Cytochrome P450s in flavonoid metabolism

In this review, cytochrome P450s characterized at the molecular level catalyzing aromatic hydroxylations, aliphatic hydroxylations and skeleton formation in the flavonoid metabolism are surveyed. They are involved in the biosynthesis of anthocyanin pigments and condensed tannin (CYP75, flavonoid 3′,5′-hydroxylase and 3′-hydroxylase), flavones [CYP93B, (2S)-flavanone 2-hydroxylase and flavone synthase II], and leguminous isoflavonoid phytoalexins [CYP71D9, flavonoid 6-hydroxylase; CYP81E, isoflavone 2′-hydroxylase and 3′-hydroxylase; CYP93A, 3,9-dihydroxypterocarpan 6a-hydroxylase; CYP93C, 2-hydroxyisoflavanone synthase (IFS)]. Other P450s of the flavonoid metabolism include methylenedioxy bridge forming enzyme, cyclases producing glyceollins, flavonol 6-hydroxylase and 8-dimethylallylnaringenin 2′-hydroxylase. Mechanistic studies on the unusual aryl migration by CYP93C, regulation of IFS expression in plant organs and its biotechnological applications are introduced, and flavonoid metabolisms by non-plant P450s are also briefly discussed.     

Expression of flavonoid 6-hydroxylase candidate genes in normal and mutant soybean genotypes for glycitein content

Soybean seeds accumulate large amounts of isoflavones (genistein, daidzein and glycitein), secondary metabolites known for their phytoestrogenic activities. Isoflavone composition depends on the seed part and glycitein is almost found exclusively in hypocotyls. Moreover, two major phenotypes are encountered in soybean cultivars, with either low (35 %) or high (55 %) levels of glycitein in their hypocotyls. This trait was under a quasi-mendelian heredity, implicating at most one or two genes. A CYP71D9 cDNA displaying a flavonoid 6-hydroxylase (F6H) activity had previously been isolated from elicitor-induced soybean (Glycine max L.) cells. This enzyme allows the synthesis of the glycitein flavanone intermediate (6,7,4′- trihydroxyflavanone) by catalyzing the A-ring hydroxylation of liquiritigenin. In this study, the CYP71D9 gene (F6H1) and two other candidates (F6H2 and F6H3) were studied using contrasted soybean cultivars for glycitein content (0, 35, 55 and 80 %). Their expression was observed in chitosan elicited leaves. They encode P450 proteins of 496, 469 and 481 amino acids respectively and were expressed in leaves with or without elicitation. The expression patterns of these three genes were performed in cotyledons and hypocotyls at different developmental stages. F6H1 and F6H2 were not expressed in the developing seed. F6H3 was only expressed in hypocotyls. Its expression levels did not correlate with hypocotyls glycitein content, but it was not expressed in the null mutant for glycitein. Thus, this F6H3 gene is a good potential candidate for glycitein biosynthesis in soybean seed.     

Hydroxylation of limonene enantiomers and analogs by recombinant (-)-limonene 3- and 6-hydroxylases from mint (Mentha) species: evidence for catalysis within sterically constrained active sites

Limonene enantiomers and substrate analogs, including specifically fluorinated derivatives, were utilized to probe active site interactions with recombinant (-)-(4S)-limonene-3-hydroxylase (CYP71D13) and (-)-(4S)-limonene-6-hydroxylase (CYP71D18) from mint (Mentha) species. (-)-(4S)-Limonene is hydroxylated by both enzymes at the designated C3- and C6-allylic positions, with strict regio- and stereospecificity and without detectable allylic rearrangement, to give the corresponding products (-)-trans-isopiperitenol and (-)-trans-carveol. CYP71D13-catalyzed hydroxylation of (+)-(4R)-limonene also yields the corresponding trans-3-hydroxylated product ((+)-transisopiperitenol); however, the C6-hydroxylase converts (+)-(4R)-limonene to a completely different product profile dominated by the enantiopure cis-6-hydroxylated product (+)-cis-carveol along with several minor products, including both enantiomers of the trans-6-hydroxylated product ((+/-)-trans-carveol), indicating allylic rearrangement during catalysis. These results demonstrate that the regiospecificity and facial stereochemistry of oxygen insertion is dictated by the absolute configuration of the substrate. Fluorinated limonene analogs are also tightly bound by both enzymes and hydroxylated at the topologically congruent positions in spite of the polarizing effect of the fluorine atom on substrate reactivity. This strict retention of oxygenation geometry suggests a rigid substrate orientation imposed by multiple hydrophobic active site contacts. Structurally simplified substrate analogs are hydroxylated at slower rates and with substantial loss of regiospecificity, consistent with a loss of active site complementarity. Evaluation of the product profiles generated allowed assessment of the role of hydrophobic contacts in orienting the substrate relative to the activated oxygen species.     

