Oxygen activation by cytochrome P450 monooxygenase

Unlike photosystem II (PSII) that catalyzes formation of the O-O bond, the cytochromes P450 (P450), members of a superfamily of hemoproteins, catalyze the scission of the O-O bond of dioxygen molecules and insert a single oxygen atom into unactivated hydrocarbons through a hydrogen abstraction-oxygen rebound mechanism. Hydroxylation of the unactivated hydrocarbons at physiological temperatures is vital for many cellar processes such as the biosynthesis of many endogenous compounds and the detoxification of xenobiotics in humans and plants. Even though it carries out the opposite of the water splitting reaction, P450 may share similarities to PSII in proton delivery networks, oxygen and water access channels, and consecutive electron transfer processes. In this article, we review recent advances in understanding the molecular mechanisms by which P450 activates dioxygen.     

Silencing myostatin gene by RNAi in sheep embryos

Myostatin (MSTN) gene is described as a negative regulator of the skeletal muscle growth. Controlling MSTN gene expression by genetic manipulation could accelerate the muscle growth and meat production of livestock animals. In the present study, several siRNAs targeting sheep MSTN gene were designed and their interfering efficiency was evaluated in vitro. The present study showed that one of the siRNAs, PSL1, could down-regulate the expression of MSTN significantly. PSL1 was ligated into lentivirus vector, GP-Supersilencing, to construct a siRNA expression lentivirus vector. Fibroblast cells were infected by lentivirus particles and positive cells were isolated by flow cytometry. Nucleus of the positive cell was transferred into enucleated oocytes of sheep. The present study showed that 99.4% of the sorted cells displayed green fluorescence. After enucleation of oocytes with microinjection, about 20% of reconstructed embryos can be developed into morulas, and strong green fluorescence could be observed using a fluorescence microscope. This method can be available to produce transgenic cell line for somatic cell nucleus transfer for transgenic animals.     

RNAi suppression of CYP82D P450 hydroxylase,an enzyme involved in gossypol biosynthesis,enhances resistance to Fusarium wilt in cotton

Cotton plants produce two classes of terpenoid defence compounds against pathogens and other pests. Both classes are derived from a common sesquiterpenoid precursor, δ-cadinen-2-one, which enters either the gossypol pathway or the lacinilene pathway. Blocking the gossypol pathway by RNAi suppression of the early pathway biosynthetic enzyme CYP82D hydroxylase resulted in enhanced resistance to the Fusarium wilt pathogen. Analyses of root terpenoids revealed no overall increases in the products of the gossypol pathway in the roots infected by the wilt pathogen. However, the lacinilene pathway was elicited by the pathogen and the lacinilene levels were 19-fold higher in the RNAi plants than in wild-type plants. In the pathogen inoculated RNAi 73R plants, the concentrations of DHC and HMC were 231 μg and 886 μg/g dry roots, respectively, which may have contributed to the inhibition of fungal invasion. In comparison, the concentrations of DHC and HMC in the pathogen inoculated control wild-type 73W plants were only 0.7 μg and 58 μg/g dry roots, respectively. Fungitoxicity testing showed that DHC at 100 μg/ml inhibited growth of the Fusarium wilt pathogen by >93%. Treatment with the phytohormone jasmonic acid failed to elicit production of lacinilene pathway terpenoids in roots of either RNAi plants or their wild-type sibling lines, but increased production of gossypol pathway terpenoids with concentrations in RNAi plants 80%–97% less than those in wild-type plants. This indicates that induction of the lacinilene pathway is not directly mediated by jasmonic acid signalling and requires other signalling to activate the pathway. These results illustrate possible mechanisms of wilt disease resistance in cotton and provide a new approach to increase host resistance by manipulating these two major cotton chemical defence pathways.     

棉铃虫幼虫加单氧酶活性的组织分布

棉铃虫（Ｈｅｌｉｃｏｖｅｒｐａ ａｒｍｉｇｅｒａ）６龄幼虫不同组织的加单氧酶活性的测定结果显示,对－硝基苯甲醚Ｏ－脱甲基酶主要分由于外来物质的入口部位,以中肠和脂肪体的活性较高,在前肠、后肠和马氏管等组织中有相对较低的活性,而在体壁和精巢中未检测到Ｏ－ 甲基作用。体壁表现一定的艾氏剂环氧化作用,但其活性不及中肠的１０％,内源性制剂被证明并非体壁低加单氧酶活性的主要原因。不同组织生物量的差异及其动态     

