The extracellular peroxygenase of the agaric fungus Agrocybe aegerita: catalytic properties and physiological background with particular emphasis on ether cleavage

Kinne, Matthias

22 October 2010

Litter-decay fungi have recently been shown to secrete heme-thiolate peroxygenases that oxidize various organic chemicals, but little is known about the physiological role or the mechanism of these enzymes. The aromatic peroxygenase of Agrocybe aegerita (AaeAPO) was purified and catalytically characterized. An overall reaction mechanism was proposed. The results show that AaeAPO catalyzed diverse H2O2-dependent monooxygenations (two-electron oxidations) including (a) the cleavage of aliphatic and aromatic ethers, (b) the regio- and enantioselective hydroxylation of aromatic compounds, (c) the stepwise oxygenation of benzylic compounds, (d) the N-dealkylation of secondary amines and (e) the dehalogenation of halogenated aliphatic compounds as well as typical peroxidase reactions (suggested to involve one-electron oxidation) such as (f) oxidation and polymerization of phenols and (g) halogenations. The enzyme failed to oxidize polymers such as polyethylene glycol (PEG). Mechanistic studies with several model substrates provided information about the reaction cycle of AaeAPO: (1) stoichiometry of tetrahydrofuran cleavage showed that the reaction was a two-electron oxidation that generated one aldehyde group and one alcohol group, yielding the ring-opened product 4-hydroxybutanal, (2) steady-state kinetics results with methyl 3,4-dimethoxybenzyl ether, which was oxidized to 3,4-dimethoxybenzaldehyde, gave parallel double reciprocal plots suggestive of a ping-pong mechanism, (3) the cleavage of methyl 4-nitrobenzyl ether, the hydroxylation of aromatics such as diclofenac and nitrophenol and the oxygenation of benzylic compounds, resulted in incorporation of 18O into the reaction product in the presence of H218O2, and (4) the demethylation of 1-methoxy-4-trideuteromethoxybenzene showed an distinct observed intramolecular deuterium isotope effect. These results support a mechanism similar to that envisaged for the peroxygenase activity of P450s in which the enzyme heme is oxidized by H2O2 to give an iron species that carries one of the peroxide oxygen. This intermediate then abstracts a hydrogen from the substrate, which is followed by rebound of an •OH equivalent to produce the monooxygenated reaction product (hydrogen abstraction and oxygen rebound mechanism). AaeAPO may accordingly have a role in the biodegradation of natural and anthropogenic low molecular weight compounds in soils and plant litter. Moreover, the results raise the possibility that fungal peroxygenases may be useful for versatile, cost-effective, and scalable syntheses of drug metabolites and herbicide precursors. / Die Peroxygenase des Südlichen Ackerling (Agrocybe aegerita, AaeAPO) wurde gereinigt, ihr Katalysepotential ermittelt und ein allgemeiner Reaktionsmechanismus postuliert. Die AaeAPO katalysiert sowohl H2O2-abhängige Monooxygenierungen (Zwei-Elektron Oxidationen) wie (a) die Spaltung aliphatischer und aromatischer Ether, (b) die regio- und enantioselektive Hydroxylierung von Aromaten, (c) die schrittweise Monooxygenierung von Toluolderivaten, (d) die N-Dealkylierung sekundärer Amine und (e) die Dehalogenierung chlorierter Aliphaten als auch typische Reaktionen bekannter Peroxidasen (vermutlich Ein-Elektron-Oxidation) unter anderem (f) die Oxidation/ Polymerisierung von Phenolen und (g) die Halogenierung von Aromaten. Polymere Verbindungen wie Polyethylenglycol (PEG) werden nicht oxidiert. Mechanistische Untersuchungen zur Etherspaltung am Beispiel der AaeAPO haben Einblick in den generellen Reaktionsmechanismus dieses neuen Enzymtyps ermöglicht: (1) die Stöchiometrie der Spaltung von Tetrahydrofuran entspricht der einer zwei-Elektron-Oxidation, (2) die Spaltung von Methyl-3,4-Dimethoxybenzylether zu 4-Dimethoxybenzaldehyd und Methanol ergaben parallele Verläufe für die ermittelten Ausgleichsgeraden in der doppelt reziproken Darstellung, was einem „Ping-Pong“-Reaktionsmechanismus entspricht (3) die Monooxygenierungen haben stets den Einbau eines aus dem Peroxid (H2O2) stammenden Sauerstoffatoms in das Produkt zur Folge, (4) die O-Dealkylierung von 1-Methoxy-4-Trideuterummethoxybenzol zeigt einen ausgeprägten Deuterium Isotopen Effekt, was auf die primäre Abspaltung eines Wasserstoffatoms vom Substratmolekül hindeutet. Demnach verläuft die Peroxygenase-katalysierte Monooxygenierung über Wasserstoffabstraktion und eine unmittelbar anschließende Sauerstoffrückbindung (hydrogen abstraction - oxygen rebound mechanism). Diese Reaktionsabfolge ähnelt dem sogenannten peroxide "shunt" pathway, der von einer Reihe Cytochrom-P450-abhängiger Monooxygenasen her bekannt ist. Die physiologische Funktion der AaeAPO besteht möglicherweise in der extrazellulären Transformation und Detoxifikation niedermolekularer Pflanzeninhaltsstoffe, mikrobieller Metabolite und anthropogener Xenobiotika. Aufgrund der Stabilität und Unabhängigkeit der AaeAPO von teuren Kofaktoren ergeben sich vielversprechende biotechnologische Möglichkeiten zum Einsatz isolierter Biokatalysatoren in selektiven (bio)chemischen Synthesen monooxygenierter Metabolite.

