Conservation and cloning of CYP51: a sterol 14 alpha-demethylase from Mycobacterium smegmatis

The genetic locus encoding cytochrome P450 51 (CYP51; P450(14DM)) in Mycobacterium smegmatis is described here together with confirmation of activity in lanosterol 14 alpha-demethylation. The protein bound azole antifungals with high affinity and the rank order based on affinity matched the ranked order for microbiological sensitivity of the organism, thus supporting a possible role for CYP51 as a target in the antimycobacterial activity of these compounds. Non-saponifiable lipids were extracted from the bacteria grown on minimal medium. Unlike a previous report using growth on complex medium, no cholesterol was detected in two strains of M. smegmatis, but a novel lipid was detected. The genetic locus of CYP51 is discussed in relation to function; it is conserved as part of a putative operon in M. smegmatis, Mycobacterium tuberculosis, Mycobacterium avium, and Mycobacterium bovis and consists of six open-reading frames including two CYPs and a ferredoxin under a putative Tet-R regulated promoter.     

19F-NMR reveals substrate specificity of CYP121A1 in Mycobacterium tuberculosis

Cytochromes P450 are versatile enzymes that function in endobiotic and xenobiotic metabolism and undergo meaningful structural changes that relate to their function. However, the way in which conformational changes inform the specific recognition of the substrate is often unknown. Here, we demonstrate the utility of fluorine (¹⁹F)-NMR spectroscopy to monitor structural changes in CYP121A1, an essential enzyme from Mycobacterium tuberculosis. CYP121A1 forms functional dimers that catalyze the phenol-coupling reaction of the dipeptide dicyclotyrosine. The thiol-reactive compound 3-bromo-1,1,1-trifluoroacetone was used to label an S171C mutation of the enzyme FG loop, which is located adjacent to the homodimer interface. Substrate titrations and inhibitor-bound ¹⁹F-NMR spectra indicate that ligand binding reduces conformational heterogeneity at the FG loop in both the dimer and in an engineered monomer of CYP121A1. However, only the dimer was found to promote a substrate-bound conformation that was preexisting in the substrate-free spectra, thus confirming a role for the dimer interface in dicyclotyrosine recognition. Moreover, ¹⁹F-NMR spectra in the presence of substrate analogs indicate the hydrogen-bonding feature of the dipeptide aromatic side chain as a dicyclotyrosine specificity criterion. This study demonstrates the utility of ¹⁹F-NMR as applied to a multimeric cytochrome P450, while also revealing mechanistic insights for an essential M. tuberculosis enzyme.     

Expression of microsomal lanosterol 14alpha-demethylase (CYP51) in an engineered soluble monomeric form

We prepared a soluble monomeric form of bovine cytochrome P450 lanosterol 14α-demethylase (CYP51), which in mammals is a ubiquitously expressed membrane protein of the endoplasmic reticulum. We constructed two variants of bovine CYP51 (bCYP51) with different truncations and modifications in their N-terminal membrane-spanning domains. Both of these were expressed in Escherichia coli at levels of 500 nmol/l. The protein variants were purified and tested for the solubility in the absence of detergent. Variant bCYP51-d1 exhibited ∼10-fold better solubility over variant bCYT51-d2. The bCYP51-d1 eluted as a single peak in size-exclusion chromatography, corresponding to its monomeric form. The activity of bCYP51-d1 is similar to that of recombinant human CYP51 with a non-truncated membrane-spanning region. High solubility and low tendency to non-specific oligomer formation make bCYP51-d1 a promising candidate for successful crystallization, which may finally allow the structural determination of this important mammalian enzyme.     

Mutations in Saccharomyces cerevisiae sterol C5-desaturase conferring resistance to the CYP51 inhibitor fluconazole

Understanding fluconazole resistance is important as it emerged as a serious clinical problem for this CYP51, sterol 14alpha-demethylase, inhibitor. One mechanism, observed first in Saccharomyces cerevisiae, was through defective sterol C5-desaturase (Erg3p) required to form the fungistatic sterol end-product resulting from CYP51 inhibition, 14alpha-methylergosta-8,24(28)-dien-3beta,6alpha-diol. Here, we report molecular changes resulting in both blocked mutants and also leaky mutants in which reduced ergosterol levels were detected. Blocked mutants exhibited nonsense and frameshift mutations, while leaky mutants contained missense mutations that were generally in conserved positions based on the alignment of sterol C5-desaturases and located mainly between residues 250 and 282.     

