A novel human cytochrome P450 gene (P450IIB): chromosomal localization and evidence for alternative splicing.

We have isolated from a single human liver cDNA library two clones which are highly homologous (78% over the coding region) to the major phenobarbital-inducible P450 from rat (P450IIB1). This is the first direct demonstration of the presence of the P450IIB gene subfamily in humans. This subfamily is much less extensive than the rodent homologues, but does appear to contain at least two genes. Of the cDNA clones isolated one is apparently normally spliced, whereas the other lacks exon 8 and retains all or part of intron 5. Both clones contain transcribed Alu sequences. The human P450IIB gene has been located to chromosome 19q12----19q13.2 using a probe derived from intron 5, and is close to the CYP 2A locus encoding cytochrome P450IIA2. Restriction fragment length polymorphisms have been found with the enzymes BamHI and MspI which will enable linkage to be determined between these two loci.     

Expression of a cytochrome P450 gene family in maize

Maize seedlings, like seedlings of many other plants, are rich in cytochrome P450 (P450) enzyme activity. Four P450 genes (CYPzm1–4), isolated from a seedling-specific cDNA library, are characterised by a transient and seedling-specific expression pattern. The maximum steady state mRNA levels are reached at 3 days in root and at 7 days in shoot tissue, respectively. All four genes belong to one gene family and are closely related to the CYP71 family of plant P450 genes, which includes the enzymes of the ripening avocado fruit (CYP71A1) and eggplant hypocotyls (CYP71A2, A3, A4). The expression of these related P450 genes in monocot and dicot plants indicates that these enzymes play a significant role in plants; however, the in vivo enzyme functions are unknown. The divergence of the four members of the maize gene family is sufficiently high to account for different substrate and/or reaction specificity. Although the general expression pattern of the four genes is identical, the maximum steady-state mRNA levels vary in different maize lines. In situ hybridisation reveals the highest mRNA levels in the coleoptile, the first developed leaflets, the ground tissue of the nodular complex, and in the cortex and pith of the region of cell division in the root. The mapping of the maize CYPzm genes shows that, as in animals, P450 genes of the same family can be clustered. The presence of the CYPzm gene cluster in maize argues for generation of distinct plant P450 gene families by gene duplication.     

Genome mining approach for the discovery of novel cytochrome P450 biocatalysts

Cytochrome P450 enzymes (P450s) are able to regioselectively and stereoselectively introduce oxygen into organic compounds under mild reaction conditions. These monooxygenases in particular easily catalyze the insertion of oxygen into less reactive carbon–hydrogen bonds. Hence, P450s are of considerable interest as oxidation biocatalysts. To date, although several P450s have been discovered through screening of microorganisms and have been further genetically engineered, the substrate range of these biocatalysts is still limited to fulfill the requirements for a large number of oxidation processes. On the other hand, the recent rapid expansion in the number of reported microbial genome sequences has revealed the presence of an unexpectedly vast number of P450 genes. This large pool of naturally evolved P450s has attracted much attention as a resource for new oxidation biocatalysts. In this review, we focus on aspects of the genome mining approach that are relevant for the discovery of novel P450 biocatalysts. This approach opens up possibilities for exploitation of the catalytic potential of P450s for the preparation of a large choice of oxidation biocatalysts with a variety of substrate specificities.     

A novel class of self-sufficient cytochrome P450 monooxygenases in prokaryotes

The Bacillus cytochrome P450 BM3 integrates an entire P450 system in one polypeptide and represents a convenient prokaryotic model for microsomal P450s. This self-sufficient class II P450 is also present in actinomycetes and fungi. By genome analysis we have identified additional homologues in the pathogenic species Bacillus anthracis and Bacillus cereus, and in Ralstonia metallidurans. This analysis also revealed a novel class of putative self-sufficient P450s, P450 PFOR, comprising a class I P450 that is related to Rhodococcus erythropolis CYP116, and a phthalate family oxygenase reductase (PFOR) module. P450 PFOR genes are found in a Rhodococcus strain, three pathogenic Burkholderia species and in the R. metallidurans strain that possesses a P450 BM3 homologue. Co-evolution of P450 and reductase domains is apparent in both types of self-sufficient enzymes. The new class of P450 enzymes is of potential interest for various biotechnological applications.     

昆虫基因启动子及细胞色素P450基因启动子研究进展

细胞色素P450是一类重要的解毒酶系。昆虫在各种内源或外源性有毒物质的胁迫下,通过调控体内细胞色素P450的过表达,对有毒化合物进行解毒代谢,从而适应不利环境。在昆虫体内,P450基因表达的调控主要发生在转录水平上,启动子作为基因的一部分,能够与RNA聚合酶结合形成转录起始复合体,进而控制基因表达的起始时间和表达程度。基于此,就昆虫启动子的分析及功能验证的主要方法、昆虫启动子的结构特征及昆虫细胞色素P450基因启动予的一些研究进展进行概述,以期为昆虫细胞色素P450基因启动子的深入研究提供借鉴。     