info:eu-repo/classification/ddc/540

ddc:540

Vliv cytochromu b5 na aktivitu cytochromů P450 / Effect of cytochrome b5 on activity of cytochromes P450

Ličko, Vojtech

January 2020

ABSTRACT Cytochrome b5 (CYB5) is heme protein capable of reduction of cytochromes P450 (CYP) or some other enzymes. However, his regulative capability was also observed by his apo form, i.e. in absence of heme prosthetic group in the active center. CYB5 can accept electron from cytochrome b5 reductase (CYB5R) or from cytochrome P450 reductase (CYPOR). CYPOR by itself is reduced by NADPH and is also able to forward electron to CYP independently of CYB5. CYB5R on the other hand is reduced by NADH. Efficiency of CYB5 to accept and forward an electron was studied in vitro with five different substrates - testosterone, Sudan I, aristolochic acid I (AAI), ellipticine and vandetanib. These substrates were chosen considering their characteristic reactions, which are catalyzed by their respective isoforms of CYP. The experiments with these substrates were carried out in the medium with recombinant CYPs prepared in insect cells or E. coli or in the medium with hepatic microsomes isolated from different organisms. Rats, from which the majority of these microsomes was isolated, were premedicated by different CYP inducers. The experiments were carried out in medium with NADH or NADPH in order to assess the capability of CYB5 to reduce CYP independently of CYPOR. The capability of CYB5 and CYB5R to act as a...

