å probe with the program VOIDOO (36). The disruption of helix F as it crosses the distal surface of the active site cavity of P450 1A2 (A) is highlighted in red. SRS5, substrate recognition site 5.

Another remarkable feature of the P450 1A2 structure is the disruption of helix F as it crosses the distal surface of the active site cavity (Fig. 2). P450 family 2 structures (6-12) display an intact helix F for this region (Fig. 2). Also, in the structure of P450 3A4 (13, 14), a coiled structure connecting helices F and F' crosses above the active site cavity (Fig. 2). In the P450 1A2 structure, the -helical hydrogen-bonding pattern is lost at Val-220 and Lys-221, causing one helical turn in the middle of helix F to unwind. Two water molecules fill the space thus created, giving rise to water-bridged contacts between Val-220 carbonyl oxygen and Thr-223 O, and Lys-221 carbonyl oxygen and His-224 amide nitrogen, respectively. The bending of helix F brings the C-terminal portion of the helix in toward the core of the protein, closing down the active site cavity. Substrates bind in the cavity located above the distal surface of the heme prosthetic group. In the P450 1A2 structure of the ANF complex, the active site is closed without evident solvent or substrate access channels. The volume of the cavity was estimated to be 375 ų, which is larger than that of P450 2A6 (260 ų) (Fig. 2). The rather compact, closed active site cavity topologies of P450 1A2 and P450 2A6 contrast with the much more open active site architectures displayed by P450 3A4 (Fig. 2) and P450 2C8, with volumes of 1385 ų and 1438 ų, respectively.

View larger version (12K): [in this window] [in a new window]   FIGURE 3. Structure and numbering of -naphthoflavone.

View larger version (30K): [in this window] [in a new window]   FIGURE 4. Detailed view of the binding of -naphthoflavone in the human P450 1A2 active site. A shows the position of ANF and the heme group defined by A-weighted 2|Fo| - |Fc| electron density maps (blue mesh). B and C show two views of the amino acid residues constituting the active site cavity depicted in sticks, with portions of the protein backbone represented as a ribbon schematic. The inhibitor ANF and the heme prosthetic group are shown in sticks, with carbons colored yellow and pink, respectively. Oxygen, nitrogen, and iron atoms are colored red, blue, and orange, respectively. A water molecule is represented as a red sphere.

ANF is reported to be a potent, competitive inhibitor of human P450 1A2-catalyzed reactions with an estimated K_i of 1-50 nM (3, 27). Several structural features are likely to contribute to the high apparent binding affinity of P450 1A2 for ANF. First, ANF closely fits the size and shape of the substrate binding cavity (Fig. 4), leading to dense and extensive Van der Waals interactions arising mainly from non-polar side chains. Also, the hydrophobic effect is likely to contribute to a favorable free energy difference for ANF binding. In addition, both orthogonal and parallel aromatic interactions between ANF and phenylalanine side chains 125 and 226 contribute to a tight binding affinity. Finally, the presence of an ordered water molecule near the carbonyl group of ANF provides an extra binding interaction. The water molecule appears to be hydrogen-bonded to the carbonyl of ANF as well as to the carbonyl of Gly-316 on helix I (Fig. 5). This water molecule is the only one present in the active site, and no apparent solvent channels that connect the active site cavity with the protein surface are evident.

The distance from the heme iron to C'4 of ANF is 4.7 Å. This distance falls at the long end of the range of distances observed for productive substrate binding in other P450 structures and is rather large for the energetically more favorable direct -attack of the compound I intermediate on the C'4 aromatic carbon (28). The capacity of human CYP1A enzymes to oxidize ANF has been reported (29). Although ANF was readily metabolized by CYP1A1 to form ANF-5,6-diol and ANF-5,6-oxide, CYP1A2 oxidation of ANF was too limited for products to be analyzed. The single preferred orientation for ANF observed in the P450 1A2 structure suggests that the site of limited CYP1A2 oxidation would be at the other end of the molecule relative to the site of CYP1A1 oxidation. The low rate of oxidation could reflect the high affinity binding of ANF in a suboptimal position for oxidation and a concomitant slow off-rate of the products. These factors are likely to contribute to the tight binding competitive inhibition of P450 1A2 by ANF.

