Hyphal anastomosis inPyricularia oryzae cav.

Summary Hyphal anastomosis inPyricularia oryzae occurs naturally in the lower epidermal cells and in the vascular bundles of young lesions on rice. In those cells the invading blast fungus are active. Two hyphal cells lying side by side start an anastomosis by forming two, one from each, very short penetration pegs which are opposite to each other. The cell wall of the pegs and the wall in the vicinity of them are then gradually eliminated and thus form a fusion aperture of 0.2–0.6 m in diameter that is big enough for the migration or exchange of nucleus and cytoplasm between two hyphal cells. The explanation of genetical variation inP. oryzae may be sought on the basis of the ultrastructural evidence of hyphal anastomoses presented in this paper.     

Chalara elegal-Infected Tobacco Roots: Ultrastructural Observations on in vitro Host-Fungus Relationships

Evidence, based on ultrastructural observations of stages involved in root infection oi Nicotiana tabacum cv. Xanthi n.c. in vitro by the black root rot fungus Chalara elegans, indicates that host cells from various layers react differently when challenged by the pathogenic fungus. All the host responses observed were associated with host cell wall modifications. Host reaction to fungal invasion occurring in the epidermal cells was limited to a disorganization of the cytoplasm. In the hypodermal cell layer, fibrillar cell wall outgrowths and wall thickenings were the earliest and the most obvious host reactions. In parenchymal cells, the host reacted by depositing papilla-like wall appositions directly adjacent to the infecting hyphae; with secondary infection of these cells, a densely staining material was laid down, mainly around the distal region of the infecting hyphae. In all these tissues, infection also led to disorganization of the host cytoplasm. Colonization of the endodermis did not lead to any rapid lethal modifications in either the host or the fungus, and a biotrophic-like state seemed to occur at this stage of the infection. No hyphal infection occurred in the central cylinder.     

The ultrastructure of the zygospore in Endogone flammicorona Trappe & Gerdemann

The ultrastructural organization of the spores of the sporocarp of Endogone flammicorona was studied. Two types of organization are described. Initially the spore possessed a vacuolate protoplasm and was bound by two cell wall layers. The spore was surrounded by a hyphal mantle formed of a sheet of vacuolized hyphae with uniformly thin walls. Secondly, although the ultrastructural features of the spore appeared the same, it was now surrounded by a hyphal mantle with unevenly thickened walls (i. e., the so-called flaming crown) due to the gradual and irregular deposition of granules and lamellae. This crown gives the spore its most commonly observed morphological feature and is the preminent character employed taxonomically to speciate Endogone flammicorona Trappe & Gerdemann.     

Polyamines stimulate hyphal branching and infection in the early stage of <Emphasis Type="Italic">Glomus etunicatum</Emphasis> colonization

Polyamines are known to strongly stimulate hyphal growth in arbuscular mycorrhizal fungi. The effect of the polyamines putrescine, spermidine and spermine on spore germination, hyphal elongation and branching by the AM fungus Glomus etunicatum was investigated in this study. The effect of spermine on infection and the development of the host and of daughter spores was further investigated using the dual monoaxenic culture system comprised of Gl. etunicatum fungal cultures in Ri T-DNA transformed carrot hairy roots. Spermidine and spermine showed positive effects on germination and all three polyamines significantly promoted hyphal growth. Hyphal branching was also strongly stimulated by treatment with polyamines, such as an increase in the number of branches. Infection during the early stages of the in vitro co-culture life cycle was enhanced in the presence of spermine, and daughter spores appeared at earlier timepoints compared to the control. Our results demonstrate that polyamines stimulate germination and hyphal branching in the early stage of AM fungal colonization. Moreover, results from the investigations conducted in the fungus-root co-culture suggest that polyamines may be involved in establishing the symbiotic relationship between root and fungus.     

Development of Dactylaria eudermata Drechsler a predaceous fungi in Meloidogyne incognita

Dactylaria eudermata Drechsler is one of the important predaceous fungi occurring widely in different soils. The fungus produces hyphal bails and network compound in which nematodes are entangled. This hyphal nets as trapping structure which may be single dimensional to two or three dimensional and are formed through repeated hyphal anastomosis, which capture nematodes either through the adhesive material present on the surface of hyphal nets or due to physical entanglement. In the experiment it was observed that inflation of hyphal bails takes 30 to 50 minutes and capturing and killing the nematode by a single conidia in water takes 35–55 hours, were as time required for inflation of hyphal bails and real trapping and killing of a nematode in maize meal (MMA: water (1:10) medium) takes one minute and 30–50 hours respectively.     

