Ultrastructural and cytochemical studies on the infection of wheat spikes by<Emphasis Type="Italic">Fusarium culmorum</Emphasis> as well as on degradation of cell wall components and localization of mycotoxins in the host tissue

The infection process and pathway of spreading ofFusarium culmorum in wheat spikes was examined by means of light, scanning and transmission electron microscopy after spray inoculation and single spikelet inoculation. Macroconidia of the pathogen germinated on the host surfaces, however, hyphal development and penetration of host tissues normally occurred on the inner surfaces of the lemma, glume and palea as well as on the ovary. The pathogen spread downward to the rachilla and rachis node by inter- and intracellular growth from the glume, lemma, palea and ovary. The pathogen extended in the rachis in upward and downward direction by inter- and intracellular growth inside and outside of the vascular bundles of the rachis. The spreading of the hyphae in the host tissues was associated with pronounced alterations including disintegration and digestion of host cell walls, suggesting production of cell wall degrading enzymes during infection and spreading in the host tissues. Immunogold labelling studies revealed that accumulation ofFusarium toxins in infected wheat spike tissue showed a close relationship to pathological changes in the host cells, symptom appearance and pathogen colonisation of the host tissue.Fusarium toxins may play an important role in wheat head blight development.     

Colonisation patterns of root tissues byPhytophthora nicotianae var.parasitica related to reduced disease in mycorrhizal tomato

Tomato plants pre-colonised by the arbuscular mycorrhizal fungusGlomus mosseae showed decreased root damage by the pathogenPhytophthora nicotianae var.parasitica. In analyses of the cellular bases of their bioprotective effect, a prerequisite for cytological investigations of tissue interactions betweenG. mosseae andP. nicotianae v.parasitica was to discriminate between the hyphae of the two fungi within root tissues. We report the use of antibodies as useful tools, in the absence of an appropriate stain for distinguishing hyphae ofP. nicotianae v.parasitica from those ofG. mosseae inside roots, and present observations on the colonisation patterns by the pathogenic fungus alone or during interactions in mycorrhizal roots. Infection intensity of the pathogen, estimated using an immunoenzyme labelling technique on whole root fragments, was lower in mycorrhizal roots. Immunogold labelling ofP. nicotianae v.parasitica on cross-sections of infected tomato roots showed that inter or intracellular hyphae developed mainly in the cortex, and their presence induced necrosis of host cells, the wall and contents of which showed a strong autofluorescence in reaction to the pathogen. In dual fungal infections of tomato root systems, hyphae of the symbiont and the pathogen were in most cases in different root regions, but they could also be observed in the same root tissues. The number ofP. nicotianae v.parasitica hyphae growing in the root cortex was greatly reduced in mycorrhizal root systems, and in mycorrhizal tissues infected by the pathogen, arbuscule-containing cells surrounded by intercellularP. nicotianae v.parasitica hyphae did not necrose and only a weak autofluorescence was associated with the host cells. Results are discussed in relation to possible processes involved in the phenomenon of bioprotection in arbuscular mycorrhizal plants.     

Wheat cells accumulate a syringyl-rich lignin during the hypersensitive resistance response

The stem rust fungus Puccinia graminis f.sp. tritici is an obligately biotrophic pathogen attacking wheat (Triticum aestivum). In compatible host/pathogen-interactions, the fungus participates in the host's metabolism by establishing functional haustoria in the susceptible plant cells. In highly resistant wheat cultivars, fungal attack is stopped by a hypersensitive response of penetrated host cells. This mechanism of programmed cell death of single plant cells is accompanied by the intracellular accumulation of material with UV-fluorescence typical of phenolic compounds. A similar reaction can be induced in healthy wheat leaves by the application of a rust-derived elicitor. We analysed the biochemical composition of this defense-induced phenolic material. Contents of total soluble and cell wall esterified and etherified phenolic acids were determined in rust-inoculated and elicitor-treated leaves of the fully susceptible wheat cultivar Prelude and its highly resistant, near-isogenic line Prelude-Sr5. While no resistance-related changes occured in any of these fractions, the lignin content as determined by the thioglycolic acid and the acetyl bromide methods increased after elicitor treatment. Nitrobenzene oxidation revealed that the entire increase can be explained by an increase in syringyl units only. These biochemical data were confirmed by fluorescence emission spectra analyses which indicated a defense-induced enrichment of syringyl lignin for cell wall samples both from elicitor-treated wheat leaves and single host cells undergoing a hypersensitive response upon fungal penetration.     

