Patterns of vegetative growth and gene flow in Rhizopogon vinicolor and R. vesiculosus (Boletales, Basidiomycota)

We have collected sporocarps and tuberculate ectomycorrhizae of both Rhizopogon vinicolor and Rhizopogon vesiculosus from three 50 x 100 m plots located at Mary's Peak in the Oregon Coast Range (USA); linear map distances between plots ranged from c. 1 km to c. 5.5 km. Six and seven previously developed microsatellite markers were used to map the approximate size and distribution of R. vinicolor and R. vesiculosus genets, respectively. Genetic structure within plots was analysed using spatial autocorrelation analyses. No significant clustering of similar genotypes was detected in either species when redundant samples from the same genets were culled from the data sets. In contrast, strong clustering was detected in R. vesiculosus when all samples were analysed, but not in R. vinicolor. These results demonstrate that isolation by distance does not occur in either species at the intraplot sampling scale and that clonal propagation (vegetative growth) is significantly more prevalent in R. vesiculosus than in R. vinicolor. Significant genetic differentiation was detected between some of the plots and appeared greater in the more clonal species R. vesiculosus with Phi(ST) values ranging from 0.010 to 0.078*** than in R. vinicolor with Phi(ST) values ranging from -0.002 to 0.022** (*P < 0.05, **P < 0.01, ***P < 0.001). When tested against the null hypothesis of no relationship between individuals, parentage analysis detected seven likely parent/offspring pairs in R. vinicolor and four in R. vesiculosus (alpha = 0.001). Of these 11 possible parent/offspring pairs, only two R. vinicolor pairs were still supported as parent/offspring when tested against the alternative hypothesis of being full siblings (alpha = 0.05). In the latter two cases, parent and offspring were located at approximately 45 m and 28 m from each other. Challenges to parentage analysis in ectomycorrhizal fungi are discussed.     

Taxonomy of the Rhizopogon vinicolor species complex based on analysis of ITS sequences and microsatellite loci

We are re-addressing species concepts in the Rhizopogon vinicolor species complex (Boletales, Basidiomycota) using sequence data from the internal-transcribed spacer (ITS) region of the nuclear ribosomal repeat, as well as genotypic data from five microsatellite loci. The R. vinicolor species complex by our definition includes, but is not limited to, collections referred to as R. vinicolor Smith, R. diabolicus Smith, R. ochraceisporus Smith, R. parvulus Smith or R. vesiculosus Smith. Holo- and/or paratype material for the named species is included. Analyses of both ITS sequences and microsatellite loci separate collections of the R. vinicolor species complex into two distinct clades or clusters, suggestive of two biological species that subsequently are referred to as R. vinicolor sensu Kretzer et al and R. vesiculosus sensu Kretzer et al. Choice of the latter names, as well as morphological characters, are discussed.     

Comparative anatomy of ectomycorrhizas synthesized on Douglas fir by Rhizopogon spp. and the hypogeous relative Truncocolumella citrina

The morphology and anatomy of ectomycorrhizas of Rhizopogon parksii , Rhizopogon vinicolor and Rhizopogon subcaerulescens , and a hypogeous relative, Truncocolumella citrina , synthesized on Douglas fir in glasshouse conditions using spore slurries as inoculum, are described and compared. Mycorrhizas formed with R. parksii and R. vinicolor did not exhibit their characteristic subtuberculate morphology in these tests, but rather had a pinnate form. All species had diagnostic features of ectomycorrhizas: a well-developed Hartig net and a fungal mantle. In addition, several species exhibited crystal inclusions in the outer mantle, usually at the interface between the mantle and soil. Truncocolumella citrina had crystal-like inclusions within the mantle but external to fungal hyphae, a feature rarely described in ectomycorrhizas.     