Identification of host plants and description of sclerotia of the truffle <Emphasis Type="Italic">Mattirolomyces terfezioides</Emphasis>

The truffle, Mattirolomyces terfezioides, is a hypogeous ascomycete with uncertain host relationships. The fungus has been regularly collected on sandy soils in the Carpathian Basin. During the study of the natural host plants of the fungus, strange, amorphous, belowground hyphal aggregates incorporating soil and sand particles have been found attached to the surface of the roots. The fruitbodies of M. terfezioides develop from these hyphal aggregates. This structure, similar to that formed by morels, could be interpreted as a sclerotium. Sclerotia were found both on roots of woody and herbaceous plants. To detect the roots colonized by M. terfezioides, a species-specific polymerase chain reaction was developed. Seven natural hosts of the fungus were identified by this method. No specificity regarding taxa or life form of the plants was found. The colonization of the roots by the septate hyphae of M. terfezioides was weak, particularly compared to the colonization by arbuscular–mycorrhizal fungi. This suggests that this fungus is not the dominant fungal partner of these plants. Therefore, using M. terfezioides as the only inoculum may be inappropriate in truffle cultivation experiments. Nevertheless, further in vitro experiments are needed to develop reliable knowledge on the still ambiguous symbiotic strategy of this fungus.     

Abundance of Collembola (Insecta) inhabiting the hyphal mat of an ectomycorrhizal fungus,Sarcodon scabrosus,in a Pinus densiflora forest

The total number of collembolans collected from the hyphal mat of the ectomycorrhizal fungus Sarcodon scabrosus was less than half of that collected from the adjacent non-mat soil. The same was true of all families of collembolans except one, although not all differences were significant. The exception was the Hypogastruridae, with more individuals in the hyphal mat on the sampling day in the fruiting season; these were also the most abundant collembolans on the fruiting bodies. These results indicate that most collembolans avoid the hyphal mat of S. scabrosus in a Japanese red pine forest.     

Separated components of root exudate and cytosol stimulate different morphologically identifiable types of branching responses by arbuscular mycorrhizal fungi

Two morphologically distinct hyphal branching responses by the AM fungus, Glomus intraradices, were stimulated by separated components of carrot root exudate. Complex branching up to the sixth order was induced by compounds most soluble in 35 % methanol, whereas the formation of more lateral branches (second order) was stimulated by compounds most soluble in 70 % methanol. This same 70 % alcohol soluble fraction also stimulated a completely different type of branching pattern in another fungus, Gigaspora gigantea. This pattern consisted of a very periodic distribution of dense clusters of hyphal branches that had a very high degree of complexity. In contrast to exudate components, separated cytosolic components of carrot roots did not stimulate any of the observed hyphal branching patterns. Alcohol-soluble fractions actually inhibited hyphal tip growth of G. gigantea and induced the formation of “recovery” branches that were identical to those induced by an inhibitor found in the exudate of Chard (Beta vulgaris ssp. cicla), a non-host plant.     

Investigation of the infection process of macrophomina phaseolina on the surface of soybean roots using scanning electron microscopy

Sclerotial germination, hyphal growth pattern, and appressorial formation of the charcoal rot fungus, Macrophomina phaseolina (Tassi) Goid. on the surface of soybean roots, Glycine max (L.) Merrill was observed using scanning electron microscopy. Sclerotial germination is followed by a hyphal growth pattern which does not appear to be associated with any specific structural feature on the corrugated root surface. Appressoria are produced on the root surface at the tips of both primary hyphae and side branches within three days after inoculation.     

Role of the conidium in dimorphism of Blastomyces dermatitidis

Fine details of yeastlike cell development of Blastomyces dermatitidis from its conidium are described and illustrated by electron micrographs. When cultured in an enriched medium at 37 °C, conidia of two strains of B. dermatitidis readily underwent ultrastructural changes consistent with mycelial to yeast dimorphism. Although hyphal cells contained in the conversion cultures were observed consistently to undergo profound degenerative changes, the conidia rapidly germinated to give rise to short germ tubes which subsequently enlarged to form intermediate yeast mother cells (YMC). The wall of the germ tube arose from the innermost layer of the wall of the germinant. During the transition globoid osmiophilic inclusions of unknown origin and function were observed in vacuolated areas of the germ tube and YMC cytoplasm. Yeastlike daughter cells then budded from the intermediate YMC. Since transformation was readily accomplished under in vitro conditions favoring mycelial to yeast dimorphism, it is suggested that the conidium of B. dermatitidis represents the primary infective unit of this pathogenic fungus.     

