Successful inoculation of mature pine with Tricholoma matsutake

Our finding demonstrates, for the first time, that the roots of mature pine trees can be successfully inoculated with a symbiotic ectomycorrhizal fungus, the valuable matsutake mushroom. Long root segments (ca. 5–10 mm in diameter, ca. 50 cm in length) of 50-year-old Pinus densiflora trees were excavated, washed, auxin-treated (2–5 mg indole butyric acid, IBA, per root) and incubated in moist Spagnum moss. Twelve months later, short roots were regenerated, of which approximately 90% were free of mycorrhizae. Mycorrhiza-free short roots were inoculated with mycelial pieces of Tricholoma matsutake and incubated further in a sterilized substrate. Four-and-a-half months later, roots putatively colonized by Matsutake were sampled near the inoculation points. A T. matsutake-specific ITS-rDNA fragment was amplified by nested PCR from approximately 80% of the root samples analyzed, whereas approximately 66% of the root samples processed for staining with Chlorazol black E displayed characteristic T. matsutake Hartig net structures. These results confirm the symbiotic infection of mature P. densiflora roots by matsutake.     

Rapid in vitro ectomycorrhizal infection onPinus densiflora roots byTricholoma matsutake

The root systems of 11-wk-oldPinus densiflora seedlings were inoculated with a hyphal suspension ofTricholoma matsutake and aseptically incubated for 4 wk in a forest soil without supplying exogenous carbohydrates. One week following inoculation, fungal hyphae had colonized the root surface and bound soil particles together establishing a root-substrate continuum. Fungal hyphae were visible within the main root cortex following clearing bleaching and staining. In the ensuing days, fungal colonization was observed within elongating lateral roots in which Hartig net formation was confirmed 4 wk after inoculation. This is the first report of rapid ectomycorrhizal infection ofP. densiflora seedings byT. matsutake.     

Ectomycorrhiza formation ofTricholoma matsutake isolates on seedlings ofPinus densiflora in vitro

Tricholoma matsutake forms ectomycorrhizas withPinus densiflora under field conditions. The present study aimed to test the ability ofT. matsutake isolates to form mycorrhizas with aseptic seedlings ofP. densiflora in vitro. Pine seeds were germinated aseptically on a nutrient agar medium, and pairs of 1-wk-old seedlings were transplanted into polymethylpentene bottles containing autoclaved sphagnum moss/vermiculite substrate. The substrate was saturated with nutrient medium containing glucose. At the same time, the bottles were inoculated with aT. matsutake isolate. Three mo after inoculation, the fungus formed a sheath and Hartig net on the pine lateral roots. Ectomycorrhizas were also confirmed on 4-6-mo-old seedlings which showed the same or slinghtly better growth than the control plants. These results indicate that culturedT. matsutake mycelium can form true ectomycorrhizas withP. densiflora seedlings in vitro.     

Mycorrhizal association of isolates from sporocarps and ectomycorrhizas withPinus densiflora seedlings

Thirty-two isolates from sporocarps of 27 species of macromycetes, 43 isolates from ectomycorrhizas ofPinus densiflora (Japanese red pine) and 1 isolate from an ectomycorrhiza ofQuercus myrsinaefolia were tested for the ability to form mycorrhizas withP. densiflora seedlings in glass tubes. Ten isolates from sporocarps ofHebeloma sp.,Laccaria bicolor, Lactarius chrysorrheus, Suillus granulatus, Scleroderma areolatum, Russula mariae andR. nigricans had formed ectomycorrhizas by 8 months after transplantation. Twenty isolates taken from mycorrhizas including ofCenococcum geophilum, R. mariae andR. nigricans formed ectomycorrhizas. The synthesized mycorrhizas were classified based on morphological characteristics such as hyphal arrangement of their fungal sheath, and appearance of cystidia and emanating hyphae. Twenty-one mycorrhizal types were recognized.Contribution No. 122, Laboratories of Plant Pathology and Mycology, Institute of Agriculture and Forestry, University of Tsukuba.     

