Dimeric indole and quinolinone alkaloids

Rutherford, M. J.

January 1985

No description available.

547

Indole alkaloid dimerization

Enantiospecific approaches to indole alkaloids

Hollinshead, S. P.

January 1987

No description available.

547

Indole alkaloid synthesis

A novel approach to the total synthesis of corynanthe indole alkaloids via cyclopentanoid intermediaries

Wingfield, M.

January 1985

No description available.

547

Indole alkaloid synthesis

Identification, Isolation, and Characterization of Developmental Toxins from the Cyanobacterium Fischerella 52-1 Using the Zebrafish (Danio rerio) Embryo Model

Walton, Katherine E

30 March 2012

Cyanobacteria, also known as blue-green algae, are known to produce a number of biologically active compounds. Extracts of cultured cyanobacteria isolated from South Florida sources were screened for possible developmental toxins using the zebrafish (Danio rerio) embryo as a model of vertebrate development. A strain of cyanobacteria, Fischerella 52-1, isolated from the Florida Everglades, was found to produce metabolites that caused a consistent developmental dysfunction in embryos exposed to lipophilic extract. Initial chemical characterization of the bioactive fraction identified a series of eight apparent indole-containing compounds. The two main components were purified using the zebrafish embryo model to guide the fractionation. Chemical characterization using 1- and 2-dimensional NMR, HESIMS, HRHESIMS, and IR determined that the two main compounds were the previously identified 12-epi-Hapalindole H Isonitrile, and a novel compound 12-epi-Ambiugine B Nitrile. The major contributor of the developmental defects detected in the zebrafish embryos was 12-epi-Hapalindole H Isonitrile.

Cyanobacteria

Fischerella

Hapalindoles

Zebrafish Embryo

Stigonemataceae

Indole Alkaloid

Total Synthesis of Indole Alkaloids Based on Direct Construction of Pyrrolocarbazaole Scaffolds via Gold-Catalyzed Cascade Cyclizations / 金触媒連続反応を用いたピロロカルバゾール骨格構築を基盤とするインドールアルカロイド類の全合成

Matsuoka, Junpei

23 March 2020

京都大学 / 0048 / 新制・課程博士 / 博士(薬学) / 甲第22405号 / 薬博第843号 / 新制||薬||241(附属図書館) / 京都大学大学院薬学研究科薬学専攻 / (主査)教授 大野 浩章, 教授 高須 清誠, 教授 竹本 佳司 / 学位規則第4条第1項該当 / Doctor of Pharmaceutical Sciences / Kyoto University / DFAM

gold catalyst

total synthesis

cascede reaction

alkyne

indole alkaloid

pyrrolocarbazaole

499

Metabolismo do alcaloide antioxidante braquicerina de Psychotria brachyceras Müll. Arg. sob estresse de calor

