INVESTIGATING KEY POST-PKS ENZYMES FROM GILVOCARCIN BIOSYNTHETIC PATHWAY

Tibrewal, Nidhi

01 January 2013

Gilvocarcin V (GV) belongs to the angucycline class of antibiotics that possesses remarkable anticancer and antibacterial activities with low toxicity. Gilvocarcin exhibits its light induced anticancer activity by mediating crosslinking between DNA and histone H3. When photo-activated by near-UV light, the C8 vinyl group forms a [2+2] cycloadduct with thymine residues of double stranded DNA. D-fucofuranose is considered essential for histone H3 interactions. However, the poor water solubility has rendered it difficult to develop gilvocarcin as a drug. We aim to design novel gilvocarcin analogues with improved pharmaceutical properties through chemo-enzymatic synthesis and mutasynthesis. Previous studies have characterized many biosynthetic genes encoding the gilvocarcin biosynthetic skeleton. Despite these previous findings the exact functions of many other key genes are yet to be fully understood. Prior gene inactivation and cross-feeding experiments have revealed that the first isolable tetracyclic aromatic product undergoes a series of steps involving C–C bond cleavage followed by two O-methylations, a penultimate C-glycosylation and final lactone formation in order to fully develop the gilvocarcin structure. To provide a deeper understanding of these complex biochemical transformations, three specific aims were devised: 1) synthesis of the proposed intermediate and in vitro enzyme reactions revealed GilMT and GilM’s roles in gilvocaric biosynthesis; 2) utilizing in vitro studies the enzyme responsible for the C–C bond cleavage and its substrate were determined; 3) a small series of structural analogues of the intermediate from the gilvocarcin pathway was generated via chemical synthesis and fed to the mixture of the enzymes, GilMT and GilM. These reaction mixtures were then analyzed to establish the diversity of substrates tolerated by the enzymes.

Gilvocarcin

S-adenosylmethionine

O-methyltransferase

Baeyer-Villiger monooxygenases

Medicinal and Pharmaceutical Chemistry

Investigação da seletividade de mono-oxigenases frente a substratos orgânicos de boro ou de selênio / Investigation on selectivity of mono-oxigenases in the presence of boron-containing or seleniun-containing organic compounds

Brondani, Patrícia Bulegon

25 May 2012

Neste trabalho foi avaliada a seletividade (quimio ou enantiosseletividade) de quatro enzimas Baeyer-Villiger mono-oxigenases (BVMOs: PAMO, PAMO M446G, HAPMO e CHMO) frente a substratos contendo boro ou selênio. Inicialmente uma série de boro-acetofenonas foram submetidas à bio-oxidação catalisada por estas BVMOs. A enzima CHMO mostrou quimiosseletividade para transformação da ligação C-B em detrimento da reação de Baeyer-Villiger. Enquanto PAMO e PAMO M446G catalisaram a oxidação de ambas as funções em substratos 4-substituídos e a seletiva transformação de C-B no caso de substratos 3-substituídos. A enzima HAPMO levou a reação de Baeyer-Villiger e a transformação da ligação C-B em todos os casos. Quando alquenos contendo boro foram utilizados como substratos, somente aqueles que continham uma porção fenila em sua estrutura foram oxidados por BVMOs. Em nenhum dos casos foi observada reação de epoxidação e todas as enzimas levaram a transformação da ligação C-B em C-O. Compostos quirais contendo boro foram submetidos a reações com as BVMOs na tentativa de transformação enantiosseletiva. PAMO e PAMO M446G foram as melhores enzimas levando, na maioria dos casos, a satisfatória oxidação dos substratos. Entretanto, somente um composto pôde ser oxidado com boa enantiosseletividade (e.e 82-91%). Compostos quirais contendo o átomo de selênio também foram alvos de estudo com BVMOs. Novamente a enzima PAMO se mostrou a melhor opção dentre as enzimas testadas e somente quando R2 e R1 = Ph houve boa enantiosseletividade na oxidação (e.e 97 %). / In this work we evaluated the selectivity (chemo or enantioselectivity) of four Baeyer-Villiger mono-oxigenases (BVMOS: PAMO, M446G PAMO, HAPMO and CHMO) in the presence of boron-containing or selenium-containing compounds. Initially, a series of boron-acetophenones were submitted to oxidation reactions mediated by BVMOs. The enzyme CHMO was chemoselective leading only to C-B bond transformation instead Baeyer-Villiger reaction. However, PAMO and PAMO M446G mediated both oxidations in 4-substituted substrates, and only the C-B transformation in 3-substituted substrates. The enzyme HAPMO leading to Baeyer- Villiger reaction and C-B transformation in all cases. When boron-containing alkenes were the substrates, only compounds with phenyl moiety in the structure were oxidized by BVMOs. It was observed only the C-B transformation and none of the epoxidation reaction. Chiral boron compounds were submitted to BVMOS mediated reactions in an attempt of enantioselective transformation. PAMO and M446G PAMO showed the best results leading, in most cases, to a satisfactory oxidation. However, only one compound was oxidized with great enantioselectivity (82-91% ee). Selenium-containing chiral compounds were also tested in reactions mediated by BVMOs. Again, PAMO showed the best results among BVMOs tested, but only when R2 e R1 = Ph the reaction occurred with great enantiosselectivity (97 % ee).

