Polymorphic change of appressoria by the tomato powdery mildew Oidium neolycopersici on host tomato leaves reflects multiple unsuccessful penetration attempts

The appressorial shapes of the powdery mildews are an important clue to the taxonomy of the powdery mildew fungi, but the conidia of the tomato powdery mildew Oidium neolycopersici KTP-01 develop non-lobed, nipple-shaped, and moderately lobed or multilobed appressoria on the same leaves. To remove this ambiguity, we performed consecutive observations of sequential appressorial development of KTP-01 conidia with a high-fidelity digital microscope. Highly germinative conidia of KTP-01, collected from conidial pseudochains formed on the tomato leaves, were inoculated into host tomato and nonhost barley leaves or an artificial hydrophobic membrane (Parafilm). Events from germination initiation to appressorium formation were synchronous in all conidia on all materials used for inoculation, but post-appressorial behaviors varied among the materials. Appressoria on the membrane-stuck glass slide formed several projections at different portions of the appressoria to repeat unsuccessful penetration attempts. Similar unsuccessful penetration behavior by KTP-01 conidia was observed in the inoculations into leaves of barley plants, wild tomato species Lycopersicon peruvianum LA2172 (carrying the Ol-4 gene for powdery mildew resistance), and a susceptible host tomato (Lycopersicon esculentum) that had been inoculated with the barley powdery mildew (Blumeria graminis f. sp. hordei, race 1) conidia. On the barley leaves, all penetrations of KTP-01 were impeded by the papillae formed beneath the sites of the appressorial projections. On both the wild tomato and the race 1-inoculated cultivated tomato plants, KTP-01 conidia were prevented from forming functional haustoria by hypersensitive epidermal cell death; this hypersensitive reaction involved the Ol-4 gene in the wild tomato plants or the 'induced resistance' acquired by the nonpathogenic conidia previously inoculated into the cultivated tomato plants. All these KTP-01 conidia produced several projections on the appressoria during the repeated unsuccessful penetration attempts and eventually exhibited multilobed appressoria. On the host tomato leaves inoculated singly with KTP-01 conidia, fewer than 20% of the conidia located appressoria on the central part of target epidermal cells and succeeded in forming functional haustoria at the first penetration attempt without forming an appressorial projection. These conidia exhibited non-lobed appressoria. The remaining conidia, however, whose appressoria were located on/near the border of the target epidermal cells, were more likely to fail to penetrate at the first penetration, and then to develop additional projections for subsequent penetrations. Most conidia succeeded in forming functional haustoria at the second to fourth penetration attempts, but a few conidia failed to produce haustoria at all attempted penetrations. Eventually, the conidia that succeeded at the second penetration possessed a single appressorial projection (exhibiting the nipple-shaped appressoria), whereas the remaining conidia exhibited moderately lobed appressoria with two to four appressorial projections and multilobed appressoria, with more projections. Thus, the present study revealed that the basic shape of appressoria of KTP-01 was the non-lobed type, and that polymorphic changes of the appressoria occurred as a result of successive production of projections during repeated unsuccessful penetration attempts.     

Barley MLO modulates actin-dependent and actin-independent antifungal defense pathways at the cell periphery

Cell polarization is a crucial process during plant development, as well as in plant-microbe interactions, and is frequently associated with extensive cytoskeletal rearrangements. In interactions of plants with inappropriate fungal pathogens (so-called non-host interactions), the actin cytoskeleton is thought to contribute to the establishment of effective barriers at the cell periphery against fungal ingress. Here, we impeded actin cytoskeleton function in various types of disease resistance using pharmacological inhibitors and genetic interference via ectopic expression of an actin-depolymerizing factor-encoding gene, ADF. We demonstrate that barley (Hordeum vulgare) epidermal cells require actin cytoskeleton function for basal defense to the appropriate powdery mildew pathogen Blumeria graminis f. sp. hordei and for mlo-mediated resistance at the cell wall, but not for several tested race-specific immune responses. Analysis of non-host resistance to two tested inappropriate powdery mildews, Erysiphe pisi and B. graminis f. sp. tritici, revealed the existence of actin-dependent and actin-independent resistance pathways acting at the cell periphery. These pathways act synergistically and appear to be under negative control by the plasma membrane-resident MLO protein.     

