Differences in early callose deposition during adapted and non-adapted powdery mildew infection of resistant Arabidopsis lines

The deposition of callose, a (1,3)-β-glucan cell wall polymer, can play an essential role in the defense response to invading pathogens. We could recently show that Arabidopsis thaliana lines with an overexpression of the callose synthase gene PMR4 gained complete penetration resistance to the adapted powdery mildew Golovinomyces cichoracearum and the non-adapted powdery mildew Blumeria graminis f. sp hordei. The penetration resistance is based on the transport of the callose synthase PMR4 to the site of attempted fungal penetration and the subsequent formation of enlarged callose deposits. The deposits differed in their total diameter comparing both types of powdery mildew infection. In this study, further characterization of these callose deposits revealed that size differences were especially pronounced in the core region of the deposits. This suggests that specific, pathogen-dependent factors exist, which might regulate callose synthase transport to the core region of forming deposits.     

Interplay between JA, SA and ABA signalling during basal and induced resistance against Pseudomonas syringae and Alternaria brassicicola

We have examined the role of the callose synthase PMR4 in basal resistance and β-aminobutyric acid-induced resistance (BABA-IR) of Arabidopsis thaliana against the hemi-biotrophic pathogen Pseudomonas syringae and the necrotrophic pathogen Alternaria brassicicola . Compared to wild-type plants, the pmr4-1 mutant displayed enhanced basal resistance against P. syringae , which correlated with constitutive expression of the PR-1 gene. Treating the pmr4-1 mutant with BABA boosted the already elevated levels of PR-1 gene expression, and further increased the level of resistance. Hence, BABA-IR against P. syringae does not require PMR4-derived callose. Conversely, pmr4-1 plants showed enhanced susceptibility to A. brassicicola , and failed to show BABA-IR. Wild-type plants showing BABA-IR against A. brassicicola produced increased levels of JA. The pmr4-1 mutant produced less JA upon A. brassicicola infection than the wild-type. Blocking SA accumulation in pmr4-1 restored basal resistance, but not BABA-IR against A. brassicicola . This suggests that the mutant's enhanced susceptibility to A. brassicicola is caused by SA-mediated suppression of JA, whereas the lack of BABA-IR is caused by its inability to produce callose. A. brassicicola infection suppressed ABA accumulation. Pre-treatment with BABA antagonized this ABA accumulation, and concurrently potentiated expression of the ABA-responsive ABI1 gene. Hence, BABA prevents pathogen-induced suppression of ABA accumulation, and sensitizes the tissue to ABA, causing augmented deposition of PMR4-derived callose.     

Enhancing blast disease resistance by overexpression of the calcium‐dependent protein kinase OsCPK4 in rice

Rice is the most important staple food for more than half of the human population, and blast disease is the most serious disease affecting global rice production. In this work, the isoform OsCPK4 of the rice calcium‐dependent protein kinase family is reported as a regulator of rice immunity to blast fungal infection. It shows that overexpression of OsCPK4 gene in rice plants enhances resistance to blast disease by preventing fungal penetration. The constitutive accumulation of OsCPK4 protein prepares rice plants for a rapid and potentiated defence response, including the production of reactive oxygen species, callose deposition and defence gene expression. OsCPK4 overexpression leads also to constitutive increased content of the glycosylated salicylic acid hormone in leaves without compromising rice yield. Given that OsCPK4 overexpression was known to confer also salt and drought tolerance in rice, the results reported in this article demonstrate that OsCPK4 acts as a convergence component that positively modulates both biotic and abiotic signalling pathways. Altogether, our findings indicate that OsCPK4 is a potential molecular target to improve not only abiotic stress tolerance, but also blast disease resistance of rice crops.     