Identification and characterization of an NADPH-cytochrome P450 reductase derived peptide involved in binding to cytochrome P450

The amino acids of cytochrome P450 reductase involved in the interaction with cytochrome P450 were identified with a differential labeling technique. The water-soluble carbodiimide EDC (1-ethyl-3-[3- (dimethylamino)propyl]-carbodiimide) was used with the nucleophile methylamine to modify carboxyl residues. When the modification was performed in the presence of cytochrome P450, there was no inhibition in the ability of the modified reductase to bind to cytochrome P450. However, subsequent modification of the reductase in the absence of cytochrome P450 caused a fourfold increase in the Km and an 80% decrease in kcat/Km (relative to the reductase modified in the first step), for the interaction with cytochrome P450. These effects are attributed to the modification of approximately 3.2 mol of carboxyl residues per mole of reductase. Tryptic peptides generated from the modified reductase were purified by reverse phase high-performance liquid chromatography and characterized. Amino acid sequencing and analysis suggest that the peptide which contains approximately 40% of the labeled carboxyl residues corresponds to amino acid residues 109-130 of rat liver NADPH-cytochrome P450 reductase. One or more of the seven carboxyl containing amino acids within this peptide is presumably involved in the interaction with cytochrome P450.     

Regulation of cytochrome P450 gene expression in the olfactory mucosa

The mammalian olfactory mucosa (OM) is unique among extrahepatic tissues in having high levels, and tissue-selective forms, of cytochrome P450 (CYP) enzymes. These enzymes may have important toxicological implications, as well as biological functions, in this chemosensory organ. In addition to a tissue-selective, abundant expression of CYP1A2, CYP2A, and CYP2G1, some of the OM CYPs are also known to have an early developmental expression, a resistance to xenobiotic inducers, and a lack of responsiveness to circadian rhythm. Efforts to fully characterize the regulation of CYP expression in the OM, and to identify the underlying mechanisms, are important for our understanding of the physiological functions and toxicological significance of these biotransformation enzymes, and may also shed unique light on the general mechanisms of CYP regulation. The aim of this mini-review is to provide a summary of current knowledge of the various modes of regulation of CYPs expressed in the OM, an update on our mechanistic studies on tissue-selective CYP expression, and a review of the literature on xenobiotic inducibility of OM CYPs. Our goal is to stimulate further studies in this exciting research area, which is of considerable importance, in view of the constant exposure of the human nasal tissues to inhaled, as well as systemically derived, chemicals, the prevalence of olfactory system damage in individuals with neurodegenerative diseases, and the current uncertainty in risk assessments for potential olfactory toxicants.     

cDNA cloning and regulation of a novel rat cytochrome P450 of the 2C gene subfamily (P450IIC24)

A novel member of the cytochrome P450 2C gene subfamily was identified by screening rat prostate cDNA libraries. Two independent clones were isolated. Clone pros1 was 1031 bp long and contained a bizarre replacement in place of putative exon 1. Clone pros2 was 1755 bp long, contained a complete 3' end, and also had bizarre sequences in place of exon 1, which in this case were compatible with an unspliced intron. Northern analysis revealed mRNA expression in the liver and the kidney. Interestingly, although livers of mature rats of both sexes have comparable amounts of P4502C24 mRNA, a dramatic sex difference is seen in the kidney where only males express detectable levels of this mRNA.     

Identification of genetically high risk individuals to lung cancer by DNA polymorphisms of the cytochrome P450IA1 gene.

A good correlation was observed between enhanced lung cancer risk and restriction fragment length polymorphisms (RFLPs) of the P450IA1 gene with the restriction enzyme MspI. Genotype frequencies of 0.49 for the predominant homozygote, 0.40 for the heterozygote, and 0.11 for the homozygous rare allele were observed in a healthy population. Among lung cancer patients, the frequency of homozygous rare allele of P450IA1 gene was found to be about 3-fold higher than that among healthy population, and this difference was statistically significant. This is the first report to identify the genetically high risk individuals to lung cancer at the gene level.     

Identification of cytochrome P450IA2 as a human autoantigen

Autoantibodies occurring in a patient with idiopathic autoimmune type chronic active hepatitis (CAH) were found to react with purified rabbit cytochrome P450IA2 and to a much lesser extent with P450IA1. Both cytochrome P450s are known to be inducible by 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) in the rabbit, and the expression of the microsomal protein recognized by the patient serum was induced in adult rabbit livers after treatment with TCDD. This protein is only weakly detected in liver microsomes from neonatal rabbits exposed to TCDD in utero, which is consistent with the age-dependent induction of P450IA2 by TCDD. The serum specifically reacted with a protein of similar size in microsomes prepared from COS-1 cells transfected with an expression vector containing the full length human P450IA2 cDNA. This reactivity was not detected in the cells transfected with the vector alone, indicating that the antibody recognizes human P450IA2. In addition, the serum extensively inhibited 7-ethoxyresorufin O-deethylation catalyzed by isolated human liver microsomes. This catalytic activity is associated with class IA P450s in other species. A screen of sera from patients with various hepatic and nonhepatic diseases indicates that the autoantibody to P450IA2 occurs rarely in CAH. Cytochrome P450IA2 becomes the third P450 identified as an autoantigen in inflammatory liver diseases.     