Active Site Architecture—The substrate binding cavity is uniformly narrow throughout its extent and is lined by residues on helix F and helix I that define a relatively planar substrate binding platform on either side (Fig. 5). Helix I bends as it crosses the heme prosthetic group. As a consequence, the helix I residues constituting one side of the substrate binding cavity adopt a relatively flat conformation of the peptide backbone, resulting in a near perfect coplanarity for the Ala-317 side chain, the Gly-316-Ala-317 peptide bond, and the Asp-320-Thr-321 peptide bond (Fig. 5). The occurrence of a water molecule within hydrogen-bonding distance from the backbone carbonyl group of Gly-318 on the backside of helix I helps to stabilize this deformation. On the other side of the cavity, the side chain of Phe-226 on helix F produces a parallel substrate binding surface. The distortion of helix F as it passes over the substrate binding cavity contributes to the narrow, extended cavity architecture. Not only is the C-terminal end of the helix positioned to produce a compact active site cavity, the observed bend in helix F also positions Phe-226 for the observed - stacking with ANF. The shape of the active site cavity is further stabilized by a strong hydrogen-bonding interaction between the side chain of Thr-223 on helix F with the side chain of Asp-320 on helix I, connecting both helices at the roof of the cavity. Both Thr-223 and Asp-320 participate in an extensive network of hydrogen-bonded water molecules and side chains, including Tyr-189, Val-220, Thr-498, and Lys-500. Taken together, these interactions produce a binding cavity that fits closely with planar compounds such as ANF and typical CYP1A2 substrates such as caffeine, melatonin, tacrine, olanzapine, arylamines, and alkoxyresorufins. In this regard, the structure of the P450 2A6 active site is most similar with that of P450 1A2, which is roughly 50% larger in volume. As CYP2A6 preferentially oxidizes small planar compounds (6), the differences in active site architecture correlate well with the respective substrate profiles.

P450 1A2 is unusual in that the substrate-free ferric enzyme has a predominantly high spin iron configuration, which probably reflects the absence of a water molecule bound as the sixth ligand to the axial ligation site of the heme iron. The relatively narrow substrate binding cavity is likely to reduce the propensity of water to fill the cavity in a stable binding pattern. The absence of solvent channels in the crystal structure of P450 1A2 in complex with ANF adds further credence to this idea. Furthermore, spectral assays indicate that the addition of ANF has no detectable effect on the iron spin state (19). Amino acid substitutions for Phe-226 and Asp-320 have been shown to produce CYP1A2 mutant enzymes that display a predominantly low spin character. The substitutions F226I, F226Y, and D320A (30) have the potential to reduce intramolecular interactions between residues that constitute the compact, closed active site cavity, leading to open water channels that could stabilize the binding of water to the heme iron. In addition, these three mutants showed a reduced catalytic efficiency indicative of an effect on active site integrity. Except for mutations of Phe-226 and Asp-320, which display a lowered catalytic activity in nearly all cases, the effect on the catalytic efficiency of single mutations in substrate recognition site regions (31) largely depends on the substrate used in the activity assay. The increased K_m values observed upon substitution of Phe-226 (32) can be rationalized based on the observed position in the active site cavity and point to its prominent role in binding a wide range of substrates. Although the D320A mutation generally decreases the catalytic efficiency of the enzyme, the catalytic efficiency for the O-deethylation of resorufin by the D320A mutant is similar to that of the wild-type CYP1A2 enzyme, although the D320A mutant exhibits a 2-fold lower K_m for 7-ethoxyresorufin (32). This is likely to reflect the effect of the mutation on substrate binding as well as the catalytic mechanism of the enzyme. The latter reflects the importance of Asp/Glu at this position for the protonation and cleavage of O₂ during the P450 reaction cycle (33). It was seen that the D320A mutation impairs the formation of the iron-oxygen intermediate (30). This, together with the role of Asp-320 in maintaining contacts that determine the substrate binding cavity architecture, leads to CYP1A2 mutants at this position that are relatively inefficient for most substrates.