Magedans, Yve Verônica da Silva

January 2017

O estresse de calor prejudica o crescimento e reprodução dos organismos vegetais, ao alterar a permeabilidade de membranas biológicas e desnaturar proteínas, limitando o metabolismo primário. Dentre as respostas ao estresse abiótico, está a síntese de metabólitos secundários. Braquicerina é um alcaloide monoterpeno indólico com ação antioxidante, protetora contra UV e antimutagênica sintetizado por partes aéreas de Psychotria brachyceras. O objetivo deste trabalho é investigar o metabolismo de braquicerina sob estresse de calor. Assim, espera-se contribuir para o conhecimento acerca do metabolismo secundário nas respostas ao estresse de calor, descrever a função in planta do composto, e fornecer ferramentas para obtenção do alcaloide para fins farmacêuticos. O acúmulo de braquicerina foi induzido em discos foliares mantidos a 40ºC por três dias, tanto em regime de elevação abrupta como gradual da temperatura. Baixa temperatura (10ºC) não afetou o acúmulo do alcaloide. Discos foliares de Psychotria carthagenensis, uma espécie que não sintetiza alcaloides monoterpeno indólicos, foram também desafiados por estresse de calor. Clorofila total, teor de peróxido de hidrogênio e peroxidação lipídica foram quantificados em ambas as espécies. P. carthagenensis foi relativamente tolerante ao calor, o que pode estar relacionado à sua elevada concentração de antocianinas, fortemente induzidas por choque térmico de 50ºC por 6h. Peroxidação lipídica foi reduzida nas amostras de P. brachyceras sob estresse de calor agudo ou gradual em comparação à condição controle, sendo este parâmetro inalterado nas duas condições em P. carthagenensis. O teor de peróxido de hidrogênio foi menor em P. brachyceras submetida a choque de térmico em relação ao controle, enquanto o mesmo parâmetro não foi alterado em P. carthagenensis. Discos foliares das espécies sensíveis ao calor Brugmansia suaveolens e Brassica oleracea, pré-tratadas com braquicerina em concentrações similares às encontradas em P. brachyceras, adquiriram fenótipo tolerante ao choque térmico. A expressão do gene que codifica a enzima triptofano descarboxilase (TDC), envolvida na biossíntese de braquicerina em P. brachyceras, foi fortemente inibida em discos foliares submetidos à 40ºC por 6h, 12h e 24h, sugerindo que o efeito da temperatura na estimulação de acúmulo de alcaloide ocorra em nível pós-transcricional. Em conjunto, os dados indicam que a exposição ao calor é um meio efetivo de aumentar o rendimento de braquicerina, cuja acumulação contribui para proteção contra os danos oxidativos associados. / Heat stress impairs plant growth and reproduction by altering membrane permeability and promoting protein denaturation, which limits primary metabolism. Secondary metabolites often take part in protection against abiotic stress responses. Brachycerine is a monoterpene indole alkaloid with antioxidant, UV protectant, and antimutagenic activity synthesized by Psychotria brachyceras shoots. Brachycerine metabolism was analyzed under heat stress, in order to shed light on brachycerine‘s in planta function and to provide potential tools to improve alkaloid yields for pharmaceutical analysis. Accumulation was induced in leaf disks kept at 40ºC for three days, both by abrupt and stepwise temperature increase. Brachycerine concentration was not affected by low temperature (10ºC) exposure. Leaf disks of Psychotria carthagenensis, a species devoided of alkaloids, were also challenged by heat. Total chlorophyll, hydrogen peroxide and lipid peroxidation concentrations were determined in both species. P. carthagenensis was relatively tolerant to heat treatments which may be explained by its high anthocyanin concentration, strongly induced by heat shock of 50ºC for 6h. Brugmansia suaveolens and Brassica oleracea, pre-treated with brachycerine in concentrations equivalent to those found in P. brachyceras, had a heat shock tolerant phenotype, based on chlorophyll content. Expression of the TRYPTOPHAN DECARBOXYLASE gene, which encodes for an enzyme involved in alkaloid biosynthesis (TDC) was strongly repressed in leaf disks exposed to 40ºC for 6h, 12h e 24h, suggesting that temperature effect may occur at post-transcriptional level. Taken together, data indicate that heat exposure is an effective means to increase yields of brachycerine, whose accumulation contributes to protect against associated oxidative damage.

Braquicerina

Psychotria

Estresse oxidativo

Brachycerine

Heat stress response

Stress tolerance

Oxidative stress

Tryptophan decarboxylase

Monoterpene indole alkaloid

Psychotria

Elucidation de la voie de biosynthèse des alcaloïdes de Catharanthus roseus et ingénierie métabolique dans la levure / Elucidation of the Catharanthus roseus alkaloid pathway and metabolic engineering in yeast

