Organisation cellulaire et subcellulaire de la voie de biosynthèse des alcaloïdes indoliques monoterpéniques de Catharantus roseus. / Cellular and subcellular organization of the monoterpene indole alkaloids biosynthetic pathway in Catharantus roseus

Guirimand, Grégory

27 June 2011

Catharanthus roseus est une plante tropicale de la famille des Apocynacées d’intérêt thérapeutique en raison de sa capacité à synthétiser des alcaloïdes indoliques monoterpéniques (AIM) utilisés en chimiothérapie anticancéreuse. La teneur en AIM in planta est très faible notamment en raison d’une haute compartimentalisation cellulaire et subcellulaire de la voie de biosynthèse. Si la compartimentalisation cellulaire était bien caractérisée, très peu de données de localisation subcellulaire in situ étaient disponibles au début de cette thèse. Une connaissance fine de cette compartimentalisation est cependant nécessaire pour identifier les transports inter-compartiment de métabolites intermédiaires, limitant potentiellement le flux métabolique, afin d’améliorer ensuite le rendement de biosynthèse des AIM par ingénierie métabolique. Dans ce contexte nous avons réalisé une étude exhaustive de la localisation subcellulaire des enzymes de cette voie par imagerie GFP dans des cellules de C. roseus transformées par biolistique permettant d’établir un nouveau modèle intégré d’organisation cellulaire et subcellulaire de la biosynthèse des AIM. / Catharanthus roseus is a tropical plant from the Apocynaceae family with a great therapeutic value due to its ability to synthesize monoterpene indole alkaloids (MIA) used in cancer treatment. The yields of these molecules in planta are very low due to a very high level of compartmentation of the biosynthetic pathway at both cellular and subcellular levels. While the cellular compartmentation was widely characterized, very few in situ subcellular localization data were available at the beginning of this PhD. An accurate knowledge of this compartmentation is necessary to identify intermediate metabolites transport events from one compartment to another one, in order to increase the MIA biosynthesis yield by metabolic engineering approaches. In this context we have proceed to the exhaustive study of the subcellular localization of these enzymes by in vivo GFP imaging in C. roseus cells transformed by biolistic. Potential interprotein interactions of these enzymes have also been studied by BiFC. Altogether, our results enabled us to draw an integrated model of the cellular and subcellular organization of MIA biosynthesis in situ.

Alcaloïdes indoliques monoterpéniques

Imagerie GFP

BiFC

Monoterpene indole alkaloid

Terpenoid

MEP

Biolistic

GFP Imaging

BiFC

Metabolic engineering

CHARACTERIZATION OF <i>G10H</i> PROMOTER AND ISOLATION OF WRKY TRANSCRIPTION FACTORS INVOLVED IN <i>CATHARANTHUS</i> TERPENOID INDOLE ALKALOID BIOSYNTHESIS PATHWAY

