P450BM-3; a tale of two domains--or is it three?

Over 400 P450s have been identified to date in prokaryotes and eukaryotes, plants and animals, mitochondria and endoplasmic reticulum. These enzymes function in areas such as metabolism and steroidogenesis. The eukaryotic members of this gene superfamily of proteins have proved difficult to study because of the hydrophobic nature of their substrates, their various redox partners, and membrane association. To better understand the structure/function relationship of P450s-what determines substrate specificity and selectivity, what determines redox-partner binding, and which regions are involved in membrane binding-we have compared the three crystallized, soluble bacterial P450s (two class I and one class II) and a model of a steroidogenic, eukaryotic P450 (P450arom), to define which structural elements form a conserved structural fold for P450s, what determines specificity of substrate binding and redox-partner binding, and which regions are potentially involved in membrane association. We believe that there is a conserved structural fold for all P450s that can be used to model those P450s that prove intransigent to structural determination. However, although there appears to be a conserved structural core among P450s, there is sufficient sequence variability that no two P450s are structurally identical. NADPH-P450 reductase transfers electrons from NADPH to P450 during the P450 catalytic cycle. This enzyme has usually been thought of as a simple globular protein; however, sequence analysis has shown that NADPH-P450 reductase is related to two separate flavoprotein families, ferredoxin nucleotide reductase (FNR) and flavodoxin. Recent studies by Wolff and his colleagues have shown that the FAD-binding FNR domain and FMN-binding flavodoxin domain of human NADPH-P450 reductase can be independently expressed in Escherichia coli. The subdomains can be used to reconstitute, however poorly, the monooxygenase activity of the P450 system. We have been utilizing the reductase domain of P450BM-3 to study the mechanism of electron transfer from NADPH to P450 in this complex multidomain protein. We have overexpressed both the FNR subdomain and the flavodoxin subdomain in E. coli and fully reconstituted the cytochrome c reductase activity of this enzyme. Our studies have shown that electron transfer from NADPH through the reductase domain to the P450 requires shuttling of the FMN subdomain between the reductase subdomain and the P450. Studies of the factors that control the molecular recognition and interaction among these three proteins are complicated by the weakness of the association and changes in the strength of the interaction depending on the redox state of each of the components. How these structural and mechanistic studies of a soluble bacterial P450 can be extended to gain a better understanding of the control of membrane-bound eukaryotic P450-dependent redox systems is discussed.

An active site substitution, F87V, converts cytochrome P450 BM-3 into a regio- and stereoselective (14S,15R)-arachidonic acid epoxygenase.

Cytochrome P450 BM-3 catalyzes the high turnover regio- and stereoselective metabolism of arachidonic and eicosapentaenoic acids. To map structural determinants of productive active site fatty acid binding, we mutated two amino acid residues, arginine 47 and phenylalanine 87, which flank the surface and heme ends of the enzyme's substrate access channel, respectively. Replacement of arginine 47 with glutamic acid resulted in a catalytically inactive mutant. Replacement of arginine 47 with alanine yielded a protein with reduced substrate binding affinity and arachidonate sp3 carbon hydroxylation activity (72% of control wild type). On the other hand, arachidonic and eicosapentaenoic acid epoxidation was significantly enhanced (154 and 137%, of control wild type, respectively). As with wild type, the alanine 47 mutant generated (18R)-hydroxyeicosatetraenoic, (14S,15R)-epoxyeicosatrienoic, and (17S,18R)-epoxyeicosatetraenoic acids nearly enantiomerically pure. Replacement of phenylalanine 87 with valine converted cytochrome P450 BM-3 into a regio- and stereoselective arachidonic acid epoxygenase ((14S,15R)-epoxyeicosatrienoic acid, 99% of total products). Conversely, metabolism of eicosapentaenoic acid by the valine 87 mutant yielded a mixture of (14S,15R)- and (17S,18R)-epoxyeicosatetraenoic acids (26 and 69% of total, 94 and 96% optical purity, respectively). Finally, replacement of phenylalanine 87 with tyrosine yielded an inactive protein. We propose that: (a) fatty acid oxidation by P450 BM-3 is incompatible with the presence of residues with negatively charged side chains at the surface opening of the substrate access channel or a polar aromatic side chain in the vicinity of the heme iron; (b) the high turnover regio- and stereoselective metabolism of arachidonic and eicosapentaenoic acids involves charge-dependent anchoring of the fatty acids at the mouth of the access channel by arginine 47, as well as steric gating of the heme-bound oxidant by phenylalanine 87; and (c) substrate binding coordinates, as opposed to oxygen chemistries, are the determining factors responsible for reaction rates, product chemistry, and, thus, catalytic outcome.