Foureau, Emilien

13 June 2016

Catharanthus roseus est une plante médicinale produisant divers types d’alcaloïdes indoliques monoterpéniques (AIM) d’intérêt en santé humaine. Ainsi, les AIM dimères comme la vinblastine et la vincristine sont utilisés en chimiothérapie anticancéreuse et les alcaloïdes monomères de type hétéroyohimbine présentent diverses activités pharmacologiques. La fabrication de ces molécules dans la plante est fort complexe. Elle requiert un haut niveau de compartimentation tissulaire et subcellulaire et met en jeu plus d’une trentaine d’étapes enzymatiques, dont certaines sont encore très mal connues. Dans ce contexte, l’objectif de la thèse a consisté à élucider plusieurs étapes enzymatiques de la voie de biosynthèse des AIM. Nos travaux ont permis de caractériser de nouvelles isoformes enzymatiques de la famille des cytochromes P450 ainsi que les réductases qui leur sont associées. Ils ont abouti à l’identification de nouvelles déshydrogénases et mis en évidence, in planta, leurs interactions avec la strictosidine synthase suggérant une biosynthèse orientée vers les divers alcaloïdes de type hétéroyohimbine. Enfin, en ayant recours à l’ingénierie métabolique, un segment de la voie de biosynthèse a été transféré dans la levure Saccharomyces cerevisiae, lui conférant la capacité de bio-transformer la tabersonine en vindoline, l’un des deux précurseurs finaux des alcaloïdes dimères. / Catharanthus roseus is a medicinal plant producing various types of monoterpene indole alkaloids (MIA) with a great interest in human health. Dimeric alkaloids such as vinblastine and vincristine are used in cancer chemotherapy and monomeric heteroyohimbine alkaloids exhibit various pharmacological activities. The production of these molecules in the plant is very complex. It requires a high level of tissular and subcellular compartmentalization and involves more than thirty enzymatic steps, some of which are largely unknown. In this context, the aim of this thesis was to elucidate several enzymatic steps of the MIA biosynthetic pathway. Our work allowed us to characterize new enzyme isoforms of cytochrome P450 and their associated reductases. They also resulted in the identification of new dehydrogenases and highlighted their interactions with the strictosidine synthase suggesting a directed biosynthesis towards various heteroyohimbine type of alkaloids. Finally, engineered yeast containing a segment of the MIA biosynthetic pathway was able to convert tabersonine into vindoline, one of the two final precursors of the dimeric alkaloids.

Catharanthus roseus

Alcaloïdes indoliques monoterpéniques

Biosynthèse

Compartimentation subcellulaire

Ingénierie métabolique

Catharanthus roseus

Monoterpene indole alkaloid

Biosynthesis

Subcellular compartmentalization

Metabolic engineering

Metabolismo do alcaloide antioxidante braquicerina de Psychotria brachyceras Müll. Arg. sob estresse de calor