Cytochrome P450 mRNA profile in human breast cancer cell lines

Warasiha, Benjamart

January 2008

Cytochrome P450 enzymes (P450s) are involved in cancer development and treatment due to their roles in the oxidative metabolism of various endogenous (e.g. oestrogen) and exogenous (e.g. tamoxifen) compounds. It is well-known that intermediate P450 metabolites derived from oestrogen metabolism are associated with breast carcinogenesis. The main aim of this project was to profile the cytochrome P450 and P450-regulatory nuclear receptor mRNAs in a series of breast cancer cell lines (BCCs) and compare this profile with normal breast cells. This study used the qualitative reverse transcriptasepolymerase chain reaction (RT-PCR) to detect mRNA expression of target genes. Results showed CYP1B1, CYP2D6, CYP2J2, CYP2R1, CYP2U1 and CYP4X1 mRNA to be present in all cell lines. CYP2A6, CYP2C8, CYP2C18, CYP2F1 and CYP4Z1 mRNA were expressed in oestrogen receptor (ER)-positiveCaucasian and ER-negative Afro- Caribbean BCCs. Although no differences in P450 mRNA were observed between the different ethnic groups, these preliminary findings suggest potential similarities in the ERpositive Caucasian and ER-negative Afro-Caribbean BCCs which warrant further investigation The CYP4Z1 PCR product was identified as two distinct bands. Specific primer sets were used to demonstrate potential intron retention in CYP4Z1. Using established in vitro models for the study of regulatory mechanisms of CYP4Z1, T47D and ZR-75-1 breast cancer cell lines were used to determine the appropriate nuclear receptors (i.e. progesterone receptor, glucocorticoid receptor or peroxisome proliferator-activated receptor alpha ). These findings suggest that there may be an alternative receptor mechanism involved in CYP4Z1 mRNA induction in these cells. In conjunction, pre-treatment of these two cell lines with the RNA synthesis inhibitor actinomycin D followed by the agonists showed a significant reduction (p < 0.05) of CYP4Z1 mRNA levels and inhibited CYP4Z1 induction by either progesterone, dexamethasone or pirinixic acid, indicating that these agonists have effects on CYP4Z1 mRNA transcription or stability. In contrast, cycloheximide differentially affected the level of CYP4Z1 mRNA induction by these agonists. Taken together, these results suggest that CYP4Z1 mRNA induction in T47D and ZR-75-1 is mediated through differential cell type specific regulatory mechanisms and there is evidence for differential regulation of the splice variants.

616.99449

Développement et validation de méthodes de dosage du midazolam, un marqueur de l'activité des CYP3A, et de la fexofénadine, un substrat de la glycoprotéine P, dans les milieux biologiques

Stepanova, Tatiana

January 2009

Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal.

Interaction médicamenteuse

Cytochromes P450

Transporteurs membranaires

Midazolam

Fexofénadine

Clarythromycine

Méthode de quantification

Drug interaction

Cytochromes P450

Membrane transporters

Midazolam

Fexofenadine

Clarythromycine

Method of quantification

Ingénierie moléculaire de cytochromes P450 pour l'hydroxylation des alcanes / Cytochrome P450 engineering for alkane hydroxylation

Bordeaux, Mélanie

26 October 2012

L'activation de molécules inertes telles que les alcanes constitue l'un des défis les plus difficiles en catalyse, du fait de la grande stabilité de la liaison C-H. Pour répondre aux principes de la chimie verte, les méthodes de fonctionnalisation doivent respecter un certain nombre d'exigences, telles que l'utilisation de solvants et de réactifs non toxiques, la réduction des apports énergétiques, en association avec une activité élevée. Afin de satisfaire ces conditions, nous nous sommes dirigés vers l'utilisation d'un système enzymatique. En effet, les liaisons C-H non activées peuvent être fonctionnalisées en conditions douces par des monooxygénases, telles que les cytochromes P450, mais leur activité est relativement faible. Dans le but de disposer de cytochromes P450 plus actifs sur les alcanes, nous décrivons la fusion entre un membre de la famille des CYP153 et un partenaire donneur d'électrons. Cette protéine de fusion a été caractérisée, et ses propriétés catalytiques étudiées. Nous avons montré que la fusion augmente de manière considérable l'activité alcane hydroxylase. Nous avons, dans un second temps, continué d'exploiter le fort potentiel de ce biocatalyseur en tentant de réduire le volume de son site actif par mutagénèse dirigée, en vue de l'hydroxylation des alcanes gazeux, notamment le méthane. Enfin, différentes modifications des conditions réactionnelles nous ont permis d'atteindre une activité non égalée pour l'hydroxylation terminale de l'octane. / Activation of inert molecules such as alkanes is considered as one of the most difficult challenges in catalysis, due to the high stability of the C-H bond. To comply with the principles of green chemistry, functionalization methods must respect multiple requirements, such as the use of non-toxic solvents and reagents, in addition to reducing energy usage whilst maintaining maximal activity. To satisfy these conditions, we decided to focus on the use of an enzymatic system. Indeed, unactivated C-H bonds can be functionalized under mild conditions by monooxygenases, such as cytochrome P450s, but their activity is relatively limited. In order to have cytochrome P450s more active on alkanes, we describe the fusion between a member of the CYP153 family and an electron donor partner. This fusion protein has been characterized and its catalytic properties studied. We have shown that the fusion increases significantly the alkane hydroxylase activity. Our second step was to continue to exploit the potential of this biocatalyst by attempting to reduce the volume of its active site using site-directed mutagenesis for the hydroxylation of gaseous alkanes, including methane. Finally, various modifications of the reaction conditions allowed us to achieve the terminal hydroxylation of octane with a previously unequalled activity.

