Expressed Sequence Tags from the oomycete Plasmopara halstedii, an obligate parasite of the sunflower

<p>Abstract</p> <p>Background</p> <p>Sunflower downy mildew is a major disease caused by the obligatory biotrophic oomycete <it>Plasmopara halstedii</it>. Little is known about the molecular mechanisms underlying its pathogenicity. In this study we used a genomics approach to gain a first insight into the transcriptome of <it>P. halstedii</it>.</p> <p>Results</p> <p>To identify genes from the obligatory biotrophic oomycete <it>Plasmopara halstedii </it>that are expressed during infection in sunflower (<it>Helianthus annuus </it>L.) we employed the suppression subtraction hybridization (SSH) method from sunflower seedlings infected by <it>P. halstedii</it>. Using this method and random sequencing of clones, a total of 602 expressed sequence tags (ESTs) corresponding to 230 unique sequence sets were identified. To determine the origin of the unisequences, PCR primers were designed to amplify these gene fragments from genomic DNA isolated either from <it>P. halstedii </it>sporangia or from <it>Helianthus annuus</it>. Only 145 nonredundant ESTs which correspond to a total of 373 ESTs (67.7%) proved to be derived from <it>P. halstedii </it>genes and that are expressed during infection in sunflower. A set of 87 nonredundant sequences were identified as showing matches to sequences deposited in public databases. Nevertheless, about 7% of the ESTs seem to be unique to <it>P. halstedii </it>without any homolog in any public database.</p> <p>Conclusion</p> <p>A summary of the assignment of nonredundant ESTs to functional categories as well as their relative abundance is listed and discussed. Annotation of the ESTs revealed a number of genes that could function in virulence. We provide a first glimpse into the gene content of <it>P. halstedii</it>. These resources should accelerate research on this important pathogen.</p

Positional cloning of a candidate gene for resistance to the sunflower downy mildew, Plasmopara halstedii race 300.

International audienceThe resistance of sunflower to Plasmopara halstedii is conferred by major resistance genes denoted Pl. Previous genetic studies indicated that the majority of these genes are clustered on linkage groups 8 and 13. The Pl6 locus is one of the main clusters to have been identified, and confers resistance to several P. halstedii races. In this study, a map-based cloning strategy was implemented using a large segregating F2 population to establish a fine physical map of this cluster. A marker derived from a bacterial artificial chromosome (BAC) clone was found to be very tightly linked to the gene conferring resistance to race 300, and the corresponding BAC clone was sequenced and annotated. It contains several putative genes including three toll-interleukin receptor-nucleotide binding site-leucine rich repeats (TIR-NBS-LRR) genes. However, only one TIR-NBS-LRR appeared to be expressed, and thus constitutes a candidate gene for resistance to P. halstedii race 300

Sunflower Hybrid Breeding: From Markers to Genomic Selection

In sunflower, molecular markers for simple traits as, e.g., fertility restoration, high oleic acid content, herbicide tolerance or resistances to Plasmopara halstedii, Puccinia helianthi, or Orobanche cumana have been successfully used in marker-assisted breeding programs for years. However, agronomically important complex quantitative traits like yield, heterosis, drought tolerance, oil content or selection for disease resistance, e.g., against Sclerotinia sclerotiorum have been challenging and will require genome-wide approaches. Plant genetic resources for sunflower are being collected and conserved worldwide that represent valuable resources to study complex traits. Sunflower association panels provide the basis for genome-wide association studies, overcoming disadvantages of biparental populations. Advances in technologies and the availability of the sunflower genome sequence made novel approaches on the whole genome level possible. Genotype-by-sequencing, and whole genome sequencing based on next generation sequencing technologies facilitated the production of large amounts of SNP markers for high density maps as well as SNP arrays and allowed genome-wide association studies and genomic selection in sunflower. Genome wide or candidate gene based association studies have been performed for traits like branching, flowering time, resistance to Sclerotinia head and stalk rot. First steps in genomic selection with regard to hybrid performance and hybrid oil content have shown that genomic selection can successfully address complex quantitative traits in sunflower and will help to speed up sunflower breeding programs in the future. To make sunflower more competitive toward other oil crops higher levels of resistance against pathogens and better yield performance are required. In addition, optimizing plant architecture toward a more complex growth type for higher plant densities has the potential to considerably increase yields per hectare. Integrative approaches combining omic technologies (genomics, transcriptomics, proteomics, metabolomics and phenomics) using bioinformatic tools will facilitate the identification of target genes and markers for complex traits and will give a better insight into the mechanisms behind the traits

Analyse moléculaire des mécanismes de résistance du tournesol à l'agent du mildiou Plasmopara halstedii contrôlés par le locus Pl5/ Pl8