Application of a new versatile electron transfer system for cytochrome P450-based Escherichia coli whole-cell bioconversions

Cytochromes P450 monooxygenases are highly interesting biocatalysts for biotechnological applications, since they perform a diversity of reactions on a broad range of organic molecules. Nevertheless, the application of cytochromes P450 is limited compared to other enzymes mainly because of the necessity of a functional redox chain to transfer electrons from NAD(P)H to the monooxygenase. In this study, we established a novel robust redox chain based on adrenodoxin, which can deliver electrons to mitochondrial, bacterial and microsomal P450s. The natural membrane-associated reductase of adrenodoxin was replaced by the soluble Escherichia coli reductase. We could demonstrate for the first time that this reductase can transfer electrons to adrenodoxin. In the first step, the electron transfer properties and the potential of this new system were investigated in vitro, and in the second step, an efficient E. coli whole-cell system using CYP264A1 from Sorangium cellulosum So ce56 was developed. It could be demonstrated that this novel redox chain leads to an initial conversion rate of 55 μM/h, which was 52 % higher compared to the 36 μM/h of the redox chain containing adrenodoxin reductase. Moreover, we optimized the whole-cell biotransformation system by a detailed investigation of the effects of different media. Finally, we are able to demonstrate that the new system is generally applicable to other cytochromes P450 by combining it with the biotechnologically important steroid hydroxylase CYP106A2 from Bacillus megaterium.     

A novel cytochrome P450 3A isoenzyme in rat intestinal microsomes

PCR with several pairs of primers facilitates screening for new isoenzymes among highly homologous cytochrome P450s (CYPs). Combinations of two pairs of primers, which amplify N- and C-terminal coding sequences of either CYP3A1/CYP3A23 or CYP3A2 detected the presence of a previously unrecognized CYP3A in enterocyte microsomes isolated from rats. PCR, Northern blot, and immunoblotting with specific antibodies indicated that this isoenzyme is clearly distinguishable from CYP3A1, 3A23 or 3A2. Sequencing of a 285 bp coding fragment of this gene revealed 97% similarity with rat olfactory CYP3A9 (P450olf3).     

Improved cloning and expression of cytochrome P450s and cytochrome P450 reductase in yeast

Combination of the pYeDP60 yeast expression system with a modified version of the improved uracil-excision (USER) cloning technique provides a new powerful tool for high-throughput expression of eukaryotic cytochrome P450s. The vector presented is designed to obtain an optimal 5' untranslated sequence region for yeast (Kozak consensus sequence), and has been tested to produce active P450s and NADPH-cytochrome P450 oxidoreductase (CPR) after 5' end silent codon optimization of the cDNA sequences. Expression of two plant cytochrome P450s, Sorghum bicolor CYP79A1 and CYP71E1, and S. bicolor CPR2 using the modified pYeDP60 vector in all three cases produced high amounts of active protein. High-throughput functional expression of cytochrome P450s have long been a troublesome task due to the workload involved in cloning of each individual P450 into a suitable expression vector. The redesigned yeast P450 expression vector (pYeDP60u) offers major improvements in cloning efficiency, speed, fidelity, and simplicity. The modified version of the USER cloning system provides great potential for further development of other yeast vectors, transforming these into powerful high-throughput expression vectors.     

Identification and characterization of a bacterial cytochrome P450 for the metabolism of diclofenac

The bacterium Actinoplanes sp. ATCC 53771 is known to perform drug metabolism of several xenobiotics similarly to humans. We identified a cytochrome P450 enzyme from this strain, CYP107E4, and expressed it in Escherichia coli using the pET101 vector. The purified enzyme showed the characteristic reduced-CO difference spectra with a peak at 450 nm, indicating the protein is produced in the active form with proper heme incorporation. The CYP107E4 enzyme was found to bind the drug diclofenac. Using redox enzymes from spinach, the reconstituted system is able to produce hydroxylated metabolites of diclofenac. Production of the human 4′-hydroxydiclofenac metabolite by CYP107E4 was confirmed, and a second hydroxylated metabolite was also produced.     

Identification of the cytochrome P450 enzymes responsible for the omega-hydroxylation of phytanic acid

Patients suffering from Refsum disease have a defect in the alpha-oxidation pathway which results in the accumulation of phytanic acid in plasma and tissues. Our previous studies have shown that phytanic acid is also a substrate for the omega-oxidation pathway. With the use of specific inhibitors we now show that members of the cytochrome P450 (CYP450) family 4 class are responsible for phytanic acid omega-hydroxylation. Incubations with microsomes containing human recombinant CYP450s (Supersomes) revealed that multiple CYP450 enzymes of the family 4 class are able to omega-hydroxylate phytanic acid with the following order of efficiency: CYP4F3A>CYP4F3B>CYP4F2>CYP4A11.