Molecular Quest for Avirulence Factors in Venturia inaequalis

Win, Joe

January 2004

The molecular basis for the gene-for-gene relationship of Vm-resistance in apple to Venturia inaequalis was investigated. Incompatible reactions involved a hypersensitive response (HR), which was accompanied by the accumulation of dark brown pigments and autofluorescent materials in epidermal and mesophyll cells at the site of invasion. Cell-free culture filtrates of the avirulent isolate elicited an HR in the Vm host (h5) leaves, but not in the susceptible host (h1). The elicitor activity was resistant to boiling but was abolished by proteinase K digestion. Elicitation of HR was used to monitor purification of the avirulence factor, AVRVm, from liquid cultures of the avirulent isolate following ultrafiltration, acetone precipitation and ion-exchange chromatography. The purest fraction contained three major proteins all with low isoelectric points (pI 3.0-4.5). The fraction also elicited HR on the differential host h4, but not on other resistant hosts (h2, h3 and h6) tested. Three candidate AVRVm proteins were identified and amino acid sequences were obtained using Edman degradation and mass spectrometry. Nucleotide sequences corresponding to these proteins were found in databases of V. inaequalis expressed sequence tags. There were no polymorphisms evident between avirulent and virulent isolates (representing races 1 and 5 respectively) either at genomic DNA or cDNA level of the full open reading frames. RT-PCR revealed that all genes were expressed in both avirulent and virulent isolates during in vitro and in planta growth. All three genes showed similar levels of expression between avirulent and virulent isolates during their in vitro growth. However, preliminary RT-PCR experiments showed that two of these genes were likely to be expressed at lower levels in the virulent compared with the avirulent isolate during compatible infection. Implications of this difference in expression and the future experiments to identify the genuine AvrVm gene were discussed.

Molecular Quest for Avirulence Factors in Venturia inaequalis

Win, Joe

January 2004

The molecular basis for the gene-for-gene relationship of Vm-resistance in apple to Venturia inaequalis was investigated. Incompatible reactions involved a hypersensitive response (HR), which was accompanied by the accumulation of dark brown pigments and autofluorescent materials in epidermal and mesophyll cells at the site of invasion. Cell-free culture filtrates of the avirulent isolate elicited an HR in the Vm host (h5) leaves, but not in the susceptible host (h1). The elicitor activity was resistant to boiling but was abolished by proteinase K digestion. Elicitation of HR was used to monitor purification of the avirulence factor, AVRVm, from liquid cultures of the avirulent isolate following ultrafiltration, acetone precipitation and ion-exchange chromatography. The purest fraction contained three major proteins all with low isoelectric points (pI 3.0-4.5). The fraction also elicited HR on the differential host h4, but not on other resistant hosts (h2, h3 and h6) tested. Three candidate AVRVm proteins were identified and amino acid sequences were obtained using Edman degradation and mass spectrometry. Nucleotide sequences corresponding to these proteins were found in databases of V. inaequalis expressed sequence tags. There were no polymorphisms evident between avirulent and virulent isolates (representing races 1 and 5 respectively) either at genomic DNA or cDNA level of the full open reading frames. RT-PCR revealed that all genes were expressed in both avirulent and virulent isolates during in vitro and in planta growth. All three genes showed similar levels of expression between avirulent and virulent isolates during their in vitro growth. However, preliminary RT-PCR experiments showed that two of these genes were likely to be expressed at lower levels in the virulent compared with the avirulent isolate during compatible infection. Implications of this difference in expression and the future experiments to identify the genuine AvrVm gene were discussed.