Nonhost resistance in Arabidopsis-Colletotrichum interactions acts at the cell periphery and requires actin filament function

Pathogenesis of nonadapted fungal pathogens is often terminated coincident with their attempted penetration into epidermal cells of nonhost plants. The genus Colletotrichum represents an economically important group of fungal plant pathogens that are amenable to molecular genetic analysis. Here, we investigated interactions between Arabidopsis and Colletotrichum to gain insights in plant and pathogen processes activating nonhost resistance responses. Three tested nonadapted Colletotrichum species differentiated melanized appressoria on Arabidopsis leaves but failed to form intracellular hyphae. Plant cells responded to Colletotrichum invasion attempts by the formation of PMR4/GSL5-dependent papillary callose. Appressorium differentiation and melanization were insufficient to trigger this localized plant cell response, but analysis of nonpathogenic C. lagenarium mutants implicates penetration-peg formation as the inductive cue. We show that Arabidopsis PEN1 syntaxin controls timely accumulation of papillary callose but is functionally dispensable for effective preinvasion (penetration) resistance in nonhost interactions. Consistent with this observation, green fluorescent protein-tagged PEN1 did not accumulate at sites of attempted penetration by either adapted or nonadapted Colletotrichum species, in contrast to the pronounced focal accumulations of PEN1 associated with entry of powdery mildews. We observed extensive reorganization of actin microfilaments leading to polar orientation of large actin bundles towards appressorial contact sites in interactions with the nonadapted Colletotrichum species. Pharmacological inhibition of actin filament function indicates a functional contribution of the actin cytoskeleton for both preinvasion resistance and papillary callose formation. Interestingly, the incidence of papilla formation at entry sites was greatly reduced in interactions with C. higginsianum isolates, indicating that this adapted pathogen may suppress preinvasion resistance at the cell periphery.     

Dynamic reorganization of microfilaments and microtubules is necessary for the expression of non-host resistance in barley coleoptile cells

To show the involvement of microfilaments and microtubules in non-host resistance of barley, partially dissected coleoptiles which had been inoculated with a non-pathogen, Erysiphe pisi, were treated with several actin and tubulin inhibitors. If the coleoptiles were not treated with any of the inhibitors, the non-pathogen always failed to penetrate the coleoptile cells. However, when coleoptiles were treated with actin or tubulin polymerization or depolymerization inhibitors, the non-pathogen was able to penetrate successfully and to form haustoria in coleoptile cells of a non-host plant, barley. Actin polymerization inhibitors, cytochalasins, were more effective in causing an increase in penetration efficiency of E. pisi than tubulin inhibitors. The effects of cytochalasins depended on the kind of cytochalasin; the strength of the actin depolymerizing activity correlated significantly with the efficiency of increasing the penetration of the non-pathogen. When both actin and tubulin inhibitors were added simultaneously, the polarization of defense-related responses, such as massive cytoplasmic aggregation, deposition of papillae and accumulation of autofluorescent compounds, at fungal penetration sites was suppressed. Actin inhibitors did not affect arrangement and stability of microtubules and vice versa, and a double treatment of coleoptile cells with both microfilament and microtubule inhibitors showed an additive effect in increasing the penetration efficiency of E. pisi. Furthermore, cytochalasin A treatment allowed other non-pathogens, Colletotrichum lagenarium and Alternaria alternata, to penetrate successfully into the non-host barley cells. These results strongly suggest that microfilaments and microtubules might play important roles in the expression of non-host resistance of barley.     