Partial reconstruction of flavonoid and isoflavonoid biosynthesis in yeast using soybean type I and type II chalcone isomerases

Flavonoids and isoflavonoids are major plant secondary metabolites that mediate diverse biological functions and exert significant ecological impacts. These compounds play important roles in many essential physiological processes. In addition, flavonoids and isoflavonoids have direct but complex effects on human health, ranging from reducing cholesterol levels and preventing certain cancers to improving women's health. In this study, we cloned and functionally characterized five soybean (Glycine max) chalcone isomerases (CHIs), key enzymes in the phenylpropanoid pathway that produces flavonoids and isoflavonoids. Gene expression and kinetics analysis suggest that the soybean type I CHI, which uses naringenin chalcone as substrate, is coordinately regulated with other flavonoid-specific genes, while the type II CHIs, which use a variety of chalcone substrates, are coordinately regulated with an isoflavonoid-specific gene and specifically activated by nodulation signals. Furthermore, we found that some of the newly identified soybean CHIs do not require the 4′-hydroxy moiety on the substrate for high enzyme activity. We then engineered yeast (Saccharomyces cerevisiae) to produce flavonoid and isoflavonoid compounds. When one of the type II CHIs was coexpressed with an isoflavone synthase, the enzyme catalyzing the first committed step of isoflavonoid biosynthesis, various chalcone substrates added to the culture media were converted to an assortment of isoflavanones and isoflavones. We also reconstructed the flavonoid pathway by coexpressing CHI with either flavanone 3β-hydroxylase or flavone synthase II. The in vivo reconstruction of the flavonoid and isoflavonoid pathways in yeast provides a unique platform to study enzyme interactions and metabolic flux.     

Involvement of a soybean ATP-binding cassette-type transporter in the secretion of genistein, a signal flavonoid in legume-Rhizobium symbiosis

Legume plants have an ability to fix atmospheric nitrogen into nutrients via symbiosis with soil microbes. As the initial event of the symbiosis, legume plants secrete flavonoids into the rhizosphere to attract rhizobia. Secretion of flavonoids is indispensable for the establishment of symbiotic nitrogen fixation, but almost nothing is known about the membrane transport mechanism of flavonoid secretion from legume root cells. In this study, we performed biochemical analyses to characterize the transport mechanism of flavonoid secretion using soybean (Glycine max) in which genistein is a signal flavonoid. Plasma membrane vesicles prepared from soybean roots showed clear transport activity of genistein in an ATP-dependent manner. This transport activity was inhibited by sodium orthovanadate, a typical inhibitor of ATP-binding cassette (ABC) transporters, but was hardly affected by various ionophores, such as gramicidin D, nigericin, or valinomycin, suggesting involvement of an ABC transporter in the secretion of flavonoids from soybean roots. The K(m) and V(max) values of this transport were calculated to be 158 mum and 322 pmol mg protein(-1) min(-1), respectively. Competition experiments using various flavonoids of both aglycone and glucoside varieties suggested that this ABC-type transporter recognizes genistein and daidzein, another signaling compound in soybean root exudates, as well as other isoflavonoid aglycones as its substrates. Transport activity was constitutive regardless of the availability of nitrogen nutrition. This is, to our knowledge, the first biochemical characterization of the membrane transport of flavonoid secretion from roots.     

