Andreas Freialdenhoven

SNARE-protein-mediated disease resistance at the plant cell wall

Failure of pathogenic fungi to breach the plant cell wall constitutes a major component of immunity of non-host plant species—species outside the pathogen host range—and accounts for a proportion of aborted infection attempts on ‘susceptible’ host plants (basal resistance). Neither form of penetration resistance is understood at the molecular level. We developed a screen for penetration (pen) mutants of Arabidopsis, which are disabled in non-host penetration resistance against barley powdery mildew, Blumeria graminis f. sp. hordei, and we isolated the PEN1 gene. We also isolated barley ROR2 (ref. 2), which is required for basal penetration resistance against B. g. hordei. The genes encode functionally homologous syntaxins, demonstrating a mechanistic link between non-host resistance and basal penetration resistance in monocotyledons and dicotyledons. We show that resistance in barley requires a SNAP-25 (synaptosome-associated protein, molecular mass 25 kDa) homologue capable of forming a binary SNAP receptor (SNARE) complex with ROR2. Genetic control of vesicle behaviour at penetration sites, and plasma membrane location of PEN1/ROR2, is consistent with a proposed involvement of SNARE-complex-mediated exocytosis and/or homotypic vesicle fusion events in resistance. Functions associated with SNARE-dependent penetration resistance are dispensable for immunity mediated by race-specific resistance (R) genes, highlighting fundamental differences between these two resistance forms.

Identification of Genes Required for the Function of Non-Race-Specific mlo Resistance to Powdery Mildew in Barley.

Recessive alleles (mlo) of the Mlo locus in barley mediate a broad, non-race-specific resistance reaction to the powdery mildew fungus Erysiphe graminis f sp hordei. A mutational approach was used to identify genes that are required for the function of mlo. Six susceptible M2 individuals were isolated after inoculation with the fungal isolate K1 from chemically mutagenized seed carrying the mlo-5 allele. Susceptibility in each of these individuals is due to monogenic, recessively inherited mutations in loci unlinked to mlo. The mutants identify two unlinked complementation groups, designated Ror1 and Ror2 (required for mlo-specified resistance). Both Ror genes are required for the function of different tested mlo alleles and for mlo function after challenge with different isolates of E. g. f sp hordei. A quantitative cytological time course analysis revealed that the host cell penetration efficiency in the mutants is intermediate compared with mlo-resistant and Mlo-susceptible genotypes. Ror1 and Ror2 mutants could be differentiated from each other by the same criterion. The spontaneous formation of cell wall appositions in mlo plants, a subcellular structure believed to represent part of the mlo defense, is suppressed in mlo/ror genotypes. In contrast, accumulation of major structural components in the appositions is seemingly unaltered. We conclude that there is a regulatory function for the Ror genes in mlo-specified resistance and propose a model in which the Mlo wild-type allele functions as a negative regulator and the Ror genes act as positive regulators of a non-race-specific resistance response.

Interaction Analyses of Genes Required for Resistance Responses to Powdery Mildew in Barley Reveal Distinct Pathways Leading to Leaf Cell Death

Race-specific resistance in barley to the powdery mildew fungus (Erysiphe graminis f sp hordei) is associated with a cell death reaction (hypersensitive response [HR]). Genetically, it is dependent on dominant resistance genes (Mlx), and in most cases, it is also dependent on Rar1 and Rar2. Non-race-specific resistance to the fungus, which is due to the lack of the Mlo wild-type allele, is dependent on Ror1 and Ror2 and is not associated with an HR in the region of pathogen attack. However, the absence of the Mlo wild-type allele stimulates a spontaneous cell death response in foliar tissue. This response is also controlled by Ror1 and Ror2, as indicated by trypan blue staining patterns. Lack of Mlo enhances transcript accumulation of pathogenesis-related genes upon fungal challenge, and this response is diminished by mutations in Ror genes. Using DNA marker-assisted selection of genotypes, we provide evidence, via gene interaction studies, that Ror1 and Ror2 are not essential components of race-specific resistance and do not compromise hypersensitive cell death. Reciprocal experiments show that neither is Rar1 a component of mlo-controlled resistance nor does it affect spontaneous cell death. We show that mlo- and Ror-dependent resistance is active when challenged with E. g. f sp tritici, a nonhost pathogen of barley. Our observations suggest separate genetic pathways operating in race-specific and non-race-specific resistance; they indicate also a separate genetic control of hypersensitive and spontaneous cell death in foliar tissue.

Nar-1 and Nar-2, Two Loci Required for Mla12-Specified Race-Specific Resistance to Powdery Mildew in Barley.