A Cytochenfical Study of Acid Phosphatas in the Mycorrhizal Cells of Gastrodia elata Seedling

A cytochemical study has been made to examine the activity of acid β-glycerophosphatase in the mycorrhizal cells of the seedling of Gastrodia elata BI. using thin sectioning technique in which sections were embedded in glycol mathacrylate (GMA). After the seedling was invaded by the hyphae of Mycena osmundicola Lange, two different kinds of infected cells were formed in its root cortex.the outer 1–2 cell layers namely the hyphae-containing cells (or host cells) contained many coiled hyphae pelotons; the inner comparativly large cell layer or fungus-digesting cells contained a few straight hyphae. Localization of acid phosphatase in hyphae-containing cells showed that only a few senescent hyphae retained the enzyme activity and the plant cells did not release hydrolytic enzyme. So it is considered that the hyphal lysis in hyphae-containing cell may be due to autolysis. In contrast, higher acid phosphatase activity was visualized in many vesicles and small vacuoles of the fungus-digesting cells. When a hypha entered a fungus-digesting cell through a hyphae-containing cell, a number of enzyme granules (i. e, enzymecontaining vesicles) gathered around it. Later on the enzyme granules expanded gradually and became small enzyme vacuoles of 1.6–2.0 μm in diameter. Still later the small enzyme vacuoles fused with each other to form a large vacuole in which a part of an invading hypha was enclosed and gradually digested by hydrolytic enzymes. Finally,the digesting vacuole changed into a residual body containing some metabolic waste. The above results suggest that fungus-digesting cells can actively release hydrolytic enzymes by lysosomal vesicles to digest the invading hyphae, but such function is not present in the hyphae-containing cells,the role of which may be attributed to attracting and controling the invading hyphae.     

Ultrastructure of freeze-substituted hyphae of the basidiomyceteLaetisaria arvalis

Summary The ultrastructure of freeze-substituted (FS) hyphae ofLaetisaria arvalis is described and compared to that of similar hyphae preserved by conventional chemical fixation (CF). The outline of membrane-bound organelles as well as the plasma membrane was smooth in FS cells. In contrast, hyphae preserved by CF exhibited membrane profiles that were extremely irregular. Centers of presumed Golgi activity were best preserved by FS. Microvesicles, 27–45 nm diameter and hexagonal in transverse section, were observed most readily in FS cells. Filasomes (= microvesicles within a filamentous matrix) were only observed in FS cells. Apical vesicles, 70–120 nm diameter, associated with the centers of Golgi activity and within the Spitzenkörper region exhibited finely granular matrices in FS hyphae, whereas in CF hyphae the contents were coarsely fibrous and less electron-dense. Microvesicles were present at hyphal apices and regions of septa formation. Filasomes were also found at regions of septa formation as well as along lateral hyphal tip cell walls. Microvesicles, but not filasomes, were observed in membrane-bound vesicles (= multivesicular bodies) and in larger vacuoles. Filaments, 5.2–5.4 nm wide, were juxtaposed with centripetally developing septa. Cytoplasmic inclusions, 20–40 m in length, composed of bundles of 6.7–8.0 nm wide filaments were observed in both FS and CF hyphae.     

Electron microscopy of the endophyte ofAlnus glutinosa

Earlier light microscopic investigations have revealed that the endophyte ofAlnus glutinosa presents itself in three different forms. In the present study this is confirmed by electron microscopy; also, new data on the cytology of the endophyte have been obtained.The host cells are primarily infected by the hyphal form of the endophyte. A plant cell nucleus and mitochondria can be found in the infected host cells.In the majority of the infected cells, so-called vesicles develop at the tips of the hyphae. Electron micrographs show that these vesicles, as well as the hyphae, are surrounded by the host-cell cytoplasmic membrane. The endophyte cytoplasm inside the vesicles is divided in all directions by cross walls, many of which are incomplete. Plasmalemmosomes are conspicuous. Some vesicles look vigorous but others shrunken or nearly devoid of cytoplasm as if being digested.A minority of host cells situated between the vesicle-containing ones are completely filled by bacteria-like cells. These host cells, in contrast to the other ones, do not contain a nucleus nor mitochondria, nor are the endophyte cells in them enveloped by a host cell cytoplasmic membrane: these host cells are dead. Vesicles are not found in these cells.It is inferred that a living host cell exerts a stimulus on the endophyte to which the latter responds by forming vesicles at the tips of the hyphae. At a later stage the host cells digest the vesicles and the hyphae. On the other hand, if a host cell does not survive the infection, the hyphae divide into bacteria-like cells, which are not digested owing to the absence of host cytoplasm.According to the cytology of the hyphae, the endophyte is an actinomycete.The cytology of the endophyte needs further elucidation. Its plasmalemmosomes, or membranous bodies connected with the cytoplasmic membrane, are beautifully developed. The striated bodies described on p. 359 under 4) may be a new feature, which may turn up in other actinomycetes or bacteria.     