棉铃虫中肠微粒体P450的分离纯化

为深入研究棉铃虫Helicoverpa armigera细胞色素P450的结构与功能,需要分离不同型的P450蛋白。作者建立了适用于棉铃虫中肠微粒体P450的纯化方法,包括聚乙二醇8000（PEG8000）沉淀、高效疏水作用色谱（HPHIC）和高效离子交换色谱（HPIEC）等连续分离步。SDS-PAGE（银染）显示,棉铃虫中肠微粒体经以上步骤分离纯化后,在含P450的馏分中检测出分子量分别为58 kD、47 kD、56 kD和45 kD的4条蛋白带。 P450的回收率为14.3%,比含量提高了39倍。     

过氧化氢驱动的细胞色素P450酶研究进展

细胞色素P450酶在自然界中广泛存在,能催化多种类型的氧化反应,在有机合成和生物化工方面具有重要的应用潜力。尽管大多数P450酶通常需要辅酶和复杂的电子传递体系协助活化氧分子,一些P450酶也可以利用过氧化氢作为末端氧化剂,这极大地简化了催化循环,为P450酶的合成应用提供了一条新的简便途径。本文系统地介绍了几类过氧化氢驱动的P450酶催化体系,包括脂肪酸羟化酶P450SPα和P450BSβ、脂肪酸脱羧酶P450OleTJE、人工改造的羟化酶P450BM3和P450cam突变体、以及基于底物误识别策略的P450-H2O2体系。通过分析催化反应机制,本文探讨了P450-H2O2催化体系在目前存在的挑战和可能的解决途径,并对其进一步应用前景进行了展望。     

过氧化氢驱动的细胞色素P450酶研究进展

细胞色素P450酶在自然界中广泛存在,能催化多种类型的氧化反应,在有机合成和生物化工方面具有重要的应用潜力。尽管大多数P450酶通常需要辅酶和复杂的电子传递体系协助活化氧分子,一些P450酶也可以利用过氧化氢作为末端氧化剂,这极大地简化了催化循环,为P450酶的合成应用提供了一条新的简便途径。本文系统地介绍了几类过氧化氢驱动的P450酶催化体系,包括脂肪酸羟化酶P450SPα和P450BSβ、脂肪酸脱羧酶P450OleTJE、人工改造的羟化酶P450BM3和P450cam突变体、以及基于底物误识别策略的P450-H2O2体系。通过分析催化反应机制,本文探讨了P450-H2O2催化体系在目前存在的挑战和可能的解决途径,并对其进一步应用前景进行了展望。     

Purification of cytochrome P450 BM-3 as a monooxygenase

After investigating two anion-exchange resins, the purification factor and activity yields of P450 BM-3 were higher with Resource Q than with DEAE-Sepharose FF. Screening of HIC media showed that Source 15ISO was the most suitable for purification of P450 BM-3. An effective isolation and purification procedure of P450 BM-3 was developed and included three steps: 35%-70% saturation (NH(4))(2)SO(4) precipitation, Source 15ISO hydrophobic interaction chromatograph and Sephacryl S-200 gel filtration chromatography. Using this protocol, the purification factor and P450 BM-3 activity recovery was 13.5 and 13.7%, respectively.     

Involvement of a cytochrome P450 monooxygenase in thaxtomin A biosynthesis by Streptomyces acidiscabies

The biosynthesis of the thaxtomin cyclic dipeptide phytotoxins proceeds nonribosomally via the thiotemplate mechanism. Acyladenylation, thioesterification, N-methylation, and cyclization of two amino acid substrates are catalyzed by the txtAB-encoded thaxtomin synthetase. Nucleotide sequence analysis of the region 3' of txtAB in Streptomyces acidiscabies 84.104 identified an open reading frame (ORF) encoding a homolog of the P450 monooxygenase gene family. It was proposed that thaxtomin A phenylalanyl hydroxylation was catalyzed by the monooxygenase homolog. The ORF was mutated in S. acidiscabies 84.104 by using an integrative gene disruption construct, and culture filtrate extracts of the mutant were assayed for the presence of dehydroxy derivatives of thaxtomin A. Reversed-phase high-performance liquid chromatography (HPLC) and HPLC-mass spectrometry indicated that the major component in culture filtrate extracts of the mutant was less polar and smaller than thaxtomin A. Comparisons of electrospray mass spectra as well as (1)H- and (13)C-nuclear magnetic resonance spectra of the purified compound with those previously reported for thaxtomins confirmed the structure of the compound as 12,15-N-dimethylcyclo-(L-4-nitrotryptophyl-L-phenylalanyl), the didehydroxy analog of thaxtomin A. The ORF, designated txtC, was cloned and the recombinant six-His-tagged fusion protein produced in Escherichia coli and purified from cell extracts. TxtC produced in E. coli exhibited spectral properties similar to those of cytochrome P450-type hemoproteins that have undergone conversion to the catalytically inactive P420 form. Based on these properties and the high similarity of TxtC to other well-characterized P450 enzymes, we conclude that txtC encodes a cytochrome P450-type monooxygenase required for postcyclization hydroxylation of the cyclic dipeptide.     