黄酮6位羟基化酶催化机制的理论研究与应用

灯盏乙素发酵生产过程中,黄酮6位羟基化酶催化效率不足,导致产生至少约18%的副产物。本研究以2种黄酮6位羟基化酶CYP82D4与CYP706X为研究目标,通过分子动力学模拟与量子化学计算,对两种黄酮6位羟基化酶的催化机制进行解析。结果表明,CYP82D4与CYP706X在反应决速步的能垒几乎相同,应当具有相似的反应速率,而CYP82D4相对较小的底物结合能可能有利于产物释放,是其具有更高催化效率的直接原因。最后,基于对底物进出过程的研究,CYP82D4的L540A突变将催化效率提高了1.37倍,证明了理论计算指导黄酮6位羟基化酶改造优化的可行性。本研究揭示了黄酮6位羟化酶的催化机制,为对其进行改造优化以提高灯盏乙素的发酵生产效率提供了参考。     

Biochemical Characterization of the Cytochrome P450 CYP107CB2 from <Emphasis Type="Italic">Bacillus lehensis</Emphasis> G1

The bioconversion of vitamin D3 catalyzed by cytochrome P450 (CYP) requires 25-hydroxylation and subsequent 1α-hydroxylation to produce the hormonal activated 1α,25-dihydroxyvitamin D3. Vitamin D3 25-hydroxylase catalyses the first step in the vitamin D3 biosynthetic pathway, essential in the de novo activation of vitamin D3. A CYP known as CYP107CB2 has been identified as a novel vitamin D hydroxylase in Bacillus lehensis G1. In order to deepen the understanding of this bacterial origin CYP107CB2, its detailed biological functions as well as biochemical characteristics were defined. CYP107CB2 was characterized through the absorption spectral analysis and accordingly, the enzyme was assayed for vitamin D3 hydroxylation activity. CYP-ligand characterization and catalysis optimization were conducted to increase the turnover of hydroxylated products in an NADPH-regenerating system. Results revealed that the over-expressed CYP107CB2 protein was dominantly cytosolic and the purified fraction showed a protein band at approximately 62 kDa on SDS–PAGE, indicative of CYP107CB2. Spectral analysis indicated that CYP107CB2 protein was properly folded and it was in the active form to catalyze vitamin D3 reaction at C25. HPLC and MS analysis from a reconstituted enzymatic reaction confirmed the hydroxylated products were 25-hydroxyitamin D3 and 1α,25-dihydroxyvitamin D3 when the substrates vitamin D3 and 1α-hydroxyvitamin D3 were used. Biochemical characterization shows that CYP107CB2 performed hydroxylation activity at 25 °C in pH 8 and successfully increased the production of 1α,25-dihydroxyvitamin D3 up to four fold. These findings show that CYP107CB2 has a biologically relevant vitamin D3 25-hydroxylase activity and further suggest the contribution of CYP family to the metabolism of vitamin D3.     

In silico and in vivo evaluation of flavonoid extracts on CYP2D6-mediated herb-drug interaction

Flavonoid extracts are widely used for preventing and treating ischemic heart disease. However, because many flavonoid extracts have been verified to inhibit CYP2D6 the main metabolic enzyme for the majority of antiarrhythmics and beta-blockers, co-administration of flavonoid extracts with these drugs may cause adverse herb-drug interaction in clinic. Here, we evaluated 43 common flavonoids on CYP2D6 inhibition in sillico and four commercial flavonoid extracts in vivo on the pharmacokinetics and pharmacodynamics of metoprolol in rats. Surprisingly, we found that the core skeletons of flavonoids instead of their substituents determine the extent of inhibiting CYP2D6 by a flavonoid extract. Isoflavones are less likely to inhibit CYP2D6, compared with other categories of flavonoids. Consistently, co-administration of soy extract that mainly contains isoflavones did not significantly increase plasma concentration of metoprolol and alter the systolic blood pressure of rats. Our results have implication in rationally selecting flavonoid extracts for therapeutic application.     

Characterization of rat and human CYP2J enzymes as Vitamin D 25-hydroxylases

vitamin D is 25-hydroxylated in the liver, before being activated by 1alpha-hydroxylation in the kidney. Recently, the rat cytochrome P450 2J3 (CYP2J3) has been identified as a principal vitamin D 25-hydroxylase in the rat [Yamasaki T, Izumi S, Ide H, Ohyama Y. Identification of a novel rat microsomal vitamin D3 25-hydroxylase. J Biol Chem 2004;279(22):22848-56]. In this study, we examine whether human CYP2J2 that exhibits 73% amino acid homology to rat CYP2J3 has similar catalytic properties. Recombinant human CYP2J2 was overexpressed in Escherichia coli, purified, and assayed for vitamin D 25-hydroxylation activity. We found significant 25-hydroxylation activity toward vitamin D3 (turnover number, 0.087 min(-1)), vitamin D2 (0.16 min(-1)), and 1alpha-hydroxyvitamin D3 (2.2 min(-1)). Interestingly, human CYP2J2 hydroxylated vitamin D2, an exogenous vitamin D, at a higher rate than it did vitamin D3, an endogenous vitamin D, whereas, rat CYP2J3 hydroxylated vitamin D3 (1.4 min(-1)) more efficiently than vitamin D2 (0.86 min(-1)). Our study demonstrated that human CYP2J2 exhibits 25-hydroxylation activity as well as rat CYP2J3, although the activity of human CYP2J2 is weaker than rat CYP2J3. CYP2J2 and CYP2J3 exhibit distinct preferences toward vitamin D3 and D2.     