Baeyer Villiger mono-oxigenases

Baeyer-Villiger monooxygenases

Boro

Boron

Chemoselectivity

Enantioselectivity

Enantiosseletividade

Oxidação

Oxidation

Quimiosseletividade

Selênio

Selenium

Investigação da seletividade de mono-oxigenases frente a substratos orgânicos de boro ou de selênio / Investigation on selectivity of mono-oxigenases in the presence of boron-containing or seleniun-containing organic compounds

Patrícia Bulegon Brondani

25 May 2012

Neste trabalho foi avaliada a seletividade (quimio ou enantiosseletividade) de quatro enzimas Baeyer-Villiger mono-oxigenases (BVMOs: PAMO, PAMO M446G, HAPMO e CHMO) frente a substratos contendo boro ou selênio. Inicialmente uma série de boro-acetofenonas foram submetidas à bio-oxidação catalisada por estas BVMOs. A enzima CHMO mostrou quimiosseletividade para transformação da ligação C-B em detrimento da reação de Baeyer-Villiger. Enquanto PAMO e PAMO M446G catalisaram a oxidação de ambas as funções em substratos 4-substituídos e a seletiva transformação de C-B no caso de substratos 3-substituídos. A enzima HAPMO levou a reação de Baeyer-Villiger e a transformação da ligação C-B em todos os casos. Quando alquenos contendo boro foram utilizados como substratos, somente aqueles que continham uma porção fenila em sua estrutura foram oxidados por BVMOs. Em nenhum dos casos foi observada reação de epoxidação e todas as enzimas levaram a transformação da ligação C-B em C-O. Compostos quirais contendo boro foram submetidos a reações com as BVMOs na tentativa de transformação enantiosseletiva. PAMO e PAMO M446G foram as melhores enzimas levando, na maioria dos casos, a satisfatória oxidação dos substratos. Entretanto, somente um composto pôde ser oxidado com boa enantiosseletividade (e.e 82-91%). Compostos quirais contendo o átomo de selênio também foram alvos de estudo com BVMOs. Novamente a enzima PAMO se mostrou a melhor opção dentre as enzimas testadas e somente quando R2 e R1 = Ph houve boa enantiosseletividade na oxidação (e.e 97 %). / In this work we evaluated the selectivity (chemo or enantioselectivity) of four Baeyer-Villiger mono-oxigenases (BVMOS: PAMO, M446G PAMO, HAPMO and CHMO) in the presence of boron-containing or selenium-containing compounds. Initially, a series of boron-acetophenones were submitted to oxidation reactions mediated by BVMOs. The enzyme CHMO was chemoselective leading only to C-B bond transformation instead Baeyer-Villiger reaction. However, PAMO and PAMO M446G mediated both oxidations in 4-substituted substrates, and only the C-B transformation in 3-substituted substrates. The enzyme HAPMO leading to Baeyer- Villiger reaction and C-B transformation in all cases. When boron-containing alkenes were the substrates, only compounds with phenyl moiety in the structure were oxidized by BVMOs. It was observed only the C-B transformation and none of the epoxidation reaction. Chiral boron compounds were submitted to BVMOS mediated reactions in an attempt of enantioselective transformation. PAMO and M446G PAMO showed the best results leading, in most cases, to a satisfactory oxidation. However, only one compound was oxidized with great enantioselectivity (82-91% ee). Selenium-containing chiral compounds were also tested in reactions mediated by BVMOs. Again, PAMO showed the best results among BVMOs tested, but only when R2 e R1 = Ph the reaction occurred with great enantiosselectivity (97 % ee).