Observations on the Responses of Lentil Root Cells to Hyphae of Fusarium oxysporum

The infection of lentil roots by Fusarium oxysporum Schlecht and the responses of the host cells to invading hyphae were examined by light microscopy. Hyphae from inoculum placed on the zone of cell elongation entered the roots at the juncture of epidermal cells within 8 h after inoculation. Although swollen hyphal apices were observed on the epidermal cells, root penetration occurred without formation of these structures or appressoria. The sheath of material found on the surface of uninoculated roots was absent from inoculated roots penetrated by hyphae. Prior to penetration, the epidermal cells became irregular in shape and their cytoplasm appeared to be plasmolysed or granular. Hyphae were observed in the cortex 10—12 h after inoculation and non–penetrated cortical cells were distinctly lobate. Often these lobed cells had a broad, peripheral band of diffuse cytoplasm. When hyphae were first observed in the cortical cells, the walls were ruptured and only slightly stained or unstained by toluidine blue. The inability of such walls to bind the stain may have been the result of the removal of wall components by fungal enzymes. Although extensive proliferation of hyphae was evident throughout the cortex after 24 h of incubation, the endodermis and vascular cylinder were free of hyphae for at least 72 h. Hyphae from inoculum placed on the root hairs or the root apex failed to penetrate the roots during the first 24 h of incubation. The cytological results herein are discussed in relation to the infection of field plantings by this pathogen.     

Ultrastructural and Cytochemical Studies on Cellulose, Xylan and Pectin Degradation in Wheat Spikes Infected by Fusarium culmorum

The cell wall components cellulose, xylan and pectin in different tissues of noninoculated healthy and Fusarium culmorum (W. G. Smith) Sacc-infected wheat spikes were localized by means of enzyme-gold and immuno-gold labelling techniques. The cell walls in the ovary, lemma and rachis of the healthy wheat spike showed labellings in different patterns and densities with cellulase-gold and xylanase-gold probes, as well as with the antipectin monoclonal antibody JIM7. The inter- and intracellular growth of the pathogen in the ovary, lemma and rachis of the infected wheat spike, not only caused pronounced alterations of cell walls and middle lamella matrices, but also led to marked modifications of cell wall components. The enzyme-gold and immuno-gold labellings in the infected host tissues revealed that the labelling densities for cellulose, xylan and pectin were significantly reduced in the cell walls of infected ovary, lemma and rachis as compared with corresponding healthy host tissues. The host cell walls in contact with or close to hyphae of the pathogen showed more marked morphological changes and much greater reduction of the labelling density than those in distance from the hyphae. These results provide evidence that F. culmorum may produce cell-wall-degrading enzymes such as cellulases, xylanases and pectinases during infection and colonization of wheat spikes tissues. Furthermore, at the early stage of infection (e.g. 3 days after inoculation), the degradation of pectin was greater than that of cellulose and xylan in the cell walls of the same infected host tissues, indirectly suggesting that the pectinases may be secreted earlier or exert higher activities than cellulases and xylanases.     