Allelic variants from Dahlia variabilis encode flavonoid 3′-hydroxylases with functional differences in chalcone 3-hydroxylase activity

In the petals of Dahlia variabilis, hydroxylation of chalcones at position 3 can be detected, except the well-known flavonoid 3′-hydroxylation. Although the reaction is well characterized at the enzymatic level, it remained unclear whether it is catalyzed by a flavonoid 3′-hydroxylase (F3′H, EC1.14.13.21, CYP75B) with broad substrate specificity. Two novel allelic variants of F3′H were cloned from D. variabilis, which differ only in three amino acids within their 508 residues. The corresponding recombinant enzymes show significant differences in their chalcone 3-hydroxylase (CH3H) activity. A substitution of alanine at position 425 with valine enables CH3H activity, whereas the reciprocal substitution leads to a loss of CH3H activity. Interaction of the valine at position 425 with not yet identified structural properties seems to be decisive for chalcone acceptance. This is the first identification of an F3′H which is able to catalyze chalcone 3-hydroxylation to a physiologically relevant extent from any plant species.     

Flavonoid hydroxylase from Catharanthus roseus: cDNA, heterologous expression, enzyme properties and cell-type specific expression in plants

We investigated the P450 dependent flavonoid hydroxylase from the ornamental plant Catharanthus roseus. cDNAs were obtained by heterologous screening with the CYP75 Hf1 cDNA from Petunia hybrida. The C. roseus protein shared 68-78% identity with other CYP75s, and genomic blots suggested one or two genes. The protein was expressed in Escherichia coli as translational fusion with the P450 reductase from C. roseus. Enzyme assays showed that it was a flavonoid 3', 5'-hydroxylase, but 3'-hydroxylated products were also detected. The substrate specificity was investigated with the C. roseus enzyme and a fusion protein of the Petunia hybrida CYP75 with the C. roseus P450 reductase. Both enzymes accepted flavanones as well as flavones, dihydroflavonols and flavonols, and both performed 3'- as well as 3'5'-hydroxylation. Kinetics with C. roseus cultures on the level of enzyme activity, protein and RNA showed that the F3'5'H was present in dark-grown cells and was induced by irradiation. The same results were obtained for cinnamic acid 4-hydroxylase and flavanone 3beta-hydroxylase. In contrast, CHS expression was strictly dependent on light, although CHS is necessary in the synthesis of the F3'5'H substrates. Immunohistochemical localization of F3'5'H had not been performed before. A comparison of CHS and F3'5'H in cotyledons and flower buds from C. roseus identified CHS expression preferentially in the epidermis, while F3'5'H was only detected in the phloem. The cell-type specific expression suggests that intercellular transport may play an important role in the compartmentation of the pathways to the different flavonoids.     

Metabolism of vitamin D by human microsomal CYP2R1

The activation of vitamin D requires 25-hydroxylation in the liver and 1alpha-hydroxylation in the kidney. However, it remains unclear which enzyme is relevant to vitamin D 25-hydroxylation. Recently, human CYP2R1 has been reported to be a potential candidate for a hepatic vitamin D 25-hydroxylase. Thus, vitamin D metabolism by CYP2R1 was compared with human mitochondrial CYP27A1, which used to be considered a physiologically important vitamin D(3) 25-hydroxylase. A clear difference was observed between CYP2R1 and CYP27A1 in the metabolism of vitamin D(2). CYP2R1 hydroxylated vitamin D(2) at the C-25 position while CYP27A1 hydroxylated it at positions C-24 and C-27. The K(m) and k(cat) values for the CYP2R1-dependent 25-hydroxylation activity toward vitamin D(3) were 0.45microM and 0.97min(-1), respectively. The k(cat)/K(m) value of CYP2R1 was 26-fold higher than that of CYP27A1. These results strongly suggest that CYP2R1 plays a physiologically important role in the vitamin D 25-hydroxylation in humans.     

