Biodiversity of CYP51 in trypanosomes.

Sterol 14alpha-demethylases (CYP51) are metabolic cytochromes P450, found in each biological kingdom. They catalyse a single three-step reaction included in all sterol biosynthetic pathways. Plant CYP51s have strict preference towards their physiological substrate O (obtusifoliol), which is C-4-monomethylated. Natural substrates of animal/fungal CYP51 (lanosterol, 24,25-dihydrolanosterol or 24-methylenelanosterol) are C-4-dimethylated. CYP51 from the pathogenic protozoa TB (Trypanosoma brucei) is the first example of O-specific sterol 14alpha-demethylase in non-photosynthetic organisms. Surprisingly, at 83% amino acid identity to the TB orthologue, CYP51 from TC (Trypanosoma cruzi) clearly prefers C-4-dimethylated sterols. Replacement of animal/fungi-like Ile(105) in the B' helix of TC CYP51 with phenylalanine, the residue found in this position in all plant and other trypanosome CYP51s, dramatically increases the ability of the enzyme to metabolize O, converting it into a more plant-like sterol 14alpha-demethylase. A more than 100-fold increase in binding and turnover is observed for the 24-desmethyl analogue of O [N (norlanosterol)], which is found in vivo in procyclic forms of TB and is a good TB CYP51 substrate in vitro. We believe that (i) N is a non-conventional CYP51 substrate, preferred in TB and perhaps other Trypanosomatidae and (ii) functional similarity of TC CYP51 to animal/fungal orthologues is a result of evolutionary convergence (including F105I mutation), leading to different pathways for sterol production in TC versus TB.

Understanding electron transport systems of Streptomyces cytochrome P450.

Streptomyces spp. are known to produce various types of biologically active compounds including antibiotics, antiparasitic agents, herbicides and immunosuppressants. P450 (cytochrome P450) enzymes may have key roles in these biosynthetic and biotransformation reactions. Recent genomic analysis of Streptomyces coelicolor A3(2) indicates that S. coelicolor may have six ferredoxins (Fdxs), four putative Fdx reductases (FdRs) and 18 P450 genes. However, there are few clues to explain the mechanisms and functions of Streptomyces P450 systems. To solve these questions, we have expressed and purified five S. coelicolor P450s, four FdRs and six Fdxs in Escherichia coli. Of the purified P450s, CYP105D5 has fatty acid hydroxylation activity in a system reconstituted with putidaredoxin reductase and Fdx4 or with spinach FdR and spinach Fdx, although the reconstitutions with FdR2 or FdR3 and any of the Fdxs did not support CYP105D5-catalysed oleic acid hydroxylation. Elucidation of the detailed mechanisms of electron transport system for Streptomyces P450 may provide the perspective for usefulness of P450s as a biocatalyst.

cAMP-dependent transcription of steroidogenic genes in the human adrenal cortex requires a dual-specificity phosphatase in addition to protein kinase A.

Steroid hormone biosynthesis in the adrenal cortex is controlled by the peptide hormone adrenocorticotropin (ACTH), which acts to increase intracellular cAMP and results in the activation of cAMP-dependent protein kinase A (PKA) and subsequent increase in steroidogenic gene transcription. Protein phosphorylation by PKA activates transcription of genes encoding steroidogenic enzymes; however the precise proteins which are phosphorylated remain to be determined. We have recently shown that phosphoprotein phosphatase (PP) activity is essential for cAMP-dependent transcription of the human CYP17 (hCYP17) gene in H295R adrenocortical cells. The aim of our current studies was to determine if inhibition of PP activity attenuates cAMP-dependent mRNA expression of other steroidogenic genes in H295R cells. Using various inhibitors of serine/threonine and tyrosine PPs, we examined the role of phosphatase activity on cAMP-dependent transcription of steroidogenic genes in the adrenal cortex. CYP11A, CYP11B1/2, CYP21, and adrenodoxin also require PP activity for cAMP-stimulated gene expression. Inhibition of both serine/threonine and tyrosine PP activities suppresses the cAMP-dependent mRNA expression of several steroidogenic genes, suggesting that a dual-specificity PP is essential for conveying ACTH/cAMP-stimulated transcription. We propose that PKA phosphorylates and activates a dual-specificity phosphatase, which mediates steroidogenic gene transcription in response to ACTH/cAMP.