Substrate preferences and catalytic parameters determined by structural characteristics of sterol 14alpha-demethylase (CYP51) from Leishmania infantum

Leishmaniasis is a major health problem that affects populations of ～90 countries worldwide, with no vaccine and only a few moderately effective drugs. Here we report the structure/function characterization of sterol 14α-demethylase (CYP51) from Leishmania infantum. The enzyme catalyzes removal of the 14α-methyl group from sterol precursors. The reaction is essential for membrane biogenesis and therefore has great potential to become a target for antileishmanial chemotherapy. Although L. infantum CYP51 prefers C4-monomethylated sterol substrates such as C4-norlanosterol and obtusifoliol (V(max) of ～10 and 8 min(-1), respectively), it is also found to 14α-demethylate C4-dimethylated lanosterol (V(max) = 0.9 min(-1)) and C4-desmethylated 14α-methylzymosterol (V(max) = 1.9 min(-1)). Binding parameters with six sterols were tested, with K(d) values ranging from 0.25 to 1.4 μM. Thus, L. infantum CYP51 is the first example of a plant-like sterol 14α-demethylase, where requirements toward the composition of the C4 atom substituents are not strict, indicative of possible branching in the postsqualene portion of sterol biosynthesis in the parasite. Comparative analysis of three CYP51 substrate binding cavities (Trypanosoma brucei, Trypanosoma cruzi, and L. infantum) suggests that substrate preferences of plant- and fungal-like protozoan CYP51s largely depend on the differences in the enzyme active site topology. These minor structural differences are also likely to underlie CYP51 catalytic rates and drug susceptibility and can be used to design potent and specific inhibitors.     

Determination of the membrane contact residues and solution structure of the helix F/G loop of prostaglandin I2 synthase

From our topological arrangement model of prostaglandin I(2) synthase (PGIS) created by homology modeling and topology studies, we hypothesized that the helix F/G loop of PGIS contains a membrane contact region distinct from the N-terminal membrane anchor domain. To provide direct experimental data we have explored the relationship between the endoplasmic reticulum (ER) membrane and the PGIS F/G loop using a constrained synthetic peptide to mimic PGIS residues 208-230 cyclized on both ends through a disulfide bond with added Cys residues. The solution structure and the residues important for membrane contact of the constrained PGIS F/G loop peptide were investigated by high-resolution 1H two-dimensional nuclear magnetic resonance (2D NMR) experiments and a spin label incorporation technique. Through the combination of 2D NMR experiments in the presence of dodecylphosphocholine (DPC) micelles used to mimic the membrane environment, complete 1H NMR assignments of the F/G loop segment have been obtained and the solution structure of the peptide has been determined. The PGIS F/G loop segment shows a defined helix turn helix conformation, which is similar to the three-dimensional crystallography structure of P450BM3 in the corresponding region. The orientation and the residues contacted with the membrane of the PGIS F/G loop were evaluated from the effect of incorporation of a spin-labeled 12-doxylstearate into the DPC micelles with the peptide. Three residues in the peptide corresponding to the PGIS residues L217 (L11), L222 (L16), and V224 (V18) have been demonstrated to contact the DPC micelles, which implies that the residues are involved in contact with the ER membrane in the native membrane-bound PGIS. These results provided the first experimental evidence to localize the membrane contact residues in the F/G loop region of microsomal P450 and are valuable to further define and understand the membrane topology of PGIS and those of other microsomal P450s in the native membrane environment.     