Geosiphon pyriforme,an Endosymbiotic Association of Fungus and Cyanobacteria: the Spore Structure Resembles that of Arbuscular Mycorrhizal (AM) Fungi

The zygomycete Geosiphon pyriforme is the only known endocyanosis of a fungus. The Nostoc spp. filaments are included in photosynthetically active and nitrogen fixing, multinucleated bladders, which grow on the soil surface. The spores of the fungus are white or slightly brownish. They are about 250 μm in diameter and develop singly on hyphal ends or, less frequently, intercalarly. The wall of the spores consists of a thin innermost layer, a laminated inner layer with a thickness of about 10–13 μm, and an evanescent outer layer. The laminated layer is composed of helicoidally arranged microfibrils, and is separated from the evanescent outer layer by a thin electron-dense sublayer. Polarisation microscopy indicates the occurrence of chitin. Shape and wall ultrastructure of the Geosiphon spores and their cytoplasm resemble that of Glomus spores, but are different from that of other genera of the Glomales and Endogonales. Germination occurs by a single thick hyphal outgrowth directly through the spore wall. Like various AM forming fungi, Geosiphon pyriforme contains endocytic bacteria-like organisms, which are not surrounded by a host membrane. Our observations indicate that Geosiphon is a potential AM fungus.     

Effect of water potential on the development of an haploid strain of Sporisorium reilianum f.sp. zeae

Sporisorium reilianum f.sp. zeae, the causal agent of head smut, infects the roots of the maize plantlets. Little information is available concerning the development of the fungus in soil, although this saprophytic phase is an important part of the life cycle. This paper reports that water potential also affects hyphal induction, and this effect on the fungus may influence disease transmission. In response to a decrease in water potential from 0 to –1.52 MPa in presence of variable molecular weight polyethylene glycols, haploid hyphae develop from the haploid yeast. Hyphal extension is fastest at low water potentials (–1.2 MPa) controlled with high molecular weight polyethylene glycols, PEG-3350 and PEG-8000. Formation of parasitic dikaryotic hyphae following fusion between haploid hyphae was possible at low water potential (–1.2 MPa) and was not inhibited by water stress. These results are consistent with the hypothesis that the effects of low soil water potential on yeast–hyphal transition and hyphal growth facilitate the convergence of compatible haploid strains, and that this may increase disease severity.     

Effect of Mannitol from Laminaria japonica, other Sugar Alcohols, and Marine Alga Polysaccharides on in vitro Hyphal Growth of Gigaspora margarita and Root Colonization of Trifoliate Orange

A compound that stimulated the growth of an arbuscular mycorrhizal (AM) fungus was isolated from 75% methyl alcohol (MeOH) extracts of a brown alga, Laminaria japonica Areschoug, using high-pressure liquid chromatography (HPLC). This compound (Compound 1) was identified as mannitol by HPLC and nuclear magnetic resonance (NMR) spectroscopy. Compound 1 and purchased polysaccharides (alginic acid, fucoidan, carrageenan and mannan from marine algae) were tested for in vitro hyphal growth of an AM fungus, Gigaspora margarita Becker and Hall. Compound 1 (50–500 mg L⁻¹) and carrageenan (1000 mg L⁻¹) significantly stimulated the hyphal growth of germinating spores of Gi. margarita. The application of 100 mg L⁻¹ of Compound 1 to trifoliate orange (Poncirus trifoliata Raf.) inoculated with Gi. margarita promoted root colonization and increased plant growth. These results suggest low concentrations of mannitol are among the reasons for enhanced hyphal growth and root colonization by the application of algal extracts. Other sugar alcohols (100–300 mg L⁻¹ of xylitol, sorbitol and meso-erythritol) also increased the hyphal growth of Gi. margarita.     

Asexual reproduction of <Emphasis Type="Italic">Hygrophorus olivaceoalbus</Emphasis> by intracellular microsclerotia in root cells of <Emphasis Type="Italic">Picea abies</Emphasis> – A winner of ozone stress?

