Class-I Elicitins in Relation to Sterol Acquisition and Lipid Profiling of <i>Phytophthora sojae</i>

Yousef, Lina Fayez

03 August 2010

No description available.

Biology

Plant Pathology

Soil Sciences

Phytophthora

elicitin

sterol-carrier proteins

Fatty Acids

Soybean

sterol

zoospore

The effects of Phytophthora ramorum stem inoculation on aspects of tanoak physiology and xylem function in saplings and seedlings

Stamm, Elizabeth A.

16 March 2012

Phytophthora ramorum, an oomycete plant pathogen, is the causal agent of sudden oak death, a serious disease of Fagaceous trees in California and Oregon over the last decade. Tanoak (Notholithocarpus densiflorus) is one of the most susceptible host species, but the cause of host mortality is poorly understood. Previous research has implicated disruption in stem water transport, phloem girdling, and activity of a class of secreted proteins known as elicitins as possible mechanisms of pathogenesis. In this study I investigated certain physiological impacts of P. ramorum infection on tanoak saplings and tanoak seedlings. In growth chamber experiments, stems of plants were inoculated with isolates that differed in the amount of elicitin secreted in vitro. Stem-wounded, non-inoculated plants served as controls. Parameters measured included net photosynthetic rate, stomatal conductance, whole plant water usage, stem specific hydraulic conductivity, tylosis production, starch partitioning, and mortality. Inoculated saplings exhibited a reduction in whole plant water usage, followed by a reduction in stem specific hydraulic conductivity implicating an interruption in stem water transport as the primary symptom. A reduction in net photosynthetic rate and stomatal conductance occurred one week later. Experiments conducted on inoculated tanoak seedlings supported the hypothesis that a reduction in stem water transport is the primary disease symptom. Stem specific hydraulic conductivity was the only parameter that appeared to be significantly impacted when treatments were compared during each measurement period. There was, however, a significant difference between treatments over the course of the entire experiment. Due to differences in isolate growth rates and similar levels of elicitin secretion, symptom expression could not be tied to elicitin production. To determine where elicitins are produced in planta, an immunolabeling technique was tested utilizing an elicitin-specific fluorescent antibody. The elicitin protein was most apparent in paratracheal parenchyma cells, although nonspecific staining in control samples confounded interpretation. / Graduation date: 2012

Phytophthora

elicitin

xylem

Elicitins -- Pathophysiology

Plants, Motion of fluids in

Sudden oak death -- Pathophysiology

Lutte biologique contre un champignon pathogène impliqué dans l’esca de la vigne, par utilisation de l’oomycète Pythium oligandrum / Biological control by the oomycete, Pythium oligandrum, of a pathogenic fungus involved in esca, a grapevine trunk disease