A Cytological Study on the Nutrient Uptake Mechanism of a Saprophytic Orchid Gastrodia elata

There are three type cells infected by the mycorrhizal fungus, ArmiUaria mellea (Vahl ex Fr. ) Karst in the tube cortex of Gastrodia elata BI., namely the passage cells, host cells and digesting cells. Ultrastructural study demonstrated that the passage cells were distroyed by the hyphae, the host cells kept symbiotic with the hyphae, but the digesting cells could become inversely parasitic on the hyphae from which nutrient were being uptaken. The detail process of the digesting cells obtaining nutrient'from the fungus is described as follows: Firstly the digesting cells began to attack the invading hyphae by releasing numerious electron-transparent vesicles of lysosomal property, secondly they took up the soluble organic material leaked out from the digested hyphae by forming many electron-dense endocytic tubes and vesicles, and finally they endocytosed and hydrolysed the insoluble hyphal walls by forming large digesting vacuole in which a piece of hyphal wall was completely enveloped.     

天麻吸收蜜环菌营养机制的细胞学研究

天麻(Gastrodia elata BI.)地下块茎皮层内具三种染菌细胞:通道细胞、寄主细胞和消化细胞。超微结构的研究表明,通道细胞被真菌所破坏,寄主细胞与真菌保持共生关系,而消化细胞能反寄生于真菌并从真菌摄取营养。消化细胞首先释放溶酶体小泡消化真菌,然后通过内吞管和内吞泡吸收菌丝细胞质降解后渗漏的可溶性有机大分子物质,后期通过消化泡进一步吞噬和消化不溶性菌丝细胞壁物质。     

Mycotrophy of Annona cherimola and the morphology of its mycorrhizae

The mycotrophic character of Annona cherimola (Magnoliales), a tropical/subtropical plantation crop of interest, is described for the first time. This crop seems to depend on mycorrhizae (arbuscular) for optimal growth, with Glomus deserticola being the most effective endophyte tested. Study of the morphology of the arbuscular mycorrhizae in Annona roots showed exclusively intracellular hyphal development, with cell-to-cell fungal passage and an abundance of arbuscules and coiled hyphae within cells. Intercellular distributive hyphae were not observed. The morphology and the pattern of spread of the mycorrhizal colonization were similar for the different endophytes involved and appeared to be dependent on the host root. Such features of mycorrhizal colonization are characteristic of host species lacking intercellular air channels and have been described for some species of ecological interest, but they are not commonly noted in the mycorrhizal literature, especially that dealing with crop species. Some ecophysiological consequences of this pattern of colonization are discussed.     

蜜环菌侵染天麻皮层过程中酸性磷酸酶的细胞化学研究

被蜜环菌(Armillaria mellea)侵染的天麻(Gastrodia elata B1.)皮层中,由外至内形成三种类型的染菌细胞:菌丝结细胞、空腔细胞和消化细胞。外部两类细胞中的酸性磷酸酶定位显示,一些位于空腔细胞或衰老的菌丝结细胞中的菌丝内部逐渐产生大量酸性磷酸酶,随后菌丝发生自溶。这两类细胞中未发现明显的释放水解酶消化菌丝的现象。当菌丝进入消化细胞以后,情况与此不同,大量包含酸性磷酸酶的微小颗粒出现在菌丝周围,随后这些酶颗粒相互融合,形成包围菌丝的消化泡,菌丝被溶酶体水解酶所消化。最后消化泡变为包含代谢废物的残体。     

In vitro production of specialized reproductive torulose hyphae byFrankia strain ORS 021001 isolated fromCasuarina junghuhniana root nodules

Summary AFrankia strain (ORS 021001) isolated fromCasuarina junghuhniana root nodules was shown to produce four type of structuresin vitro: vegetative hyphae, sporangiospores within sporangia, N₂-fixing vesicles, and a fourth type of structure which is described in detail in this report. Structures of this latter type which we propose to call reproductive torulose hyphae: (RTH) result from enlargement and multiple segmentation of vegetative hyphae into torulose chaions of spore-like cells. RTH differ from sporangia in three major aspects: morphology, morphogenesis and outgrowth. RTH play an important role in survival and reproduction ofFrankia strain ORS 021001. Adding activated charcoal to the nutrient medium promotes the formation ofFrankia colonies orginating from RTH.     