Aromatase expression in health and disease.

Family 19 of the P450 superfamily is responsible for the conversion of C19 androgenic steroids to the corresponding estrogens, a reaction known as aromatization, since it involves conversion of the delta 4-3-one A-ring of the androgens to the corresponding phenolic A-ring characteristic of estrogens. Its members occur throughout the entire vertebrate phylum. The reaction mechanism of aromatase is very interesting from a chemical point of view and has been studied extensively; however, a detailed examination of structure-function relationships has not been possible due to lack of a crystal structure. Recent attempts to model the three-dimensional structure of aromatase have permitted a model that accounts for the reaction mechanism and predicts the location of aromatase inhibitors. The gene encoding human aromatase has been cloned and characterized and shown to be unusual compared to genes encoding other P450 enzymes, since there are a number of untranslated first exons that occur in aromatase transcripts in a tissue-specific fashion, due to differential splicing as a consequence of the use of tissue-specific promoters. Thus, expression in ovary utilizes a proximal promoter that is regulated primarily by cAMP. On the other hand, expression in placenta utilizes a distal promoter that is located at least 40 kb upstream of the start of transcription and that is regulated by retinoids. Other promoters are employed in brain and adipose tissue. In the latter case, class I cytokines such as IL-6 and IL-11 as well as TNF alpha are important regulatory factors. PGE2 is also an important regulator of aromatase expression in adipose mesenchymal cells via cAMP and PGE2 appears to be a major factor produced by breast tumors that stimulates estrogen biosynthesis in local mesenchymal sites. In all of the splicing events involved in the use of these various promoters, a common 3'-splice junction is employed that is located upstream of the start of translation; thus, the coding regions of the transcripts- and hence the protein-are identical regardless of the tissue site of expression; what differ in a tissue-specific fashion are the 5'-ends of the transcripts. This pattern of expression has great significance both from a phylogenetic and ontogenetic standpoint as well as for the physiology and pathophysiology of estrogen formation. Recently, a number of mutations of the aromatase gene have been described, which give rise to complete estrogen deficiency. In females this results in virilization in utero and primary amenorrhea with hypergonadotropic hypogonadism at the time of puberty. In men the most striking feature is continued linear bone growth beyond the time of puberty, delayed bone age, and failure of epiphyseal closure, thus indicating an important role of estrogens in bone metabolism in men. In both sexes the symptoms can be alleviated by estrogen administration.

The highly stereoselective oxidation of polyunsaturated fatty acids by cytochrome P450BM-3.

Cytochrome P450BM-3 catalyzes NADPH-dependent metabolism of arachidonic acid to nearly enantiomerically pure 18(R)-hydroxyeicosatetraenoic acid and 14(S), 15(R)-epoxyeicosatrienoic acid (80 and 20% of total products, respectively). P450BM-3 oxidizes arachidonic acid with a rate of 3.2 +/- 0.4 micromol/min/nmol at 30 degrees C, the fastest ever reported for an NADPH-dependent, P450-catalyzed reaction. Fatty acid, oxygen, and NADPH are utilized in an approximately 1:1:1 molar ratio, demonstrating efficient coupling of electron transport to monooxygenation. Eicosapentaenoic and eicosatrienoic acids, two arachidonic acid analogs that differ in the properties of the C-15-C-18 carbons, are also actively metabolized by P450BM-3 (1.4 +/- 0.2 and 2.9 +/- 0.1 micromol/min/nmol at 30 degrees C, respectively). While the 17,18-olefinic bond of eicosapentaenoic acid is epoxidized with nearly absolute regio- and stereochemical selectivity to 17(S),18(R)-epoxyeicosatetraenoic acid (>/=99% of total products, 97% optical purity), P450BM-3 is only moderately regioselective during hydroxylation of the eicosatrienoic acid omega-1, omega-2, and omega-3 sp3 carbons, with 17-, 18-, and 19-hydroxyeicosatrienoic acid formed in a ratio of 2.4:2.2:1, respectively. Based on the above and on a model of arachidonic acid-bound P450BM-3, we propose: 1) the formation by P450BM-3 of a single oxidant species capable of olefinic bond epoxidation and sp3 carbon hydroxylation and 2) that product chemistry and, thus, catalytic outcome are critically dependent on active site spatial coordinates responsible for substrate binding and productive orientation between heme-bound active oxygen and acceptor carbon bond(s).

A three-dimensional model of aromatase cytochrome P450.