Root endophyte interaction between ectomycorrhizal basidiomycete Tricholoma matsutake and arbuscular mycorrhizal tree Cedrela odorata, allowing in vitro synthesis of rhizospheric “shiro”

The ectomycorrhizal basidiomycete Tricholoma matsutake associates with members of the Pinaceae such as Pinus densiflora (red pine), forming a rhizospheric colony or “shiro,” which produces the prized “matsutake” mushroom. We investigated whether the host specificity of T. matsutake to conifers is innately determined using somatic plants of Cedrela odorata, a tropical broad-leaved tree (Meliaceae) that naturally harbors arbuscular mycorrhizal fungi. We found that T. matsutake could form in vitro shiro with C. odorata 140 days after inoculation, as with P. densiflora. The shiro was typically aromatic like that of P. densiflora. However, this was a root endophytic interaction unlike the mycorrhizal association with P. densiflora. Infected plants had epidermal tissues and thick exodermal tissues outside the inner cortex. The mycelial sheath surrounded the outside of the epidermis, and the hyphae penetrated into intra- and intercellular spaces, often forming hyphal bundles or a pseudoparenchymatous organization. However, the hyphae grew only in the direction of vascular bundles and did not form Hartig nets. Tricholoma fulvocastaneum or “false matsutake” naturally associates with Fagaceae and was also able to associate with C. odorata as a root endophyte. With T. matsutake, C. odorata generated a number of roots and showed greatly enhanced vigor, while with T. fulvocastaneum, it generated a smaller number of roots and showed somewhat lesser vigor. We argue that the host–plant specificity of ectomycorrhizal matsutake is not innately determined, and that somatic arbuscular mycorrhizal plants have a great potential to form mutualistic relationships with ectomycorrhizal fungi.     

Ectomycorrhizal symbiosis in vitro between Tricholoma matsutake and Pinus densiflora seedlings that resembles naturally occurring ‘shiro’

We established an in vitro ectomycorrhizal symbiosis between Tricholoma matsutake and Pinus densiflora. Mycorrhiza formed in a substrate of Modified Norkrans' C medium and granite-based soil had features similar to those observed previously only in naturally occurring mycorrhizal system called ‘shiro,’ and promoted the growth of plants with smaller root/shoot ratios. The in vitro formation of ‘shiro’ is essential for the development of T. matsutake system to produce mushrooms and is useful for the propagation and plantation of the mycorrhizal seedlings.     

Detection of the ectomycorrhizal fungusTricholoma matsutake and some related species with specific ITS primers

Oligonucleotide primers (Tm1 and Tm4) were designed to amplify a 447–448 base pair fragment, comprising sections of the rDNA internal transcribed spacers (ITS) and the entire 5.8S rDNA, ofTricholoma matsutake. PCR products of predicted size were produced for six of eight isolates ofT. matsutake from across its natural range in Asia, and for isolates of some closely related fungi includingT. bakamatsutake, T. magnivelare, andT. caligatum. The closely relatedT. robustum could be discriminated fromT. matsutake by PCR fragment size. No PCR products were produced where the primers were tested against 16 species of ectomycorrhizal fungi associated withPinus spp. in the Southern Hemisphere. The specific primers were also used successfully to produce PCR products from matsutake infected roots collected in natural forests in China and Japan, and from pure culture synthesisedPinus radiata-T. matsutake material. These primers will be useful in research directed at establishing matsutake in the Southern Hemisphere, and also have the potential to be applied to the study of matsutake within its natural range.     

Mycorrhizae ofMonotropastrum globosum growing in aFagus crenata forest

The achlorophyllousMonotropastrum globosum was found growing in aFagus crenata forest. Samples ofM. globosum and their interpenetrating root systems ofF. crenata were collected to investigate the mycorrhizal association.Monotropastrum globosum mycorrhizae showed thick sheaths, invasion of the epidermal cells by fungal pegs, and Hartig nets, which reached only the first layer of cortical cells. TheF. crenata mycorrhizae also showed thick sheaths, but Hartig nets penetrated deep into the cortex and intracellular hypha were seen in the outer cortical cells. The similarities observerd in the mantle inner plan view and emanating hypha suggest that both mycorrhizae are formed by the same fungus.     