Baeyer Villiger mono-oxigenases

Boro

Enantiosseletividade

Oxidação

Quimiosseletividade

Selênio

Baeyer-Villiger monooxygenases

Boron

Chemoselectivity

Enantioselectivity

Oxidation

Selenium

Baeyer-Villiger monooxygenases d'Acinetobacter : réactions biocatalysées et dédoublements cinétiques dynamiques / Baeyer-Villiger monooxygenases of Acinetobacter strains : biocatalyzed reactions and dynamic kinetic resolution

Hamze, Khalil

24 April 2014

L'oxydation de Baeyer-Villiger (BV) par voie enzymatique est une méthode efficace pour obtenir de lactones sous forme énantiomériquement pure. Les Baeyer-Villiger Monooxygénases (BVMO) sont ainsi capables d'oxyder de nombreux substrats avec une stéréospécificité remarquable.Nous avons recherché de nouvelles enzymes dans le génome de deux souches appartenant au genre Acinetobacter, A. baylyi ADP1 et A. baumannii AYE. Six gènes ont été clonés dans E. coli. Leur profil de substrat a été étudié en utilisant des cellules entières de ce microorganisme recombinant comme biocatalyseur. Quatre enzymes ont montré une spécificité de substrat similaire, avec une préférence pour les petites cétones cycliques et pour les substituants aryliques. Une de ces enzymes a permis le Dédoublement Cinétique Parallèle Régiodivergent d'une bicyclohepténone et la désymétrisation de cyclobutanones benzyliques avec, dans chaque cas, une énantiosélectivité intéressante car conduisant à des énantiomères rarement obtenus par réaction de BV enzymatique.Dans une seconde partie, des Dédoublements Cinétiques Dynamiques, associant réaction de BV enzymatique et racémisation in situ ont été réalisés avec des cellules entières d'E. coli produisant la Cyclohexanone Monooxygenase (CHMO) issue d'A. calcoaceticus. La racémisation de cyclohexanones α-substituées, habituellement difficilement racémisables, a été assurée par l'emploi de solutions tampons à base de sels de phosphate ou de glycine. Les -caprolactones correspondantes ont été isolées sous forme d'esters méthyliques hydroxylés quasi énantiopurs avec des rendements compris entre 70 et 80%. / Enzyme-mediated Baeyer-Villiger oxidation is nowadays largely recognized as an efficient method to obtain highly optically active lactones. An increasing number of Baeyer-Villiger Monooxygenases from various sources has been found to oxidize a large range of substrates with a good to excellent stereospecificity.Firstly, in order to enlarge the scope of these biotransformations, the genome of two strains of the Acinetobacter genus, A.baylyi ADP1 and A.baumannii AYE was explored. Six genes were expressed in E. coli and the substrate profile of each enzyme was studied using whole cell biotransformations. Four enzymes showed close substrate specificity with a preference for small cyclic ketones and for arylic substituents. Interestingly, one enzyme led to a Kinetic Parallel Regiodivergent Resolution of a bicycloheptenone and desymmetrisation of benzylic cyclobutanones in an enantiocomplementary manner when compared to the most of already known enzymes.The second part of this work describes the implementation of Dynamic Kinetic Resolution processes combining enzymatic BV oxidation and in situ racemization of α-substituted cyclohexanones to afford corresponding lactones in more than 50% yield. Cyclohexanone Monooxygenase (CHMO) from another Acinetobacter strain, A. calcoaceticus, was selected and the reactions were carried out with whole cells of producing CHMO E. coli strain. The racemization of α-substituted cyclohexanones, usually slowly racemized under basic conditions, was ensured by the use of containing phosphate salts or glycine buffer solutions. Several corresponding -caprolactones were isolated after methylation as enantiopure hydroxy methyl esters in 70-80% yield.

Baeyer-Villiger Monooxygénases

Dédoublement cinétique dynamique

Synthèse de lactones

Chimie verte

Biocatalyse

Acinetobacter

Baeyer-Villiger Monooxygenases

Asymmetric Baeyer-Villiger oxidation

Dynamic kinetic resolution

Lactones synthesis

Green chemistry

Biocatalysis

Acinetobacter