Functional Redundancy of Steroid C26-monooxygenase Activity in Mycobacterium tuberculosis Revealed by Biochemical and Genetic Analyses

One challenge to the development of new antitubercular drugs is the existence of multiple virulent strains that differ genetically. We and others have recently demonstrated that CYP125A1 is a steroid C₂₆-monooxygenase that plays a key role in cholesterol catabolism in Mycobacterium tuberculosis CDC1551 but, unexpectedly, not in the M. tuberculosis H37Rv strain. This discrepancy suggests that the H37Rv strain possesses compensatory activities. Here, we examined the roles in cholesterol metabolism of two other cytochrome P450 enzymes, CYP124A1 and CYP142A1. In vitro analysis, including comparisons of the binding affinities and catalytic efficiencies, demonstrated that CYP142A1, but not CYP124A1, can support the growth of H37Rv cells on cholesterol in the absence of cyp125A1. All three enzymes can oxidize the sterol side chain to the carboxylic acid state by sequential oxidation to the alcohol, aldehyde, and acid. Interestingly, CYP125A1 generates oxidized sterols of the (25S)-26-hydroxy configuration, whereas the opposite 25R stereochemistry is obtained with CYP124A1 and CYP142A1. Western blot analysis indicated that CYP124A1 was not detectably expressed in either the H37Rv or CDC1551 strains, whereas CYP142A1 was found in H37Rv but not CDC1551. Genetic complementation of CDC1551 Δcyp125A1 cells with the cyp124A1 or cyp142A1 genes revealed that the latter can fully rescue the growth defect on cholesterol, whereas cells overexpressing CYP124A1 grow poorly and accumulate cholest-4-en-3-one. Our data clearly establish a functional redundancy in the essential C₂₆-monooxygenase activity of M. tuberculosis and validate CYP125A1 and CYP142A1 as possible drug targets.     

Age-related changes in the mRNA levels of CYP1A1, CYP2B1/2 and CYP3A1 isoforms in rat small intestine

It has been established beyond doubt that, as well as the liver, the small intestine is an important site of first-pass metabolism of numerous drugs, food components and toxic xenobiotics. However, there is not much information available about age-dependent changes of intestinal biotransformation pathways. In the present paper, we evaluated the relationships between intestinal cytochrome P450 complex activity and the age of animals. The study was carried out on male Sprague–Dawley rats (n = 5) from 5 age series: 0.5-, 2-, 4-, 20-, and 28 months old. Animals at every age series were divided into 4 groups: control and three groups of rats treated with the CYP450 specific inducers: phenobarbital, β-naphtoflavone and dexamethasone, respectively. RNA was isolated from intestinal mucosa, and then standard RT-PCR was used for the analysis of CYP1A1, CYP2B1/2 and CYP3A1 mRNA expression. Additionally, the activities of NADPH-cytochrome P450 and NADH-cytochrome b₅ reductases in the microsomal fraction were biochemically estimated. The constitutive intestinal CYP1A1 mRNA expression changes during maturation and aging. Inducibility of CYP1A1 gene was evident in intestinal mucosa at 2-, 4- and 20-month-old rats. A similar pattern of changes was observed for CYP2B1/2 isoforms. CYP3A1 mRNA expression was not detected in small intestine of 2-week-old rats. In matured rats, constitutive intestinal CYP3A1 expression was low, although after induction, significant increases in CYP3A1 mRNA amount were noted in aged individuals. Intestinal activity of both analyzed reductases was lowest in immature rats and highest in 28-month-old animals. In conclusion, the activity of cytochrome P450 complex in rat small intestine was not decreased by the aging processes, so the high rate of oxidative metabolic reactions in intestinal mucosa can be maintained till the advanced life stage.     

Effects of garden and water cress juices and their constituents,benzyl and phenethyl isothiocyanates,towards benzo(a)pyrene-induced DNA damage: a model study with the single cell gel electrophoresis/Hep G2 assay