Secreted Fungal Effector Lipase Releases Free Fatty Acids to Inhibit Innate Immunity-Related Callose Formation during Wheat Head Infection

The deposition of the (1,3)-β-glucan cell wall polymer callose at sites of attempted penetration is a common plant defense response to intruding pathogens and part of the plant’s innate immunity. Infection of the Fusarium graminearum disruption mutant Δfgl1, which lacks the effector lipase FGL1, is restricted to inoculated wheat (Triticum aestivum) spikelets, whereas the wild-type strain colonized the whole wheat spike. Our studies here were aimed at analyzing the role of FGL1 in establishing full F. graminearum virulence. Confocal laser-scanning microscopy revealed that the Δfgl1 mutant strongly induced the deposition of spot-like callose patches in vascular bundles of directly inoculated spikelets, while these callose deposits were not observed in infections by the wild type. Elevated concentrations of the polyunsaturated free fatty acids (FFAs) linoleic and α-linolenic acid, which we detected in F. graminearum wild type-infected wheat spike tissue compared with Δfgl1-infected tissue, provided clear evidence for a suggested function of FGL1 in suppressing callose biosynthesis. These FFAs not only inhibited plant callose biosynthesis in vitro and in planta but also partially restored virulence to the Δfgl1 mutant when applied during infection of wheat spikelets. Additional FFA analysis confirmed that the purified effector lipase FGL1 was sufficient to release linoleic and α-linolenic acids from wheat spike tissue. We concluded that these two FFAs have a major function in the suppression of the innate immunity-related callose biosynthesis and, hence, the progress of F. graminearum wheat infection.The molecular and physiological regulation of the biosynthesis of callose, which is a (1,3)-β-glucan polymer with some (1,6)-branches (Aspinall and Kessler, 1957), and its importance for plant development as well as plant defense are still under examination. Regarding the involvement of callose in plant defense responses, particular attention has been focused on the formation of cell wall thickenings in plants, so-called papillae, at sites of microbial attack. They were already described 150 years ago (deBary, 1863) and reported to commonly contain callose (Mangin, 1895). Since then, examinations have identified callose as the most abundant chemical constituent in papillae, which may also include proteins (e.g. peroxidases and antimicrobial thionins), phenolics, and other constituents (Aist and Williams, 1971; Sherwood and Vance, 1976; Mims et al., 2000). Papillae have been regarded as an early defense reaction that may not completely stop the pathogen; rather, they have been considered to act as a physical barrier to slow pathogen invasion (Stone and Clarke, 1992; Voigt and Somerville, 2009) and to contribute to the plant’s innate immunity (Jones and Dangl, 2006; Schwessinger and Ronald, 2012). The host plant can gain time to initiate defense reactions that require gene activation and expression, such as the hypersensitive reactions, phytoalexin production, and pathogenesis-related protein synthesis (Lamb and Dixon, 1997; Brown et al., 1998). However, our recent study revealed that callose can also act as a barrier that completely prevents fungal penetration. The overexpression of POWDERY MILDEW RESISTANT4 (PMR4), a gene encoding a stress-induced callose synthase, resulted in early elevated callose deposition at sites of attempted powdery mildew penetration in Arabidopsis (Arabidopsis thaliana; Ellinger et al., 2013). Interestingly, the pmr4 deletion mutant also showed an increased resistance to powdery mildew that, however, was induced at later stages of powdery mildew infection because an initial fungal penetration still occurred. In fact, the absence of the functional callose synthase PMR4 in the pmr4 mutant resulted in papillae that were free from callose but also induced a hyperactivation of the salicylic acid defense pathway, which was shown to be the basis of resistance in double mutant and microarray analyses (Jacobs et al., 2003; Nishimura et al., 2003). The callose synthase gene PMR4 from Arabidopsis belongs to the GLUCAN SYNTHASE-LIKE (GSL) family, genes that have been identified in higher plants including wheat (Triticum aestivum; Cui et al., 2001; Doblin et al., 2001; Hong et al., 2001; Østergaard et al., 2002; Voigt et al., 2006). The predicted function