Activation de la liaison C-H

Biocatalyse

Alcane

Hydroxylation

Chimie verte

Cytochrome P450

C-H bond activation

Biocatalysis

Alkane

Hydroxylation

Green Chemistry

Cytochrome P450

Srovnání vlastností buněčných linií rezistentních k ellipticinu, doxorubicinu a cisplatině / The comparison of properties of cell lines resistant to ellipticine, doxorubicin, and cisplatin

Černá, Tereza

January 2014

7 Abstract Neuroblastoma is the most common extracranial solid tumor of childhood. Despite advances in cancer diagnosis and therapy, the treatment of some forms of neuroblastoma is still complicated. One of the major complications of the chemotherapy is a developed drug resistance. This master thesis deals with the effect of cytostatics on protein and gene expression of selected proteins, which may contribute to chemoresistance of the human neuroblastoma cell line UKF-NB-4. The sensitive line UKF-NB-4 and the resistant line UKF-NB-4CDDP , UKF-NB-4DOXO and UKF-NB-4ELLI were exposed to cisplatin, doxorubicin, ellipticine for 24, 48 and 72 hours. The Western blot analysis showed that cytostatic agents cisplatin, doxorubicin or ellipticine added to the sensitive neuroblastoma cell line UKF-NB-4 in amounts which are added to resistant neuroblastoma cell lines in order to maintain resistance induced expression of p53 and reduced expression of retinoblastoma protein pRb after 72 hours of cultivation. Differences in the expression of RAS protein, cytochrome P450 1A1, 3A4 and cytochrome b5 has not been shown. Changes in the expression of the studied proteins in resistant lines UKF-NB-4CDDP , UKF-NB-4DOXO and UKF-NB-4ELLI cultured with and without cytostatic agents were not detected by the Western blot analysis....

Oxidace ellipticinu lidskými cytochromy P450 exprimovanými v prokaryotním a eukaryotním systému / Oxidation of ellipticine by human cytochromes P450 expressed in prokaryotic and eukaryotic systems

Vejvodová, Lucie

January 2013

Ellipticine is an alkaloid with antitumor activity, whose mechanism of action is based on intercalation into DNA, inhibition of topoisomerase II and formation of covalent adducts with DNA, after its enzymatic activation by cytochromes P450 and/or peroxidases. Ellipticine is oxidized by cytochromes P450 to form up to five metabolites (7-hydroxy-, 9-hydroxy, 12- hydroxy-, 13-hydroxyellipticine and N2 -oxide ellipticine). 9-Hydroxy- and 7- hydroxyellipticine are considered to be detoxification metabolites, whereas 12-hydroxy-, 13- hydroxyellipticine and N2 -oxide of ellipticine are considered as activation metabolites, which are responsible for formation of covalent DNA adducts. The aim of this thesis was to examine the efficiency of human recombinant cytochromes P450 expressed in eukaryotic (SupersomesTM ) and two prokaryotic expression systems (Bactosomes) in oxidation of ellipticine. Cytochromes P450 expressed in prokaryotic systems differed in the amounts of "coexpressed" NADPH:CYP reductase. The resulting ellipticine metabolites were analyzed by HPLC. The results obtained in this thesis demonstrate that human cytochromes P450 2C9/2D6/2C19 expressed in prokaryotic or eukaryotic systems oxidize ellipticine to form up to four metabolites: 9-hydroxy-, 12-hydroxy-, 13-hydroxyellipticine and N2 -oxide...