Hygrophorus olivaceoalbus has long been known as an ectomycorrhizal fungus, formerly designated with the artificial binomen Piceirhiza gelatinosa. Recently, it has been found to be abundant and very frequent under double ambient ozone free air fumigation of mature Norway spruce trees. As it has already been reported that this fungus can form intercellular hyphae within the root meristem, a more detailed study was performed to clarify its type of root colonization. The present study not only revealed intercellular hyphae within the meristematic zone but also intracellular hyphae within root cortex cells which grow towards and into large tannin droplets—phenolic compounds usually deposited as defensive aids—to finally fill them completely. The hyphal assemblages become globular which at first sit as separated hyphal balls within cells still containing cytoplasm. Later on, they are apparently released from the root cells, presumably as microsclerotia for dispersal of the species. Old ectomycorrhizae (ECM) show an apical pore, and later a large orifice of a tube-like cylinder formed by the thick, persistent hyphal mantle. The root tissue is progressively degrading towards proximal parts. Disintegrating root cells apparently liberate the microsclerotia through the orifice. Further studies have to find out the mechanism by which the microsclerotia are liberated and whether they operate as asexual propagules and lastly how and by whom they are propagated. As these ECM are found under ozone stress, and with identical features at higher altitudes, stress impact on trees might be the causative agent for the high frequency and abundance of Hygrophorus olivaceoalbus ECM.     

Disruption of actin motor function due to MoMyo5 mutation impairs host penetration and pathogenicity in Magnaporthe oryzae

Actin motor myosin proteins are the driving forces behind the active transport of vesicles, and more than 20 classes of myosin have been found to contribute to a wide range of cellular processes, including endocytosis and exocytosis, autophagy, cytokinesis and the actin cytoskeleton. In Saccharomyces cerevisiae, class V myosin Myo2 (ScMyo2p) is important for the transport of distinct sets of cargo to regions of the cell along the cytoskeleton for polarized growth. To study whether myosins play a role in the formation or function of the appressorium (infectious structure) of the rice blast fungus Magnaporthe oryzae, we identified MoMyo5 as an orthologue of ScMyo2p and characterized its function. Targeted gene disruption revealed that MoMyo5 is required for intracellular transport and is essential for hyphal growth and asexual reproduction. Although the ΔMomyo5 mutant could form appressorium‐like structures, the structures were unable to penetrate host cells and were therefore non‐pathogenic. We further found that MoMyo5 moves dynamically from the cytoplasm to the hyphal tip, where it interacts with MoSec4, a Rab GTPase involved in secretory transport, hyphal growth and fungal pathogenicity. Our studies indicate that class V myosin and its translocation are tightly coupled with hyphal growth, asexual reproduction, appressorium function and pathogenicity in the rice blast fungus.     

Effects of a fraction from maize root exudates on haploid strains of Sporisorium reilianum f. sp. zeae

Sporisorium reilianum f. sp. zeae is the causal agent of head smut of maize. Although the main symptom of this disease is the formation of a black fungal sorus on the reproductive parts of the maize, the infection always occurs via the roots. Early infection stages are characterised by a hyphal proliferation of the fungus around the roots. In this paper, we describe effects of a fraction extracted from maize root exudates on growth of S. reilianum f. sp. zeae. The fungus grew as a yeast form on artificial medium, but in presence of these fractions, some yeasts switched to a hyphal form. In addition, an increased proliferation of the yeast form was also observed with exudates from a variety of maize susceptible to head smut. In the presence of exudates obtained from a tolerant variety of maize, proliferation of the yeast form was inhibited, whereas the induction of yeast-hypha transition was always observed. These results indicated that some molecules in root exudates could play a role in the pre-infectious stage between maize and S. reilianum f. sp. zeae.     

Studies on initiation and development of the partner association inGeosiphon pyriforme (Kütz.) v. Wettstein,a unique endocytobiotic system of a fungus (Glomales) and the cyanobacteriumNostoc punctiforme (Kütz.) Hariot