Previously isolated susceptible host mutants were used in a genetic and functional study of the resistance response of barley specified by resistance gene Mla12 to the fungal pathogen Erysiphe graminis f sp hordei. Mutant M66 represents a defective allele of Mla12, whereas M22, M82, and M100 represent mutations in loci unlinked to Mla12. Intermutant crosses of the latter three show that susceptibility in M82 and M100 is caused by allelic, recessive mutations that define the Nar-1 gene (necessary for Mla12 resistance gene 1), whereas the semidominant mutation in M22 defines a second unlinked locus, Nar-2. We show that both genes are required for resistance specified by Mlal2 in different genetic backgrounds of barley. Nar-1 maps on barley chromosome 2 within an ~6-centimorgan restriction fragment length polymorphism interval: this is 0.5 centimorgans from the anthocyanin pigmentation gene Ant2. Quantitative cytological analysis showed that functional alleles of Mla12, Nar-1, and Nar-2 are required for triggering a cell death reaction of attacked host cells at early stages during infection. Functional alleles of all three genes were also required for high-level transcript accumulation of barley defense-related genes that encode chitinase, peroxidase, and pathogenesis-related protein-1. The data support the hypothesis that host cell death and high-level accumulation of defense-related gene transcripts, which are under common control of Mla12, Nar-1, and Nar-2, are crucial events of race-specific resistance to powdery mildew.

High-resolution genetic and physical mapping of the Rar1 locus in barley

Abstract The Mla-12-mediated resistance in barley against Erysiphe graminis f. sp. hordei requires for its function the Rar1 gene. High-resolution genetic mapping was accomplished by inspecting more than 4000 plants segregating for Rar1 within an 0.7-cM interval containing the target gene. Marker enrichment in the target region was carried out by an amplified fragment length polymorphism (AFLP)-based search for polymorphic loci using bulked DNA templates from resistant and susceptible recombinants adjacent to Rar1. RFLP markers closely linked to Rar1 were used to investigate the relationship between physical and genetical distances by PFGE Southern analysis, indicating the physical linkage of two genetically separated RFLP loci. Comparative mapping of Rar1-linked RFLP probes in barley and rice identified a break of collinearity in the orthologous chromosome segments.

Barley Rom1 Reveals a Potential Link Between Race-Specific and Nonhost Resistance Responses to Powdery Mildew Fungi

The Rar1 gene, identified in the context of race-specific powdery mildew resistance mediated by the Hordeum vulgare (barley) resistance (R) gene Mla12, is required for the function of many R-mediated defense responses in mono- and dicotyledonous plant species. Mla resistance is associated with an oxidative burst and a subsequent cell death reaction of attacked cells. Rar1 mutants are impaired in these responses and, to identify genetic elements which negatively regulate the Mla12-triggered response, we have screened mutagenized Mla12 rar1 mutant populations for restoration of the resistance response. Here we describe the restoration of Mla12-specified resistance (rom1) mutant that restores features of disease resistance to a Blumeria graminis f. sp. hordei isolate expressing the avirulence gene AvrMla12 and retains susceptibility to an isolate lacking AvrMla12. Histochemical analyses show that, in rom1 mutant plants, a whole-cell oxidative burst and cell death response in attacked epidermal cells is restored in the incompatible interaction. Defense responses against tested inappropriate powdery mildews, B. graminis f. sp. tritici and Golovinomyces orontii, were diminished in rar1 mutant plants and enhanced in rom1 mutant plants relative to the wild type. These findings indicate antagonistic activities of Rar1 and Rom1 and reveal their contribution to nonhost and race-specific resistance responses.

Dissection of Resistance Pathways in Barley to Powdery Mildew Attack

Erysiphe graminis f sp hordei is an obligate biotrophic fungus that exclusively attacks epidermal leaf tissue of its host, barley. In a compatible interaction, the following fungal structures differentiate successively within the first 24 hr after contact of a spore with the wax layer of a barley leaf [1]: the primary germ tube, the appressorial germ tube, and the haustorium, which invaginates the epidermal plasma membrane after penetration of the cell wall. Formation of aerial mycelium and sporulation represent late differentiation events between 4-7 days post inoculation. In many incompatible interactions the development of the fungus usually is abrogated either before or during haustorium differentiation. In these cases, incompatibility can be envisaged as a single-cell event mediated by the host epidermal cell attacked first. Two putative resistance responses are easily detected in the attacked host cell: a subcellularly restricted, highly localized cell wall apposition (cwa) at attempted penetration sites (which is often termed papilla) and/or the activation of a cell death response (indicated by whole-cell autofluorescence which is often termed hypersensitive response (HR);[2]).