Suttpanta, Nitima

01 January 2011

Catharanthus roseus produces a large array of terpenoid indole alkaloids (TIAs) that are an important source of natural or semi-synthetic anticancer drugs. Biosynthesis of TIAs is tissue-specific and induced by certain phytohormones and fungal elicitors, indicating the involvement of a complex transcriptional control network. However, the transcriptional regulation of the TIA pathway is poorly understood. This study reports the isolation and characterization of the G10H promoter and two WRKY transcription factors regulating TIA biosynthesis. Geraniol 10-hydroxylase (G10H) controls the first committed step in the biosynthesis of terpenoid indole alkaloids (TIA). The C. roseus G10H promoter sequence was isolated by a PCR-based genome walking method. Sequence analysis revealed that the G10H promoter contains several potential eukaryotic regulatory elements involved in regulation of gene expression. For functional characterization, fusion constructs of G10H promoter fragments with the GUS reporter gene were generated and expression was analyzed in a tobacco protoplast transient expression assay. Gain-of-function experiments revealed the presence of three potential transcriptional enhancers located in regions between -191 and -147, -266 and -188, and -318 and -266, respectively. The G10H promoter was capable of conferring stable GUS expression in transgenic tobacco plants and C. roseus hairy roots. In transgenic tobacco seedlings, GUS expression was tissue-specific, restricted to the leaf and actively growing cells around the root tip. GUS expression was not detected in the hypocotyls, root cap and older developing areas of the root. The GUS expression in both transgenic C. roseus hairy roots and tobacco seedlings were responsive to fungal elicitors and methyljasmonate. Compared to other known promoters of TIA pathway genes, the G10H promoter contains unique binding sites for several transcription factors, suggesting that the G10H promoter may be regulated by a different transcriptional cascade. The majority of TIA pathway gene promoters contain typical W-box elements, which are frequently found to be the binding sites of WRKY transcription factors. CrWRKY1 and CrWRKY2 transcription factors were isolated using a degenerate PCR method. The C. roseus WRKY transcription factor, CrWRKY1 is preferentially expressed in roots and induced by phytohormones, jasmonate, gibberellic acid and ethylene. Overexpression of CrWRKY1 in C. roseus hairy roots up-regulated several key TIA pathway genes, especially tryptophan decarboxylase (TDC), as well as transcriptional repressors ZCT1, ZCT2 and ZCT3. In contrast, CrWRKY1 overexpression repressed the transcriptional activators ORCA2, ORCA3 and CrMYC2. Overexpression of a dominant-repressive form of CrWRKY1, created by fusing the SRDX-repressor domain to CrWRKY1, resulted in down-regulation of TDC and ZCTs but up-regulation of ORCA3 and CrMYC2. CrWRKY1 bound to the W-box elements of the TDC promoter in electrophoretic mobility shift, yeast one-hybrid and C. roseus protoplast assays. In CrWRKY1 hairy roots, up-regulation of TDC increased TDC activity, tryptamine concentration and resistance to 4-methyl tryptophan inhibition. Compared to control roots, CrWRKY1 hairy roots accumulated up to 3-fold higher levels of serpentine. The preferential expression of CrWRKY1 in roots and its interaction with transcription factors, including ORCA3, CrMYC2 and ZCTs, may play a key role in determining the root-specific accumulation of serpentine in C. roseus plants. CrWRKY2 is induced by methyljasmonate induction. In plant, CrWRKY2 expression is mainly found in young leaves and the stem. The stable transformation of CrWRKY2 in C. roseus hairy roots up-regulated many pathway genes, especially the genes in vindoline biosynthesis. The accumulation of vindoline was observed in CrWRKY2 hairy roots.

Terpenoid indole alkaloid biosynthesis

Catharanthus roseus

WRKY transcription factors

G10H promoter analysis

Molecular Biology

Plant Biology

Plant Sciences

Marine natural products as antimicrobial chemical defenses and sources of potential drugs

Lane, Amy L.

11 November 2008

Marine organisms are widely recognized sources of an impressive array of structurally unusual compounds. Marine natural products have exhibited interesting biomedical activities, provided targets for synthetic organic chemists, and afforded opportunities for elucidation of enzymatic mechanisms involved in biosyntheses of these molecules. Secondary metabolite pathways probably evolved to mediate interactions between organisms in their natural habitats; however, the ecological functions of natural products remain poorly understood for the vast majority of cases. In the present series of investigations, I evaluate the hypothesis that macroalgal natural products play a role in defending these organisms against potentially pathogenic microbes in the marine environment. Further, I combine these ecology-driven investigations with evaluation of algal natural products as sources of novel human drugs. This combined approach resulted in discovery of 15 novel natural products from two tropical red algae, Callophycus serratus and an unidentified crustose red alga. These new molecules included seven novel carbon-carbon connectivity patterns, not previously reported in the synthetic or natural product literature, illustrating the abundance of secondary metabolite diversity among marine macroalgae. Further, many compounds exhibited both biomedical and ecological activities, suggesting the synergistic potential of combined biomedical/ecological investigations in providing drug leads as well as insights into the natural functions of secondary metabolites. Bromophycolides and callophycoic acids, natural products from C. serratus, inhibited growth of the marine fungal pathogen Lindra thalassiae. Spatially-resolved desorption ionization mass spectrometry (DESI-MS) revealed that antifungal natural products were found at specific sites on algal surfaces. The heterogeneous presentation of antimicrobial chemical defenses on host surfaces suggests the potential importance of spatial scale in understanding host-pathogen interactions, and illustrates the capacity of mass spectrometry imaging in understanding chemically-mediated biological processes. Finally, assessment of antimicrobial chemical defenses among extracts from 72 collections of tropical red algae revealed that nearly all algae were defended against at least one marine pathogen or saprophyte and further suggested the untapped potential of ecological investigations in the discovery of novel chemistry.