Transcriptional complexes at the CYP17 CRS.

Steroid hormone biosynthesis in the adrenal cortex is controlled by the peptide hormone adrenocorticotropin (ACTH), which acts to increase intracellular cAMP, resulting in the activation of cAMP-dependent protein kinase (PKA) and subsequent increase in steroidogenic gene transcription. We have identified three proteins interacting with the human CYP17 cAMP responsive sequence (CRS): steroidogenic factor 1 (SF-1), p54nrb, and polypyrimidine tract-binding protein-associated splicing factor (PSF). Nuclear extracts isolated from cAMP stimulated of H295R cells showed cAMP-inducible binding to the human CYP17 (hCYP17) CRS. This cAMP-inducible binding was dependent on a dual-specificity phosphatase (DSP). DSP activity was subsequently shown to be is essential for conveying ACTH/cAMP-stimulated transcription of several steroidogenic genes in the human adrenal cortex. We report here that the transactivation potential of SF-1 is also dependent on phosphatase activity; suggesting that SF-1 is dephosphorylated in response to ACTH/cAMP stimulation. Finally, we demonstrate a role for mitogen-activated protein kinase phosphatase 1 (MKP-1), a nuclear DSP, in conveying SF-1-dependent transcription of an hCYP17 promoter-reporter construct in the H295R human adrenocortical cell line. We conclude that a DSP, possibly MKP-1, is essential for enhancing hCYP17 transcription in the adrenal cortex by desphosphorylating of SF-1, thereby increasing the binding affinity of SF-1, p54nrb, and PSF for the hCYP17 promoter.

Substrate recognition sites in 14alpha-sterol demethylase from comparative analysis of amino acid sequences and X-ray structure of Mycobacterium tuberculosis CYP51.

The crystal structure of 14alpha-sterol demethylase from Mycobacterium tuberculosis (MTCYP51) [Proc. Natl. Acad. Sci. USA 98 (2001) 3068-3073] provides a template for analysis of eukaryotic orthologs which constitute the CYP51 family of cytochrome P450 proteins. Putative substrate recognition sites (SRSs) were identified in MTCYP51 based on the X-ray structures and have been compared with SRSs predicted based on Gotoh's analysis [J. Biol. Chem. 267 (1992) 83-90]. While Gotoh's SRS-4, 5, and 6 contribute in formation of the putative MTCYP51 substrate binding site, SRS-2 and 3 likely do not exist in MTCYP51. SRS-1, as part of the open BC loop, in the conformation found in the crystal can provide only limited contacts with the sterol. However, its role in substrate binding might dramatically increase if the loop closes in response to substrate binding. Thus, while the notion of SRSs has been very useful in leading to our current understanding of P450 structure and function, their identification by sequence alignment between distant P450 families will not necessarily be a good predictor of residues associated with substrate binding. Localization of CYP51 mutation hotspots in Candida albicans azole resistant isolates was analyzed with respect to SRSs. These mutations are found to be outside of the putative substrate interacting sites indicating the preservation of the protein active site under the pressure of azole treatment. Since the mutations residing outside the putative CYP51 active side can profoundly influence ligand binding within the active site, perhaps they provide insight into the basis of evolutionary changes which have occurred leading to different P450s.

Evolutionarily divergent electron donor proteins interact with P450MT2 through the same helical domain but different contact points.