Human P450 family 1 enzymes show overlapping specificities for which the molecular planarity of substrates and inhibitors is of great importance. Thus, the planar active site topology observed in the P450 1A2 structure, which is well adapted for the oxidation of relatively large aromatic compounds, is likely to be conserved among the family 1 enzymes. Of the 22 residues lining the active site cavity in the P450 1A2 structure described here, 13 are identical, and an additional 7 are (semi)-conserved among human family 1 enzymes (supplemental Fig. S2). Relatively small changes in the enzyme active site residues indeed assist in the rationalization of CYP1A specificities for the O-dealkylation of alkoxyresorufins. Although wild-type CYP1A1 versus CYP1A2 shows a clear preference for 7-ethoxyresorufin versus 7-methoxyresorufin O-dealkylation, the reciprocal CYP1A1 V382L and CYP1A2 L382V mutants display interchanged specificities (34). In our structure, the distance between Leu-382 C and C'3 and C'4 of ANF is only 3.9 and 4.1 Å, respectively, which demonstrates the restricted architecture at the base of the CYP1A2 active site cavity and explains the preference of CYP1A2 for shorter alkoxyresorufins. Differences in residues that are expected to have more profound changes on P450 family 1 active site architecture are clustered around the central portion of helix F and in the B'-C loop region. It is possible that the disruption of helix F observed in the P450 1A2 structure is not a conserved feature of P450 family 1 enzymes. The Thr-223 side chain plays a crucial role in the unusual disruption of helix F by its involvement in water-bridged contacts with solvent molecules that fill the void created by the unwinding of one helical turn and by its contribution in the firm connection between helices F and I. Human CYP1A1 and CYP1B1 both display an asparagine at the equivalent position of Thr-223, which may alter folding interactions within helix F as well as between helices F and I. The absence of a disruption in helix F would essentially result in a less compact active site topology. The B'-C region in the P450 1A2 structure is characterized by the presence of 3 polar residues (Thr-118, Ser-122, and Thr-124) pointing into the active site cavity, in contrast to the more hydrophobic nature of the majority of amino acids lining the cavity. Both threonines are unique to CYP1A2. Based on homology modeling, Lewis and Lake (35) proposed that Thr-118 and Thr-124 would be implicated in two hydrogen bonds to both carbonyl oxygen atoms of caffeine. The P450 1A2 structure indicates that at least for Thr-124, this is likely to be true. The position of Thr-118 appears to be too distant to directly position smaller CYP1A2 substrates such as caffeine but may contribute to substrate binding and positioning by playing a prominent role in stable hydration that is likely to occur in the distal portion of the active site cavity upon binding of smaller substrates. The importance of Thr-124 in substrate binding was also observed in the equivalent reciprocal CYP1A1 S122T mutant, which displayed significantly increased O-dealkylation activity for both 7-ethoxy and 7-methoxyresorufin over the CYP1A1 wild-type enzyme (34). In contrast, O-demethylation activity for 7-methoxyresorufin of the CYP1A2 T124S mutant dropped by 80% relative to the wild-type activity. The occurrence of Thr-124, with a demonstrated influence on substrate binding and its position at the base of the P450 1A2 active site cavity, may also assist in the orientation for N-hydroxylation of heterocyclic arylamines. Based on the observed aromatic stacking and staggering interactions seen for ANF, mutagens such as 2-amino-3-methylimidazo[4,5-f]quinoline and 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine can be docked in the P450 1A2 structure in a position suitable for N-hydroxylation, in which the heterocyclic nitrogen atom next to the site of metabolism is ideally positioned for a hydrogen-bonding interaction with Thr-124. Taken together, the planarity of the active site cavity, the compact and restricted active site architecture, the ability to provide an H-bonding partner in close proximity to the heme, and the potential for stable hydration of the distal part of the active site cavity can all be identified as potentially important determinants of human CYP1A2 specificity. The predicted less compact P450 1A1 active site topology, in which hydrogen-bonding interactions have less of an influence on substrate binding and orientation, is concordant with the CYP1A1 preferred substrates that are usually more lipophilic and slightly bulkier than CYP1A2 substrates and may explain the differences in catalytic activities for overlapping substrates observed with these enzymes.

View larger version (31K): [in this window] [in a new window]   FIGURE 5. The active site topology of human P450 1A2 is well adapted for the binding of relatively large planar aromatic compounds. ANF is sandwiched between the flat surfaces formed by Gly-316 and Ala-317 on helix I and Phe-226 on helix F. The atom color code is the same as described in the legend for Fig. 4.

	FOOTNOTES

 
The atomic coordinates and structure factors (code 2HI4) have been deposited in the Protein Data Bank, Research Collaboratory for Structural Bioinformatics, Rutgers University, New Brunswick, NJ (http://www.rcsb.org/).

^* This work was supported by Pfizer Global Research and Development, National Institutes of Health Grant GM031001 (to E. F. J.) and the Sam and Rose Stein Charitable Trust. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

The on-line version of this article (available at http://www.jbc.org) contains a supplemental table and two figures.

This article was selected as a Paper of the Week.

¹ Present address: Dept. of Structural Biology, Takeda San Diego, 10410 Science Center Dr., San Diego, Ca 92121.

² Present address: F. Hoffmann-La Roche Ltd., Pharma Discovery Research Basel, CH-4070 Basel, Switzerland.

³ To whom correspondence may be addressed: Dept. of Molecular Biology, The Scripps Research Institute, 10550 N. Torrey Pines Rd., MB8, La Jolla, CA 92037. Tel.: 858-784-8738; Fax: 858-784-2857; E-mail: dave{at}scripps.edu. ⁴ To whom correspondence may be addressed: Dept. of Molecular and Experimental Medicine, The Scripps Research Institute, 10550 N. Torrey Pines Rd., MEM-255, La Jolla, CA 92037. Tel.: 858-784-7918; Fax: 858-784-7978; E-mail: johnson{at}scripps.edu.

⁵ CYP and P450 are generic terms for a cytochrome P450 enzyme. Individual P450s are identified using a number-letter-number format based on amino acid sequence relatedness.

⁶ The abbreviations used are: PAH, polynuclear aromatic hydrocarbon; ANF, -naphthoflavone; PEG, polyethylene glycol; PDB, Protein Data Bank.

	ACKNOWLEDGMENTS

 
We thank Qiping Zhao for excellent technical support. Robert Tukey (UCSD) is gratefully acknowledged for providing the plasmid containing the human CYP1A2 cDNA. We thank Caroline Lee, Ben Burke, Hans Parge, and Michael Wester for constructive discussions and comments on the manuscript. Portions of the research were carried out at the Stanford Synchrotron Radiation Laboratory (SSRL), a national user facility operated by Stanford University on behalf of the U.S. Department of Energy, Office of Basic Energy Sciences. The SSRL Structural Molecular Biology Program is supported by the U.S. Department of Energy, Office of Biological and Environmental Research and by the National Center for Research Resources, Biomedical Technology Program, and NIGMS of the National Institutes of Health.

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TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS AND DISCUSSION REFERENCES

 

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