of these genes as callose synthases is generally supported by homology with the yeast FK506 SENSITIVITY (FKS) genes, which are believed to be subunits of (1,3)-β-glucan synthase complexes (Douglas et al., 1994; Dijkgraaf et al., 2002). Additionally, the predicted proteins encoded by the GSL genes correlate with the approximately 200-kD catalytic subunit of putative callose synthases. Li et al. (2003) showed that the amino acid sequence predicted from a GSL gene in barley (Hordeum vulgare; HvGSL1) correlates with the amino acid sequence of an active (1,3)-β-glucan synthase fraction.In this study, we aimed to examine the involvement of callose synthesis and callose deposition in plant defense against intruding fungal pathogens in the pathosystem wheat-Fusarium graminearum. We focused on the ability of wheat to inhibit a further spread of fungal pathogens after an initial, successful infection. This resistance to fungal spread within the host has been referred to as type II resistance and is part of a widely accepted two-component system of resistance, which includes type I resistance operating against initial infection (Schroeder and Christensen, 1963). For our analyses, we used the direct interaction between wheat as host and F. graminearum as a pathogen. On the one hand, Fusarium head blight (FHB) of wheat, caused by F. graminearum, is one of the most destructive crop diseases worldwide (McMullen et al., 1997; del Blanco et al., 2003; Madgwick et al., 2011) and classifies this fungus as a top 10 plant pathogen based on its importance in science and agriculture (Dean et al., 2012). On the other hand, only a limited number of wheat cultivars were identified that revealed FHB resistance. However, these cultivars did not qualify for commercial cultivation or breeding approaches due to inappropriate agronomic traits (Buerstmayr et al., 2009). Further elucidation of the mechanisms of spreading resistance could support the generation of FHB-resistant wheat cultivars.In this regard, we demonstrated that the secreted lipase FGL1 of F. graminearum is a virulence factor required for wheat infection (Voigt et al., 2005). A strong resistance to fungal spread was observed in a susceptible wheat cultivar after infection with the lipase-deficient F. graminearum strain Δfgl1. Light microscopy indicated barrier formation in the transition zone of rachilla and rachis of directly inoculated spikelets. In contrast, neither spreading resistance nor barrier formation was observed during F. graminearum wild type infection. An active role of lipases in establishing full virulence was also recently proposed for the plant pathogen Fusarium oxysporum f. sp. lycopersici, where reduced lipolytic activity due to the deletion of lipase regulatory genes resulted in reduced colonization of tomato (Solanum lycopersicum) plants (Bravo-Ruiz et al., 2013). Because the expression of the lipase-encoding gene LIP1 was induced in the biotrophic fungus Blumeria graminis during early stages of infection (Feng et al., 2009) and disruption of the putative secreted lipase gene lipA resulted in reduced virulence of the bacterial plant pathogen Xanthomonas campestris (Tamir-Ariel et al., 2012), a general importance of extracellular lipolytic activity during plant colonization is indicated.We evaluated a possible role of callose in plant defense by infecting wheat spikes with the virulent fungal pathogen F. graminearum wild type, the virulence-deficient F. graminearum deletion mutant Δfgl1, and the barley leaf pathogen Pyrenophora teres, the latter intended to induce strong plant defense responses as known from incompatible, nonhost interactions. The formation of callose plugs within the vascular bundles of inoculated spikelets and the callose synthase activity of infected spikelet tissue correlated directly with increased plant resistance. Subsequent analyses of free fatty acid (FFA) concentrations revealed that those polyunsaturated FFAs were enriched during wheat infection with the F. graminearum wild-type strain that could inhibit callose synthase activity in vitro as well as in planta and partially restored the virulence of the lipase-deficient F. graminearum strain Δfgl1. On the basis of these results, we propose a model for FHB where defense-related callose synthase is inhibited by specific FFAs whose accumulation is caused by the fungus during fungal infection; this inhibition is required for full infection of the wheat head.     