Magedans, Yve Verônica da Silva

January 2017

O estresse de calor prejudica o crescimento e reprodução dos organismos vegetais, ao alterar a permeabilidade de membranas biológicas e desnaturar proteínas, limitando o metabolismo primário. Dentre as respostas ao estresse abiótico, está a síntese de metabólitos secundários. Braquicerina é um alcaloide monoterpeno indólico com ação antioxidante, protetora contra UV e antimutagênica sintetizado por partes aéreas de Psychotria brachyceras. O objetivo deste trabalho é investigar o metabolismo de braquicerina sob estresse de calor. Assim, espera-se contribuir para o conhecimento acerca do metabolismo secundário nas respostas ao estresse de calor, descrever a função in planta do composto, e fornecer ferramentas para obtenção do alcaloide para fins farmacêuticos. O acúmulo de braquicerina foi induzido em discos foliares mantidos a 40ºC por três dias, tanto em regime de elevação abrupta como gradual da temperatura. Baixa temperatura (10ºC) não afetou o acúmulo do alcaloide. Discos foliares de Psychotria carthagenensis, uma espécie que não sintetiza alcaloides monoterpeno indólicos, foram também desafiados por estresse de calor. Clorofila total, teor de peróxido de hidrogênio e peroxidação lipídica foram quantificados em ambas as espécies. P. carthagenensis foi relativamente tolerante ao calor, o que pode estar relacionado à sua elevada concentração de antocianinas, fortemente induzidas por choque térmico de 50ºC por 6h. Peroxidação lipídica foi reduzida nas amostras de P. brachyceras sob estresse de calor agudo ou gradual em comparação à condição controle, sendo este parâmetro inalterado nas duas condições em P. carthagenensis. O teor de peróxido de hidrogênio foi menor em P. brachyceras submetida a choque de térmico em relação ao controle, enquanto o mesmo parâmetro não foi alterado em P. carthagenensis. Discos foliares das espécies sensíveis ao calor Brugmansia suaveolens e Brassica oleracea, pré-tratadas com braquicerina em concentrações similares às encontradas em P. brachyceras, adquiriram fenótipo tolerante ao choque térmico. A expressão do gene que codifica a enzima triptofano descarboxilase (TDC), envolvida na biossíntese de braquicerina em P. brachyceras, foi fortemente inibida em discos foliares submetidos à 40ºC por 6h, 12h e 24h, sugerindo que o efeito da temperatura na estimulação de acúmulo de alcaloide ocorra em nível pós-transcricional. Em conjunto, os dados indicam que a exposição ao calor é um meio efetivo de aumentar o rendimento de braquicerina, cuja acumulação contribui para proteção contra os danos oxidativos associados. / Heat stress impairs plant growth and reproduction by altering membrane permeability and promoting protein denaturation, which limits primary metabolism. Secondary metabolites often take part in protection against abiotic stress responses. Brachycerine is a monoterpene indole alkaloid with antioxidant, UV protectant, and antimutagenic activity synthesized by Psychotria brachyceras shoots. Brachycerine metabolism was analyzed under heat stress, in order to shed light on brachycerine‘s in planta function and to provide potential tools to improve alkaloid yields for pharmaceutical analysis. Accumulation was induced in leaf disks kept at 40ºC for three days, both by abrupt and stepwise temperature increase. Brachycerine concentration was not affected by low temperature (10ºC) exposure. Leaf disks of Psychotria carthagenensis, a species devoided of alkaloids, were also challenged by heat. Total chlorophyll, hydrogen peroxide and lipid peroxidation concentrations were determined in both species. P. carthagenensis was relatively tolerant to heat treatments which may be explained by its high anthocyanin concentration, strongly induced by heat shock of 50ºC for 6h. Brugmansia suaveolens and Brassica oleracea, pre-treated with brachycerine in concentrations equivalent to those found in P. brachyceras, had a heat shock tolerant phenotype, based on chlorophyll content. Expression of the TRYPTOPHAN DECARBOXYLASE gene, which encodes for an enzyme involved in alkaloid biosynthesis (TDC) was strongly repressed in leaf disks exposed to 40ºC for 6h, 12h e 24h, suggesting that temperature effect may occur at post-transcriptional level. Taken together, data indicate that heat exposure is an effective means to increase yields of brachycerine, whose accumulation contributes to protect against associated oxidative damage.

Braquicerina

Psychotria

Estresse oxidativo

Brachycerine

Heat stress response

Stress tolerance

Oxidative stress

Tryptophan decarboxylase

Monoterpene indole alkaloid

Psychotria

Metabolismo do alcaloide antioxidante braquicerina de Psychotria brachyceras Müll. Arg. sob estresse de calor