Development and function of Pisolithus and Scleroderma ectomycorrhizas formed in vivo with Allocasuarina,Casuarina and Eucalyptus

The effect of inoculating seedlings of Eucalyptus grandis, Allocasuarina littoralis and Casuarina equisetifolia with two isolates of Pisolithus and two isolates of Scleroderma from under eucalypts was examined in a glasshouse trial. Ectomycorrhizas formed extensively on Eucalyptus (23–46% fine roots ectomycorrhizal) and Allocasuarina (18–51% fine roots ectomycorrhizal). On Casuarina, the fungi were either unable to colonize the rhizosphere (one isolate of Pisolithus), or sheathed roots, resembling ectomycorrhizas, formed on 1–2% of the fine roots. Colonization of roots by one isolate of Scleroderma resulted in the death of Casuarina seedlings. Inoculation with fungi increased shoot dry weight by up to a factor of 32 (Eucalyptus), 4 (Allocasuarina) and 3 (Casuarina). Ectomycorrhizas formed in associations with Eucalyptus and Allocasuarina had fully differentiated mantles and Hartig nets in which the host and fungal cells were linked by an extensive fibrillar matrix. Sheathed roots in Casuarina lacked a Hartig net, and the epidermis showed a hypersensitive reaction resulting in wall thickening and cell death. The sheaths are described as mantles since the density and arrangement of the hyphae in the sheaths was similar to that in mantles of the eucalypt ectomycorrhizas. The intercellular carbohydrate matrix was not produced in the Casuarina mantle in association with Pisolithus, hence the mantle was not cemented to the root. These structures differ from poorly compatible associations described previously for Pisolithus and Eucalyptus. The anatomical data indicate that ectomycorrhizal assessment based on surface morphological features may be misleading in ecological studies because compatible and incompatible associations may not be distinguishable.     

A qPCR assay that specifically quantifies <Emphasis Type="Italic">Tricholoma matsutake</Emphasis> biomass in natural soil

Tricholoma matsutake is an ectomycorrhizal basidiomycete that produces prized, yet uncultivable, “matsutake” mushrooms along densely developed mycelia, called “shiro,” in the rhizosphere of coniferous forests. Pinus densiflora is a major host of this fungus in Japan. Measuring T. matsutake biomass in soil allows us to determine the kinetics of fungal growth before and after fruiting, which is useful for analyzing the conditions of the shiro and its surrounding mycorrhizosphere, predicting fruiting timing, and managing forests to obtain better crop yields. Here, we document a novel method to quantify T. matsutake mycelia in soil by quantifying a single-copy DNA element that is uniquely conserved within T. matsutake but is absent from other fungal species, including close relatives and a wide range of ectomycorrhizal associates of P. densiflora. The targeted DNA region was amplified quantitatively in cultured mycelia that were mixed with other fungal species and soil, as well as in an in vitro co-culture system with P. densiflora seedlings. Using this method, we quantified T. matsutake mycelia not only from shiro in natural environments but also from the surrounding soil in which T. matsutake mycelia could not be observed by visual examination or distinguished by other means. It was demonstrated that the core of the shiro and its underlying area in the B horizon are predominantly composed of fungal mycelia. The fungal mass in the A or A₀ horizon was much lower, although many white mycelia were observed at the A horizon. Additionally, the rhizospheric fungal biomass peaked during the fruiting season.     

Isolation ofTricholoma matsutake andT. bakamatsutake cultures from field-collected ectomycorrhizas

Tricholoma matsutake was isolated into pure cultures from field samples of ectomycorrhizas onPinus densiflora. The mycorrhizal tips were collected at different times of the year from a colony ofT. matsutake in aP. densiflora stand. The mycorrhizal tips were continuously washed with sterilized distilled water and diluted Tween 80 solution, surface-sterilized with calcium hypochlorite solution, and inoculated on several kinds of nutrient agar media. Most of the mycorrhizal tips collected in winter and spring produced colonies that were morphologically similar to cultures ofT. matsutake isolated from basidiocarps. The identity of isolates obtained from mycorrhizas was further confirmed to beT. matsutake based on fungal morphology and RFLP patterns of PCR amplified rDNA. The feasibility ofT. bakamatsutake isolation into pure culture from ectomycorrhizas onQuercus serrata was also confirmed. These results indicated that mycelium of matsutake mushrooms can be isolated into pure culture from ectomycorrhizas at different times of the year. Mycorrhizas of bothT. matsutake andT. bakamatsutake were not observed to have any specific association with soil fungi such asMortierella spp.     