Arabidopsis ocp3 mutant reveals a mechanism linking ABA and JA to pathogen-induced callose deposition

In the present study, we evaluated the role of the defense-related gene OCP3 in callose deposition as a response to two necrotrophic fungal pathogens, Botrytis cinerea and Plectosphaerella cucumerina. ocp3 plants exhibited accelerated and intensified callose deposition in response to fungal infection associated with enhanced disease resistance to the two pathogens. A series of double mutant analyses showed potentiation of callose deposition and the heightened disease resistance phenotype in ocp3 plants required the plant hormone abscisic acid (ABA) and the PMR4 gene encoding a callose synthase. This finding was congruent with an observation that ocp3 plants exhibited increased ABA accumulation, and ABA was rapidly synthesized following fungal infection in wild-type plants. Furthermore, we determined that potentiation of callose deposition in ocp3 plants, including enhanced disease resistance, also required jasmonic acid (JA) recognition though a COI1 receptor, however JA was not required for basal callose deposition following fungal infection. In addition, potentiation of callose deposition in ocp3 plants appeared to follow a different mechanism than that proposed for callose β-amino-butyric acid (BABA)-induced resistance and priming, because ocp3 plants responded to BABA-induced priming for callose deposition and induced resistance of a magnitude similar to that observed in wild-type plants. Our results point to a model in which OCP3 represents a specific control point for callose deposition regulated by JA yet ultimately requiring ABA. These results provide new insights into the mechanism of callose deposition regulation in response to pathogen attack; however the complexities of the processes remain poorly understood.     

PMR5, an acetylation protein at the intersection of pectin biosynthesis and defense against fungal pathogens

Powdery mildew (Golovinomyces cichoracearum), one of the most prolific obligate biotrophic fungal pathogens worldwide, infects its host by penetrating the plant cell wall without activating the plant's innate immune system. The Arabidopsis mutant powdery mildew resistant 5 (pmr5) carries a mutation in a putative pectin acetyltransferase gene that confers enhanced resistance to powdery mildew. Here, we show that heterologously expressed PMR5 protein transfers acetyl groups from [¹⁴C]‐acetyl‐CoA to oligogalacturonides. Through site‐directed mutagenesis, we show that three amino acids within a highly conserved esterase domain in putative PMR5 orthologs are necessary for PMR5 function. A suppressor screen of mutagenized pmr5 seed selecting for increased powdery mildew susceptibility identified two previously characterized genes affecting the acetylation of plant cell wall polysaccharides, RWA2 and TBR. The rwa2 and tbr mutants also suppress powdery mildew disease resistance in pmr6, a mutant defective in a putative pectate lyase gene. Cell wall analysis of pmr5 and pmr6, and their rwa2 and tbr suppressor mutants, demonstrates minor shifts in cellulose and pectin composition. In direct contrast to their increased powdery mildew resistance, both pmr5 and pmr6 plants are highly susceptibile to multiple strains of the generalist necrotroph Botrytis cinerea, and have decreased camalexin production upon infection with B. cinerea. These results illustrate that cell wall composition is intimately connected to fungal disease resistance and outline a potential route for engineering powdery mildew resistance into susceptible crop species.     

Lic4, a nuclear phosphoprotein that cooperates with calcineurin to regulate cation homeostasis in Saccharomyces cerevisiae