We have investigated the sites of N-terminally truncated cytochrome P4501A1 targeted to mitochondria (P450MT2) which interact with adrenodoxin (Adx), cytochrome P450 reductase (CPR) and bacterial flavodoxin (Fln). The binding site was mapped by a combination of in vitro mutagenesis, in vivo screening with a mammalian two-hybrid system, spectral analysis, reconstitution of enzyme activity and homology-based structural modeling. Our results show that part of an aqueous accessible helix (putative helix G, residues 264-279) interacts with all three electron donor proteins. Mutational studies revealed that Lys267 and Lys271 are crucial for binding to Adx, while Lys268 and Arg275 are important for binding to CPR and FLN: Additive effects of different electron donor proteins on enzyme activity and models on protein docking show that Adx and CPR bind in a non-overlapping manner to the same helical domain in P450MT2 at different angular orientations, while CPR and Fln compete for the same binding site. We demonstrate that evolutionarily divergent electron donor proteins interact with the same domain but subtly different contact points of P450MT2.

Folding requirements are different between sterol 14alpha-demethylase (CYP51) from Mycobacterium tuberculosis and human or fungal orthologs.

Upon sequence alignment of CYP51 sterol 14alpha-demethylase from animals, plants, fungi, and bacteria, arginine corresponding to Arg-448 of CYP51 in Mycobacterium tuberculosis (MT) is conserved near the C terminus of all family members. In MTCYP51 Arg-448 forms a salt bridge with Asp-287, connecting beta-strand 3-2 with helix J. Deletion of the three C-terminal residues of MTCYP51 has little effect on expression of P450 in Escherichia coli. However, truncation of the fourth amino acid (Arg-448) completely abolishes P450 expression. We have investigated whether Arg-448 has other structural or functional roles in addition to folding and whether its conservation reflects conservation of a common folding pathway in the CYP51 family. Characterization of wild type protein and three mutants, R448K, R448I, and R448A, including examination of catalytic activity, secondary and tertiary structure analysis by circular dichroism and tryptophan fluorescence, and studies of both equilibrium and temporal MTCYP51 unfolding behavior, shows that Arg-448 does not play any role in P450 function or maintenance of the native structure. C-terminal truncation of Candida albicans and human CYP51 orthologs reveals that, despite conservation in sequence, the requirement for arginine at the homologous C-terminal position in folding in E. coli is not conserved. Thus, despite similar spatial folds, functionally related but evolutionarily distinct P450s can follow different folding pathways.

Alterations in the regulation of androgen-sensitive Cyp 4a monooxygenases cause hypertension.

Hypertension is a leading cause of cardiovascular, cerebral, and renal disease morbidity and mortality. Here we show that disruption of the Cyp 4a14 gene causes hypertension, which is, like most human hypertension, more severe in males. Male Cyp 4a14 (-/-) mice show increases in plasma androgens, kidney Cyp 4a12 expression, and the formation of prohypertensive 20-hydroxyarachidonate. Castration normalizes the blood pressure of Cyp 4a14 (-/-) mice and minimizes Cyp 4a12 expression and arachidonate omega-hydroxylation. Androgen replacement restores hypertensive phenotype, Cyp 4a12 expression, and 20-hydroxy-arachidonate formation. We conclude that the androgen-mediated regulation of Cyp 4a arachidonate monooxygenases is an important component of the renal mechanisms that control systemic blood pressures. These results provide direct evidence for a role of Cyp 4a isoforms in cardiovascular physiology, establish Cyp 4a14 (-/-) mice as a monogenic model for the study of cause/effect relationships between blood pressure, sex hormones, and P450 omega-hydroxylases, and suggest the human CYP 4A homologues as candidate genes for the analysis of the genetic and molecular basis of human hypertension.

Crystal structure of cytochrome P450 14alpha -sterol demethylase (CYP51) from Mycobacterium tuberculosis in complex with azole inhibitors.