The morphology of the imperfect states of powdery mildews (Erysiphaceae)

In contrast to popular belief, a rich variety of morphological characteristics exists in the imperfect states of powdery mildews. Because it has been generally assumed that species cannot be distinguished by their appressoria, haustoria, conidiophores, conidia, fibrosin bodies, and conidial germ tubes, their morphology has received little attention and several older publications have even been forgotten. As with the perfect states, few species can be recognized by one characteristic of the imperfect state alone but many species can be identified when a combination of several characteristics is used. Important characteristics are the location of the mycelium, the production of conidia singly or in chains, the presence or absence of conspicuous fibrosin bodies, the appressoria, the size and shape of the conidia, and the position and type of their germ tubes. Many species are associated with particular families or genera of plants and therefore these are included in a key to identify 131 species of powdery mildew. This key shows how much and especially how little is known about many species. It is hoped that this review will stimulate study of the morphology of the imperfect states of numerous species. Consideration of both the perfect and the imperfect state should result in a more natural classification of several genera, for exampleUncinula andErysiphe which at present include both species which produce conidia in long chains and those which produce conidia singly. It appears that there are two lines of development of the imperfect states. One is characterized by lobed appressoria and conidiophores which produce conidia singly. The other is characterized by more or less rounded, unlobed appressoria and conidiophores which produce conidia in chains. A better knowledge of all the different imperfect states may provide more information regarding the evolution of powdery mildews.     

The receptor-like MLO protein and the RAC/ROP family G-protein RACB modulate actin reorganization in barley attacked by the biotrophic powdery mildew fungus Blumeria graminis f.sp. hordei

Cytoskeleton remodelling is a crucial process in determining the polarity of dividing and growing plant cells, as well as during interactions with the environment. Nothing is currently known about the proteins, which regulate actin remodelling during interactions with invading pathogens. The biotrophic powdery mildew fungus Blumeria graminis f.sp. hordei (Bgh) invades susceptible barley (Hordeum vulgare L.) by penetrating epidermal cells, which remain intact during fungal development. In contrast, resistant host plants prevent infection by inhibiting penetration through apoplastic mechanisms, which require focusing defence reactions on the site of attack. We stained actin filaments in a susceptible Mlo-genotype and a near-isogenic race-non-specifically resistant barley mlo5-mutant genotype using fluorescence-labelled phalloidin after chemical fixation. This revealed that the actin cytoskeleton is differentially reorganized in susceptible and resistant hosts challenged by Bgh. Actin filaments were polarized towards the sites of attempted penetration in the resistant host, whereas when susceptible hosts were penetrated, a more subtle reorganization took place around fungal haustoria. Strong actin filament focusing towards sites of fungal attack was closely associated with successful prevention of penetration. Actin focusing was less frequent and seemingly delayed in susceptible wild-type barley expressing the susceptibility factor MLO. Additionally, single cell overexpression of a constitutively activated RAC/ROP G-protein, CA RACB, another potential host susceptibility factor and hypothetical actin cytoskeleton regulator, partly inhibited actin reorganization when under attack from Bgh, whereas knockdown of RACB promoted actin focusing. We conclude that RACB and, potentially, MLO are host proteins involved in the modulation of actin reorganization and cell polarity in the interaction of barley with Bgh.     

Suppression of the powdery mildew pathogen by chitinase microinjected into barley coleoptile epidermal cells

An exogenous chitinase from Streptomyces griseus was introduced into coleoptile epidermal cells of barley (Hordeum vulgare) by microinjection, and the effect of injected chitinase on the growth or development of the powdery mildew pathogen (Erysiphe graminis f. sp. hordei) was examined. Prior to microinjection, an enzymatic degradation of fungal haustorium, the organ taking nutrients from host plant cells, was examined by treating fixed coleoptile epidermis harboring haustoria with this enzyme. The result showed that haustoria were effectively digested by chitinase, suggesting the effectiveness of chitinase treatment for suppressing the fungal development. Microinjection of chitinase was conducted using living coleoptile tissues inoculated with the pathogen. Epidermal cells in which the haustorial primordia had been formed, or in which the haustoria had matured, were selected as targets for injection. The result clearly indicated that injection at the stage of primordium formation was effective in completely digesting haustoria and suppressing the subsequent formation of secondary hyphae of the pathogen. In microinjection after haustorial maturation, hyphal elongation was considerably suppressed though there was no detectable morphological change in the haustoria. Thus, the present study provides the experimental basis for genetically manipulating barley to produce transgenic plants resistant to the powdery mildew disease.     