Anatomical study on the interaction between the root endophytic fungus <Emphasis Type="Italic">Heteroconium chaetospira</Emphasis> and Chinese cabbage

Chinese cabbage roots colonized by the dematiaceous fungal taxon Heteroconium chaetospira were previously found to become highly resistant to clubroot and Verticillium yellows. The dematiaceous fungus possesses an endophytic nature, but no detailed anatomical studies on endophyte–host plant interactions have so far been provided. Light and electron microscopy revealed that hyphae of H. chaetospira were abundant on and inside the root epidermal cells by 3 weeks following inoculation. The penetration pegs easily breached into epidermal cells, and the infection hyphae penetrated into cortical cells. Some appressorium-like swollen structures formed from intracellular hyphae, but no visible degradation of the host cell walls was evident where the hyphae contacted. No visible signs of host reactions and no invagination of the host plasma membrane around the hyphae were seen in the host cells. By 8 weeks following inoculation, masses of closely packed fungal cells had been formed in some cells of the epidermis and cortical layers, but further hyphal ingress was halted, mostly in the inner cortical cell layer. Thus, root vascular cylinders remained intact.     

小麦雪霉叶枯病菌侵染过程的细胞学研究

采用电镜技术研究了小麦雪霉叶枯病菌(Gerlachia nivalis)侵染过程的细胞学特征。电镜观察发现,分生孢子萌发产生的芽管由孢子细胞壁内层延伸而成;病菌侵入寄主体内后,胞间菌丝先在寄主细胞间扩展,随后胞间菌丝侵入坏死的寄主细胞,形成胞内菌丝;胞间菌丝和胞内菌丝在形态结构上无明显差异。在病菌扩展过程中,寄主细胞发生了一系列的病理变化,并最终坏死消解,寄主细胞的变化可能与病菌分泌的毒素有关。     

Fungal endophytes in Astromyelon-type (Sphenophyta,Equisetales, Calamitaceae) roots from the Upper Pennsylvanian of France

A distinctive fungal endophyte, Cashhickia acuminata nov. gen. et sp., is described from permineralized calamite roots from the Upper Pennsylvanian Grand-Croix cherts of France. Heavily infected roots contain numerous intracellular hyphae in the outer cortex that arise from a meshwork-like mycelium extending between cortical cells. All intracellular hyphae are oriented toward the root center; none occur on the inner periclinal host cell walls. Other roots of the same type show localized infection by this fungus in which isolated cortical cells contain or give rise to intracellular fungal growth. Within the cortical cells are host responses in the form of callosities that indicate the roots were alive at the time of infection. Other endophytes are present in the same host tissue but are less frequent. The discovery of this association provides the first detailed account on the morphology of a Carboniferous fungal root endophyte, as well as the spatial distribution within the host, and infection pathways within the cortical tissues.     

Ultrastructural Changes Caused by Fusarium oxysporum f. sp. lycopersici in Meloidogyne javanica Induced Giant Cells in Fusarium Resistant and Susceptible Tomato Cultivars

Tomato (Lycopersicon esculentum Mill.) seedlings, susceptible (cv. Pearson A-I Improved) and resistant (cv. Pearson Improved) to race 1 Fusarium oxysporum f. sp. lycopersici (Sacc.) Snyd &Hans., were inoculated with Meloidogyne javanica (Trueb) Chitwood second-stage juveniles and 3 weeks later with race 1 F. oxysporum f. sp. lycopersici spores. One week after fungal inoculation, no fungus was visible in root tissue of the tomato cultivars and the giant cells were normal. Two weeks after fungal inoculation, abundant hyphae were visible in xylem tissues of Fusarium-susceptible but not of Fusarium-resistant plants. In susceptible plants, giant cell degeneration occurred, characterized by membrane and organelle disruption. In addition, where hyphae were in direct contact with the giant cell, dissolution of the giant cell wall occurred. Three weeks after fungal inoculation, fungal hyphae and spores were visible inside xylem tissues and giant cells in Fusarium-susceptible plants and in xylem tissue of the resistant plants. In susceptible and resistant plants, giant cell degeneration was apparent. Giant cell walls were completely broken down in Fusarium-susceptible tomato plants. In both cultivars infected by Fusarium, giant cell nuclei became spherical and dark inclusions occurred within the chromatin material which condensed adjacent to the fragmented nuclear membrane. No such ultrastructural changes were seen in the giant cells of control plants inoculated with nematode alone. Giant cell deterioration in both cultivars is probably caused by toxic fungal metabolites.     