P450 hemeproteins comprise a large gene superfamily that catalyzes monooxygenase reactions in the presence of a redox partner. Because the mammalian members are, without exception, membrane-bound proteins, they have resisted structure-function analysis by means of X-ray crystallographic methods. Among P450-catalyzed reactions, the aromatase reaction that catalyzes the conversion of C19 steroids to estrogens is one of the most complex and least understood. Thus, to better understand the reaction mechanism, we have constructed a three-dimensional model of P450arom not only to examine the active site and those residues potentially involved in catalysis, but to study other important structural features such as substrate recognition and redox-partner binding, which require examination of the entire molecule (excepting the putative membrane-spanning region). This model of P450arom was built based on a "core structure" identified from the structures of the soluble, bacterial P450s (P450cam, P450terp, and P450BM-P) rather than by molecular replacement, after which the less conserved elements and loops were added in a rational fashion. Minimization and dynamic simulations were used to optimize the model and the reasonableness of the structure was evaluated. From this model we have postulated a membrane-associated hydrophobic region of aliphatic and aromatic residues involved in substrate recognition, a redox-partner binding region that may be unique compared to other P450s, as well as residues involved in active site orientation of substrates and an inhibitor of P450arom, namely vorozole. We also have proposed a scheme for the reaction mechanism in which a "threonine switch" determines whether oxygen insertion into the substrate molecule involves an oxygen radical or a peroxide intermediate.

Functional domains of human aromatase cytochrome P450 characterized by linear alignment and site-directed mutagenesis.

The relationship of function to structure of aromatase cytochrome P450 (P450arom; the product of the CYP19 gene) has been examined by means of sequence alignment and site-directed mutagenesis. Comparison has been made between the sequence of P450arom and the two soluble bacterial cytochrome P450 isoforms, whose three-dimensional structure has been determined (P450BM3 and P450cam). From this comparison, it appears that although there is a similarity of overall structure in cytochromes P450, there is enough significant difference in the regions involved in substrate recognition and substrate binding that residues believed to be involved, even in the known structures, must be tested. With this in mind, we have generated a detailed alignment of P450arom, including the definition of putative alpha-helices and beta-sheets based on comparison of the alignments of P450BM3 and P450cam, generated from their three-dimensional structure, and have made mutations in regions we believe to be involved in substrate recognition at the solvent surface and orientation in the heme pocket. We have mutated F116 and F134 to determine if they are present in the heme pocket, and Q225 and L228 to determine if they are a part of the substrate recognition loop. Although F116E is essentially inactive and may be a folding mutant or may inhibit reductase binding, F134E is more active than the wild type and may be located in the heme pocket facilitating the hydrogen abstraction from C2 of androstenedione. Mutations at Q225 and L228 also result in the anticipated changes in the apparent Km and maximum velocity.(ABSTRACT TRUNCATED AT 250 WORDS)

Active sites of the cytochrome p450cam (CYP101) F87W and F87A mutants. Evidence for significant structural reorganization without alteration of catalytic regiospecificity.

Ferricyanide oxidation of the aryl-iron complexes formed by the reaction of cytochrome P450 enzymes with arylhydrazines causes in situ migration of the aryl group from the iron to the porphyrin nitrogen atoms. The regiochemistry of this migration, defined by the ratio of the four possible N-arylprotoporphyrin IX isomers, provides a method for mapping the topologies of cytochrome P450 active sites. The method has been validated by using it to examine the active site of cytochrome P450cam (CYP101), for which a crystal structure is available. In agreement with the crystal structure, reaction with phenylhydrazine gives a 5:25:70 ratio of the NA:NC:ND (subscript indicates pyrrole ring) N-phenylprotoporphyrin IX isomers. Naphthylhydrazine, however, yields exclusively the NC regioisomer and 4-(phenyl)phenylhydrazine the NA:NC:ND isomers in a 14:40:46 ratio. These isomer ratio differences are readily explained by topological differences between the upper and lower reaches of the active site. Having validated the aryl-iron shift as a topological probe, we used it to investigate the structural changes caused by mutation of Phe-87, a residue that provides the ceiling over pyrrole ring D in the crystal structure of cytochrome P450cam. Mutation of Phe-87 to a tryptophan causes no detectable change in the regiochemistry of camphor hydroxylation and only minor changes in the N-aryl isomer ratios. However, mutation of Phe-87 to an alanine, which was expected to open up the region above pyrrole ring D, severely decreased the proportion of the ND in favor of the NA isomer. Less rather than more space is therefore available over pyrrole ring D in the F87A mutant despite the fact that the regiochemistry of camphor hydroxylation remains unchanged. These results provide evidence for significant structural reorganization in the upper regions of the substrate binding site without alteration of the camphor hydroxylation regiospecificity in the F87A mutant.