Specific Isolation of RNA from the Grape Powdery Mildew Pathogen Erysiphe necator, an Epiphytic, Obligate Parasite

RNA expression profiling of obligately parasitic plant microbes is hampered by the requisite interaction of host and parasite. This can be especially problematic in the case of powdery mildews, such as Erysiphe necator (syn. Uncinula necator ), which grow superficially but tightly adhere to the plant epidermis. We developed and refined a simple and efficient technique in which nail polish was used to remove conidia, appressoria, hyphae, conidiophores, and developing ascocarps of E. necator from grapevine ( Vitis vinifera ) leaves and showed that RNA isolated after removal was not contaminated with V. vinifera RNA. This approach can be applied to expression analyses throughout fungal development and could be extended to other epiphytic pathogens and saprophytes.     

Targeted destruction of fungal structures of Erysiphe trifoliorum on flat leaf surfaces of Marchantia polymorpha

In this study, we observed the germination behaviour of airborne conidia from powdery mildews that settle on thalloid surfaces. We inoculated thalli (flat, sheet‐like leaf tissues) and gemmae (small, flat, sheet‐like leaf tissues that propagate asexually via bud‐like structures) of the common liverwort (Marchantia polymorpha) with conidia from tomato powdery mildew (Oidium neolycopersici; KTP‐02) and red clover powdery mildew (Erysiphe trifoliorum; KRCP‐4N) and examined their germination and subsequent appressorium formation under a high‐fidelity digital microscope. Conidial bodies and germ tubes of the inoculated KRCP‐4N conidia were destroyed on both the thalli and gemmae. The destruction of these fungal structures was observed only for KRCP‐4N conidia inoculated onto M. polymorpha on both leaf surfaces. No differences in destruction of the KRCP‐4N fungal structures between thalli and gemmae were observed. At 4 h post‐inoculation, destruction of the germ tube tip was observed when it reached the gemmae leaf surface. At 6 h post‐inoculation, the conidial bodies and germ tubes were destroyed. In contrast, KTP‐02 conidia were not destroyed and formed normal, well‐lobed appressoria on the surface of M. polymorpha gemmae.     

Actin Microfilaments are Required for the Expression of Nonhost Resistance in Higher Plants

We investigated the role of actin microfilaments in nonhostresistance of higher plants. Here we present several lines ofevidence to indicate that microfilaments are indeed involvedin blocking fungal penetration of nonhost plants. Erysiphe pisi,a pathogen of pea, normally fails to penetrate into nonhostplants such as barley, wheat, cucumber and tobacco. When tissuesof these nonhost plants were treated with cytochalasins, specificinhibitors of actin polymerization, this fungus became ableto penetrate and formed haustoria in epidermal cells of theseplants. Moreover, treatment of these plants with various kindsand concentrations of cytochalasins allowed several other non-pathogenicfungi, E.graminis hordei, E.graminis tritici, Sphaerotheca fuliginea,Colletotrichum graminicola, My-cosphaella pinodes, C. lagenarium,Altemaria kikuchiana and Corynespora melonis, to also penetratethe cells of these plants. The degree of microfilament depolymeriza-tionvaried depending on the kinds and concentrations of cytochalasinsapplied and we show that this is significantly correlated withthe penetration efficiency of C. graminicola. This indicatesthat the polymerized, filamentous state of actin is necessaryfor plants to block fungal penetration. These results stronglysuggest that actin microfilaments may play important roles inthe expression of nonhost resistance of higher plants. ¹Contribution no. 129 from the Laboratory of Plant Pathology,Mie University     

The ARP2/3 complex,acting cooperatively with Class I formins,modulates penetration resistance in Arabidopsis against powdery mildew invasion