Cytochrome P450 14alpha-sterol demethylases (CYP51) are essential enzymes in sterol biosynthesis in eukaryotes. CYP51 removes the 14alpha-methyl group from sterol precursors such as lanosterol, obtusifoliol, dihydrolanosterol, and 24(28)-methylene-24,25-dihydrolanosterol. Inhibitors of CYP51 include triazole antifungal agents fluconazole and itraconazole, drugs used in treatment of topical and systemic mycoses. The 2.1- and 2.2-A crystal structures reported here for 4-phenylimidazole- and fluconazole-bound CYP51 from Mycobacterium tuberculosis (MTCYP51) are the first structures of an authentic P450 drug target. MTCYP51 exhibits the P450 fold with the exception of two striking differences-a bent I helix and an open conformation of BC loop-that define an active site-access channel running along the heme plane perpendicular to the direction observed for the substrate entry in P450BM3. Although a channel analogous to that in P450BM3 is evident also in MTCYP51, it is not open at the surface. The presence of two different channels, with one being open to the surface, suggests the possibility of conformationally regulated substrate-in/product-out openings in CYP51. Mapping mutations identified in Candida albicans azole-resistant isolates indicates that azole resistance in fungi develops in protein regions involved in orchestrating passage of CYP51 through different conformational stages along the catalytic cycle rather than in residues directly contacting fluconazole. These new structures provide a basis for rational design of new, more efficacious antifungal agents as well as insight into the molecular mechanism of P450 catalysis.

Structural requirements for substrate recognition of Mycobacterium tuberculosis 14 alpha-demethylase: implications for sterol biosynthesis.

Sterol 14 alpha-demethylase (14DM) is a cytochrome P-450 involved in sterol biosynthesis in eukaryotes. It was reported that Mycobacterium smegmatis also makes cholesterol and that cholesterol is essential to Mycobacterium tuberculosis (MT) infection, although the origin of the cholesterol is unknown. A protein product from MT having about 30% sequence identity with eukaryotic 14 alpha-demethylases has been found to convert sterols to their 14-demethyl products indicating that a sterol pathway might exist in MT. To determine the optimal sterol structure recognized by MT 14DM, binding of 28 sterol and sterol-like (triterpenoids) molecules to the purified recombinant 14 alpha-demethylase was examined. Like eukaryotic forms, a 3 beta-hydroxy group and a 14 alpha-methyl group are essential for substrate acceptability by the bacterial 14 alpha-demethylase. The high affinity binding of 31-norcycloartenol without detectable activity indicates that the Delta(8)-bond is required for activity but not for binding. As for plant 14 alpha-demethylases, 31-nor-sterols show a binding preference for MT 14DM. Similar to enzymes from mammals and yeast, a C24-alkyl group is not required for MT 14DM binding and activity, whereas it is for plant 14 alpha-demethylases.Thus, substrate binding to MT 14DM seems to share common features with all eukaryotic 14 alpha-demethylases, the MT form seemingly having the broadest substrate recognition of all forms of 14 alpha-demethylase studied so far. - Bellamine, A., A. T. Mangla, A. L. Dennis, W. D. Nes, and M. R. Waterman. Structural requirements for substrate recognition of Mycobacterium tuberculosis 14 alpha-demethylase: implications for sterol biosynthesis. J. Lipid Res. 2001. 42: 128;-136.

Microsomal p450s use specific proline-rich sequences for efficient folding, but not for maintenance of the folded structure.

