Sébastien Besseau

Defense-related transcription factors WRKY70 and WRKY54 modulate osmotic stress tolerance by regulating stomatal aperture in Arabidopsis

WRKY transcription factors (TFs) have been mainly associated with plant defense, but recent studies have suggested additional roles in the regulation of other physiological processes. Here, we explored the possible contribution of two related group III WRKY TFs, WRKY70 and WRKY54, to osmotic stress tolerance. These TFs are positive regulators of plant defense, and co-operate as negative regulators of salicylic acid (SA) biosynthesis and senescence. We employed single and double mutants of wrky54 and wrky70, as well as a WRKY70 overexpressor line, to explore the role of these TFs in osmotic stress (polyethylene glycol) responses. Their effect on gene expression was characterized by microarrays and verified by quantitative PCR. Stomatal phenotypes were assessed by water retention and stomatal conductance measurements. The wrky54wrky70 double mutants exhibited clearly enhanced tolerance to osmotic stress. However, gene expression analysis showed reduced induction of osmotic stress-responsive genes in addition to reduced accumulation of the osmoprotectant proline. By contrast, the enhanced tolerance was correlated with improved water retention and enhanced stomatal closure. These findings demonstrate that WRKY70 and WRKY54 co-operate as negative regulators of stomatal closure and, consequently, osmotic stress tolerance in Arabidopsis, suggesting that they have an important role, not only in plant defense, but also in abiotic stress signaling.

A pair of tabersonine 16-hydroxylases initiates the synthesis of vindoline in an organ dependent manner in Catharanthus roseus

A newly identified cytochrome P450 isoform initiates the synthesis of valuable alkaloids in leaves of Catharanthus roseus by hydroxylating tabersonine. Hydroxylation of tabersonine at the C-16 position, catalyzed by tabersonine 16-hydroxylase (T16H), initiates the synthesis of vindoline that constitutes the main alkaloid accumulated in leaves of Catharanthus roseus. Over the last decade, this reaction has been associated with CYP71D12 cloned from undifferentiated C. roseus cells. In this study, we isolated a second cytochrome P450 (CYP71D351) displaying T16H activity. Biochemical characterization demonstrated that CYP71D12 and CYP71D351 both exhibit high affinity for tabersonine and narrow substrate specificity, making of T16H, to our knowledge, the first alkaloid biosynthetic enzyme displaying two isoforms encoded by distinct genes characterized to date in C. roseus. However, both genes dramatically diverge in transcript distribution in planta. While CYP71D12 (T16H1) expression is restricted to flowers and undifferentiated cells, the CYP71D351 (T16H2) expression profile is similar to the other vindoline biosynthetic genes reaching a maximum in young leaves. Moreover, transcript localization by carborundum abrasion and RNA in situ hybridization demonstrated that CYP71D351 messenger RNAs are specifically located to leaf epidermis, which also hosts the next step of vindoline biosynthesis. Comparison of high- and low-vindoline-accumulating C. roseus cultivars also highlights the direct correlation between CYP71D351 transcript and vindoline levels. In addition, CYP71D351 down-regulation mediated by virus-induced gene silencing reduces vindoline accumulation in leaves and redirects the biosynthetic flux toward the production of unmodified alkaloids at the C-16 position. All these data demonstrate that tabersonine 16-hydroxylation is orchestrated in an organ-dependent manner by two genes including CYP71D351, which encodes the specific T16H isoform acting in the foliar vindoline biosynthesis.

Antifungal Activity of Resveratrol Derivatives against Candida Species

trans-Resveratrol (1a) is a phytoalexin produced by plants in response to infections by pathogens. Its potential activity against clinically relevant opportunistic fungal pathogens has previously been poorly investigated. Evaluated herein are the candidacidal activities of oligomers (2a, 3-5) of 1a purified from Vitis vinifera grape canes and several analogues (1b-1j) of 1a obtained through semisynthesis using methylation and acetylation. Moreover, trans-ε-viniferin (2a), a dimer of 1a, was also subjected to methylation (2b) and acetylation (2c) under nonselective conditions. Neither the natural oligomers of 1a (2a, 3-5) nor the derivatives of 2a were active against Candida albicans SC5314. However, the dimethoxy resveratrol derivatives 1d and 1e exhibited antifungal activity against C. albicans with minimum inhibitory concentration (MIC) values of 29-37 μg/mL and against 11 other Candida species. Compound 1e inhibited the yeast-to-hyphae morphogenetic transition of C. albicans at 14 μg/mL.