Anatomy and mycotrophy of the achlorophyllous Afrothismia winkleri

Afrothismia winkleri develops fleshy rhizomes, densely covered with small root tubercles, narrowing to filiform roots with age. The exclusively intracellular mycorrhizal fungus has distinct morphologies in different tissues of the plant. In the filiform root the hyphae grow straight and vesicles are borne on short hyphal stalks. The straight hyphae are present in the epidermis of the root tubercles, but change to loosely coiled and swollen hyphae in the rhizome tissue. No penetration from epidermis to root cortex was found. From the rhizome, a separating cell layer permits only one or rarely two hyphal penetrations into the cortex of each root tubercle. The hyphae proceed apically within the root hypodermis in a spiral row of distinctively coiled hyphae, branches of which colonize the inner root cortex. In the inner root cortex the hyphal coils degenerate to amorphous clumps. In older roots the cortex itself also deteriorates, but epidermis, hypodermis, endodermis and central cylinder persist. The mycorrhizal pattern in A. winkleri is interpreted as an elaborate exploitation system whereby the fungus provides carbon and nutrients to the plant and, simultaneously but spatially distinct, its hyphae are used to translocate and store the matter within the plant. Several features indicate that the endophyte is an arbuscular mycorrhizal fungus.     

Identification of a New Coiled Body Component

Coiled bodies are small, round nuclear inclusions that have been identified in many somatic cell types. Equivalent structures are found in the germinal vesicles of amphibian and insect oocytes, known respectively as sphere organelles and Binnenkörper. Their functions are not known, but their molecular composition is being brought to light. In addition to the nucleolar protein, fibrillarin, coiled bodies contain DNA topoisomerase I and an array of RNA processing molecules characteristic of spliceosomes. One coiled body protein absent from nucleoli and spliceosomes, known as p80-coilin, has also been described. We have now identified pigpen, a new member of the EWS family of proteins, as a second protein enriched in coiled bodies. In an earlier report we found that pigpen's structure and expression pattern were suggestive of a role in endothelial cell proliferation and differentiation. In this brief report we characterize pigpen's nuclear compartment and describe its reorganization during mitosis.     

The response of arbuscular mycorrhizae to fertilization, mowing, and removal of dominant species in a diverse oligotrophic wet meadow

In a wet oligotrophic meadow located in the Czech Republic, a factorial experiment with treatments consisting of fertilization, mowing, and removal of the dominant species (Molinia caerulea) was established in 1994. In 1997 Holcus lanatus, Molinia caerulea, Potentilla erecta, Prunella vulgaris, and Ranunculus auricomus were examined for arbuscular mycorrhizal (AM) hyphae, arbuscles, and vesicles three times over the season. Time had a significant effect on AM in all five species. Except for Molinia arbuscles, a modal effect occurred, with the second sampling having a greater level of AM structures than the first and the third. Fertilization had the greatest effect on AM levels by decreasing the level of Holcus hyphae and vesicles, Potentilla vesicles, Prunella hyphae, and Ranunculus hyphae and vesicles. Mowing significantly increased the number of Potentilla vesicles, and the removal of dominant species had no significant effects. Interactions between time and treatments were common. Significant effects to the arbuscle:vesicle ratio were infrequent, and those that occurred were related to changes over the season. Seasonal effects appear to have a more powerful effect on AM structures and the arbuscle:vesicle ratio than do treatment effects. In a second experiment, Ranunculus auricomus, R. acris, and R. nemorosus, sampled four times over the season, showed significant changes in AM colonization. Overall, AM structures either declined over the season or increased from April to May and then declined. There was no AM colonization response to a spring fertilization in the three species. It is postulated that the patterns observed are due to phosphorus availability and seasonal changes in soil moisture and rates of root growth and turnover.     