The actin cytoskeleton regulates an array of diverse cellular activities that support the establishment of plant–microbe interactions and plays a critical role in the execution of plant immunity. However, molecular and cellular mechanisms regulating the assembly and rearrangement of actin filaments (AFs) at plant–pathogen interaction sites remain largely elusive. Here, using live-cell imaging, we show that one of the earliest cellular responses in Arabidopsis thaliana upon powdery mildew attack is the formation of patch-like AF structures beneath fungal invasion sites. The AFs constituting actin patches undergo rapid turnover, which is regulated by the actin-related protein (ARP)2/3 complex and its activator, the WAVE/SCAR regulatory complex (W/SRC). The focal accumulation of phosphatidylinositol-4,5-bisphosphate at fungal penetration sites appears to be a crucial upstream modulator of the W/SRC–ARP2/3 pathway-mediated actin patch formation. Knockout of W/SRC–ARP2/3 pathway subunits partially compromised penetration resistance with impaired endocytic recycling of the defense-associated t-SNARE protein PEN1 and its deposition into apoplastic papillae. Simultaneously knocking out ARP3 and knocking down the Class I formin (AtFH1) abolished actin patch formation, severely impaired the deposition of cell wall appositions, and promoted powdery mildew entry into host cells. Our results demonstrate that the ARP2/3 complex and formins, two actin-nucleating systems, act cooperatively and contribute to Arabidopsis penetration resistance to fungal invasion.

ARP2/3 complex, acting cooperatively with Class I formins, modulates actin patch formation beneath fungal penetration sites, contributing to the penetration resistance of Arabidopsis against powdery mildew invasion.     

Mechanisms of powdery mildew resistance in the Vitaceae family

The cultivated grapevine, Vitis vinifera, is a member of the Vitaceae family, which comprises over 700 species in 14 genera. Vitis vinifera is highly susceptible to the powdery mildew pathogen Erysiphe necator. However, other species within the Vitaceae family have been reported to show resistance to this fungal pathogen, but little is known about the mechanistic basis of this resistance. Therefore, the frequency of successful E. necator penetration events, in addition to programmed cell death (PCD) responses, were investigated in a representative genotype from a range of different species within the Vitaceae family. The results revealed that penetration resistance and PCD-associated responses, or combinations of both, are employed by the different Vitaceae genera to limit E. necator infection. In order to further characterize the cellular processes involved in the observed penetration resistance, specific inhibitors of the actin cytoskeleton and secretory/endocytic vesicle trafficking function were employed. These inhibitors were demonstrated to successfully break the penetration resistance in V. vinifera against the nonadapted powdery mildew E. cichoracearum. However, the use of these inhibitors with the adapted powdery mildew E. necator unexpectedly revealed that, although secretory and endocytic vesicle trafficking pathways play a crucial role in nonhost penetration resistance, the adapted powdery mildew species may actually require these pathways to successfully penetrate the plant host.     

Conidia of <Emphasis Type="Italic">Erysiphe trifoliorum</Emphasis> attempt penetration twice during a two-step germination process on non-host barley leaves and an artificial hydrophobic surface

In the present study, using a high-fidelity digital microscope, we observed the sequence of appressorial development on the germ tubes of a powdery mildew fungus isolated from red clover leaves. Based on its morphological characteristics and rDNA internal transcribed spacer (ITS) sequences, the fungus was identified as Erysiphe trifoliorum, and one of its isolates, designated as KRCP-4N, was used in this work. The conidial germination of isolate KRCP-4N was studied on host (red clover) and non-host (barley) leaves, as well as on an artificial hydrophobic membrane (Parafilm). More than 90% of conidia germinated synchronously and developed dichotomous appressoria (symmetrical double-headed appressoria) on all substrata used. On host leaves, all appressorium-forming conidia developed hyphae (colony-forming hyphae) from conidial bodies without extending germ tubes from the tips of the appressoria. On non-host leaves and on Parafilm-covered glass slides, however, all conidia extended germ tubes from one side of dichotomous appressoria (two-step germination). In addition to the dichotomous appressoria, we detected a few conidia that produced hooked appressoria and extended germ tubes from the tip of the appressorium. Penetration attempts by KRCP-4N conidia on barley leaves were impeded by papillae formed at penetration sites beneath these two types of appressorium. From these results, we conclude that the “two-step germination” of E. trifoliorum KRCP-4N conidia is the result of an unsuccessful penetration attempt, causing diversity in appressorial shape.     