Gerbore, Jonathan

24 October 2013

Les recherches sur la lutte biologique (ou biocontrôle) par utilisation de micro-organismes connaissent un essor remarquable, les applications au champ étant cependant encore limitées en raison des variations d’efficacité dans la protection des plantes. Celles-ci sont souvent imputées à la non persistance des agents de biocontrôle dans la rhizosphère ou sur le végétal qu’ils sont censés protéger. Afin de réduire ce risque, une solution consiste à utiliser des micro-organismes isolés du végétal que l’on souhaite protéger. Dans le cadre de cette thèse, Pythium oligandrum, un oomycète colonisateur de la rhizosphère de nombreuses plantes dont la vigne, a été étudié pour lutter contre l’esca, une maladie du bois de la vigne pour laquelle il n’existe actuellement aucune méthode de lutte disponible. Des souches de P. oligandrum ont été isolées de la rhizosphère de ceps cultivés dans 3 régions viticoles (12 vignobles) du Bordelais présentant des sols variés : argilo-calcaire, sable-graveleux et graveleux. Les analyses des communautés fongiques et bactériennes obtenues par empreinte moléculaire (Single Strand Conformation Polymorphism) ont montré que, contrairement aux bactéries, les espèces fongiques différaient selon les régions. Des Pythium spp. aux oospores échinulées ont été isolées à partir des racines des ceps échantillonnés, avec une prédominance de P. oligandrum (séquençage de la région ITS). L’analyse des séquences des gènes codant pour le cytochrome oxydase I et une tubuline a permis de constituer 3 groupes de souches. Le séquençage d’autres gènes codant pour des protéines « élicitines-like » a indiqué que chaque souche présentait au moins un gène codant pour chacun des 2 types d’éliciteurs de P. oligandrum : l’oligandrine et les protéines de la paroi cellulaire (CWPs). Il apparaît que le type de sol et la microflore associée à la rhizosphère n’exerceraient pas une influence suffisante pour que la structure génétique des populations de P. oligandrum soient associées à un contexte tellurique particulier. En revanche, le type de porte-greffe et la méthode de désherbage (chimique ou mécanique) pourraient avoir une incidence sur la colonisation racinaire par P. oligandrum. Les relations entre P. oligandrum et les racines de la vigne ont été étudiées par analyse transcriptomique (microarray Vitis vinifera de 29 549 gènes). Les résultats obtenus montrent que de jeunes plants de vigne ont répondu à la colonisation racinaire par P. oligandrum en modifiant l’expression de gènes intervenant dans plusieurs voies métaboliques. Deux aspects a priori opposés ont été observés : P. oligandrum serait perçu comme (1) un agresseur contre lequel la plante a mis en place des réactions de défense mais en même temps, comme (2) un micro-organisme symbiotique car un certain nombre de modifications transcriptionnelles étaient similaires à celles reportées dans les interactions rhyzosphèriques symbiotiques (e.g. forte stimulation de gènes codant pour des subtilases). Un essai visant à induire chez la vigne une protection contre un champignon pathogène impliqué dans l’esca, Phaeomoniella chlamydospora, grâce à P. oligandrum, a été réalisé. La colonisation des racines par P. oligandrum a été associée à une réduction de la longueur des nécroses dues à P. chlamydospora. En adéquation avec ce résultat, l’analyse transcriptomique par RT-PCRq et microarrays a montré une surexpression de la voie de l’éthylène. Plusieurs gènes spécifiquement induits constitueraient des marqueurs de résistance qu’il conviendra de valider lors de prochaines expérimentations. / Biocontrol research based on the use of microorganisms is expanding very rapidly. However, the use of such bioncontrol agents is still too inconsistent to effectively protect plants in field applications. This phenomenon is often attributed to the non-persistence of biocontrol agents in the rhizosphere or on the plants. In order to reduce the risk of this happening, one solution consists in using microorganisms that are isolated from the plants needing protection. In this thesis, an oomycete called Pythium oligandrum, which colonizes the rhizosphere of many plants, including grapevine, was assessed for the control of esca, a grapevine trunk disease for which no control method is currently available. P. oligandrum strains have been isolated from the rhizosphere of vines cultivated in 3 wine-growing regions (12 grapevines) of Bordeaux with different types of soil: stony-sandy, silty and stony. Analyses of fungal and bacterial communities using a molecular fingerprinting method (Single Strand Conformation Polymorphism) showed that, unlike bacteria, the fungal species varied according to the sampling region. Roots of all the vines sampled were colonized by echinulated-oospore Pythium spp., with P. oligandrum strains predominating. Phylogenetic analyses based on the genes encoding the cytochrome oxidase I and one tubulin allowed these strains to be clustered into three groups. The sequencing of the elicitin-like genes, whose proteins are key components in inducing systemic resistance in plants, showed that each strain held at least one gene encoding for each of the two kinds of P. oligandrum elicitors (i.e. oligandrin and Cell Wall Proteins). Sequencing and molecular fingerprinting analyses showed thus that the type of soil and the rhizosphere microbiota did not shape the population structure of P. oligandrum. However, other factors such as the different kinds of rootstock and weeding management can also have an influence on the root colonization by P. oligandrum. The relationship between P. oligandrum and grapevine was studied using a transcriptomic approach (microarray Vitis vinifera, 29 549 genes). The results highlighted the modifications induced by young vines in response to P. oligandrum root colonization, in the genetic expression of several genes belonging to different metabolic pathways. Two aspects, that are usually opposed, were observed: P. oligandrum was perceived by the plant either (i) as a pathogen because certain defence reactions were triggered (e.g. calcium signalling, resistance genes, abscissic acid metabolism) or as (ii) a symbiotic microorganism since several transcriptional changes were similar to those reported in symbiotic interactions (e.g. induction of subtilase genes). An assay aimed at protecting grapevine against a pathogenic fungus involved in esca, and known to be responsible for wood necrosis, i.e. Phaeomoniella chlamydospora, was carried out. The root colonization by P. oligandrum was associated with a reduction in the length of necroses. In line with this result, transcriptomic analyses by microarrays and RT-qPCR showed overexpression of several genes, particularly those of the ethylene pathway. Some of these induced genes could be thus used as resistance markers, but this needs to be validated in further experiments.

Biocontrôle

Élicitines-like protéines,

Esca

Maladies du bois

Microflore tellurique

Pythium oligandrum

Phaeomoniella chlamydospora

Résistance induite

Biocontrol

Elicitin-like proteins

Esca

Grapevine trunk diseases

Induced resistance

Pythium oligandrum

Phaeomoniella chlamydospora

Soil microflora