Molekulární mechanismus karcinogenity aristolochové kyseliny / Molecular mechanism of carcinogenicity of aristolochic acid

Levová, Kateřina

January 2013

Aristolochic acids (AA) are carcinogenic and nephrotoxic alkaloids from Aristolochia species. Aristolochic acid I (AAI), the major component of AA, causes the development of Aristolochic acid nephropathy (AAN) and Balkan endemic nephropathy (BEN). These two diseases cause total renal failure and urothelial malignancies. The fact that these diseases have not been developed in all persons, who have been exposed to their action, might be causd by different activities and protein levels of the enzymes metabolizing AAI. Thus, the identification of enzymes involved in the metabolism, and detailed knowledge of their expression and catalytic specifities is a major importance. Aristolochic acid I (AAI) can be metabolized by several types of reactions. Like most nitroaromatics, the main activation pathway of AAI is reduction of its nitro group to form a cyclic acylnitrenium ion, which can bind to the purine bases, thereby forming AAI-DNA adducts. The detoxication pathway of AAI is its oxidative demethylation by cytochromes P450 forming detoxication metabolite 8-hydroxyaristolochic acid Ia (AAIa). In the present thesis, using rat and human enzymes and as well as several mice models, the metabolism of AAI in vitro and in vivo was investigated. The first model has deleted gene for NADPH:cytochrome P450...

Modelování interakcí cytochromů P450 s flavodoxinem / Interaction of Cytochromes P450 with Flavodoxin: a theoretical study

Culka, Martin

January 2013

Cytochromes P450 are diverse group of heme enzymes found in most species on Earth. In humans they are involved in metabolism of foreign compounds or steroids, bacteria employ cytochromes P450 for utilization of various hydrophobic substrates. General reaction catalyzed by cytochromes P450 is monooxygenation, when one atom of oxygen molecule is introduced into the substrate, while the other is reduced producing water. NADPH:cytochrome P450 oxidoreductase or cytochrome b5 usually serves as an electron donor providing electrons needed for activation of oxygen in eukaryotic organisms, in bacteria small FeS proteins or flavoproteins are these electron donors. It was shown earlier that bacterial electron donor flavodoxin could also interact with human cytochromes P450 in vitro. This thesis employs molecular modeling techniques to support a hypothesis that flavodoxin is responsible for reduction of human (1A2, 2A6, 2A13, 2C9, 2C19, 3A4) and bacterial (101A1 a 176A1) cytochromes P450 heterologously expressed in Escherichia coli. An initial guess of possible mutual orientations of cytochrome P450 and flavodoxin was predicted using information-driven protein-protein docking. The stability of these complexes was examined by directed dissociation method. The most stable orientation for each cytochrome P450 was further...

Résistance au fenhexamid dans le complexe d'espèces Botrytis cinerea/ Botrytis pseudocinerea : Etudes génétiques et moléculaires / Fenhexamid resistance in the species complexe of Botrytis cinerea / Botrytis pseudocinerea : genetic and molecular study