Biosynthetic Origin of E-Resveratrol Accumulation in Grape Canes during Postharvest Storage

Grape canes are vineyard waste products containing valuable phytochemicals of medicine and agriculture interest. Grape canes storage is critical for the accumulation of these bioactive compounds. In the present study, we investigated the changes in stilbenoid phytochemical composition during grape cane storage and the influence of the temperature on final concentrations. A strong increase in the concentration of the monomer E-resveratrol (approximately 40-fold) was observed during the first 6 weeks of storage at 20 °C in eight different grape varieties without any change in oligomer concentrations. The E-resveratrol accumulation was temperature-dependent with an optimal range at 15-20 °C. A 2 h heat-shock treatment aiming at protein denaturation inhibited E-resveratrol accumulation. The constitutive expression of key genes involved in the stilbene precursor biosynthesis along with an induction of stilbene synthase (STS) expression during the first weeks of storage contribute to a de novo biosynthesis of E-resveratrol in pruned wood grapes.

Deciphering the Evolution, Cell Biology and Regulation of Monoterpene Indole Alkaloids

Monoterpene indole alkaloids (MIAs) constitute a large group of specialised metabolites with many potent pharmaceutical properties, including the antitumoral vinblastine and hypotensive ajmalicine. Hence a large body of phytochemical investigation delineates the distribution and diversity of various MIA structural classes in Gentianales families. The biosynthetic pathway of these secondary metabolites involves several specific branches, including indole and monoterpenoid formations, secoiridoid assembly, central MIA biosynthesis and branch-specific reactions, as well as supply of primary metabolite precursors by the methylerythritol phosphate and shikimate pathways. Several genes and enzymatic activities involved in these pathways have been characterised, allowing detailed analysis of the molecular biology of this system in model plants such as Catharanthus roseus and Rauvolfia serpentina. With the prospects of improving production of MIAs in plant and cell culture, regulations of biosynthetic capacities have been thoroughly investigated. This pathway also presents a high degree of spatial organisation at the organ, cellular and subcellular levels. This chapter presents an overview of the structural diversity, the complexity of MIA biosynthesis, and regulation with an evolutionary perspective.

Subcellular localization of the histidine kinase receptors Sln1p, Nik1p and Chk1p in the yeast CTG clade species Candida guilliermondii.

Fungal histidine kinase receptors (HKR) sense and transduce many intra- and extracellular signals that regulate a wide range of physiological processes. Candida CTG clade species commonly possess three types of HKR namely Sln1p (type VI), Nik1p (type III) and Chk1p (type X). Although some recent work has demonstrated the potential involvement of HKR in osmoregulation, morphogenesis, sexual development, adaptation to osmotic stresses and drug resistance in distinct Candida species, little data is available in relation to their subcellular distribution within yeast cells. We describe in this work the comparative subcellular localization of class III, VI, and X HKRs in Candida guilliermondii, a yeast CTG clade species of clinical and biotechnological interest. Using a fluorescent protein fusion approach, we showed that C. guilliermondii Sln1p fused to the yellow fluorescent protein (Sln1p-YFP) appeared to be anchored in the plasma membrane. By contrast, both Chk1p-YFP and YFP-Chk1p were localized in the nucleocytosol of C. guilliermondii transformed cells. Furthermore, while Nik1p-YFP fusion protein always displayed a nucleocytosolic localization, we noted that most of the cells expressing YFP-Nik1p fusion protein displayed an aggregated pattern of fluorescence in the cytosol but not in the nucleus. Interestingly, Sln1p-YFP and Nik1p-YFP fusion protein localization changed in response to hyperosmotic stress by rapidly clustering into punctuated structures that could be associated to osmotic stress signaling. To date, this work provides the first insight into the subcellular localization of the three classes of HKR encoded by CTG clade yeast genomes and constitutes original new data concerning this family of receptors. This represents also an essential prerequisite to open a window into the understanding of the global architecture of HKR-mediated signaling pathways in CTG clade species.

A TRP5/5-fluoroanthranilic acid counter-selection system for gene disruption in Candida guilliermondii

Candida guilliermondii is an interesting biotechnological model for the industrial production of value-added metabolites and also remains an opportunistic emerging fungal agent of candidiasis often associated with oncology patients. The aim of the present study was to establish a convenient transformation system for C. guilliermondii by developing both an ATCC 6260-derived recipient strain and a recyclable selection marker. We first disrupted the TRP5 gene in the wild-type strain and demonstrated that trp5 mutants were tryptophan auxotroph as well as being resistant to the antimetabolite 5-fluoroanthranilic acid (FAA). Following an FAA selection of spontaneous mutants derived from the ATCC 6260 strain and complementation analysis, we demonstrated that trp5 genotypes could be directly recovered on FAA-containing medium. The TRP5 wild-type allele, flanked by two short repeated sequences of its 3′UTR, was then used to disrupt the FCY1 gene in C. guilliermondii trp5 recipient strains. The resulting fcy1 mutants displayed strong flucytosine resistance and a counter-selection on FAA allowed us to pop-out the TRP5 allele from the FCY1 locus. To illustrate the capacity of this blaster system to achieve a second round of gene disruption, we knocked out both the LEU2 and the HOG1 genes in the trp5,fcy1 background. Although all previously described yeast “TRP blaster” disruption systems used TRP1 as counter-selectable marker, this study demonstrated the potential of the TRP5 gene in such strategies. This newly created “TRP5 blaster” disruption system thus represents a powerful genetic tool to study the function of a large pallet of genes in C. guilliermondii.