Molecular Quest for Avirulence Factors in Venturia inaequalis

Win, Joe

January 2004

The molecular basis for the gene-for-gene relationship of Vm-resistance in apple to Venturia inaequalis was investigated. Incompatible reactions involved a hypersensitive response (HR), which was accompanied by the accumulation of dark brown pigments and autofluorescent materials in epidermal and mesophyll cells at the site of invasion. Cell-free culture filtrates of the avirulent isolate elicited an HR in the Vm host (h5) leaves, but not in the susceptible host (h1). The elicitor activity was resistant to boiling but was abolished by proteinase K digestion. Elicitation of HR was used to monitor purification of the avirulence factor, AVRVm, from liquid cultures of the avirulent isolate following ultrafiltration, acetone precipitation and ion-exchange chromatography. The purest fraction contained three major proteins all with low isoelectric points (pI 3.0-4.5). The fraction also elicited HR on the differential host h4, but not on other resistant hosts (h2, h3 and h6) tested. Three candidate AVRVm proteins were identified and amino acid sequences were obtained using Edman degradation and mass spectrometry. Nucleotide sequences corresponding to these proteins were found in databases of V. inaequalis expressed sequence tags. There were no polymorphisms evident between avirulent and virulent isolates (representing races 1 and 5 respectively) either at genomic DNA or cDNA level of the full open reading frames. RT-PCR revealed that all genes were expressed in both avirulent and virulent isolates during in vitro and in planta growth. All three genes showed similar levels of expression between avirulent and virulent isolates during their in vitro growth. However, preliminary RT-PCR experiments showed that two of these genes were likely to be expressed at lower levels in the virulent compared with the avirulent isolate during compatible infection. Implications of this difference in expression and the future experiments to identify the genuine AvrVm gene were discussed.

Molecular Quest for Avirulence Factors in Venturia inaequalis

Win, Joe

January 2004

The molecular basis for the gene-for-gene relationship of Vm-resistance in apple to Venturia inaequalis was investigated. Incompatible reactions involved a hypersensitive response (HR), which was accompanied by the accumulation of dark brown pigments and autofluorescent materials in epidermal and mesophyll cells at the site of invasion. Cell-free culture filtrates of the avirulent isolate elicited an HR in the Vm host (h5) leaves, but not in the susceptible host (h1). The elicitor activity was resistant to boiling but was abolished by proteinase K digestion. Elicitation of HR was used to monitor purification of the avirulence factor, AVRVm, from liquid cultures of the avirulent isolate following ultrafiltration, acetone precipitation and ion-exchange chromatography. The purest fraction contained three major proteins all with low isoelectric points (pI 3.0-4.5). The fraction also elicited HR on the differential host h4, but not on other resistant hosts (h2, h3 and h6) tested. Three candidate AVRVm proteins were identified and amino acid sequences were obtained using Edman degradation and mass spectrometry. Nucleotide sequences corresponding to these proteins were found in databases of V. inaequalis expressed sequence tags. There were no polymorphisms evident between avirulent and virulent isolates (representing races 1 and 5 respectively) either at genomic DNA or cDNA level of the full open reading frames. RT-PCR revealed that all genes were expressed in both avirulent and virulent isolates during in vitro and in planta growth. All three genes showed similar levels of expression between avirulent and virulent isolates during their in vitro growth. However, preliminary RT-PCR experiments showed that two of these genes were likely to be expressed at lower levels in the virulent compared with the avirulent isolate during compatible infection. Implications of this difference in expression and the future experiments to identify the genuine AvrVm gene were discussed.

Molecular Quest for Avirulence Factors in Venturia inaequalis

Win, Joe

January 2004

The molecular basis for the gene-for-gene relationship of Vm-resistance in apple to Venturia inaequalis was investigated. Incompatible reactions involved a hypersensitive response (HR), which was accompanied by the accumulation of dark brown pigments and autofluorescent materials in epidermal and mesophyll cells at the site of invasion. Cell-free culture filtrates of the avirulent isolate elicited an HR in the Vm host (h5) leaves, but not in the susceptible host (h1). The elicitor activity was resistant to boiling but was abolished by proteinase K digestion. Elicitation of HR was used to monitor purification of the avirulence factor, AVRVm, from liquid cultures of the avirulent isolate following ultrafiltration, acetone precipitation and ion-exchange chromatography. The purest fraction contained three major proteins all with low isoelectric points (pI 3.0-4.5). The fraction also elicited HR on the differential host h4, but not on other resistant hosts (h2, h3 and h6) tested. Three candidate AVRVm proteins were identified and amino acid sequences were obtained using Edman degradation and mass spectrometry. Nucleotide sequences corresponding to these proteins were found in databases of V. inaequalis expressed sequence tags. There were no polymorphisms evident between avirulent and virulent isolates (representing races 1 and 5 respectively) either at genomic DNA or cDNA level of the full open reading frames. RT-PCR revealed that all genes were expressed in both avirulent and virulent isolates during in vitro and in planta growth. All three genes showed similar levels of expression between avirulent and virulent isolates during their in vitro growth. However, preliminary RT-PCR experiments showed that two of these genes were likely to be expressed at lower levels in the virulent compared with the avirulent isolate during compatible infection. Implications of this difference in expression and the future experiments to identify the genuine AvrVm gene were discussed.