Effects of gossypol on fitness costs associated with resistance to Bt cotton in pink bollworm

Fitness costs associated with insect resistance to Bacillus thuringiensis (Bt) crops may help to delay or prevent the spread of resistance alleles, especially when refuges of non-Bt host plants are present. The potential for such delays increases as the magnitude and dominance of fitness costs increase. Here, we examined the idea that plant secondary chemicals affect expression of fitness costs associated with resistance to Bt cotton in Pectinophora gossypiella (Saunders). Specifically, we tested the hypotheses that gossypol affects the magnitude or dominance of fitness costs, by measuring performance of three independent sets of pink bollworm populations fed artificial diet with and without gossypol. Each set had an unselected susceptible population, a resistant population derived by selection from the susceptible population, and the F1 progeny of the susceptible and resistant populations. No individuals completed development on diets with gossypol in one set, suggesting that these individuals partially lost the ability to detoxify this chemical. In the other two sets, costs affecting survival did not support the hypotheses, but costs affecting pupal weight did. Adding gossypol to diet increased the magnitude and dominance of costs affecting pupal weight. In one of the two sets with survivors on diet with gossypol, costs affecting development time were less recessive when gossypol was present in diet. These results indicate that gossypol increased the magnitude and dominance of some fitness costs. Better understanding of the effects of natural plant defenses on fitness costs could improve our ability to design refuges for managing insect resistance to Bt crops.     

Sequence-based screening for self-sufficient P450 monooxygenase from a metagenome library

AIMS: Cytochrome P450 monooxygenases (CYPs) are useful catalysts for oxidation reactions. Self-sufficient CYPs harbour a reductive domain covalently connected to a P450 domain and are known for their robust catalytic activity with great potential as biocatalysts. In an effort to expand genetic sources of self-sufficient CYPs, we devised a sequence-based screening system to identify them in a soil metagenome. METHODS AND RESULTS: We constructed a soil metagenome library and performed sequence-based screening for self-sufficient CYP genes. A new CYP gene, syk181, was identified from the metagenome library. Phylogenetic analysis revealed that SYK181 formed a distinct phylogenic line with 46% amino-acid-sequence identity to CYP102A1 which has been extensively studied as a fatty acid hydroxylase. The heterologously expressed SYK181 showed significant hydroxylase activity towards naphthalene and phenanthrene as well as towards fatty acids. CONCLUSIONS: Sequence-based screening of metagenome libraries is expected to be a useful approach for searching self-sufficient CYP genes. The translated product of syk181 shows self-sufficient hydroxylase activity towards fatty acids and aromatic compounds. SIGNIFICANCE AND IMPACT OF THE STUDY: SYK181 is the first self-sufficient CYP obtained directly from a metagenome library. The genetic and biochemical information on SYK181 are expected to be helpful for engineering self-sufficient CYPs with broader catalytic activities towards various substrates, which would be useful for bioconversion of natural products and biodegradation of organic chemicals.     

Cytochrome P450 monooxygenases in the cotton bollworm (Lepidoptera: Noctuidae): tissue difference and induction

Differences in the microsomal P450 monooxygenase system and its inducibility by pentamethylbenzene (PMB) and naphathalene (NA) were investigated in midgut and fatbody tissues of the cotton bollworm, Helicoverpa armigera (Boddie), larvae. Orthogonal array design was used to establish the optimal conditions for measuring Aldrin epoxidation (AE). The optima for AE were similar for the midgut and the fatbody at a temperature of 30 degrees C, pH 7.4, and a time of 10 min. In comparison to fatbody, the midgut had higher levels of total cytochrome P450s, p-nitroanisole O-demethylation (ODM) and AE. In vivo administration of 0.2% PMB or 0.2% NA resulted in higher microsomal protein content and levels of total cytochrome P450 as well as the two examined monooxygenase activities. Total cytochrome P450 and ODM activity were induced to a greater degree in the fatbody. In the midgut, PMB was significantly more effective on ODM than NA. Differences existed in SDS-PAGE profiles between the midgut and the fatbody. The induction of the midgut with PMB and of the fatbody with NA and PMB resulted in marked intensification of the protein bands with molecular masses of 59,100, 53,400, 50,400 Da.     