Magedans, Yve Verônica da Silva

January 2017

O estresse de calor prejudica o crescimento e reprodução dos organismos vegetais, ao alterar a permeabilidade de membranas biológicas e desnaturar proteínas, limitando o metabolismo primário. Dentre as respostas ao estresse abiótico, está a síntese de metabólitos secundários. Braquicerina é um alcaloide monoterpeno indólico com ação antioxidante, protetora contra UV e antimutagênica sintetizado por partes aéreas de Psychotria brachyceras. O objetivo deste trabalho é investigar o metabolismo de braquicerina sob estresse de calor. Assim, espera-se contribuir para o conhecimento acerca do metabolismo secundário nas respostas ao estresse de calor, descrever a função in planta do composto, e fornecer ferramentas para obtenção do alcaloide para fins farmacêuticos. O acúmulo de braquicerina foi induzido em discos foliares mantidos a 40ºC por três dias, tanto em regime de elevação abrupta como gradual da temperatura. Baixa temperatura (10ºC) não afetou o acúmulo do alcaloide. Discos foliares de Psychotria carthagenensis, uma espécie que não sintetiza alcaloides monoterpeno indólicos, foram também desafiados por estresse de calor. Clorofila total, teor de peróxido de hidrogênio e peroxidação lipídica foram quantificados em ambas as espécies. P. carthagenensis foi relativamente tolerante ao calor, o que pode estar relacionado à sua elevada concentração de antocianinas, fortemente induzidas por choque térmico de 50ºC por 6h. Peroxidação lipídica foi reduzida nas amostras de P. brachyceras sob estresse de calor agudo ou gradual em comparação à condição controle, sendo este parâmetro inalterado nas duas condições em P. carthagenensis. O teor de peróxido de hidrogênio foi menor em P. brachyceras submetida a choque de térmico em relação ao controle, enquanto o mesmo parâmetro não foi alterado em P. carthagenensis. Discos foliares das espécies sensíveis ao calor Brugmansia suaveolens e Brassica oleracea, pré-tratadas com braquicerina em concentrações similares às encontradas em P. brachyceras, adquiriram fenótipo tolerante ao choque térmico. A expressão do gene que codifica a enzima triptofano descarboxilase (TDC), envolvida na biossíntese de braquicerina em P. brachyceras, foi fortemente inibida em discos foliares submetidos à 40ºC por 6h, 12h e 24h, sugerindo que o efeito da temperatura na estimulação de acúmulo de alcaloide ocorra em nível pós-transcricional. Em conjunto, os dados indicam que a exposição ao calor é um meio efetivo de aumentar o rendimento de braquicerina, cuja acumulação contribui para proteção contra os danos oxidativos associados. / Heat stress impairs plant growth and reproduction by altering membrane permeability and promoting protein denaturation, which limits primary metabolism. Secondary metabolites often take part in protection against abiotic stress responses. Brachycerine is a monoterpene indole alkaloid with antioxidant, UV protectant, and antimutagenic activity synthesized by Psychotria brachyceras shoots. Brachycerine metabolism was analyzed under heat stress, in order to shed light on brachycerine‘s in planta function and to provide potential tools to improve alkaloid yields for pharmaceutical analysis. Accumulation was induced in leaf disks kept at 40ºC for three days, both by abrupt and stepwise temperature increase. Brachycerine concentration was not affected by low temperature (10ºC) exposure. Leaf disks of Psychotria carthagenensis, a species devoided of alkaloids, were also challenged by heat. Total chlorophyll, hydrogen peroxide and lipid peroxidation concentrations were determined in both species. P. carthagenensis was relatively tolerant to heat treatments which may be explained by its high anthocyanin concentration, strongly induced by heat shock of 50ºC for 6h. Brugmansia suaveolens and Brassica oleracea, pre-treated with brachycerine in concentrations equivalent to those found in P. brachyceras, had a heat shock tolerant phenotype, based on chlorophyll content. Expression of the TRYPTOPHAN DECARBOXYLASE gene, which encodes for an enzyme involved in alkaloid biosynthesis (TDC) was strongly repressed in leaf disks exposed to 40ºC for 6h, 12h e 24h, suggesting that temperature effect may occur at post-transcriptional level. Taken together, data indicate that heat exposure is an effective means to increase yields of brachycerine, whose accumulation contributes to protect against associated oxidative damage.

Braquicerina

Psychotria

Estresse oxidativo

Brachycerine

Heat stress response

Stress tolerance

Oxidative stress

Tryptophan decarboxylase

Monoterpene indole alkaloid

Psychotria

TRANSCRIPTOMIC ANALYSES OF <em>CATHATRANTHUS ROSEUS</em> HAIRY ROOTS OVEREXPRESSING CRMYC2 AND ORCA3 AND ROLES OF CROSS-FAMILY TRANSCRIPTION FACTOR INTERACTION IN TERPENOID INDOLE ALKALOID BIOSYNTHESIS