The mode of interaction between Vitis and Plasmopara viticola Berk. & Curt. Ex de Bary depends on the host species

In order to obtain insight into host responses to grapevine downy mildew ( Plasmopara viticola ), we compared pathogen development on a panel of Vitis species from North America, Asia and Europe. Leaf discs from different host species were inoculated in parallel, and the colonisation of the mesophyll was visualised by aniline blue staining and quantified with respect to infection incidence and mycelial growth. In parallel, the morphology of guard cells was screened for the presence of an internal cuticular rim after staining with acridine orange and using low-temperature scanning electron microscopy. We observed three response patterns: (i) inhibition of pathogen development early after attachment of zoospores; (ii) successful colonisation of the mesophyll by the pathogen; and (iii) aberrant development, where the pathogen does not attach to guard cells, but produces hyphae on the leaf surface without formation of viable sporangiophores. Inhibition is observed in the North American and Siberian species, successful colonisation prevails in the European hosts, and surface hyphae are found on non-Siberian Asiatic species. We propose that the interaction between host and pathogen is under control of specific signals that have been subject to evolutionary diversification.     

Successful Agrobacterium mediated transformation of Thielaviopsis basicola by optimizing multiple conditions

Thielaviopsis basicola is a hemibiotrophic root pathogen causing black root rot in a wide range of economically important crops. Our initial attempts to transform T. basicola using standard Agrobacterium tumefaciens–mediated transformation (ATMT) protocols were unsuccessful. Successful transformation required the addition of V8 juice (to induce germination of T. basicola chlamydospores) and higher concentrations of acetosyringone in the co-cultivation medium, and of chlamydospores/endoconidia, A. tumefaciens cells during co-cultivation. With these modifications, two T. basicola strains were successfully transformed with the green (egfp) or red (AsRed) fluorescent protein genes. Chlamydospores/endoconidia transformed with the egfp gene exhibited strong green fluorescence, but their fluorescence became weaker as the germ tubes emerged. Transformants harbouring the AsRed gene displayed strong red fluorescence in both chlamydospores/endoconidia and germ tubes. Fluorescent microscopic observations of an AsRed-labelled strain colonizing roots of transgenic Nicotiana benthamiana plants, which express the actin filaments labelled with EGFP, at 24 hours post inoculation showed varying levels of fungal germination and penetration. At this stage, the infection appeared to be biotrophic with the EGFP-labelled host actin filaments not being visibly degraded, even in host root cells in close contact with the hyphae. This is the first report of ATMT of T. basicola, and the use of an AsRed-labelled strain to directly observe the root infection process.     

Cytological Study of Wheat Spike Infection by Bipolaris sorokiniana

The infection of wheat spikelets by Bipolaris sorokiniana , the causal agent of black point on grains and grain shrivelling, was examined by light and electron microscopy. Conidia of the pathogen germinated 6–12 h after inoculation on the surfaces of the different spike tissues. Extracellular sheaths were observed on germ tubes and appressoria attached to the surfaces of lemma, palea and seeds, but were only scarcely detected on the surface of conidia. Appressoria, frequently found over grooves, formed penetration hyphae invading the epidermal cell walls. Infection process was similar on the surface of the lemma, palea and glume. Growth of the fungus in the epidermal and parenchyma cells was found predominantly in the cell walls, and hyphae also extended intercellularly and intracellularly. Infection of seeds appeared to occur via two ways: (i) direct infection of the outer layers of the cell walls of the pericarp and (ii) through entering the stigma into the pericarp cells. Secretion of host cell wall hydrolytic enzymes at the apex of the penetrating hyphae may facilitate the spread of the fungus. In addition, toxins secreted by the fungus might explain the rapid death of host cells in contact with or distant to fungal cells. A host response to fungal infection involved the development of appositions between cell wall and plasma membrane in cells adjacent to fungal cells. Fungal hyphae were sometimes also surrounded by electron dense material.     