Comparative structural study ofQuercus serrata andQ. acutissima formed byPisolithus tinctorius andHebeloma cylindrosporum

Ectomycorrhizas were synthesized in pots and growth pouches betweenQuercus serrata, Q. acutissima, and two ectomycorrhizal fungi,Pisolithus tinctorius andHebeloma cylindrosporum. Root morphology and the structure of the mantle and Hartig net were compared using light, fluorescence, scanning and transmission electron microscopy.P. tinctorius initially colonized root cap cells, and eventually produced a highly branched lateral root system with a complete mantle, whereasH. cylindrosporum promoted root elongation with few hyphae on the root apex surface indicating that interaction between roots differs with fungal species. Hartig net structure and hyphal inclusions varied between all the combinations tested. There were structural differences between mycorrhizas ofH. cylindrosporum/Q. acutissima grown in soil and growth pouches, which indicate that the growth pouch environment can induce artefacts in roots. Fruit bodies ofH. cylindrosporum developed in pots withQ. acutissima. AlthoughP. tinctorius has been used to inoculate oak seedlings in the nursery, results of this study indicate thatH. cylindrosporum may also be an effective ectomycorrhizal fungus forQ. serrata andQ. acutissima.     

Tricholoma matsutake Y1 strain associated with Pinus densiflora shows a gradient of in vitro ectomycorrhizal specificity with Pinaceae and oak hosts

Tricholoma matsutake produces commercially valuable yet uncultivable matsutake mushrooms during an ectomycorrhizal association with coniferous trees. In the Far East, most matsutake are harvested in managed Pinus densiflora forests. To determine whether T. matsutake has host plant specificity, we synthesized mycorrhiza in vitro between T. matsutake Y1 that originated from a P. densiflora forest and various Pinaceae and oak hosts. The strain Y1 formed a continuous Hartig net, a sign of ectomycorrhization, in the lateral roots of Pinus sylvestris, Pinus koraiensis, Pinus parviflora var. pentaphylla, Picea glehnii, Picea abies, and Tsuga diversifolia seedlings in vitro, which resembled those formed with the natural host Pinus densiflora. The strain conferred a discontinuous Hartig net with Pinus thunbergii, Picea yezoensis, Abies veitchii, and Larix kaempferi. However, no such development by this strain was observed on the roots of Quercus serrata, unlike T. bakamatsutake B1, a false matsutake that is symbiotic with oak trees. The data suggest that T. matsutake can be associated with diverse conifers but may establish ectomycorrhizal relationships only with specific host plant species.     

Tricholoma matsutake– an assessment of in situ and in vitro infection by observing cleared and stained whole roots

 Structures present within field-collected Tricholoma matsutake/Pinus densiflora ectomycorrhizas and in vitro infections of P. densiflora roots by T. matsutake were observed by clearing, bleaching and staining whole lateral roots and mycorrhizas. Field mycorrhizas were characterized by a lack of root hairs, by the presence of a sparse discontinuous mantle composed of irregularly darkly staining hyphae over the root surface, primarily behind the root cap, and by the presence of Hartig net mycelium within the root cortex. Hartig net 'palmettis' were classified into three basic structures, each with distinctive morphologies. Aerial hyphae, bearing terminal swellings, were observed emanating from the mantle. Cleared, bleached and stained in vitro-infected roots possessed multibranched hyphal structures within the host root cortex and aerial hyphae bearing terminal swellings were observed arising from the mycelium colonizing the root surface. T. matsutake on P. densiflora conforms to the accepted morphology of an ectomycorrhiza. This staining protocol is particularly suited to the study of Matsutake mycorrhizal roots and gives rapid, clear, high-contrast images using standard light microscopy while conserving spatial relationships between hyphal elements and host tissues. Accepted: 26 August 1999     

Identification of ectomycorrhizae formed betweenTricholoma matsutake andPinus densiflora by polymerase chain reaction (PCR) targeting retroelement coding regions

We previously reported that conservation and diversification of repetitive sequences carrying motifs of retroposons have occurred inTricholoma matsutake and related ectomycorrhizal basidiomycetes through their evolution. Here we report that the polymerase chain reaction using primers designed to amplify retroelement coding regions specified ectomycorrhizae formed betweenT. matsutake andPinus densiflora.     