Structural basis for interactions of the Phytophthora sojae RxLR effector Avh5 with phosphatidylinositol 3-phosphate and for host cell entry

Sun, Furong

04 May 2012

Oomycetes, such as Phytophthora sojae, are plant pathogens that employ protein effectors that enter host cells to facilitate infection. Plants may overcome infection by recognizing pathogen effectors via intracellular receptors (R proteins) that form part of their defense system. Entry of some effector proteins into plant cells is mediated by conserved RxLR motifs in the effectors and phosphoinositides (PIPs) resident in the host plasma membrane such as phosphatidylinositol 3-phosphate (PtdIns(3)P). Recent reports differ regarding the regions on RxLR effector proteins involved in PIP recognition. To clarify these differences, I have structurally and functionally characterized the P. sojae effector, avirulence homolog-5 (Avh5). Using NMR spectroscopy, I demonstrate that Avh5 is helical in nature with a long N-terminal disordered region. Heteronuclear single quantum coherence titrations of Avh5 with the PtdIns(3)P head group, inositol 1,3-bisphosphate (Ins(1,3)P2), allowed us to identify a C-terminal lysine-rich helical region (helix 2) as the principal lipid-binding site in the protein, with the N-terminal RxLR (RFLR) motif playing a more minor role. Furthermore, mutations in the RFLR motif slightly affected PtdIns(3)P binding, while mutations in the basic helix almost abolished it. Avh5 exhibited moderate affinity for PtdIns(3)P, which increased the thermal stability of the protein. Mutations in the RFLR motif or in the basic region of Avh5 both significantly reduced protein entry into plant and human cells. Both regions independently mediated cell entry via a PtdIns(3)P-dependent mechanism. My findings support a model in which Avh5 transiently interacts with PtdIns(3)P by electrostatic interactions mainly through its positively charged helix 2 region, providing stability to the protein during RFLR-mediated host entry. / Ph. D.

Phytophthora sojae

Protein-lipid interactions

Phosphatidylinositol 3-phosphate

Avirulence homolog-5

Etude de l’activité et de la reconnaissance d’AVR-CO39, un effecteur du champignon pathogène Magnaporthe oryzae, agent causal de la pyriculariose du riz / Activity and recognition of AVR-CO39, an effector of the rice blast fungus Magnaporthe oryzae.