The aim of this study was to investigate the chemoprotective effects of water and garden cress juices towards benzo(a)pyrene (B(a)P)-induced DNA damage using the single cell gel electrophoresis (SCGE)/Hep G2 test system. This experimental model combines the advantages of the SCGE assay with that of human derived cells possessing inducible phase I and phase II enzymes. Treatment of Hep G2 cells with small amounts of water cress or garden cress juice (0.1-1.25 microl/ml) and B(a)P reduced the genotoxic effect of the latter in a dose-dependent manner. Contrary to the results with the juices, unexpected synergistic effects were observed with benzyl isothiocyanate (BITC, 0.6 microM), a breakdown product of glucotropaeolin contained abundantly in garden cress. Although these concentrations of BITC did not cause DNA damage per se, at higher concentrations (> or = 2.5 microM), the compound caused a pronounced dose-dependent DNA damage by itself. With phenethyl isothiocyanate (PEITC), the breakdown product of gluconasturtin contained in water cress, no synergistic effects with B(a)P were seen; however, significant induction of DNA damage was observed when the cells were exposed to the pure compound at concentrations > or = 5 microM. In experiments with (+/-)-anti-benzo(a)pyrene-7,8-dihydrodiol-9,10-epoxide (BPDE, 5.0 microM), the ultimate genotoxic metabolite of B(a)P, and the juices, only moderate protective effects were seen indicating that detoxification of BPDE is not the main mechanism behind the protective effect of the juices against B(a)P-induced DNA damage. In conclusion, our findings show that garden and water cress juices are highly protective against B(a)P-induced DNA damage in human derived cells and that their effects can not be explained by their isothiocyanate contents.     

CYP710A genes encoding sterol C22-desaturase in <Emphasis Type="Italic">Physcomitrella patens</Emphasis> as molecular evidence for the evolutionary conservation of a sterol biosynthetic pathway in plants

We have characterized cytochromes P450, CYP710A13, and CYP710A14, as the sterol C22-desaturase in the moss Physcomitrella patens. GC–MS analyses demonstrated that P. patens accumulated stigmasterol as the major sterol (56–60% of total sterol) and sitosterol to a lesser extent (8–12%); this sterol profile contrasts with those in higher plants accumulating stigmasterol as a minor component. Recombinant CYP710A13 and CYP710A14 proteins prepared using a baculovirus/insect cell system exhibited the C22-desaturase activity with β-sitosterol to produce stigmasterol, while campesterol and 24-epi-campesterol were not accepted as the substrates. The K _m values for β-sitosterol of CYP710A13 (1.0 ± 0.043 μM) and CYP710A14 (2.1 ± 0.17 μM) were at comparable levels of those reported with higher plant CYP710A proteins. In Arabidopsis T87 cells over-expressing CYP710A14, stigmasterol contents reached a level 20- to 72-fold higher than those in the basal level of T87 cells, confirming the C22-desaturase activity of this P450 enzyme. The occurrence of the end-products together with the enzymes involved in the last step of the pathway substantiated the presence of an entire sterol biosynthetic pathway in P. patens, providing evidence for the conservation of the sterol biosynthetic pathway through the evolutionary process of land plants. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Molecular basis of ligand recognition by OASS from E. histolytica: Insights from structural and molecular dynamics simulation studies

Background

O-acetyl serine sulfhydrylase (OASS) is a pyridoxal phosphate (PLP) dependent enzyme catalyzing the last step of the cysteine biosynthetic pathway. Here we analyze and investigate the factors responsible for recognition and different conformational changes accompanying the binding of various ligands to OASS.

Methods

X ray crystallography was used to determine the structures of OASS from Entamoeba histolytica in complex with methionine (substrate analog), isoleucine (inhibitor) and an inhibitory tetra-peptide to 2.00 Å, 2.03 Å and 1.87 Å resolutions, respectively. Molecular dynamics simulations were used to investigate the reasons responsible for the extent of domain movement and cleft closure of the enzyme in presence of different ligands.

Results

Here we report for the first time an OASS-methionine structure with an unmutated catalytic lysine at the active site. This is also the first OASS structure with a closed active site lacking external aldimine formation. The OASS-isoleucine structure shows the active site cleft in open state. Molecular dynamics studies indicate that cofactor PLP, N88 and G192 form a triad of energy contributors to close the active site upon ligand binding and orientation of the Schiff base forming nitrogen of the ligand is critical for this interaction.

Conclusions

Methionine proves to be a better binder to OASS than isoleucine. The β branching of isoleucine does not allow it to reorient itself in suitable conformation near PLP to cause active site closure.

General significance

Our findings have important implications in designing better inhibitors against OASS across all pathogenic microbial species.     