Ectomycorrhizae formed in vitro by quaking aspen: including Inocybe lacera and Amanita pantherina

Ectomycorrhizae formed in synthesis tubes by aspen (Populus tremuloides) seedlings and each of seven fungal isolates are described. Isolates of Amanita muscaria v. formosa, A. pantherina, Inocybe lacera, and Paxillus vernalis, from sporocarps collected in aspen stands in southwestern Montana, developed mantles and Hartig nets on aspen roots, as did the broad-hostrange fungi Cenococcum geophilum and Pisolithus tinctorius from the VPI culture collection. Chalciporus piperatus failed to form mycorrhizae, and Piloderma croceum formed a mantle, but no Hartig net. The first syntheses of I. lacera and A. pantherina with aspen are reported.     

Nitrogen decreases and precipitation increases ectomycorrhizal extramatrical mycelia production in a longleaf pine forest

The rates and controls of ectomycorrhizal fungal production were assessed in a 22-year-old longleaf pine (Pinus palustris Mill.) plantation using a complete factorial design that included two foliar scorching (control and 95% plus needle scorch) and two nitrogen (N) fertilization (control and 5 g N m⁻² year⁻¹) treatments during an annual assessment. Ectomycorrhizal fungi production comprised of extramatrical mycelia, Hartig nets and mantles on fine root tips, and sporocarps was estimated to be 49 g m⁻² year⁻¹ in the control treatment plots. Extramatrical mycelia accounted for approximately 95% of the total mycorrhizal production estimate. Mycorrhizal production rates did not vary significantly among sample periods throughout the annual assessment (p = 0.1366). In addition, reduction in foliar leaf area via experimental scorching treatments did not influence mycorrhizal production (p = 0.9374), suggesting that stored carbon (C) may decouple the linkage between current photosynthate production and ectomycorrhizal fungi dynamics in this forest type. Nitrogen fertilization had a negative effect, whereas precipitation had a positive effect on mycorrhizal fungi production (p = 0.0292; r ² = 0.42). These results support the widely speculated but poorly documented supposition that mycorrhizal fungi are a large and dynamic component of C flow and nutrient cycling dynamics in forest ecosystems.     

Detecting nonculturable bacteria in the active mycorrhizal zone of the pine mushroom <Emphasis Type="Italic">Tricholoma matsutake</Emphasis>

The fungus Tricholoma matsutake forms an ectomycorrhizal relationship with pine trees. Its sporocarps often develop in a circle, which is commonly known as a fairy ring. The fungus produces a solid, compact, white aggregate of mycelia and mycorrhizae beneath the fairy ring, which in Japanese is called a ’shiro’. In the present study, we used soil dilution plating and molecular techniques to analyze the bacterial communities within, beneath, and outside the T. matsutake fairy ring. Soil dilution plating confirmed previous reports that bacteria and actinomycetes are seldom present in the soil of the active mycorrhizal zone of the T. matsutake shiro. In addition, the results showed that the absence of bacteria was strongly correlated with the presence of T. matsutake mycorrhizae. The results demonstrate that bacteria, especially aerobic and heterotrophic forms, and actinomycetes, are strongly inhibited by T. matsutake. Indeed, neither bacteria nor actinomycetes were detected in 11.3% of 213 soil samples from the entire shiro area by culture-dependent methods. However, molecular techniques demonstrated that some bacteria, such as individual genera of Sphingomonas and Acidobacterium, were present in the active mycorrhizal zone, even though they were not detected in soil assays using the dilution plating technique.     

Morphological classification of ectomycorrhizas ofPinus densiflora

Morphological classification of ectomycorrhizas ofPinus densiflora was conducted. Fifty soil samples containing pine ectomycorrhizas, and 40 pine seedlings were collected randomly in two separate reforested stands ofP. densiflora (45 yr old) from May 1992 to October 1994. Fifty-six types of ectomycorrhizas could be classified based upon microscopically observable morphological characteristics. Fifty percent of the types showed cystidia or other specific characteristics such as laticiferous hyphae in the fungal sheaths, verrucose emanating hyphae and a positive hyphal reaction to UV irradiation. Four mycorrhizal types were confirmed to be formed by the fungiRussula delica, R. mariae, R. nigricans, andCenococcum geophilum, respectively. Although the other 52 types were unidentified mycobionts at species level, it was inferred that they were formed by the fungiHebeloma, Lactarius, Russula andTuber. There was a slight difference in the observed mycorrhizal types between the tree ages. Contribution No. 127, Laboratories of Plant Pathology and Mycology, Institute of Agriculture and Forestry, University of Tsukuba.