Cesari, Stella

18 December 2012

Le pouvoir pathogène des microorganismes repose sur leur capacité à manipuler des processus cellulaires de l'hôte à l'aide de protéines sécrétées dans le tissu végétal : les effecteurs. En plus de leur rôle primordial dans le pouvoir pathogène, les effecteurs sont centraux pour la résistance des plantes. La reconnaissance de certains d'entre eux par des récepteurs du système immunitaire végétal, nommées protéines de résistance (R), déclenche la résistance de la plante. Cette thèse a permis la caractérisation moléculaire d'AVR-CO39, un effecteur du champignon pathogène du riz Magnaporthe oryzae. Nous montrons qu'AVR-CO39 est transloqué dans le cytoplasme des cellules infectées par un mécanisme indépendant de facteurs fongiques et est reconnu dans ce même compartiment par le produit du locus R nommé Pi-CO39. La surexpression d'AVR-CO39 dans des plantes transgéniques révèle que cet effecteur influence des processus développementaux et physiologiques du riz. Un crible double hybride dans la levure a permis d'identifier 9 protéines du riz potentiellement ciblées par AVR-CO39. Une d'elles, nommée RGA5, confère la résistance Pi-CO39 avec une seconde protéine R du riz appelée RGA4. Nos résultats indiquent que RGA4 induit l'activation de la défense tandis que RGA5 agit comme récepteur de protéines Avr. En effet, RGA5 interagit physiquement avec AVR-CO39 et AVR-Pia, un autre effecteur de M. oryzae, via un domaine C-terminal homologue à des protéines de liaison au cuivre. Cette thèse a donc permis l'identification d'un nouveau domaine de reconnaissance de protéines Avr et le développement d'un modèle mécanistique pour le fonctionnement de paires de protéines R chez les plantes. / Pathogenic microorganisms secrete numerous proteins during infection into the plant tissue to manipulate host cellular processes. These proteins are called effectors and are central to pathogenicity. Certain effectors are recognized by receptors of the plant immune system called resistance (R) proteins and this recognition triggers plant resistance. The objective of the thesis was the molecular characterization of AVR-CO39, an effector of the rice blast fungus Magnaporthe oryzae. Localization studies indicate that AVR-CO39 is translocated into the cytoplasm of infected rice-cells by a mechanism independent of fungal factors and that it is recognized within this compartment by the product of the corresponding R locus Pi-CO39. Overexpression of AVR-CO39 in transgenic rice plants suggests that the effector influences plant physiology and development. Yeast two-hybrid screening identified 9 rice proteins potentially targeted by AVR-CO39. One of them, called RGA5, interacts with a second R protein, RGA4, to confer Pi-CO39 resistance. Our results suggest that RGA4 activates plant defense while RGA5 represses RGA4 function in the absence of effectors proteins and acts as an Avr receptor protein. Indeed, RGA5 physically interacts with AVR-CO39 and another M. oryzae effector named AVR-Pia through a previously undescribed C-terminal domain displaying homology to copper-binding proteins. Therefore, this work identified a new Avr recognition domain in R proteins and generated a new mechanistic model for the action of R protein pairs in plant resistance.

Riz

Résistance des plantes

Effecteur

Magnaporthe oryzae

Protéine de résistance

Protéine d'avirulence

Rice

Plant resistance

Effector

Magnaporthe oryzae

Resistance protein

Avirulence protein

Evolution moleculaire sous pression de selection et implication dans la reconnaissance avrlm3/rlm3 du gene d'avirulence avrlm4-7 chez leptosphaeria maculans