Cytochrome P-450terp. Isolation and purification of the protein and cloning and sequencing of its operon.

Cytochromes P-450 are extremely important in the oxidative metabolism of a variety of endogenous and exogenous compounds in pro- and eukaryotic organisms. Progress in understanding the structure and mechanism of action of this superfamily of enzymes has been hampered by the properties of the eukaryotic enzymes and the availability of only one well-characterized prokaryotic enzyme as a model. We report here the isolation of a Pseudomonas species which will utilize a monoterpene natural product, alpha-terpineol, as its sole source of carbon and energy. Approximately 1% of the soluble protein in the cell-free extract is a novel cytochrome P-450 (P-450terp). This enzyme and its associated iron sulfur protein electron carrier (terpredoxin) have been purified to homogeneity and their NH2-terminal amino acid sequences determined. The amino acid sequences of six tryptic peptide fragments of cytochrome P-450terp have also been determined. This sequence information was used to clone the gene encoding cytochrome P-450terp. Three clones representing approximately 8 kilobase pairs of unique sequences were selected and sequenced. Five non-overlapping open reading frames (ORFs) were found in the sequences, and the translated sequences were used to search the Protein Identification Resource for comparable proteins. The ORFs were identified as: 1) an alcohol dehydrogenase, 2) an aldehyde dehydrogenase, 3) cytochrome P-450terp, 4) terpredoxin reductase, and 5) terpredoxin. The identification of both the cytochrome P-450terp and terpredoxin DNA sequence was confirmed by the presence of each of the corresponding amino acid sequences found in the purified proteins. The five ORFs were bounded on both the 5' and 3' ends by consensus factor-independent terminator sequences. A consensus promoter sequence was found immediately 5' to the first ORF. These results indicate that we have sequenced the complete terp operon. Comparison of the amino acid sequence of cytochrome P-450terp to that of all other cytochromes P-450 has shown that it is the first member of the gene family CYP108. Preliminary characterization of the chemical and physical properties and the preparation of crystals of this new cytochrome P-450, suitable for x-ray diffraction analysis, indicate that it will be useful in comparison studies with other members of this class of proteins.

Nucleotide sequence of a cDNA encoding porcine testis 17 alpha-hydroxylase cytochrome P-450.

We describe the isolation and characterization of a cDNA encoding the complete porcine neonatal testis 17 alpha-hydroxylase/C-17,20-lyase cytochrome P-450. The deduced amino acid sequence is 509 amino acids in length.

3 beta-hydroxysteroid dehydrogenase/delta 5----4-isomerase expression in rat and characterization of the testis isoform.

The isolation, cloning and expression of a DNA insert complementary to mRNA encoding rat testis 3 beta-hydroxysteroid dehydrogenase/delta 5----4-isomerase (3 beta-HSD) is reported. The insert contains an open reading frame encoding a protein of 373 amino acids, which exhibits 73% and 78% identity to the cDNA encoding the human placental form at the amino acid and nucleotide levels respectively. Northern blot analysis of total RNA of rat tissues using as probe a specific radiolabeled cDNA insert encoding rat testis 3 beta-HSD demonstrated high levels of 1.6 kb mRNA species in ovary, adrenal and Leydig tumor, with lower but detectable message in testis and adult male liver, while the probe also hybridized to a 2.1 kb mRNA species in liver. The cDNA was inserted into a modified pCMV vector and expressed in COS-1 monkey kidney tumor cells. The expressed protein was similar in size to 3 beta-HSD present in H540 Leydig tumor cell homogenate and human placental microsomal 3 beta-HSD, as detected by immunoblot analysis, and catalyzed the conversion of pregnenolone to progesterone, 17 alpha-hydroxypregnenolone to 17 alpha-hydroxyprogesterone, and dehydroepiandrosterone to androstenedione. Transfected COS cell homogenates, supplemented with NAD+, but not NADP+, converted pregnenolone to progesterone and dehydroepiandrosterone to androstenedione with apparent Km values of 0.13 and 0.09 microM, respectively. Immunoblot analysis of various rat tissues using a polyclonal antibody directed against human placental 3 beta-HSD, in addition to immunoreactivity in the adrenal and testis, demonstrated immunoreactive 3 beta-HSD protein in adult male liver, but not in adult female or fetal liver. We conclude that while one gene product is highly expressed in testicular Leydig cells, and probably adrenal and ovary, accounting for their 3 beta-HSD content, a 3 beta-HSD is also expressed in liver in a sex-specific manner.