CLERMONT FD-BCIU Sci.et Tech. (630142101) / SudocSudocFranceF

Caractérisation biochimique et moléculaire du complexe SCF (SKP1-CULLIN-FBOX) chez le blé tendre

Les modifications post-traductionnelles des protéines constituent un niveau crucial de régulation de l expression des gènes. Parmi elles, la conjugaison peptidique impliquant l ubiquitine intervient entre autre dans la régulation de la stabilité protéique. La fixation de ce peptide de 76 acides aminés, extrêmement conservé, sous forme de chaîne de polyubiquitine, nécessite l intervention de trois enzymes (E1, E2 et E3) et constitue un signal de dégradation de la protéine ainsi modifiée. Cette voie de régulation intervient dans de très nombreux processus biologiques. Les complexes SCF sont impliqués dans la voie de protéolyse ciblée. Ils représentent l' une des classes les plus fréquentes d'ubiquitine ligase E3 et ils sont composés de quatre sous-unités (Rbx, Cullin, SKP1, et F-box). La structure et la fonction des complexes SCF, ont été étudiées chez la levure, l Homme et la plante modèle A. thaliana. Cependant, peu de travaux ont été réalisés chez des plantes cultivées, en particulier les céréales, telles que le blé. Cinq gènes codant pour la sous-unité Skp1 (TSK1, TSK3, TSK6, TSK11 et TSK16), cinq gènes codant pour la sous-unité F-box (ZTL, ATFBL5, EBF, TIR1 et ABA-T), un gène codant pour la sous-unité Cullin1 et un gène codant pour la protéine RBX du complexe SCF du blé, ont été isolés et clonés. Les différents tests d interaction entre les quatre sous-unités du complexe SCF ont été réalisés par la méthode du double-hybride dans la levure en utilisant la technologie Gateway. Ces études ont montré que les deux protéines, TSK1 et TSK3, fixent spécifiquement différentes sous-unités F-box. Parallèlement, nous avons montré que la protéine TSK11 représente une structure particulière. Des études d insertion/délétion sur la protéine TSK11 ont permis d identifier un nouveau domaine indispensable à l interaction. Les analyses par PCR semi-quantitative des différents gènes codant pour la sous-unité Skp1, dans trois tissus différents (feuille tige et racine), ont mis en évidence une expression constitutive des gènes TSK3, TSK6 et TSK11. Tandis que les gènes TSK1 et TSK16 sont exprimés préférentiellement dans les racines. Les analyses par PCR semi-quantitative sur des plantules de blé à différents stades de développement, ont mis en évidence une surexpression du gène TSK11 au moment de la floraison. Ce qui suggère que TSK11 est probablement un équivalent fonctionnel d ASK1 chez Arabidopsis thaliana.The selective degradation of proteins is an important means of regulating gene expression and plays crucial roles in the control of various cellular processes. The Ubiquitin (Ub) Proteasome System (UPS) is the principal non-lysosomal proteolytic pathway in eukaryotic cells and is required for the degradation of key regulatory proteins. Ubiquitin is a 76-residue protein that can be attached covalently to target proteins through an enzymatic conjugation cascade involving three enzymes denoted, E1, E2 and E3.The SCF complex is a type of ubiquitin-protein ligase (E3) that acts as the specific factor responsible for substrate recognition and ubiquitination. Some polyubiquitinated proteins are then targeted to the 26S proteasome for degradation. The SCF complex consists of four components including SKP1, Cullin1, Rbx1 and a large gene family of F-box proteins. Twenty one SKP1-related genes have been described in the Arabidopsis genome and some of these genes have been analyzed genetically. By contrast, little is known about the function and structure of SKP1 homologues in wheat. Some of the Triticum SKP1-related protein (TSKs) have been characterized in this study. Five complete sequences of SKP1 (TSK1, TSK3, TSK6, TSK11 and TSK16), five F-box (ZTL, ATFBL5, EBF, TIR1 and ABA-T), one Cullin1 and one Rbx, were successfully cloned and biochemically characterized. Yeast two-hybrid analysis showed that TSK1 and TSK3 are capable of interacting with different F-box proteins. Furthermore, TSK11 contains an additional domain that changed its interaction capabilities. In vitro analysis using a chimeric protein showed that this additional domain could modify the interaction between a SKP-like protein and two F-box proteins. Expression analyses revealed that TSK1 and TSK16 were expressed predominantly in roots. While, TSK3, TSK6 and TSK11 were expressed in several wheat organs. In addition, the TSK11 was up-regulated in the leaves at the flowering stage.CLERMONT FD-Bib.électronique (631139902) / SudocSudocFranceF

Analyse fonctionnelle de TaGW2, une E3 ligase de type RING, dans le développement du grain de blé tendre (Triticum aestivum)