The spatiotemporal control of KatG2 catalase-peroxidase contributes to the invasiveness of Fusarium graminearum in host plants

Reactive oxygen species (ROS) are involved in the pathogen-host interactions, and play a Janus-faced role in the resistance and susceptibility of plants to biotrophic and necrotrophic pathogens. The ascomycete fungus Fusarium graminearum causes hazardous wheat Fusarium head blight worldwide. Deletion of the putative secreted catalase-peroxidase gene in F. graminearum, KatG2, reduced the virulence in wheat spike infection. However, it remains unclear when and where KatG2 scavenges ROS during the invasion of wheat. In this study, we delineate the change in ROS levels in the transition of the infection phase under microscopic observation. Correspondingly, the pathogen switches its strategy of infection with temporal and spatial regulation of KatG2 to counteract oxidative stress generated by host plant cells. With the native promoter-driven KatG2-mRFP strain, we show that KatG2-mRFP expression was induced in planta and accumulated in the infection front region at the early infection stage. In contrast to its ubiquitous cellular localization in runner hyphae, KatG2-mRFP is exclusively located on the cell wall of invading hyphal cells, especially at the pathogen-host cellular interface. Using posttranslational modification analysis, we found that asparagine residues at the 238 and 391 positions of KatG2 could be modified by N-glycosylation and that these two residues are required for KatG2 accumulation and cell wall localization in planta.     

Characterisation of the early events in atypical tomato root colonisation by a biocontrol agent, Pythium oligandrum.

The specific oomycete-plant relationship established between a biological agent, Pythium oligandrum, and tomato (Lycopersicon esculentum Mill.) plants was examined over the first 48 h after inoculation of tomato roots with the antagonist. One of the most significant effects was the quick colonisation of cortical and vascular root areas by P. oligandrum (until 9 h post-inoculation); it was similar to invasions by the major pathogens of Pythium genus, and much faster than those by Pythium-minor pathogens. Despite the multiplication of hyphae in the root areas, fungal colonisation was associated with neither host wall disruption nor host cell alterations. The colonising hyphae looked healthy till the ninth hour after inoculation, then, they progressively became highly vacuolated. Cytological observations showed that, over the first 14 h of experiment, oomycete invasion was accompanied with rare host-induced defence reactions. Biochemical analysis evidenced an accumulation of phenolic compounds starting 3 h after inoculation. The 14th hour corresponded to the beginning of rishitin (phytoalexin) synthesis. Accumulation of biochemical host defence compounds was concomitant with early signs of hyphae alterations. During the next 34 h several host reactions were regularly amplified as evidenced by the plugging of invaded host cells with heterogeneous osmiophilic or high electron-dense (ED) materials. Fungal cell decay was accompanied with the formation of oogonia in the cortex, vascular parenchyma and xylem vessels. All these early events suggest a peculiar relationship established between P. oligandrum and the plant.     

Electron microscopy of vesicular-arbuscular mycorrhizae of yellow poplar. II. Intracellular hyphae and vesicles.

Intracellular hyphae and vesicles in mycorrhizal roots of yellow poplar were examined by electron microscopy. An investing layer of host wall material and cytoplasm enclosed the endophyte within the cells. Young developing hyphae contained abundant cytoplasm and few vacuoles. As hyphae matured, they became highly vacuolated and accumulated carbohydrate (glycogen) and lipid reserves. Mature vesicles were engorged with lipid droplets, possessed a trilaminate wall and were also enclosed by host wall material and cytoplasm. Compared with uninfected cells, infected cortical cells showed an increase in cytoplasmic volume, enlarged nuclei, and a reduction of starch reserves. Host nuclei were always proximal to the hyphae during hyphal development and deterioration. While other cytoplasmic components of infected and uninfected cells were comparable large electron-dense bodies occurred in vacuoles of most cells containing hyphae. Deterioration of intracellular hyphae occurred throughout the samples examined. Septa separated functional and degenerating portions of the hyphae. Hyphal deterioration involved degeneration and ultimate disappearance of fungal cytoplasm as well as collapse of hyphal walls. Based on these observations, the authors hypothesize that deterioration of the endophyte may release significant quantities of mineral nutrients, via hyphal contents, which are absorbed by the host.     