The target of the immunosuppressants cyclosporin A(CsA) and FK506 is calcineurin, a highly conserved protein phosphatase that is required for T-cell activation and the regulation of ion homeostasis in yeast. Here we identify two genes, PMR2B and LIC4 which, when overexpressed, suppress the cation-sensitive phenotype of yeast cells lacking calcineurin. PMR2B encodes a Na⁺/Li⁺-specific plasma membrane pump and is similar to PMR2A, whose expression is known to be regulated by calcineurin. LIC4 (lithium comvertas) encodes a novel 33-kDa protein with no identity to known proteins. LIC4 overexpression suppresses the Li⁺-sensitive phenotype of calcineurin mutants but not the defect in recovery from pheromone arrest or viability of calcineurin dependent mutants, indicating a specific role in cation homeostasis. Similarly, lic4 mutations increase the Li⁺ sensitivity of both wild-type and calcineurin mutant strains, and reduce expression of pmr2A in calcineurin mutant strains, indicating that calcineurin and Lic4 may regulate parallel cation homeostatic pathways. lic4 mutations also exacerbate the Li⁺-sensitive phenotype of hal3 mutant strains, and overexpression of either Lic4 or Hal3 suppresses the salt sensitivity of mutant strains lacking calcineurin, Hal3, or Lic4, either singly or in combination. Taken together, these observations suggest that calcineurin, Hal3, and Lic4 cooperatively regulate the response of yeast cells to?cation stress. Lic4 is phosphoprotein in vivo and a calcineurin substrate in vitro. By indirect and direct immunofluorescence detection of HA- and GFP-tagged proteins, Lic4 is localized in the nucleus in wild-type cells but predominantly cytoplasmic in cells lacking calcineurin. Taken together, our findings support a model in which calcineurin and Lic4 are components of signalling cascades that regulate cation stress responses in yeast.     

ABA is required for Leptosphaeria maculans resistance via ABI1- and ABI4-dependent signaling

Abscisic acid (ABA) is a defense hormone with influence on callose-dependent and -independent resistance against Leptosphaeria maculans acting in the RLMcol pathway. ABA-deficient and -insensitive mutants in Ler-0 background (abal-3 and abil-1) displayed susceptibility to L. maculans, along with a significantly decreased level of callose depositions, whereas abi2-1 and abi3-1 remained resistant, together with the abi5-1 mutant of Ws-0 background. Suppressor mutants of abil-1 confirmed that the L. maculans-susceptible response was due to the dominant negative nature of the abil-1 mutant. Highly induced camalexin levels made ABA mutants in Col-0 background (aba2-1, aba3-1, and abi4-1) appear resistant, but displayed enhanced susceptibility as double mutants with pad3-1, impaired in camalexin biosynthesis. beta-Aminobutyric acid (BABA) pretreatment of Ler-0 contributed to an elevated level of endogenous ABA after L. maculans inoculation. Comparisons between (RLM1co1)pad3 and rlmlLerpad3 showed that ABA and BABA enhancement of callose deposition requires induction from RLM1col. ABII, but not ABI2, was found to be involved in a feedback mechanism that modulates RLM1co, expression. Genetic analysis showed further that this feedback occurs upstream of ABI4 and that components downstream of ABI4 modulate ABIJ activity. ABA and BABA treatments of the L. maculans-susceptible callose synthase mutant pmr4 showed that ABA also induces a callose-independent resistance. Similar treatments enhanced callose depositions and induced resistance to L. maculans in oilseed rape, and BABA-induced resistance was found to be independent of salicylic acid.     

Rapid linkage of indole carboxylic acid to the plant cell wall identified as a component of basal defence in Arabidopsis against hrp mutant bacteria

Changes occurring to plant cell walls were examined following inoculation of Arabidopsis leaves with pathogenic and non-pathogenic (hrpA mutant) strains of Pseudomonas syringae pv. tomato. We have targeted low molecular weight, cross-linked phenolic and indolic compounds that were released from wall preparations by alkaline hydrolysis at 70 °C and in a microwave bomb. Significantly higher concentrations of syringaldehyde, p hydroxybenzaldehyde and indole carboxylic acid were recovered from cell walls isolated from leaves 24 h after challenge with the hrpA mutant compared with wild-type DC3000. Time course experiments showed that the accumulation of indole carboxylic acid and the other group of differentiating metabolites had occurred within 12 h of inoculation. The callose synthase deficient mutant pmr4-1 was more resistant than wild-type Columbia plants to P. syringae pv. tomato. Restricted bacterial multiplication was associated with increased accumulation of indole carboxylic acid on the plant cell wall. In the absence of callose deposition in the pmr 4-1 mutant, indolic derivatives may serve as a structural scaffold for wall modifications following bacterial challenge.     