Arabidopsis PAD3, a gene required for camalexin biosynthesis, encodes a putative cytochrome P450 monooxygenase

Phytoalexins are low molecular weight antimicrobial compounds that are synthesized in response to pathogen attack. The phytoalexin camalexin, an indole derivative, is produced by Arabidopsis in response to infection with the bacterial pathogen Pseudomonas syringae. The phytoalexin deficient 3 (pad3) mutation, which causes a defect in camalexin production, has no effect on resistance to P. syringae but compromises resistance to the fungal pathogen Alternaria brassicicola. We have now isolated PAD3 by map-based cloning. The predicted PAD3 protein appears to be a cytochrome P450 monooxygenase, similar to those from maize that catalyze synthesis of the indole-derived secondary metabolite 2,4-dihydroxy-1, 4-benzoxazin-3-one. The expression of PAD3 is tightly correlated with camalexin synthesis and is regulated by PAD4 and PAD1. On the basis of these findings, we conclude that PAD3 almost certainly encodes an enzyme required for camalexin biosynthesis. Moreover, these results strongly support the idea that camalexin does not play a major role in plant resistance to P. syringae infection, although it is involved in resistance to a fungal pathogen.     

Fitness cost of resistance to Bt cotton linked with increased gossypol content in pink bollworm larvae

Fitness costs of resistance to Bacillus thuringiensis (Bt) crops occur in the absence of Bt toxins, when individuals with resistance alleles are less fit than individuals without resistance alleles. As costs of Bt resistance are common, refuges of non-Bt host plants can delay resistance not only by providing susceptible individuals to mate with resistant individuals, but also by selecting against resistance. Because costs typically vary across host plants, refuges with host plants that magnify costs or make them less recessive could enhance resistance management. Limited understanding of the physiological mechanisms causing fitness costs, however, hampers attempts to increase costs. In several major cotton pests including pink bollworm (Pectinophora gossypiella), resistance to Cry1Ac cotton is associated with mutations altering cadherin proteins that bind this toxin in susceptible larvae. Here we report that the concentration of gossypol, a cotton defensive chemical, was higher in pink bollworm larvae with cadherin resistance alleles than in larvae lacking such alleles. Adding gossypol to the larval diet decreased larval weight and survival, and increased the fitness cost affecting larval growth, but not survival. Across cadherin genotypes, the cost affecting larval growth increased as the gossypol concentration of larvae increased. These results suggest that increased accumulation of plant defensive chemicals may contribute to fitness costs associated with resistance to Bt toxins.     

Crystal structure of a phenol-coupling P450 monooxygenase involved in teicoplanin biosynthesis

The lipoglycopeptide antibiotic teicoplanin has proven efficacy against gram‐positive pathogens. Teicoplanin is distinguished from the vancomycin‐type glycopeptide antibiotics, by the presence of an additional cross‐link between the aromatic amino acids 1 and 3 that is catalyzed by the cytochrome P450 monooxygenase Orf6* (CYP165D3). As a goal towards understanding the mechanism of this phenol‐coupling reaction, we have characterized recombinant Orf6* and determined its crystal structure to 2.2‐Å resolution. Although the structure of Orf6* reveals the core fold common to other P450 monooxygenases, there are subtle differences in the disposition of secondary structure elements near the active site cavity necessary to accommodate its complex heptapeptide substrate. Specifically, the orientation of the F and G helices in Orf6* results in a more closed active site than found in the vancomycin oxidative enzymes OxyB and OxyC. In addition, Met226 in the I helix replaces the more typical Gly/Ala residue that is positioned above the heme porphyrin ring, where it forms a hydrogen bond with a heme iron‐bound water molecule. Sequence comparisons with other phenol‐coupling P450 monooxygenases suggest that Met226 plays a role in determining the substrate regiospecificity of Orf6*. These features provide further insights into the mechanism of the cross‐linking mechanisms that occur during glycopeptide antibiotics biosynthesis. Proteins 2011; © 2011 Wiley‐Liss, Inc.