Overexpression of GhPFN2 enhances protection against Verticillium dahliae invasion in cotton

Growing evidence indicates that actin cytoskeleton is involved in plant innate immune responses,but the functional mechanism remains largely unknown.Here,we investigated the behavior of a cotton profilin gene(GhPFN2) in response to Verticillium dahliae invasion,and evaluated its contribution to plant defense against this soil-borne fungal pathogen.GhPFN2 expression was up-regulated when cotton root was inoculated with V.dahliae,and the actin architecture was reorganized in the infected root cells,with a clear increase in the density of filamentous actin and the extent of actin bundling.Compared to the wild type,GhPFN2-overexpressing cotton plants showed enhanced protection against V.dahliae infection and the actin cytoskeleton organization in root epidermal cells was clearly altered,which phenocopied that of the wild-type(WT) root cells challenged with V.dahliae.These results provide a solid line of evidence showing that actin cytoskeleton reorganization involving GhPFN2 is important for defense against V.dahliae infection.     

Transient over-expression of barley BAX Inhibitor-1 weakens oxidative defence and MLA12-mediated resistance to Blumeria graminis f.sp. hordei

BAX Inhibitor-1 (BI-1) is a conserved cell death suppressor protein. In barley, BI-1 ( HvBI-1 ) expression is induced upon powdery mildew infection and when over-expressed in epidermal cells of barley, HvBI-1 induces susceptibility to the biotrophic fungal pathogen Blumeria graminis . We co-expressed mammalian pro-apoptotic BAX together with HvBI-1, and the mammalian BAX antagonist BCL-X_L in barley epidermal cells. BAX expression led to cessation of cytoplasmic streaming and collapse of the cytoplasm while co-expression of HvBI-1 and BCL-X_L partially or completely, respectively, rescued cells from BAX lethality. When B. graminis was attacking epidermal cells, a green fluorescent protein fusion of HvBI-1 accumulated at the site of attempted penetration and was also present around haustoria. Over-expression of HvBI-1 in epidermal cells weakened a cell-wall-associated local hydrogen peroxide burst in a resistant mlo -mutant genotype and supported haustoria accommodation in race-specifically resistant MLA12 -barley. HvBI-1 is a cell death regulator protein of barley with the potential to suppress host defence reactions.     

The powdery mildew resistance protein RPW8.2 is carried on VAMP721/722 vesicles to the extrahaustorial membrane of haustorial complexes

Plants employ multiple cell‐autonomous defense mechanisms to impede pathogenesis of microbial intruders. Previously we identified an exocytosis defense mechanism in Arabidopsis against pathogenic powdery mildew fungi. This pre‐invasive defense mechanism depends on the formation of ternary protein complexes consisting of the plasma membrane‐localized PEN1 syntaxin, the adaptor protein SNAP33 and closely sequence‐related vesicle‐resident VAMP721 or VAMP722 proteins. The Arabidopsis thaliana resistance to powdery mildew 8.2 protein (RPW8.2) confers disease resistance against powdery mildews upon fungal entry into host cells and is specifically targeted to the extrahaustorial membrane (EHM), which envelops the haustorial complex of the fungus. However, the secretory machinery involved in trafficking RPW8.2 to the EHM is unknown. Here we report that RPW8.2 is transiently located on VAMP721/722 vesicles, and later incorporated into the EHM of mature haustoria. Resistance activity of RPW8.2 against the powdery mildew Golovinomyces orontii is greatly diminished in the absence of VAMP721 but only slightly so in the absence of VAMP722. Consistent with this result, trafficking of RPW8.2 to the EHM is delayed in the absence of VAMP721. These findings implicate VAMP721/722 vesicles as key components of the secretory machinery for carrying RPW8.2 to the plant–fungal interface. Quantitative fluorescence recovery after photobleaching suggests that vesicle‐mediated trafficking of RPW8.2–yellow fluorescent protein (YFP) to the EHM occurs transiently during early haustorial development and that lateral diffusion of RPW8.2–YFP within the EHM exceeds vesicle‐mediated replenishment of RPW8.2–YFP in mature haustoria. Our findings imply the engagement of VAMP721/722 in a bifurcated trafficking pathway for pre‐invasive defense at the cell periphery and post‐invasive defense at the EHM.     