Le blé tendre, Triticum aestivum, est une des céréales les plus cultivées au monde et est d une importance considérable pour l alimentation humaine, fournissant environ un cinquième des calories consommées par l Homme. Le rendement en grain chez les céréales dépend majoritairement du nombre et de la taille des grains. Chez le riz (Oryza sativa), le gène GW2 a été isolé dans un locus à effet quantitatif majeur pour la taille et le poids du grain. Ce gène code pour une enzyme E3 ligase de type RING, qui régule négativement la taille et le poids du grain de riz. L homologue de GW2 chez le blé tendre, le gène TaGW2, est exprimé par trois copies TaGW2-A,TaGW2-B et TaGW2-D, portées par chacun des génomes homéologues A, B et D. Les trois copies présentent des profils d expression distincts au cours du développement du grain. TaGW2-A a été cartographié dans une région de QTLs pour le rendement, sur le chromosome 6AS ; et du polymorphisme dans sa séquence promotrice et intronique a été retrouvé associé au poids de 1000-grains dans une core collection mondiale de blé tendre. Afin de rechercher la fonction de TaGW2, l extinction stable des trois copies TaGW2 a été entreprise par ARN interférence. De manière surprenante, les plantes transgéniques montrent des réductions significatives des dimensions et du poids du grain de blé (- 22,5 et - 30% du volume et de la masse du grain, respectivement), ainsi que du nombre de cellules de l albumen (- 25%), comparé aux plantes témoins dans nos conditions ; suggérant que TaGW2 est un régulateur positif de la taille finale du grain chez le blé tendre. La protéine TaGW2-A a été caractérisée aux niveaux moléculaire et biochimique : elle est une E3 ubiquitine ligase fonctionnelle in vitro, et s accumule dans la cellule au niveau du nucléole, du nucléoplasme et du cytoplasme. Sa fonction E3 ligase semble notamment influencer sa localisation subcellulaire. Afin de déterminer la ou les voie(s) de signalisation dans la(es)quelle(s) intervient TaGW2, une banque ADNc de grains de blé a été construite et criblée par double-hybride avec 320 acides aminés de la protéine TaGW2-A. Les premiers interacteurs potentiels identifiés suggèrent d une part un rôle de TaGW2 dans la régulation de la division cellulaire, et d autre part une fonction E3 Nedd8 ligase, en plus de son activité E3 ligase.Wheat, Triticum aestivum, is one of the world s major cereal crops and is of considerable importance to human nutrition, supplying one-fifth of the calories consumed by humans. For important food crops such as wheat, rice and maize, grain yield mainly depends on grain number and size. In rice (Oryza sativa), GW2 was isolated from a major quantitative trait locus for grain size and weight, and encodes an E3 RING ligase that negatively regulates these yield components. Wheat has TaGW2 homologs in A, B and D genomes; and copies show distinct expression pattern during whole grain development in wheat. TaGW2-A was mapped in a genomic region on 6AS, encompassing previous reported QTLs for yield; and polymorphisms in TaGW2-A (promoter and intron 7) were associated with thousand-grain weight, in a worldwide wheat core collection. To investigate TaGW2 function, RNA interference was used to down-regulate TaGW2 transcripts levels. Surprisingly, transgenic wheat lines significantly showed decreased grain weight and size-related dimensions, and endosperm cell number compared to controls. The present study thus suggests that TaGW2 is a positive regulator of the final grain size in wheat, conversely to GW2 in rice. Biochemical and molecular analyses of the protein TaGW2-A revealed that 1) TaGW2-A is a functional E3 ubiquitine ligase in vitro, 2) TaGW2-A accumulates in the nucleolus, the nucleoplasm, and the cytosol, 3) E3 ubiquitine ligase activity seems to impact TaGW2-A subcellular localization. To investigate the TaGW2 signalling pathway(s), cDNA library from whole wheat grains was built and screened with the bait protein TaGW2(1-320). Preliminary results from the interactomic study suggest that TaGW2 may regulate cell division. Moreover, TaGW2 may also function as an E3 Nedd8 ligase, besides its E3 ubiquitin ligase function.CLERMONT FD-Bib.électronique (631139902) / SudocSudocFranceF

Dynamics of the Transcriptome Response to Heat in the Moss, Physcomitrella patens