Priming for JA-dependent defenses using hexanoic acid is an effective mechanism to protect Arabidopsis against B. cinerea

Soil drench treatments with hexanoic acid can effectively protect Arabidopsis plants against Botrytis cinerea through a mechanism based on a stronger and faster accumulation of JA-dependent defenses.Plants impaired in ethylene, salicylic acid, abscisic acid or glutathion pathways showed intact protection by hexanoic acid upon B. cinerea infection. Accordingly, no significant changes in the SA marker gene PR-1 in either the SA or ABA hormone balance were observed in the infected and treated plants. In contrast, the JA signaling pathway showed dramatic changes after hexanoic acid treatment, mainly when the pathogen was present. The impaired JA mutants, jin1-2 and jar1, were unable to display hexanoic acid priming against the necrotroph. In addition, hexanoic acid-treated plants infected with B. cinerea showed priming in the expression of the PDF1.2, PR-4 and VSP1 genes implicated in the JA pathways. Moreover, JA and OPDA levels were primed at early stages by hexanoic acid. Treatments also stimulated increased callose accumulation in response to the pathogen. Although callose accumulation has proved an effective IR mechanism against B. cinerea, it is apparently not essential to express hexanoic acid-induced resistance (HxAc-IR) because the mutant pmr4.1 (callose synthesis defective mutant) is protected by treatment.We recently described how hexanoic acid treatments can protect tomato plants against B. cinerea by stimulating ABA-dependent callose deposition and by priming OPDA and JA-Ile production. We clearly demonstrate here that Hx-IR is a dependent plant species, since this acid protects Arabidopsis plants against the same necrotroph by priming JA-dependent defenses without enhancing callose accumulation.     

Penetration and Post-Penetration Resistance to Magnaporthe oryzae in Arabidopsis

The rate of entry of Magnaporthe oryzae into the Arabidopsis pen2 quintuple (pen2 NahG pmr5 agb1 mlo2) mutant was significantly higher than those into the pen2 quadruple (pen2 NahG pmr5 agb1 and pen2 NahG pmr5 mlo2) mutants. The lengths of the infection hyphae in the pen2 quintuple mutant were intermediate between the pen2 quadruple mutants. These results suggest that different genetic networks, consisting of PEN2, PMR5, AGB1, and MLO2, control penetration and post-penetration resistance to M. oryzae in Arabidopsis.     

The Plasmodesmal Protein PDLP1 Localises to Haustoria-Associated Membranes during Downy Mildew Infection and Regulates Callose Deposition

The downy mildew pathogen Hyaloperonospora arabidopsidis (Hpa) is a filamentous oomycete that invades plant cells via sophisticated but poorly understood structures called haustoria. Haustoria are separated from the host cell cytoplasm and surrounded by an extrahaustorial membrane (EHM) of unknown origin. In some interactions, including Hpa-Arabidopsis, haustoria are progressively encased by host-derived, callose-rich materials but the molecular mechanisms by which callose accumulates around haustoria remain unclear. Here, we report that PLASMODESMATA-LOCATED PROTEIN 1 (PDLP1) is expressed at high levels in Hpa infected cells. Unlike other plasma membrane proteins, which are often excluded from the EHM, PDLP1 is located at the EHM in Hpa-infected cells prior to encasement. The transmembrane domain and cytoplasmic tail of PDLP1 are sufficient to convey this localization. PDLP1 also associates with the developing encasement but this association is lost when encasements are fully mature. We found that the pdlp1,2,3 triple mutant is more susceptible to Hpa while overexpression of PDLP1 enhances plant resistance, suggesting that PDLPs enhance basal immunity against Hpa. Haustorial encasements are depleted in callose in pdlp1,2,3 mutant plants whereas PDLP1 over-expression elevates callose deposition around haustoria and across the cell surface. These data indicate that PDLPs contribute to callose encasement of Hpa haustoria and suggests that the deposition of callose at haustoria may involve similar mechanisms to callose deposition at plasmodesmata.     