Active-site residues move independently from the rest of the protein in a 200 ns molecular dynamics simulation of cytochrome P450 CYP119

The conformational dynamics of cytochrome P450 enzymes are critical to their catalytic activity. In this study, the correlated motion between residues in a 200 ns molecular dynamics trajectory of the thermophilic CYP119 was analyzed to parse out conformational relationships. Residues that are structurally related, for example residues within a helix, generally have highly correlated motion. In addition, clusters of non-adjacent residues that show correlated motion (“hot spots”) are seen in various regions, including at the base of the F and G helices that make up the most dynamic region of the enzyme. A modified k-means algorithm that clusters residues based on their correlated motion indicates that functionally related residues are in the same cluster (e.g., the catalytic threonines and the heme). Tightly coupled clusters form a solvent-exposed “shell” around the enzyme, whereas less coupling between clusters is seen in regions that are critical to ligand interactions, redox partner interactions, and catalysis. Most notably, we find that residues in the active site move independently from the rest of the enzyme, effectively insulating the catalytic machinery from other regions of the protein.     

Analysis of multiple nuclear receptor binding sites for CAR/RXR in the phenobarbital responsive unit of CYP2B2

The phenobarbital (PB) responsive enhancers in CYP2B genes contain a core of two direct repeat-4 nuclear receptor binding sites, NR-1 and NR-2, which flank an NF-1 site and appear to be most important for PB responsiveness. Additional sequences outside the core are required for maximal PB responsiveness, including a third direct repeat-4 site, NR-3. The PB response is mediated by constitutive androstane receptor (CAR) which binds as a CAR/RXR heterodimer to the NR sites. To determine the relative importance of the third NR site, each of the NR sites was mutated individually and in all combinations in the rat PB responsive unit (PBRU). Mutation of NR-3 resulted in similar effects on transactivation of the PBRU by CAR in HepG2 cells as did mutations of NR-1 and NR-2. The recruitment of GRIP1/SRC-2 by CAR/RXR to the PBRU assessed by gel shift assays was cooperatively enhanced if more than one NR site in the PBRU was occupied by CAR/RXR. NR-3 in combination with NR-1 or NR-2 was equal to NR-1 and NR-2 in mediating this cooperative recruitment. Recruitment of SRC-1 and GRIP1/SRC-2 was similar for all NR sites, while some selectivity of NR-1 for SRC-3 was observed. SRC-3 also exhibited CAR-independent activation of the PBRU in HepG2 cells. Micrococcal nuclease mapping of nucleosomes revealed that the NR-1/NR-2 core of the PBRU is present in a nucleosome while NR-3 is present in the linker adjacent to the nucleosome. In the linear sequence NR-3 is further from NR-1 than NR-2 is, but in a nucleosomal structure, NR-3 is well positioned for cooperative recruitment of GRIP1/SRC-2 by CAR/RXR that is bound to NR-3 and either NR-1 or NR-2, while NR-1 and NR-2 are on opposite sides of the nucleosome separated by the histone core. These results demonstrate that NR-3 is functionally similar to NR-1 and NR-2 in CAR transactivation of the PBRU in vitro and suggest that NR-3 may have a greater role in a chromatin context in vivo than is apparent from transient transfection studies.     

Hydroxylation of long chain fatty acids by CYP147F1, a new cytochrome P450 subfamily protein from Streptomyces peucetius

Cytochrome P450 (CYP) 147F1 from Streptomyces peucetius is a new CYP subfamily of that has been identified as ω-fatty acid hydroxylase. We describe the identification of CYP147F1 as a fatty acid hydroxylase by screening for the substrate using a substrate binding assay. Screening of substrates resulted in the identification of fatty acid groups of compounds as potential hits for CYP147F1 substrates. Fatty acids from C_10:0 to C_18:0 all showed type I shift spectra indicating their potential as substrates. Among several fatty acids tested, lauric acid, myrsitic acid, and palmitic acid were used to characterize CYP147F1. CYP147F1 activity was reconstituted using putidaredoxin reductase and putidaredoxin from Pseudomonas putida as surrogate electron transfer partners. Kinetic parameters, including the dissociation constant, K_m, NADH consumption assay, production formation rate, and coupling efficiency for CYP147F1 were also determined.     