International audienceThermal stress negatively impacts crop yields, and as the overall temperature of the earth's atmosphere is gradually increasing, the identification of the temperature transduction pathway of the heat signal is essential in developing new strategies in order to adapt plant breeding to warmer climates. Heat stress damages the molecular structures and physiological processes in plants in proportion to the level and duration of the stress, which leads to different types of responses. In general, plants respond more efficiently when they are first subjected to a moderate temperature increase before being subjected to a higher temperature stress. This adaptive response is called the acclimation period and has been investigated in several plant species. However, there is a lack of information on the dynamic of the Heat Shock Response (HSR) over a continuous period of temperature rise without an acclimation period. In this paper, we investigated the effects of mild (30 degrees C) and high (37 degrees C) continuous heat stress over a 24-h period. Through RNA-Seq analysis, we assessed the remodeling of the transcriptome in the moss Physcomitrella patens. Our results showed that the 30 degrees C treatment particularly affected the expression of a few genes at 1 and 24 h, suggesting a biphasic response. Up-regulated genes at 1 h encode mainly HSR proteins (protein folding and endoplasmic reticulum stress), indicating an early heat response; while the up-regulated genes at 24 h belong to the thiamine biosynthesis pathway. In contrast, the genes involved in photosynthesis and carbon partitioning were repressed by this treatment. Under a higher temperature stress (37 degrees C), the induction of the HSR occurred rapidly (1 h) and was then attenuated throughout the time points investigated. A network approach (Weighted Gene Correlation Network Analysis, WGCNA) was used to identify the groups of genes expressing similar profiles, highlighting a HsfA1E binding motif within the promoters of some unrelated genes which displayed rapid and transient heat-activation. Therefore, it could be suggested that these genes could be direct targets of activation by a HsfA1E transcription factors

The Landscape of the Genomic Distribution and the Expression of the F-Box Genes Unveil Genome Plasticity in Hexaploid Wheat during Grain Development and in Response to Heat and Drought Stress

International audienceFBX proteins are subunits of the SCF complex (Skp1–cullin–FBX) belonging to the E3 ligase family, which is involved in the ubiquitin–proteasome 26S (UPS) pathway responsible for the post-translational protein turnover. By targeting, in a selective manner, key regulatory proteins for ubiquitination and 26S proteasome degradation, FBX proteins play a major role in plant responses to diverse developmental and stress conditions. Although studies on the genomic organization of the FBX gene family in various species have been reported, knowledge related to bread wheat (Triticum aestivum) is scarce and needs to be broadened. Using the latest assembly of the wheat genome, we identified 3670 TaFBX genes distributed non-homogeneously within the three subgenomes (A, B and D) and between the 21 chromosomes, establishing it as one of the richest gene families among plant species. Based on the presence of the five different chromosomal regions previously identified, the present study focused on the genomic distribution of the TaFBX family and the identification of differentially expressed genes during the embryogenesis stages and in response to heat and drought stress. Most of the time, when comparing the expected number of genes (taking into account the formal gene distribution on the entire wheat genome), the TaFBX family harbors a different pattern at the various stratum of observation (subgenome, chromosome, chromosomal regions). We report here that the local gene expansion of the TaFBX family must be the consequence of multiple and complex events, including tandem and small-scale duplications. Regarding the differentially expressed TaFBX genes, while the majority of the genes are localized in the distal chromosomal regions (R1 and R3), differentially expressed genes are more present in the interstitial regions (R2a and R2b) than expected, which could be an indication of the preservation of major genes in those specific chromosomal regions

Molecular Characterization of Two Types of Resistance in Sunflower to Plasmopara halstedii, the Causal Agent of Downy Mildew

Depending on host-pathotype combination, two types of sunflower Plasmopara halstedii incompatibility reactions have previously been identified. Type 1 resistance can restrict the growth of the pathogen in the basal region of the hypocotyls, whereas type II cannot, thus allowing the pathogen to reach the cotyledons. In type II resistance, a large portion of the hypocotyls is invaded by the pathogen and, subsequently, a hypersensitive reaction (FIR) is activated over a long portion of the hypocotyls. Thus, the HR in type II resistance coincides with a higher induction of hsr203j sunflower homologue in comparison with type 1 resistance, where the HR is activated only in the basal part of hypocotyls. Although the pathogen was not detected in cotyledons of type I resistant plants, semiquantitative polymerase chain reaction confirmed the early abundant growth of the pathogen in cotyledons of susceptible plants by 6 days postinfection (dpi). This was in contrast to scarce growth of the pathogen in cotyledons of type II-resistant plants at a later time point (12 dpi). This suggests that pathogen growth differs according to the host pathogen combination. To get more information about sunflower downy mildew resistance genes, the full-length cDNAs of RGC151 and RGC203, which segregated with the Pl(ARG) gene (resistance type 1) and Pl(14) gene (resistance type II), were cloned and sequenced. Sequence analyses revealed that RGC151 belongs to the Toll/interleukin-1 receptor (TIR) nucleotide-binding site leucine-rich repeat (NBS-LRR) class whereas RGC203 belongs to class coiled-coil (CC)-NBS-LRR. This study suggests that type II resistance may be controlled by CC-NBS-LRR gene transcripts which are enhanced upon infection by P. halstedii, rather than by the TIR-NBS-LRR genes that might control type I resistance