The amino-terminal region of microsomal P450s contains three distinct sequence motifs, the signal-anchor sequence (SA), the basic sequence (BS), and the proline-rich sequence (PR). Studies with two P450s of the CYP2C subfamily, P4502C11 (CYP2C11) and P4502C2 (CYP2C2), have indicated that upon expression in eukaryotic cells (yeast, COS cells, and insect cells), specific proline residues in PR are important for proper folding. In the present study, we have established that the PR region in a very different CYP gene family, P450c17 (CYP17), is also important for efficient folding. These studies have been carried out using expression in Escherichia coli. Using P4502C11, we have established that the folding requirements for P450s in bacteria are very similar to those in eukaryotic cells. Interestingly, when the PR from P450c17 is swapped for that of P4502C11 and visa versa, complete misfolding is observed. However, both the BS and SA can be swapped between these P450s without affecting folding. After proper folding of P450c17, removal of the PR by factor Xa protease has no effect on the maintenance of the P450 structure. Inspection of the sequences of many different CYP gene families indicates that the PR sequence is conserved within a gene family but varies considerably between families. We conclude that PR is important for directing the folding pathway leading to the functional P450, but not for maintaining the functional form.

Importance of a proline-rich sequence in the amino-terminal region for correct folding of mitochondrial and soluble microbial p450s.

All microsomal P450s have a proline-rich sequence (PR) in the amino-terminal region that is needed for proper folding [Kusano, K., Sakaguchi, M., Kagawa, N., Waterman, M.R. and Omura, T. (2001) J. Biochem., 129, 259-269]. There are also multiple proline residues near the amino-termini of the mature forms of all mitochondrial P450s and the amino-termini of soluble microbial P450s. To examine the functional significance of the PR in mitochondrial P450s, we expressed human P450c27 (CYP27) and bovine P450scc (CYP11A1) in an Escherichia coli heterologous expression system, and found that in each one specific proline residue is important for correct folding. Deletions from the amino-terminus further indicated the importance of the PR for the expression of a spectrally normal P450c27. Essentially the same results were obtained with two soluble microbial P450s, P450cam (CYP101) and P450nor, in each of which a PR is important for proper folding. We conclude that in all P450s (mitochondrial, microbial and microsomal P450s), a proline-rich sequence located in the amino-terminal region is important for proper folding. Furthermore, we predict that the importance of the PR in P450 folding is to reduce the tendency of the polypeptide to misfold prior to heme binding.

Lanosterol 14alpha-demethylase (CYP51), NADPH-cytochrome P450 reductase and squalene synthase in spermatogenesis: late spermatids of the rat express proteins needed to synthesize follicular fluid meiosis activating sterol.

Lanosterol 14alpha-demethylase (CYP51) is a cytochrome P450 enzyme involved primarily in cholesterol biosynthesis. CYP51 in the presence of NADPH-cytochrome P450 reductase converts lanosterol to follicular fluid meiosis activating sterol (FF-MAS), an intermediate of cholesterol biosynthesis which accumulates in gonads and has an additional function as oocyte meiosis-activating substance. This work shows for the first time that cholesterogenic enzymes are highly expressed only in distinct stages of spermatogenesis. CYP51, NADPH-P450 reductase (the electron transferring enzyme needed for CYP51 activity) and squalene synthase (an enzyme preceding CYP51 in the pathway) proteins have been studied. CYP51 was detected in step 3-19 spermatids, with large amounts in the cytoplasm/residual bodies of step 19 spermatids, where P450 reductase was also observed. Squalene synthase was immunodetected in step 2-15 spermatids of the rat, indicating that squalene synthase and CYP51 proteins are not equally expressed in same stages of spermatogenesis. Discordant expression of cholesterogenic genes may be a more general mechanism leading to transient accumulation of pathway intermediates in spermatogenesis. This study provides the first evidence that step 19 spermatids and residual bodies of the rat testis have the capacity to produce MAS sterols in situ.

Three zinc finger nuclear proteins, Sp1, Sp3, and a ZBP-89 homologue, bind to the cyclic adenosine monophosphate-responsive sequence of the bovine adrenodoxin gene and regulate transcription.