Gibberellin regulates infection and colonization of host roots by arbuscular mycorrhizal fungi

Arbuscular mycorrhiza (AM) is established by the entry of AM fungi into the host plant roots and the formation of symbiotic structures called arbuscules. The host plant supplies photosynthetic products to the AM fungi, which in return provide phosphate and other minerals to the host through the arbuscules. Both partners gain great advantages from this symbiotic interaction, and both regulate AM development. Our recent work revealed that gibberellic acids (GAs) are required for AM development in the legume Lotus japonicus. GA signaling interact with symbiosis signaling pathways, directing AM fungal colonization in host roots. Expression analysis showed that genes for GA biosynthesis and metabolism were induced in host roots around AM fungal hyphae, suggesting that the GA signaling changes with both location and time during AM development. The fluctuating GA concentrations sometimes positively and sometimes negatively affect the expression of AM-induced genes that regulate AM fungal infection and colonization.     

Surface Ultrastructural Studies on the Germination,Penetration and Conidial Development of Aspergillus Flavus Link : Fries Infecting Silkworm,Bombyx Mori Linn

Aspergillosis is a common disease of the silkworm Bombyx mori Linn., caused by an insect mycopathogen Aspergillus flavus Link:Fries. The present study reveals the germination, penetration and conidial development of A. flavus on the larval integument of B. mori under SEM. Four different strains (NB18, KA, NB4D2 and NB7) of B. mori was surface inoculated with ca. of 1 x 10(6) conidia/ml. Each conidium germinated on the cuticle approximately 6 h after inoculation, forming a humpy or suctorial appressoria within 24 h. The hyphae which entered into haemocoel 2 day post-inoculation, grew and multiplied extensively, forming a mycelial complex, causing death of the host larva in about 4-5 days. This occurred with minimal breakdown of the internal tissues. Death of the host was followed by ramification of the fungus through the mesodermal and epidermal tissues, leading to larval mummification about 5-6 days after inoculation. Extensive fungal growths on the entire larval body followed, consisting of aerial hyphae, which developed branched conidiophores. The aerial hyphae with abundant conidiophores formed a confluent yellowish green fungal mat over the entire larval body in 6-7 days of post-inoculation. The tip of each emerging conidiophores gradually dilated and developed to become a bulbous head known as the vesicle. A large number of conidiogenous cells were produced over the entire surface of vesicle, which later developed into finger-like projections termed as sterigmata or phialides. The phialides matured within 2 days after the aerial hyphae emerged as evidenced by chains of conidia at their tips. The conidia were globose with externally roughened walls. The life cycle of the fungus on B. mori was completed in six to seven days.     

A morphological study of the mycorrhiza ofEntoloma clypeatum f.hybridum onRosa multiflora

Mycorrhizas ofEntoloma clypeatum f.hybridum onRosa multiflora in the field in Japan were studied by stereo, light and electron microscopy. In most mycorrhizas, the root cap, meristem, and apical region of the cortex disappeared, but in a few mycorrhizas, these tissues remained. Fungal hyphae of the mycorrhizas invaded root tissues and branched palmately. Hyphae in contact with cortical cells were larger than those far from the root cells and contained many mitochondria, cisternae of endoplasmic reticulum and transitional vesicles. Invading hyphae were undulate in the apical part of the mycorrhiza, and some of them lacked distinct organelles. Electron-dense granules accumulated in the root cells adjacent to the fungal hyphae. Both the remnants of the plant cells and the fungal hyphae were included in the amorphous materials on the tip of the stele. These observations suggest the destructive infection by fungal hyphae of the root cells and their collapse near the tip of the stele.