Extracellular transport and integration of plant secretory proteins into pathogen-induced cell wall compartments

Many fungal parasites enter plant cells by penetrating the host cell wall and, thereafter, differentiate specialized intracellular feeding structures, called haustoria, by invagination of the plant's plasma membrane. Arabidopsis PEN gene products are known to act at the cell periphery and function in the execution of apoplastic immune responses to limit fungal entry. This response underneath fungal contact sites is tightly linked with the deposition of plant cell wall polymers, including PMR4/GSL5-dependent callose, in the paramural space, thereby producing localized wall thickenings called papillae. We show that powdery mildew fungi specifically induce the extracellular transport and entrapment of the fusion protein GFP–PEN1 syntaxin and its interacting partner monomeric yellow fluorescent protein (mYFP)–SNAP33 within the papillary matrix. Remarkably, PMR4/GSL5 callose, GFP–PEN1, mYFP–SNAP33, and the ABC transporter GFP–PEN3 are selectively incorporated into extracellular encasements surrounding haustoria of the powdery mildew Golovinomyces orontii , suggesting that the same secretory defense responses become activated during the formation of papillae and haustorial encasements. This is consistent with a time-course analysis of the encasement process, indicating that these extracellular structures are generated through the extension of papillae. We show that PMR4/GSL5 callose accumulation in papillae and haustorial encasements occurs independently of PEN1 syntaxin. We propose a model in which exosome biogenesis/release serves as a common transport mechanism by which the proteins PEN1 and PEN3, otherwise resident in the plasma membrane, together with membrane lipids, become stably incorporated into both pathogen-induced cell wall compartments.     

Powdery Mildew Resistance in Tomato by Impairment of SlPMR4 and SlDMR1

Genetic dissection of disease susceptibility in Arabidopsis to powdery and downy mildew has identified multiple susceptibility (S) genes whose impairment results in disease resistance. Although several of these S-genes have been cloned and characterized in more detail it is unknown to which degree their function in disease susceptibility is conserved among different plant species. Moreover, it is unclear whether impairment of such genes has potential in disease resistance breeding due to possible fitness costs associated with impaired alleles. Here we show that the Arabidopsis PMR4 and DMR1, genes encoding a callose synthase and homoserine kinase respectively, have functional orthologs in tomato with respect to their S-gene function. Silencing of both genes using RNAi resulted in resistance to the tomato powdery mildew fungus Oidium neolycopersici. Resistance to O. neolycopersici by SlDMR1 silencing was associated with severely reduced plant growth whereas SlPMR4 silencing was not. SlPMR4 is therefore a suitable candidate gene as target for mutagenesis to obtain alleles that can be deployed in disease resistance breeding of tomato.     

Cell wall synthesis in cotton roots after infection with Fusarium oxysporum

Fusarium oxysporum f. sp. vasinfectum penetration hyphae infect living cells in the meristematic zone of cotton (Gossypium barbadense L.) roots. We characterized wall modifications induced by the fungus during infection of the protodermis using antibodies against callose, arabinogalactan-proteins, xyloglucan, pectin, polygalacturonic acid and rhamnogalacturonan I in high-pressure frozen, freeze-substituted root tissue. Using quantitative immunogold labelling we compared the cell walls before and after hyphal contact, cell plates with plasmodesmata during cytokinesis, and wall appositions induced by fungal contact. In the already-existing wall, fungal contact induced only minor modifications such as an increase of xyloglucan epitopes. Wall appositions mostly exhibited epitopes similar to the cell plate except that wall appositions had a much higher callose content. This study shows that wall appositions induced by Fusarium oxysporum hyphae are the result of normal cell wall synthesis and the addition of large amounts of callose. The appositions do not stop fungal growth.     