Chemical defense

Natural product

Chemical ecology

Shikimate

Terpenoid

NMR

DESI-MS

Algae

Antimicrobial

Drug discovery

Marine

Marine natural products

Pharmacognosy

Anti-infective agents

The chemistry of Salvia divinorum

Munro, Thomas Anthony

Unknown Date

Salvia divinorum is a hallucinogenic sage used to treat illness by the Mazatec Indians of Mexico. Salvinorin A (1a), a neoclerodane diterpenoid isolated from the plant, is a potent, selective agonist at the kappa opioid receptor (KOR), and is the first non-nitrogenous opioid. The plant is used recreationally as a hallucinogen, but is unpopular due to its dysphoric effects. 1a has been prohibited in Australia under an invalid systematic name. An early report of psychoactive alkaloids in S. divinorum proved to be irreproducible. Similarly, tests in mice suggesting the presence of psychoactive compounds other than 1a were confounded and therefore unreliable. In this work, an improved isolation method for 1a was developed, using filtration through activated carbon to decolourise the crude extract. Six new diterpenoids were isolated: salvinorins D–F (1d–1f) and divinatorins A–C (28a–28c). Five known terpenoids not previously reported from this species were also isolated. The structure–activity relationships of 1a were evaluated via selective modifications of each functional group. Useful synthetic methods are reviewed, including the first thorough review of furanolactone hydrogenations. Testing of the derivatives at the KOR suggests that the methyl ester and furan ring of 1a are required for activity, but that the lactone and ketone functionalities are not. Other compounds from S. divinorum did not bind to the KOR, suggesting that 1a is the plant’s active principle.

Sclareol biosynthesis in clary sage and its regulation / Biosynthèse du sclaréol et sa régulation chez la sauge sclarée