Adrenocorticotropin acting through cyclic adenosine monophosphate (cAMP) regulates transcription of the bovine adrenodoxin (Adx) gene in the adrenal cortex. The bovine Adx cAMP-responsive transcription sequence (CRS) has previously been found to contain two consensus GC boxes. By use of nuclear extracts from adrenocortical cells, Sp1 and Sp3 are shown here to bind to CRS. Mutations designed to enhance the identification of additional CRS binding proteins by reducing Sp protein binding showed the presence of an additional DNA-binding protein (Adx factor). Adx factor binding is inhibited by the zinc-chelating agent, 1,10-o-phenanthroline, suggesting it might be a zinc finger protein. By a fractionation/renaturation technique the Adx factor in mouse Y1 adrenocortical cells was found to be in the size range of 106-115 kDa by gel mobility shift assay. On the basis of size, the CRS sequence to which it binds, and its tentative identification as a zinc finger protein, Adx factor has been identified as a Krüppel-like zinc finger protein (a mouse ZBP-89 homologue). Further mutagenesis of CRS demonstrates that it can further be divided into two similar cAMP-responsive elements, and elimination of ZBP-89 binding does not affect cAMP responsiveness of either. Expression of these three nuclear proteins in Drosophila SL2 cells has been used to decipher the role of Adx CRS binding proteins in regulating transcription. Sp1 and Sp3 confer basal transcriptional activities, yet only Sp1 confers cAMP-responsive activity. ZBP-89 represses basal transcriptional activity.

The tertiary structure of full-length bovine adrenodoxin suggests functional dimers.

The three-dimensional X-ray crystal structure of full-length oxidized bovine adrenodoxin (Adx) has been determined at 2.5 A resolution by molecular replacement using a structure of a truncated form as a starting model. Crystals of Adx belong to a primitive monoclinic space group P2(1) with four Adx molecules in an asymmetric unit. The unit cell dimensions are a = 59.44 A, b = 77.03 A, c = 59.68 A, and beta = 94.83 degrees. The structure has been refined to an R factor of 23.5%. Structures of the four molecules of full-length Adx (127 amino acids) in the asymmetric unit were compared with each other and also with that of the truncated Adx (4-108). The overall topology of full-length Adx remains the same as described earlier for the truncated protein. Differences that do occur are almost wholly confined to alternate side-chain conformations that reflect differing lattice contacts made by two proteins. Extensive interactions found between molecules 1 and 2 in the full-length Adx asymmetric unit may reflect the ability of Adx to form dimers in vivo and are consistent with hydrodynamic measurements which show that in solution there is an equilibrium between monomeric and dimeric forms of Adx. Dimerization of Adx could explain why the truncated form has greater affinity for the P450 redox partner than the full-length form. From these results it can be considered that the mechanism of electron transfer is not necessarily the same in different mitochondrial P450 systems.

The use of random chimeragenesis to study structure/function properties of rat and human P450c17.

The microsomal 17alpha-hydroxylase/17,20-lyase cytochrome P450 (P450c17) catalyzes the 17alpha-hydroxylase reaction required to produce cortisol, the major glucocorticoid in many species and the 17,20-lyase activity required for the production of androgens in all species. Utilizing the technique of random chimeragenesis we have attempted to map regions of primary sequence that contribute to the species-specific biochemical differences between rat and human P450c17. We have previously reported significant differences between rat and human P450c17 in their activities, stability and substrate-dependent coupling efficiencies even though they share 68% amino acid identity. Identification of the regions of primary sequence that contribute to each of these properties would be helpful in understanding the structure/function relationships in this enzyme. A single plasmid containing the cDNAs encoding both enzymes in a tandem orientation was constructed. This plasmid was linearized at unique restriction sites and used to transform Escherichia coli. A three-step screening protocol identified five chimeras with a uniform distribution of 5' rat and 3' human sequence. All chimeric proteins yield the characteristic reduced-CO difference spectra, indicating proper folding. The chimeras exhibit a range of stability and activities that are not consistent with the degree of parental primary sequence. A chimera containing 301 N-terminal rat P450c17 amino acids and lacking the rat P450c17 phenylalanine 343, had the highest lyase activity. Generation of these functional rat/human chimeras suggests that the tertiary structures of rat and human P450c17 are sufficiently conserved to allow proper folding of chimeric enzymes. However, the properties of these chimeras did not permit identification of a region of primary sequence that contributes to a species-specific property of rat and human P450c17. Stability of these chimeras and insight into the presence of secondary structural elements is discussed.