Azeddine, Saad

11 June 2014

La pourriture grise est une maladie qui affecte de nombreuses cultures dont la vigne. Elle est provoquée par un complexe de deux espèces fongiques, l’espèce majoritaire Botrytis cinerea et l’espèce minoritaire Botrytis pseudocinerea. Les deux espèces se distinguent par leur sensibilité à certains fongicides notamment au fenhexamid, inhibiteur de la 3-cétoréductase des stérols. Ce fongicide a un spectre d’action restreint aux espèces phylogénétiquement proches du genre Botrytis (Sclerotinia et Monilinia fructicola). Son utilisation a conduit à la sélection de souches résistantes parmi lesquelles on distingue trois phénotypes : le phénotype HydR1 correspond à l’espèce B. pseudocinerea naturellement résistante ; les phénotypes HydR2 et HydR3 correspondent à l’espèceB. cinerea ayant acquis la résistance suite à l’introduction du fongicide. L’objet de cette thèse est l’étude des phénotypes HydR1 et HydR2 présents à de faibles, voire très faibles fréquences dans des populations de pourriture grise.Chez B. pseudocinerea (HydR1), nous avons identifié une monooxygénase à cytochrome P450 nommée Cyp684 responsable de la résistance au fenhexamid. Le gène cyp684 montre des polymorphismes (structure et séquence nucléotidique) entre les espèces ainsi qu’une induction par le fenhexamid chez B. pseudocinerea. La comparaison de la séquence du gène cyp684 chez plusieurs espèces de Botrytis et de leurs niveaux de résistance au fenhexamid indique que les acides aminés polymorphes de la protéine Cyp684 sont responsables de la résistance au fenhexamid chez B. pseudocinerea. Le rôle connu des monooxygénase à cytochrome P450 dans la métabolisation des xénobiotiques et la synergie entre le fenhexamid et des inhibiteurs de monooxygénases à P450 suggèrent que Cyp684 soit impliqué dans la métabolisation du fenhexamid. Concernant le phénotypeHydR2 de B. cinerea, le mécanisme de résistance reste à identifier. Les souches HydR2 se distinguent par leur phénotype rose dû à un métabolite secondaire nommé bikavérine. Le génotypage réalisé sur les descendantes d’un croisement entre une souche HydR2 et une souche sensible a mis en évidence un lien physique entre le gène ou l’allèle hydR2 et le cluster bikavérine. Afin d’identifier la niche écologique et de comprendre l'épidémiologie de B. pseudocinerea, nous avons développé une méthode de qPCR espèce spécifique, nommée « B. pseudocinerea allele specific PCR » (BpASP). Cet outil permettra de détecter et de quantifier l’espèce B.pseudocinerea dans les populations de Botrytis, selon la saison, la région géographique et les plantes hôtes. / Grey mold is a fungal disease affecting many crops including grapevine. It is generated by a species complex of two fungal species, the major one, Botrytis cinerea, and the minor species, Botrytis pseudocinerea. Both species differ by their sensitivity to several fungicides, in particular to fenhexamid, a potent inhibitor of sterol 3-ketoreductase. This fungicide has a narrow spectrum of activity limited to species closely related to the genus Botrytis (e.g., Sclerotinia and Monilinia fructicola). Fenhexamid applications have led to the selection of resistant strains with three different phenotypes: the HydR1 phenotype corresponds to the naturally resistant species B. pseudocinerea; HydR2 and HydR3 phenotypes correspond to B. cinerea strains that acquired resistance after the introduction of fenhexamid. The topic of this thesis is the study of the phenotypes HydR1 andHydR2 present at low or even very low frequencies in grey mold populations. We identified a cytochrome P450 monooxygenase named Cyp684 responsible for resistance to fenhexamid in B.pseudocinerea (HydR1). The cyp684 gene differs between both species in its gene structure, nucleotide sequence (polymorphisms) and expression. The comparison of cyp684 sequences among different Botrytis species and their resistance levels to fenhexamid indicate the polymorphic amino acids of the Cyp684 protein to be responsible for fenhexamid resistance in B. pseudocinerea. The known involvement of cytochrome P450s in xenobiotic metabolisation and synergy between fenhexamid and P450-inhibitors suggest that Cyp684 could be involved in fenhexamid metabolisation. Concerning the B. cinerea HydR2 phenotype, the resistance mechanism remains to be identified. HydR2 strains have a specific purple pigmentation due to the secondary metabolite bikaverin. Genotyping of progeny derived from a cross between a HydR2 and a sensitive strain revealed aphysical link between the hydR2 gene or allele and the gene cluster involved in bikaverin biosynthesis. In order to identify the ecological niche of B. pseudocinerea and its epidemiological behavior we developed a species-specific qPCR method named “B. pseudocinerea allele specific PCR” (BpASP). This tool will allow detecting and quantifying the species B. pseudocinerea in natural Botrytis populations, collected according to season, geographic origin or plant hosts.

Pourriture grise

Botrytis cinerea

Botrytis pseudocinerea

Fenhexamid

Résistance naturelle

Métabolisation

Cytochrome P450

Gray mould

Botrytis cinerea

Botrytis pseudocinerea

Fenhexamid

Natural resistance

Metabolization

Cytochrome P450