Characterization of a spermidine hydroxycinnamoyltransferase in Malus domestica highlights the evolutionary conservation of trihydroxycinnamoyl spermidines in pollen coat of core Eudicotyledons

Phenolamides, so called hydroxycinnamic acid amides, are specialized metabolites produced in higher plants, involved in development, reproduction and serve as defence compounds in biotic interactions. Among them, trihydroxycinnamoyl spermidine derivatives were initially found to be synthetized by a spermidine hydroxycinnamoyltransferase (AtSHT) in Arabidopsis thaliana and to accumulate in the pollen coat. This study reports the identification, in Malus domestica, of an acyltransferase able to complement the sht mutant of Arabidopsis. The quantitative RT-PCR expression profile of MdSHT reveals a specific expression in flowers coordinated with anther development and tapetum cell activities. Three phenolamides including N (1),N (5),N (10)-tricoumaroyl spermidine and N (1),N (5)-dicoumaroyl-N (10)-caffeoyl spermidine identified by LC/MS, were shown to accumulate specifically in pollen grain coat of apple tree. Moreover, in vitro biochemical characterization confirmed MdSHT capacity to synthesize tri-substituted spermidine derivatives with a substrate specificity restricted to p-coumaroyl-CoA and caffeoyl-CoA as an acyl donor. Further investigations of the presence of tri-substituted hydroxycinnamoyl spermidine conjugates in higher plants were performed by targeted metabolic analyses in pollens coupled with bioinformatic analyses of putative SHT orthologues in a wide range of available plant genomes. This work highlights a probable early evolutionary appearance in the common ancestral core Eudicotyledons of a novel enzyme from the BAHD acyltransferase superfamily, dedicated to the synthesis of trihydroxycinnamoyl spermidines in pollen coat. This pathway was maintained in most species; however, recent evolutionary divergences have appeared among Eudicotyledons, such as an organ reallocation of SHT gene expression in Fabales and a loss of SHT in Malvales and Cucurbitales.

Characterization of an autonomously replicating sequence in Candida guilliermondii

Candida guilliermondii is an ascomycetous yeast widely studied due to its clinical importance, biotechnological interest, and biological control potential. During a series of preliminary experiments aiming at optimizing the electroporation procedure of C. guilliermondii cells, we observed that the efficiency of transformation of an ura5 recipient strain with the corresponding dominant marker URA5 was more than a thousand fold higher as compared with the transformation of an ura3 strain with the URA3 wild type allele. This result allowed the identification of an autonomously replicating sequence (ARS) within an A/T rich region located upstream of the URA5 open reading frame (ORF). Interestingly, linear double strand DNAs (dsDNAs) containing this putative ARS are circularized and then autonomously replicated in C. guilliermondii transformed cells. We demonstrated that the C. guilliermondii Lig4p ligase, involved in the canonical non-homologous end-joining (NHEJ) pathway, was responsible for this phenomenon since a lig4 mutant was unable to circularize and to autonomously maintain transforming dsDNAs containing the putative ARS. Finally, a functional dissection of the C. guilliermondii A/T rich region located upstream of the URA5 ORF revealed the presence of a 60 bp-length sequence essential and sufficient to confer ARS properties to shuttle plasmid and linear dsDNAs.

Folivory elicits a strong defense reaction in Catharanthus roseus: metabolomic and transcriptomic analyses reveal distinct local and systemic responses

Plants deploy distinct secondary metabolisms to cope with environment pressure and to face bio-aggressors notably through the production of biologically active alkaloids. This metabolism-type is particularly elaborated in Catharanthus roseus that synthesizes more than a hundred different monoterpene indole alkaloids (MIAs). While the characterization of their biosynthetic pathway now reaches completion, still little is known about the role of MIAs during biotic attacks. As a consequence, we developed a new plant/herbivore interaction system by challenging C. roseus leaves with Manduca sexta larvae. Transcriptomic and metabolic analyses demonstrated that C. roseus respond to folivory by both local and systemic processes relying on the activation of specific gene sets and biosynthesis of distinct MIAs following jasmonate production. While a huge local accumulation of strictosidine was monitored in attacked leaves that could repel caterpillars through its protein reticulation properties, newly developed leaves displayed an increased biosynthesis of the toxic strictosidine-derived MIAs, vindoline and catharanthine, produced by up-regulation of MIA biosynthetic genes. In this context, leaf consumption resulted in a rapid death of caterpillars that could be linked to the MIA dimerization observed in intestinal tracts. Furthermore, this study also highlights the overall transcriptomic control of the plant defense processes occurring during herbivory.