Cyclic adenosine 3',5'-monophosphate(cAMP)/cAMP-responsive element modulator (CREM)-dependent regulation of cholesterogenic lanosterol 14alpha-demethylase (CYP51) in spermatids.

Lanosterol 14alpha-demethylase (CYP51) produces MAS sterols, intermediates in cholesterol biosynthesis that can reinitiate meiosis in mouse oocytes. As a cholesterogenic gene, CYP51 is regulated by a sterol/sterol-regulatory element binding protein (SREBP)-dependent pathway in liver and other somatic tissue. In testis, however, cAMP/cAMP-responsive element modulator CREMtau-dependent regulation of CYP51 predominates, leading to increased levels of shortened CYP51 mRNA transcripts. CREM-/- mice lack the abundant germ cell-specific CYP51 mRNAs in testis while expression of somatic CYP51 transcripts is unaffected. The mRNA levels of squalene synthase (an enzyme preceding CYP51 in cholesterol biosynthesis in testis of CREM-/- mice are unchanged as compared with wild-type animals, showing that regulation by CREMtau is not characteristic for all cholesterogenic genes expressed during spermatogenesis. The -334/+314 bp CYP51 region can mediate both the sterol/SREBP-dependent as well as the cAMP/CREMtau-dependent transcriptional activation. SREBP-1a from somatic cell nuclear extracts binds to a conserved CYP51-SRE1 element in the CYP51 proximal promoter. The cAMP-dependent transcriptional activator CREMtau from germ cell nuclear extracts binds to a conserved CYP51-CRE2 element while no SREBP-1 binding is observed in germ cells. The two regulatory pathways mediating expression of CYP51 describe this gene as a cholesterogenic gene (SREBP-dependent expression in liver and other somatic cells) and also as a haploid expressed gene (CREMtau-dependent expression in haploid male germ cells). While in somatic cells all genes involved in cholesterol biosynthesis are regulated coordinately by the sterol/SREBP-signaling pathway, male germ cells contain alternate routes to control expression of cholesterogenic genes.

Characterization and catalytic properties of the sterol 14alpha-demethylase from Mycobacterium tuberculosis.

Sterol 14alpha-demethylase encoded by CYP51 is a mixed-function oxidase involved in sterol synthesis in eukaryotic organisms. Completion of the Mycobacterium tuberculosis genome project revealed that a protein having homology to mammalian 14alpha-demethylases might be present in this bacterium. Using genomic DNA from mycobacterial strain H(37)Rv, we have established unambiguously that the CYP51-like gene encodes a bacterial sterol 14alpha-demethylase. Expression of the M. tuberculosis CYP51 gene in Escherichia coli yields a P450, which, when purified to homogeneity, has the predicted molecular mass, ca. 50 kDa on SDS/PAGE, and binds both sterol substrates and azole inhibitors of P450 14alpha-demethylases. It catalyzes 14alpha-demethylation of lanosterol, 24, 25-dihydrolanosterol, and obtusifoliol to produce the 8,14-dienes stereoselectively as shown by GC/MS and (1)H NMR analysis. Both flavodoxin and ferredoxin redox systems are able to support this enzymatic activity. Structural requirements of a 14alpha-methyl group and Delta(8(9))-bond were established by comparing binding of pairs of sterol substrate that differed in a single molecular feature, e.g., cycloartenol paired with lanosterol. These substrate requirements are similar to those established for plant and animal P450 14alpha-demethylases. From the combination of results, the interrelationships of substrate functional groups within the active site show that oxidative portions of the sterol biosynthetic pathway are present in prokaryotes.