A barley ROP GTPase ACTIVATING PROTEIN associates with microtubules and regulates entry of the barley powdery mildew fungus into leaf epidermal cells

Little is known about the function of host factors involved in disease susceptibility. The barley (Hordeum vulgare) ROP (RHO of plants) G-protein RACB is required for full susceptibility of the leaf epidermis to invasion by the biotrophic fungus Blumeria graminis f. sp hordei. Stable transgenic knockdown of RACB reduced the ability of barley to accommodate haustoria of B. graminis in intact epidermal leaf cells and to form hairs on the root epidermis, suggesting that RACB is a common element of root hair outgrowth and ingrowth of haustoria in leaf epidermal cells. We further identified a barley MICROTUBULE-ASSOCIATED ROP-GTPASE ACTIVATING PROTEIN (MAGAP1) interacting with RACB in yeast and in planta. Fluorescent MAGAP1 decorated cortical microtubules and was recruited by activated RACB to the cell periphery. Under fungal attack, MAGAP1-labeled microtubules built a polarized network at sites of successful defense. By contrast, microtubules loosened where the fungus succeeded in penetration. Genetic evidence suggests a function of MAGAP1 in limiting susceptibility to penetration by B. graminis. Additionally, MAGAP1 influenced the polar organization of cortical microtubules. These results add to our understanding of how intact plant cells accommodate fungal infection structures and suggest that RACB and MAGAP1 might be antagonistic players in cytoskeleton organization for fungal entry.     

DEVELOPMENT OF POWDERY MILDEW (ERYSIPHE POLYGONI) ON SUSCEPTIBLE AND RESISTANT RACES OF OENOTHERA BIENNIS

Races of Oenothera biennis (evening primrose) resistant and susceptible to Erysiphe polygoni (a powdery mildew fungus) were artificially inoculated with E. polygoni and the time course and mode of disease development recorded. This study was the initial stage in investigating the host's resistance mechanism(s). On leaves of susceptible and resistant races, spores germinated within 5 hr, appressoria were formed in 8-12 hr, and penetration had been effected and haustoria initiated by 20 hr. There was no further development on resistant plants. On susceptible hosts, secondary penetration occurred by 26 hr after inoculation, secondary haustoria were formed, and sporulating colonies were seen in 4 days. It was concluded that the fungus is unable to establish a feeding relationship with the epidermal cells of resistant Oe. biennis, marking the period between 20 and 26 hr after inoculation as the time frame for the manifestation of the resistance mechanism(s).     

Effect of exogenous cytokinins on dynamics of development and differentiation of infectious structures of the pathogen of wheat powdery mildew

The infectious structures for the development and differentiation of Erysiphe graminis DC. f. sp. tritici March., the pathogen of wheat powdery mildew, under the effects of exogenous zeatin was studied by methods of light and electron scanning microscopy. It was shown for the first time that physiologically active substances, specifically phytohormones of the cytokinin type, can affect dimensions of the halo revealed in the pathogen penetration site at cytochemical staining. Treatment with zeatin affected conidia germination and pathogen growth in the ectophytic stage. The concentration curve of the action of zeatin for the number of mature pathogen colonies (6 days after infection) was represented by a multiphase curve with two maxima (1 and 3 μM) and one minimum (1.5 μM). Similar curves have been obtained for the number of normal appressoria and for large halo diameters, which possibly indicates the existence of the factors affecting these both parameters, as well as the final number of pathogen colonies. The obtained data indicate that the origin of the multiphase dose response curve for effect of cytokinins on the development of powdery mildew pathogen is connected with factors that are active at the early stages of pathogenesis.     

New records of microcyclic conidiogenesis in some powdery mildew fungi

Microcyclic conidiogenesis (MC) was recently described in several species of powdery mildew fungi. This process, defined as the production of conidia on a fungal spore without any, or only a minimal, involvement of hyphal growth, was observed on powdery mildew conidia that have already germinated on host plant surfaces and have been attached to the epidermal cells. Most probably, MC contributes to a quick propagation of young powdery mildew colonies because new conidia are sometimes produced in a shorter time on microcyclic conidiophores than on the hyphae of the young mycelium. This article reports MC in Erysiphe necator ex grapevine, Podosphaera leucotricha ex apple, Golovinomyces orontii ex tobacco, and Neoerysiphe galeopsidis ex Lamium purpureum based on light and low-temperature scanning electron microscopic studies.