Chalvin, Camille

12 July 2019

Le sclaréol est un diterpène produit par les organes floraux de la sauge sclarée (Salvia sclarea, Lamiaceae). Il est utilisé en parfumerie pour l’hémisynthèse de l’ambroxide, une substance caractérisée par une odeur ambrée et une grande capacité de fixation des parfums. L’augmentation de la demande mondiale en sclaréol stimule actuellement les tentatives d’accroître le rendement de la production de sclaréol à partir de la sauge sclarée. L’objectif du travail présenté dans ce manuscrit était d’améliorer notre compréhension de la biosynthèse du sclaréol et de sa régulation chez la sauge sclarée, afin de mettre en évidence des stratégies d’augmentation du contenu en sclaréol de la sauge sclarée. L'analyse de la surface des calices de sauge sclarée par imagerie par spectrométrie de masse suggère que le sclaréol est principalement sécrété par des structures épidermiques spécialisées appelées trichomes glandulaires. De plus, nous avons mis en évidence les contributions respectives des deux voies de biosynthèse des terpènes présentes chez les plantes, les voies MVA et MEP, à la biosynthèse de trois terpènes de la sauge sclarée. Des expériences de marquage au ¹³C indiquent que le sclaréol et l’acétate de linalyle sont tous deux issus de la voie MEP, alors que le β-caryophyllène semble être d’origine mixte. Nous avons également étudié le rôle potentiel d’une phytohormone, le méthyljasmonate, dans la régulation de la production de sclaréol chez la sauge sclarée. Enfin, nous avons exploré la diversité génétique et phénotypique de populations croates de sauge sclarée sauvage, et montrons que ces populations représentent une ressource génétique distincte par rapport aux populations de référence. L’ensemble de ces résultats met en évidence des pistes prometteuses pour l'amélioration génétique ciblée des performances de la sauge sclarée. / Sclareol is a diterpene produced by floral organs of clary sage (Salvia sclarea, Lamiaceae). It is used in perfume industry for the hemisynthesis of ambroxide, a high-valued perfume component characterized by an amber scent and a high perfume fixation capacity. The global demand for sclareol currently rises, prompting attempts at increasing the yield of sclareol production from clary sage. The purpose of the work presented in this manuscript was to improve knowledge on sclareol biosynthesis and its regulation in clary sage, in order to highlight strategies aiming at enhancing clary sage sclareol content. The analysis of the surface of clary sage calyces by mass spectrometry imaging suggests that sclareol is mainly secreted by specialized epidermal structures called glandular trichomes. Moreover, we have highlighted the respective contributions of the two terpenoid biosynthesis pathways present in plants, MVA and MEP pathways, to the biosynthesis of three terpenoids of clary sage. ¹³C-labeling experiments indicate that sclareol and linalyl acetate both originate from the MEP pathway, whereas β-caryophyllene seems to be of mixed origin. We have also investigated the potential role of a phytohormone, methyljasmonate, in the regulation of sclareol production in clary sage. Finally, we have explored the genetic and phenotypic diversity of Croatian wild clary sage populations and show that these populations represent a distinct genetic resource compared to reference populations. Taken together, these results highlight promising avenues for targeted genetic enhancement of clary sage performances.

Biologie des plantes

Terpène

Ingénierie métabolique

Sauge sclarée

Sclaréol

Métabolisme spécialisé des plantes

Plant biology

Terpenoid

Metabolic engineering

Clary sage

Sclareol

Plant specialized metabolism

Fixation, Partitioning and Export of Carbon in two Species of the Plantaginaceae

Szucs, Ildiko

05 April 2013

During photosynthesis Plantaginaceae species can produce glucose derivatives such as iridoid glycosides and alcohol sugars that in addition to sucrose can be exported from leaves. Plantago lanceolata transported sorbitol in addition to sucrose especially at warmer leaf temperatures. However, two iridoids, catalpol and aucubin, found in P. lanceolata were not readily labelled from 14CO2 under any conditions examined. In contrast, in two greenhouse, cut-flower cultivars of Antirrhinum majus the iridoids, antirrhinoside and antirrhide, were readily 14C-labelled along with sucrose but little 14C was recovered in alcohol sugars (e.g., mannitol). The amount of 14C-partitioned into antirrhinoside increased at higher temperatures. Exposing leaves of P. lanceolata and A. majus to reduced-photorespiratory conditions (e.g. short-term CO2 enrichment and/or low O2) increased fixation and export. Under low O2 in P. lanceolata sorbitol 14C-labelling increased relative to sucrose and in A. majus 14C-labelling of sucrose increased relative to antirrhinoside. Also 14C-labelling of antirrhide increased more than antirrhinoside. During both short-term and long-term acclimation to high CO2, whole plant NCER, leaf photosynthesis and export increased in A. majus. Taken together the temperature and CO2 enrichment studies show plasticity in Plantaginaceae species to synthesize and transport sucrose and auxiliary glucose esters and alcohol sugars in a species-specific manner (depending on the rate of carboxylation).

Iridoid

glycoside

terpenoid

terpene

monoterpene

Antirrhinum majus

Plantago lanceolata

Plantaginaceae

whole plant

photosynthesis

reduced photorespiratory

low O2

elevated CO2

CO2

14CO2

14C-labelling

14C-partitioning

temperature

alcohol sugar

sorbitol

mannitol

snapdragon

aucubin

catalpol

antirrhide

antirrhinoside

leaf

long term

short term

export

phloem

partitioning

glucose derivative

gas exchange