Summary Phagocytosis ofNostoc filaments byGeosiphon, a fungus closely related to AM forming Glomales, was observed under light microscopes. Incorporation can only be performed ifNostoc primordia come into contact with growing hyphal tips of the fungus. The fungal wall just below the apex softens, and fungal cytoplasm is bulged out repeatedly covering the vegetativeNostoc cells but not the heterocytes. New heterocytes are differentiated by the internalised filament whose cells can increase up to ten times in volume after recovering from incorporation strain. TheNostoc cells are coated stepwise by short finger-shaped protuberances of the fungal hypha. These hernia-like outgrowths first remain separated, after 1 to 2 days they merge. Adjacent hyphal walls inside the complex covering disintegrate. Periphal fungal wall portions are united to form a smooth strong outer envelope. Internalisation is categorised as phagocytosis. The partnership is partly specific,Nostoc strains capable of living endocytobiotically are often partners in other symbioses besidesGeosiphon.Abbreviations AM arbuscular mycorrhiza (formerly VAM vesicular arbuscular mycorrhiza) - DIC differential interference contrast - LD light/dark Dedicated to Prof. Dr. Dr. h.c. Eberhard Schnepf on the occasion of his retirement     

The ectomycorrhizal morphotype Pinirhiza sclerotia is formed by Acephala macrosclerotiorum sp. nov., a close relative of Phialocephala fortinii

Relatively few ectomycorrhizal fungal species are known to form sclerotia. Usually, sclerotia are initiated at the extraradical mycelium. In this study, we present anatomical and ultrastructural evidence for the formation of sclerotia directly in the hyphal mantle of the mycorrhizal morphotype Pinirhiza sclerotia. A dark-pigmented fungal strain was isolated from Pinirhiza sclerotia and identified by molecular tools as Acephala macrosclerotiorum sp. nov., a close relative of Phialocephala fortinii s.l. As dark septate fungi are known to be mostly endophytic, resyntheses with Pinus sylvestris and A. macrosclerotiorum as well as Populus tremula × Populus tremuloides and A. macrosclerotiorum or P. fortinii s.l. were performed under axenic conditions. No mycorrhizas were found when hybrid aspen was inoculated with A. macrosclerotiorum or P. fortinii. However, A. macrosclerotiorum formed true ectomycorrhizas in vitro with P. sylvestris. Anatomical and ultrastructural features of this ectomycorrhiza are presented. The natural and synthesized ectomycorrhizal morphotypes were identical and characterized by a thin hyphal mantle that bore sclerotia in a later ontogenetic stage. The Hartig net was well-developed and grew up to the endodermis. To our knowledge, this is the first evidence at the anatomical and ultrastructural level that a close relative of P. fortinii s.l. forms true ectomycorrhizas with a coniferous host.     

Endomycorrhizal fungi in nitrogen transfer from soybean to maize

Using ¹⁵N as a tracer, interspecific N-transfer was studied during the course of plant development. The use of barriers of differing permeabilities between donor and receiver plants allowed separation of the effect of mycorrhizal colonization, root or hyphal contact and interplant hyphal bridging, on ¹⁵N-transfer from soybean (Glycine max (L.) Merrill) to maize (Zea mays L.). More transfer was measured between mycorrhizal plants, but transport of ¹⁵N from the labelled host plant to Glomus versiforme (Karsten) Berch did not seem to occur at the symbiotic interface, suggesting that the fungus is independent of its host for its N-nutrition, and that the role of hyphal bridges in N-transfer between plants, is not significant. Uptake by the receiver plant of the N excreted by the donor plant root system appears to be the mechanism of N-transfer between plants. The factor most affecting ¹⁵N-transfer between plants was found to be the extent of the contact between plant root systems. The presence of the endomycorrhizal fungus in plant roots reduced ¹⁵N-loss from soybean, but at the same time, its extensive hyphal network improved the efficiency of the maize root system for the recovery of the ¹⁵N excreted by soybeans. The net result was a better conservation of the N resource within the plant system. The transfer of N between mycorrhizal plants was particularly enhanced by the death of the soybean.     

Effect of onion (Allium cepa) root exudates on the hyphal growth of Gigaspora margarita

 The effect of root exudates from onions differing in P status on spore germination and hyphal growth of arbuscular mycorrhizal fungi was investigated. Onion (Allium cepa) was grown in solution culture at different phosphorus concentrations (0, 0.1, 1.0, 8.0 and 24.0 mg P l^–1) and root exudates were collected. When spores of the arbuscular mycorrhizal fungus, Gigaspora margarita were incubated with these root exudates, spore germination was only slightly affected but hyphal growth was greatly affected, particularly with exudates from P-deficient plants. This suggests that the P nutrition of host plants influences the composition of root exudates and thereby the hyphal growth of arbuscular mycorrhizal fungi. Accepted: 25 June 1995