Structure-function relationships of human aromatase cytochrome P-450 using molecular modeling and site-directed mutagenesis.

The conversion of androgens to estrogens is catalyzed by an enzyme complex named aromatase, which consists of a form of cytochrome P-450, aromatase cytochrome P-450 (cytochrome P-450AROM), and the flavoprotein, NADPH-cytochrome P-450 reductase. As a first step toward investigation of the structure-function relationships of cytochrome P-450AROM, we have used computer modeling to align the amino acid sequence of cytochrome P-450AROM with that of cytochrome P-450CAM from Pseudomonas putida and thus create a substrate pocket using the heme-binding region and the I-helix of cytochrome P-450CAM as the template. Site-directed mutagenesis was then carried out at two sites: one at a region that aligns with the bend in the I-helix of cytochrome P-450CAM and the other at a glutamate (Glu302) just N-terminal of this bend, which is predicted to be in close proximity to the C2-position of the androstenedione substrate. To determine the importance of the former region, three mutants were constructed: A307G (Ala307----Gly), P308V (Pro308----Val), and GAGV, which changed -Ile305-Ala306-Ala307-Pro308- to -Gly-Ala-Gly-Val- (the corresponding sequence found in 17 alpha-hydroxylase cytochrome P-450). When these proteins were expressed in COS-1 cells, it was found that the activity of P308V was approximately one-third that of the wild type. These observations are consistent with the concept that Pro308 causes a bend in the I-helix of cytochrome P-450AROM, similar to that observed in cytochrome P-450CAM, which is believed to be important in forming the substrate-binding pocket. The next set of mutants were designed to determine the importance of Glu302 in catalysis. Four mutants were prepared in which Glu302 was changed either to Ala, Val, Gln, or Asp, and the activities of the expressed proteins were examined. It was found that mutations in which the carboxylic acid was replaced were essentially devoid of activity. On the other hand, changing Glu302 to Asp resulted in a two-thirds reduction in the apparent Vmax. These results support the role of a carboxylic acid residue at position 302 in the catalytic activity of cytochrome P-450AROM.

Use of molecular probes to study regulation of aromatase cytochrome P-450.

Aromatase, an enzyme complex localized in the endoplasmic reticulum of estrogen-producing cells, is composed of NADPH-cytochrome P-450 reductase, and aromatase cytochrome P-450 (cytochrome P-450AROM). To define the molecular mechanisms involved in the multifactorial regulation of cytochrome P-450AROM in estrogen-producing cells, we have isolated a cDNA specific for human cytochrome P-450AROM and have used this cDNA to isolate the human cytochrome P-450AROM gene. The cDNA sequence encodes a polypeptide of 503 amino acids and contains--near the carboxy-terminus, a region of high homology with the putative heme-binding regions of other P-450 cytochromes. COS1 cells transfected with an expression plasmid containing the cytochrome P-450AROM cDNA had the capacity to aromatize testosterone, androstenedione and 16 alpha-hydroxyandrostenedione, suggesting that a single polypeptide catalyzes all steps of the aromatization reaction using either of the three major C19-substrates. The human cytochrome P-450AROM gene is greater than 52 kb in size and consists of 10 exons and 9 introns. Hormonally induced changes in aromatase activity of human ovarian granulosa and adipose stromal cells are associated with comparable changes in cytochrome P-450AROM gene expression and synthesis, whereas the reductase component is only modestly affected. Studies are in progress to define the molecular mechanisms involved in the regulation of cytochrome P-450AROM gene expression in estrogen-producing cells.

Isolation of a full-length cDNA insert encoding human aromatase system cytochrome P-450 and its expression in nonsteroidogenic cells.

The isolation and cloning of a full-length cDNA insert complementary to mRNA encoding human aromatase system cytochrome P-450 is reported. The insert contains an open reading frame encoding a protein of 503 amino acids. This gene is clearly a member of the cytochrome P-450 gene superfamily, because the sequence contains regions of marked homology to those of other members, notably a putative membrane-spanning region, I helix, Ozols, and heme-binding regions. The cDNA was inserted into a modified pCMV vector and expressed in COS-1 monkey kidney tumor cells. The expressed protein was similar in size to human placental aromatase system cytochrome P-450, as detected by immunoblot analysis, and catalyzed the aromatization of androstenedione, testosterone, and 16 alpha-hydroxyandrostenedione. This activity was inhibited by the known aromatase inhibitors, 4-hydroxyandrostenedione and econazole. Thus the several steps involved in the aromatization reaction appear to be catalyzed by a single polypeptide chain, which can metabolize the three major physiological substrates.