Lic4, a nuclear phosphoprotein that cooperates with calcineurin to regulate cation homeostasis in Saccharomyces cerevisiae

The target of the immunosuppressants cyclosporin A(CsA) and FK506 is calcineurin, a highly conserved protein phosphatase that is required for T-cell activation and the regulation of ion homeostasis in yeast. Here we identify two genes, PMR2B and LIC4 which, when overexpressed, suppress the cation-sensitive phenotype of yeast cells lacking calcineurin. PMR2B encodes a Na⁺/Li⁺-specific plasma membrane pump and is similar to PMR2A, whose expression is known to be regulated by calcineurin. LIC4 (lithium comvertas) encodes a novel 33-kDa protein with no identity to known proteins. LIC4 overexpression suppresses the Li⁺-sensitive phenotype of calcineurin mutants but not the defect in recovery from pheromone arrest or viability of calcineurin dependent mutants, indicating a specific role in cation homeostasis. Similarly, lic4 mutations increase the Li⁺ sensitivity of both wild-type and calcineurin mutant strains, and reduce expression of pmr2A in calcineurin mutant strains, indicating that calcineurin and Lic4 may regulate parallel cation homeostatic pathways. lic4 mutations also exacerbate the Li⁺-sensitive phenotype of hal3 mutant strains, and overexpression of either Lic4 or Hal3 suppresses the salt sensitivity of mutant strains lacking calcineurin, Hal3, or Lic4, either singly or in combination. Taken together, these observations suggest that calcineurin, Hal3, and Lic4 cooperatively regulate the response of yeast cells to␣cation stress. Lic4 is phosphoprotein in vivo and a calcineurin substrate in vitro. By indirect and direct immunofluorescence detection of HA- and GFP-tagged proteins, Lic4 is localized in the nucleus in wild-type cells but predominantly cytoplasmic in cells lacking calcineurin. Taken together, our findings support a model in which calcineurin and Lic4 are components of signalling cascades that regulate cation stress responses in yeast. Received: 17 August 1998 / Accepted: 7 December 1998     

<Emphasis Type="Italic">Arabidopsis</Emphasis> KHZ1 and KHZ2, two novel non-tandem CCCH zinc-finger and K-homolog domain proteins,have redundant roles in the regulation of flowering and senescence

Key message

Progression of the infection canal that conducts rhizobia to the nodule primordium requires a functional Rab GTPase located in Golgi/trans-Golgi that also participate in root hair polar growth.

Abstract

Common bean (Phaseolus vulgaris) symbiotically associates with its partner Rhizobium etli, resulting in the formation of root nitrogen-fixing nodules. Compatible bacteria can reach cortical cells in a tightly regulated infection process, in which the specific recognition of signal molecules is a key step to select the symbiotic partner. In this work, we show that RabA2, a monomeric GTPase from common bean, is required for the progression of the infection canal, referred to as the infection thread (IT), toward the cortical cells. Expression of miss-regulated mutant variants of RabA2 resulted in an increased number of abortive infection events, including bursting of ITs and a reduction in the number of nodules. Nodules formed in these plants were small and contained infected cells with disrupted symbiosome membranes, indicating either early senescence of these cells or defects in the formation of the symbiosome membrane during bacterial release. RabA2 localized to mobile vesicles around the IT, but mutations that affect GTP hydrolysis or GTP/GDP exchange modified this localization. Colocalization of RabA2 with ArfA1 and a Golgi marker indicates that RabA2 localizes in Golgi stacks and the trans-Golgi network. Our results suggest that RabA2 is part of the vesicle transport events required to maintain the integrity of the membrane during IT progression.