Schizophyllum commune Fr. as a destructive mycoparasite

Schizophyllum commune Fr. was shown, by light, scanning, and transmission electron microscopy, to be a destructive mycoparasite on several phytopathogenic and nematode-trapping fungi. The hyphae of S. commune coiled around host hyphae and fruiting structures and penetrated them by means of either unspecialized hyphae or by penetration pegs that developed from terminal appressoria. The host cell walls were usually chemically degraded after which the parasite grew through an electron-dense, papillate, reaction region and its underlying membrane(s) produce trophic hyphae inside the host cells.     

墨兰菌根的结构及酸性磷酸酶定位研究

利用光学显微镜、电子显微镜及细胞化学方法,对墨兰菌根的结构和酸性磷酸酶定位进行了初步研究。结果表明墨兰具有典型的兰科植物根结构,发现该兰花的根的外皮层不具薄壁通道细胞,菌根真菌通过破坏部分根被和外皮层细胞而侵入根的皮层细胞并在细胞内形成菌丝结,侵入的菌丝被染菌皮层细胞质膜和电子透明物质包围,进一步被消化并聚集成衰败菌丝团块。酸性磷酸酶在染菌皮层细胞及包围菌丝的皮层细胞质膜和衰败菌丝细胞壁上有强烈的酶反应,衰败菌丝周围分布有许多单层膜的含酶小泡,它们可相互愈合形成大的含酶泡或与包围菌丝的质膜融合,类似于兰科植物共生原球茎中观察到的现象。说明皮层细胞可主动释放水解酶参与对菌丝的消化     

Observations on the ultrastructure ofFrankia sp. in root nodules ofDatisca cannabina L.

Summary The fine structures of the microsymbiont inside the root nodules ofDatisca cannabina have been studied by light, by transmission- and by scanning-electron microscopy. The endophyte is prokaryotic and actinomycetal in nature. The hyphae are septate and branched, diameter 0.3–0.5 m. The tips of hyphae are swollen to form electron-dense, clubshaped to filamentous vesicles, ranging in diameter: 0.4–1.4 m. The endophyte penetrates through walls of the cortial cells. The infected zone is kidney shaped and confined to one side of the acentric stele. The orientation of infection is reversed from other actinorhizae exceptCoriaria. The hyphae are near the host cell wall and vesicles are directed towards the central vacuole. Vesicles are aseptate and no collapsing of the vesicle cell wall (void area) has been observed. Vesicle clusters structures are globular with an opening at one side of the cluster. The host cell is multinucleate or contains a lobed nucleus. Groups of mitochondria are located in between the hyphae, suggesting a strong association between the host and the endophyte for energy supply and amino acid production. The consequences of the inability to separate the mitochondria from the vesicle clusters in nodule homogenates in physiological studies have been discussed.Isolated vesicles clusters showed dehydrogenase activity, indicated by the presence of formazan crystals, after incubation with NADH and NBT. Strongest reducing activity was found within the vesicles. The possible role of filamentous vesicles in nitrogen fixation has been discussed.     

Study on Structure and Localization of Acid Phosphatase of Mycorrhizal Root of Cymbidium sinense (Orchidaceae)

The microstructure and ultrastructure of mycorrhizal root of Cymbidum sinenese (Andr.) Wild were studied. The results showed that this species possesses the typical root structure of orchids. There is no passage cells in the exodermis of root. Mycorrhizal fungi invade into the cortex by destroying the velamen and exodermal cells, and form pelotons in cortical cells. The hyphae colonizing cortical cells were separated from the cortical cells by electron- lucent material and cortical cell plasma membrane and digested. They often gathered to form clumps. Localization of acid phosphatase revealed that this enzyme possessed higher activity in the cortical cells containing hyphae. Many products of it also occurred on cortical cell plasma membrane surrounding hyphae and degenerated hyphae cell wall. Higher acid phosphatase activity was observed in many vesicles in the cortical cells infected by fimgi. These enzyme vesicles gathered around the invaded hy-phae and often fused with each other, or with cortical cell plasma membrane surrounding hyphae to digest these hyphae. It means cortical cells were able to release hydrolytic enzyme to digest the invaded hyphae.     

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.