Metabolic pathways of dioxin by CYP1A1: species difference between rat and human CYP1A subfamily in the metabolism of dioxins

Metabolism of polychlorinated dibenzo-p-dioxins by CYP1A subfamily was examined by using the recombinant yeast microsomes. In substrate specificity and reaction specificity, considerable species differences between rats and humans were observed in both CYP1A1- and CYP1A2-dependent metabolism of dioxins. Among four CYPs, rat CYP1A1 showed the highest activity toward dibenzo-p-dioxin (DD) and mono-, di-, and trichloroDDs. To reveal the mechanism of dioxin metabolism, we examined rat CYP1A1-dependent metabolism of 2-chloro-dibenzo-p-dioxin. In addition to hydroxylation at an unsubstituted position, hydroxylation with migration of a chloride substituent, hydroxylation with elimination of a chloride substituent, and cleavage of an ether linkage of the dioxin ring were observed. In particular, the cleavage of an ether linkage of the dioxin ring appeared most important for the detoxication of dioxins. Based on these results, the metabolic pathways of 2-chloro-dibenzo-p-dioxin by rat CYP1A1 were proposed. The metabolic pathways contain most of the metabolites observed in vivo using experimental animals, suggesting that P450 monooxygenase systems including CYP1A1 are greatly responsible for dioxin metabolism in vivo.     

Design, synthesis, and antifungal activities of novel 1H-triazole derivatives based on the structure of the active site of fungal lanosterol 14 alpha-demethylase (CYP51)

A series of fluconazole (1) analogues, compounds 3a-k, were prepared as potential antifungal agents. They were designed by computational docking experiments to the active site of the cytochrome P450 14alpha-sterol demethylase (CYP51), whose crystal structure is known. Preliminary biological tests showed that most of the target compounds exhibit significant activities against the eight most-common pathogenic fungi. Thereby, the most potent congener, 1-[(4-tert-butylbenzyl)(cyclopropyl)amino]-2-(2,4-difluorophenyl)-3-(1H-1,2,4-triazol-1-yl)propan-2-ol (3j), was found to exhibit a broad antifungal spectrum, being more active against Candida albicans, Candida tropicalis, Cryptococcus neoformans, Microsporum canis, and Trichophyton rubrum (MIC80 < 0.125 microg/ml) than the standard clinical drug itraconazole (2). The observed affinities of the lead molecules towards CYP51 indicate that a cyclopropyl residue enhances binding to the target enzyme. Our results may provide some guidance for the development of novel triazole-based antifungal lead structures.     

Structural and biochemical characterization of Mycobacterium tuberculosis CYP142: evidence for multiple cholesterol 27-hydroxylase activities in a human pathogen

The Mycobacterium tuberculosis cytochrome P450 enzyme CYP142 is encoded in a large gene cluster involved in metabolism of host cholesterol. CYP142 was expressed and purified as a soluble, low spin P450 hemoprotein. CYP142 binds tightly to cholesterol and its oxidized derivative cholest-4-en-3-one, with extensive shift of the heme iron to the high spin state. High affinity for azole antibiotics was demonstrated, highlighting their therapeutic potential. CYP142 catalyzes either 27-hydroxylation of cholesterol/cholest-4-en-3-one or generates 5-cholestenoic acid/cholest-4-en-3-one-27-oic acid from these substrates by successive sterol oxidations, with the catalytic outcome dependent on the redox partner system used. The CYP142 crystal structure was solved to 1.6 Å, revealing a similar active site organization to the cholesterol-metabolizing M. tuberculosis CYP125, but having a near-identical organization of distal pocket residues to the branched fatty acid oxidizing M. tuberculosis CYP124. The cholesterol oxidizing activity of CYP142 provides an explanation for previous findings that ΔCYP125 strains of Mycobacterium bovis and M. bovis BCG cannot grow on cholesterol, because these strains have a defective CYP142 gene. CYP142 is revealed as a cholesterol 27-oxidase with likely roles in host response modulation and cholesterol metabolism.