Identification of beta-amyrin and sophoradiol 24-hydroxylase by expressed sequence tag mining and functional expression assay

Triterpenes exhibit a wide range of structural diversity produced by a sequence of biosynthetic reactions. Cyclization of oxidosqualene is the initial origin of structural diversity of skeletons in their biosynthesis, and subsequent regio- and stereospecific hydroxylation of the triterpene skeleton produces further structural diversity. The enzymes responsible for this hydroxylation were thought to be cytochrome P450-dependent monooxygenase, although their cloning has not been reported. To mine these hydroxylases from cytochrome P450 genes, five genes (CYP71D8, CYP82A2, CYP82A3, CYP82A4 and CYP93E1) reported to be elicitor-inducible genes in Glycine max expressed sequence tags (EST), were amplified by PCR, and screened for their ability to hydroxylate triterpenes (beta-amyrin or sophoradiol) by heterologous expression in the yeast Saccharomyces cerevisiae. Among them, CYP93E1 transformant showed hydroxylating activity on both substrates. The products were identified as olean-12-ene-3beta,24-diol and soyasapogenol B, respectively, by GC-MS. Co-expression of CYP93E1 and beta-amyrin synthase in S. cerevisiae yielded olean-12-ene-3beta,24-diol. This is the first identification of triterpene hydroxylase cDNA from any plant species. Successful identification of a beta-amyrin and sophoradiol 24-hydroxylase from the inducible family of cytochrome P450 genes suggests that other triterpene hydroxylases belong to this family. In addition, substrate specificity with the obtained P450 hydroxylase indicates the two possible biosynthetic routes from triterpene-monool to triterpene-triol.     

Flavone synthase II (CYP93B16) from soybean (Glycine max L.)

Flavonoids are a very diverse group of plant secondary metabolites with a wide array of activities in plants, as well as in nutrition and health. All flavonoids are derived from a limited number of flavanone intermediates, which serve as substrates for a variety of enzyme activities, enabling the generation of diversity in flavonoid structures. Flavonoids can be characteristic metabolites, like isoflavonoids for legumes. Others, like flavones, occur in nearly all plants. Interestingly, there exist two fundamentally different enzymatic systems able to directly generate flavones from flavanones, flavone synthase (FNS) I and II. We describe an inducible flavone synthase activity from soybean (Glycine max) cell cultures, generating 7,4′-dihydroxyflavone (DHF), which we classified as FNS II. The corresponding full-length cDNA (CYP93B16) was isolated using known FNS II sequences from other plants. Functional expression in yeast allowed the detailed biochemical characterization of the catalytic activity of FNS II. A direct conversion of flavanones such as liquiritigenin, naringenin, and eriodictyol into the corresponding flavones DHF, apigenin and luteolin, respectively, was demonstrated. The enzymatic reaction of FNS II was stereoselective, favouring the (S)- over the (R)-enantiomer. Phylogenetic analyses of the subfamily of plant CYP93B enzymes indicate the evolution of a gene encoding a flavone synthase which originally catalyzed the direct conversion of flavanones into flavones, via early gene duplication into a less efficient enzyme with an altered catalytic mechanism. Ultimately, this allowed the evolution of the legume-specific isoflavonoid synthase activity.     

The importance of residues in substrate recognition site 3 for the catalytic function of CYP2D25 (vitamin D 25-hydroxylase).

Porcine CYP2D25, microsomal vitamin D(3) 25-hydroxylase, catalyzes the essential first step in the bioactivation of the prohormone vitamin D(3). Although CYP2D25 shows a high degree of sequence identity with other members of the CYP2D subfamily, such as human CYP2D6, the vitamin D(3) 25-hydroxylase activity is a unique property among CYP2D enzymes. In addition to 25-hydroxylation, CYP2D25 also metabolizes the drug tolterodine. In this study, CYP2D25 was functionally expressed in the Saccharomyces cerevisiae W(R) strain and site-directed mutagenesis was used to study the role of substrate recognition site 3 (SRS-3) for the catalytic specificity of CYP2D25. Five residues in SRS-3 of CYP2D25 were simultaneously mutated to the equivalent residues in CYP2D6, an enzyme not active in 25-hydroxylation. Western blot analysis of microsomes from transformed yeast cells showed that both the wild-type and mutant CYP2D25 were expressed at comparable levels. The 25-hydroxylase activity of recombinant mutant CYP2D25 was completely lost whereas the activity toward tolterodine remained virtually unaffected. The results implicate that residues in SRS-3 of CYP2D25 are important determinants for its function in vitamin D(3) metabolism.     