Sui, Xueyi

01 January 2017

Catharanthus roseus (Madagascar periwinkle), is a well-known medicinal plant that produces a vast array of terpenoid indole alkaloids (TIAs), including two anticancer compounds vinblastine and vincristine. Industrial scale production of TIAs is hampered by the difficulties of total chemical synthesis of these compounds and the fragmented knowledge on TIA pathway. Transcriptional regulation of the TIA biosynthetic pathway has not been thoroughly investigated in Catharanthus and only a few structural genes have been identified as the targets of two master regulators: the basic helix-loop-helix (bHLH) transcription factor (TF) CrMYC2 and APETALA2/ETHYLENE RESPONSE FACTOR (AP2/ERF), ORCA3. Next generation sequencing (NGS) has been used as a tool to isolate novel genes encoding enzymes and regulators of TIA pathway in Catharanthus. In this dissertation, I have performed the transcriptomic analysis of transgenic Catharanthus hairy roots ectopically expressing a dominant repressive form of CrMYC2 or ORCA3 in order to understand their potential impact on the TIA transcriptional regulatory network and to identify and characterize novel target(s) of these two key TFs. MYC2 acts as regulatory hub involved in diverse aspects of plant growth, development, and specialized metabolite biosynthesis by coordinating the crosstalk among different phytohormone signals. CrMYC2 was initially identified in Catharanthus as a regulator of ORCA3. CrMYC2 transactivates ORCA3 by binding to the T/G-box in jasmonate-responsive element (JRE) of ORCA3 promoter. RNA interference (RNAi) mediated knockdown of CrMYC2 strongly reduced TIA accumulation in Catharanthus cell suspension culture. However, the potential influence of CrMYC2 on the expression of other regulatory and structural genes in the TIA pathway remains poorly understood. Transcriptomic analyses revealed that CrMYC2 plays an essential role in JA-induced gene expression and the differentially expressed genes are involved in diverse aspects of growth and development as well as abiotic and biotic stress responses in Catharanthus. Additionally, the expression of genes related to auxin, ethylene, and abscisic acid signaling cascades were affected in hairy roots with modified CrMYC2 expression, suggesting this TF mediates cross-talk between JA and other phytohormones. Surprisingly, overexpression of CrMYC2 resulted in repressed expression of TIA pathway genes in transgenic hairy roots. Expressions of key activators of indole and iridoid pathway were downregulated whereas expression of repressors were upregulated in CrMYC2 hairy roots. Activators (i.e. CrMYC2 and ORCA3) and repressors (i.e. G-box binding factors; GBFs) have been isolated and characterized for their role in regulation of TIA pathway. However, the interconnection between those regulators and the underlying molecular mechanism has not been throughly studied. I identified (i) the interaction of CrMYC2 with CrGBFs and (ii) how this cross-family transcription factor interactions fine-tunes TIA biosynthesis in Catharanthus. The expression profiles of CrMYC2 and CrGBFs were highly correlated in different tissues and in response JA. Moreover, CrMYC2 interacted with CrGBF1 and CrGBF2 in both yeast and plant cells. CrGBF1 and CrGBF2 could form homo- and hetero-dimer which bound T/G-box elements of TIA pathway gene promoters. In plant cells, CrGBF1 antagonizes the activity of CrMYC2 on target promoters in a dosage dependent-manner. Similarly, CrMYC2 can overcome CrGBF1-mediated repression of target promoters in a dosage dependent manner. ORCA3 is another major regulator of TIA biosynthesis in Catharanthus. The transcriptomic analysis of ORCA3 transgenic hairy roots revealed (i) the effect of ORCA3 on newly identified TIA pathway biosynthetic enzymes; (ii) identify the potential effect of ORCA3 on three biological processes: abiotic stress response, plant secondary metabolic process, and response to hormonal stimulus; and (iii) the identification of potential regulator(s) of TIA biosynthesis using ORCA3 based co-expression analysis.

Transcriptomic analysis

CrMYC2

ORCA3

Transcriptional regulation

Terpenoid indole alkaloid pathway

Catharanthus roseus

Bioinformatics

Biotechnology

Molecular Biology

Molecular Genetics