Daverdin, Guillaume

04 March 2011

Leptosphaeria maculans, agent de la nécrose du collet des crucifères, est un agent pathogène majeur du colza (Brassica napus). La lutte génétique est aujourd'hui le procédé le plus utilisé afin de protéger les cultures des attaques de ce champignon. Cette méthode se base principalement sur l'utilisation de cultivars possédant des gènes de résistance spécifique (Rlm) qui permettent le déclenchement des réactions de défense de la plante parla reconnaissance directe ou indirecte des produits des gènes d'avirulence correspondants (AvrLm) présents dans la population pathogène. Plusieurs de ces résistances ont déjà été massivement déployées en France et dans le monde, connaissant dans un premier temps un fort succès commercial grâce à la protection fournie, suivie d'une perte d'efficacité très rapide. Avant cette thèse, le nombre d'études au champ des processus impliqués dans le contournement d'un gène de résistance était très limité, en particulier chez les champignons. L'objectif de cette thèse était d'étudier l'évolution moléculaire du gène d'avirulence AvrLm4-7sous pression de sélection, en profitant de son clonage et de la commercialisation récente de cultivars Rlm7, afin d'obtenir une étude précoce et détaillée des mécanismes moléculaires à l'origine du contournement d'une résistance spécifique. Le gène AvrLm4-7 présente l'originalité de coder pour une protéine responsable d'une double spécificité d'interaction vis-à-vis des gènes Rlm4 et Rlm7. Dans un premier temps, j'ai pu valider par mutagenèse dirigée le rôle primordial de l'acide aminé 120 dont la mutation affecte la reconnaissance d'AvrLm4 par Rlm4 sans toutefois altérer la reconnaissance d'AvrLm7 par Rlm7.Le contournement de la résistance Rlm7 a été ensuite analysé à l'aide d'une importante collection de souches prélevée sur deux sites expérimentaux indépendants (Grignon ; Versailles) sur une période de trois ans. Sur le premier site était cultivée une variété Rlm7 en monoculture avec un travail du sol simplifié tandis que sur le second site, le mode de culture incluait rotation culturale et enfouissement par labour des résidus de cultures. Il a ensuite été montré que, au contraire de la reconnaissance AvrLm4/Rlm4, un grand nombre d'évènements de mutation peuvent être à l'origine de la virulence d'une souche vis-à-vis de Rlm7. L'analyse moléculaire des souches virulentes et avirulentes de cette collection a ainsi permis de répertorier sept catégories d'évènements de mutation. La grande majorité des cas concerne la délétion d'AvrLm4-7 mais des mutations dues au RIP et plusieurs autres évènements de mutation provoquant l'introduction prématurée de codons stop dans la séquence codante du gène sont aussi observés. La majorité de ces évènements de mutation sont liés à la reproduction sexuée du champignon et ont lieu au sein même de la parcelle d'étude. Le phénotypage de cette collection a par ailleurs révélé un fort contraste entre les deux sites expérimentaux, démontrant ainsi l'importance des pratiques culturales dans le maintien de l'efficacité de la résistance Rlm7 dans le temps. En effet, après trois années de culture de cultivars Rlm7, la fréquence des souches virulentes a7 dans les populations du site de Versailles reste inférieure à 1 % contre environ 30 % sur le site de Grignon. Finalement, le phénotypage de la collection de souches a également montré que le contournement de Rlm7 s'accompagnait dans plus de 98% des souches de la résurgence de l'avirulence AvrLm3. Par l'étude de cette collection et par croisements génétiques, j'ai pu montrer que AvrLm3 n'était pas un nouvel allèle d'avrLm4-7 mais un second gène situé en région télomérique à 19.3 cM d'AvrLm4-7. J'ai également démontré une interaction fonctionnelle antagoniste entre AvrLm4-7 et AvrLm3 qui empêche la reconnaissance Rlm3 /AvrLm3 en présence d'AvrLm4-7 et explique la restauration de l'avirulence AvrLm3 lors de la perte de l'avirulence AvrLm7.Par une association originale de biologie moléculaire, de génétique des populations et d'agronomie, j'ai ainsi pu apporter une nouvelle illustration à la course aux armements entre un agent pathogène et sa plante hôte, les gènes AvrLm3 et AvrLm4-7 utilisant deux stratégies distinctes afin d'échapper à la reconnaissance de leurs gènes de résistance spécifiques.

Leptosphaeria maculans

Brassica napus

Colza

Avirulence

Interaction

Résistance

Evolution

Plant-Pathogen Interactions: Turnip Crinkle Virus Suppression of the Hypersensitive Response in Arabidopsis thaliana

Christopher, Stephen James

29 April 2003

The presence of turnip crinkle virus (TCV) in Arabidopsis thaliana plants has previously been shown to suppress the ability of these plants to produce a hypersensitive response (HR) upon inoculation with pathogens that would normally elicit this defense response. The ecotype Colombia-0 was examined using wildtype TCV and non-pathogenic strains of Pseudomonas syringae pv. glycinea Race 4 containing virulence genes avrRpt2, avrRpm1 and avrRps4. Transgenic lines of A. thaliana that express the TCV proteins p8, p9 or CP were also examined in an attempt to determine if these proteins play a role in suppression of the HR. Crosses of these transgenic lines were made in order to determine if binary combinations of these proteins were sufficient for HR suppression. In addition, assays were completed to determine if the inhibition of the HR correlated with suppression of resistance to the virulent Pseudomonas syringae pv. maculicola ES4236 avrRpt2 growth in the plant. Finally, PR-1 protein expression was inspected by visual and quantitative GUS reporter gene assays to determine if TCV also played a role in inhibition of the plants ability to develop systemic acquired resistance (SAR).

Turnip crinkle virus

arabidopsis

thaliana

TCV

avrRpt2

avrRpm1

avrRps4

systemic acquired resistance

resistance

plant disease

susceptability

PR-1

transgenics

avirulence

virulence

Avr gene

R gene

pseudomonas syringae.

Plants

Virus resistance

Turnip crinkle virus

Arabidopsis