Metabolism of 25-hydroxyvitamin D3 by microsomal and mitochondrial vitamin D3 25-hydroxylases (CYP2D25 and CYP27A1): a novel reaction by CYP27A1

The metabolism of 25-hydroxyvitamin D(3) was studied with a crude mitochondrial cytochrome P450 extract from pig kidney and with recombinant human CYP27A1 (mitochondrial vitamin D(3) 25-hydroxylase) and porcine CYP2D25 (microsomal vitamin D(3) 25-hydroxylase). The kidney mitochondrial cytochrome P450 catalyzed the formation of 1alpha,25-dihydroxyvitamin D(3), 24,25-dihydroxyvitamin D(3) and 25,27-dihydroxyvitamin D(3). An additional metabolite that was separated from the other hydroxylated products on HPLC was also formed. The formation of this 25-hydroxyvitamin D(3) metabolite was dependent on NADPH and the mitochondrial electron transferring protein components. A monoclonal antibody directed against purified pig liver CYP27A1 immunoprecipitated the 1alpha- and 27-hydroxylase activities towards 25-hydroxyvitamin D(3) as well as the formation of the unknown metabolite. These results together with substrate inhibition experiments indicate that CYP27A1 is responsible for the formation of the unknown 25-hydroxyvitamin D(3) metabolite in kidney. Recombinant human CYP27A1 was found to convert 25-hydroxyvitamin D(3) into 1alpha,25-dihydroxyvitamin D(3), 25,27-dihydroxyvitamin D(3) and a major metabolite with the same retention time on HPLC as that formed by kidney mitochondrial cytochrome P450. Gas chromatography-mass spectrometry (GC-MS) analysis of the unknown enzymatic product revealed it to be a triol different from other known hydroxylated 25-hydroxyvitamin D(3) metabolites such as 1alpha,25-, 23,25-, 24,25-, 25,26- or 25,27-dihydroxyvitamin D(3). The product had the mass spectrometic properties expected for 4beta,25-dihydroxyvitamin D(3). Recombinant porcine CYP2D25 converted 25-hydroxyvitamin D(3) into 1alpha,25-dihydroxyvitamin D(3) and 25,26-dihydroxyvitamin D(3). It can be concluded that both CYP27A1 and CYP2D25 are able to carry out multiple hydroxylations of 25-hydroxyvitamin D(3).     

Substrate specificity of the cytochrome P450 enzymes CYP79A1 and CYP71E1 involved in the biosynthesis of the cyanogenic glucoside dhurrin in Sorghum bicolor (L.) Moench

The two multifunctional cytochrome P450 enzymes, CYP79A1 and CYP71E1, involved in the biosynthesis of the cyanogenic glucoside dhurrin in Sorghum bicolor (L.) Moench have been characterized with respect to substrate specificity and cofactor requirements using reconstituted, recombinant enzymes and sorghum microsomes. CYP79A1 has a very high substrate specificity, tyrosine being the only substrate found. CYP71E1 has less stringent substrate requirements and metabolizes aromatic oximes efficiently, whereas aliphatic oximes are slowly metabolized. Neither CYP79A1 nor CYP71E1 catalyze the metabolism of a range of different herbicides. The reported resistance of sorghum to bentazon is therefore not linked to the presence of CYP79A1 or CYP71E1. NADPH is a much better cofactor than NADH although NADH does support the entire catalytic cycle of both P450 enzymes. Km and Vmax values for NADPH when supporting CYP71E1 activity are 0.013 mM and 111 nmol/mg protein/s. For NADH, the corresponding values are 0. 3 mM and 42 nmol/mg protein/s. CYP79A1 is a fairly stable enzyme. In contrast, CYP71E1 is labile and prone to rapid denaturation at room temperature. CYP71E1 is isolated in the low spin form. CYP71E1 catalyzes an unusual dehydration reaction of an oxime to the corresponding nitrile which subsequently is C-hydroxylated. The oxime forms a peculiar reverse Type I spectrum, whereas the nitrile forms a Type I spectrum. Several compounds which do not serve as substrates formed Type I substrate binding spectra with the two P450 enzymes.