The structure and histochemistry of sclerotia of Ophiocordyceps sinensis

The structure and histochemistry of sclerotia of Ophiocordyceps sinensis (synonym: Cordyceps sinensis) are described. The remains of the caterpillar epidermis and sometimes setae of the caterpillar were attached to the pigmented layer that is external to the rind of the sclerotium. The outer aerial hyphae and hyphae of the inner medulla were densely interwoven around the epidermis of the caterpillar; these eventually differentiated into the rind of the sclerotium. The medulla of the sclerotium consisted of three intergrading regions of hyphal density: high, low and a region of intermediate hyphal density. All hyphae of the medulla contained large quantities of protein, polysaccharide and polyphosphate; only the region of high hyphal density was rich in beta-1,3 glucans; the center of the sclerotium was almost devoid of hyphae and contained what are most likely the remains of caterpillar tissue. These features are compared with those of sclerotia of other fungi, and their possible significance is discussed.     

THE MORPHOGENESIS AND POSSIBLE EVOLUTIONARY ORIGINS OF FUNGAL SCLEROTIA

1. Fungal sclerotia are able to survive adverse conditions for long periods and they are formed by many important plant pathogens. An understanding of the factors involved in their initiation and development may lead to a method of repressing their formation in nature, thereby reducing the chances of survival of fungi that depend on them as persistent resting stages in their life-cycles. Also, data on sclerotial morphogenesis may be applicable to other multihyphal fungal structures. 2. There are three types of sclerotial development. The most primitive and least common is the loose type, which is illustrated by Rhizoctonia solani. The sclerotium forms by irregular branching of the mycelium followed by intercalary septation and hyphal swelling. When mature, it consists of loosely interwoven hyphae that are rich in food reserves and darkly pigmented. The main types of development are terminal and lateral. The former develops from the coalescence of initials that are produced by a well-defined pattern of branching at the tip of a hypha or tips of closely associated hyphae, e.g. Botrytis cinerea. Lateral sclerotia are formed by the interweaving of side branches of one or several main hyphae. When only one main hypha is involved the sclerotium is of the lateral, simple type, e.g. Sclerotinia gladioli. If several main hyphae give rise to a sclerotium, the term strand type has been used. Sclerotium rolfsii is the classical example. 3. There is a considerable literature on the effects of environmental conditions on the initiation, development and maturation of sclerotia but few attempts have been made to interpret the data. Phenolics and/or polyphenol oxidases have been found to be connected with morphogenesis of the protoperithecium of Neurospora crassa, the perithecium of Podospora anserina and of Hypomyces sp. and the basidiocarp of Schixophyllum commune. A close correlation has been shown between melanin synthesis and microsclerotial development by Verticillium but there appears to be no literature on the role of phenolics and polyphenol oxidases in the morphogenesis of sclerotia. Possibly these substances may inhibit growth of the apices of main hyphae by changing the permeability of the membrane, by inducing a thickening of the cell wall at the tip or by reducing the plasticity of the wall. Such a check in growth could trigger-off the formation of initials close to the margin of the colony or elsewhere in the culture. Sulphydryl groups and disulphide bonds are of great significance in morphogenesis of organisms and are probably involved in sclerotial initiation. The formation of a large number of hyphal branches is a prerequisite for sclerotial initiation and mycelial branching is possible only if there is plasticity of hyphal walls. The ability of the wall to be moulded is possibly related to changes in the sulphur linkages of the protein of the protein-carbohydrate complexes of the cell wall and could be influenced by sulphur availability or the activity of specific enzymes. 4. After a sclerotial primordium has been initiated, further increase in size will depend on the continued, active translocation of nutrients to the site of development. Movement of nutrients to sclerotia is through a few translocatory hyphae. Presumably, nutrients will continue to move into the young sclerotium as long as a concentration or pressure gradient is maintained. Energy and substances for the formation of new branches are supplied in this way and as the requirements for hyphal branches are reduced, excess nutrients become available for conversion to inactive or insoluble reserves and for exudation. The exudates are often complex, consisting of proteins, including enzymes, lipids and carbohydrates. Many sclerotia have a mucilaginous matrix in which the medullary hyphae are embedded. Sclerotium-forming, fungal species that are not regarded as having such a matrix appear to secrete a layer of mucilage over the surface of sclerotial hyphae. This mucilage could have a morphogenetic function and serve as an adhesive which loosely binds hyphae together. More permanent unions are by hyphal fusions or anastomoses. 5. The sclerotium matures within a few days of attaining its maximum size. The rind effectively seals off the medullary hyphae from the surroundings and the translocatory hyphae cease to function. Thus the sclerotium is isolated both physiologically and nutritionally. The endogenous reserves enable the structure to exist in the absence of exogenous nutrients and then, when conditions become suitable, to germinate. 6. The sclerotium appears to provide an example of convergent evolution whereby analogous structures, which have become adapted to resist adverse conditions, have evolved. Data are available mainly for Typhula spp. and ScZerotinia spp. Sclerotia may be degenerate sexual reproductive structures, hyphal aggregates that have developed from closely interwoven conidiophores and undifferentiated conidia or they may be modified vegetative structures.     

Structure of the outer surfaces of sclerotia of certain fungi

Summary The surfaces of sclerotia of Rhizoctonia solani, Botrytis cinerea and Sclerotinia rolfsii were examined with the Stereoscan electron microscope.The periphery of the sclerotium of R. solani consists of a loose net-work of hyphae which are not sufficiently thickened to withstand the extreme desiccation that takes place when the material is coated with gold-palladium alloy.The surface of the sclerotium of B. cinerea has many closely packed hyphal tips which project outwards from the centre of the structure. The thickening of the walls of the hyphae enable them to retain their shapes. A film was observed on the most exposed areas and this may have been dried-up melanin pigment.The outer skin of the sclerotium of S. rolfsii is an almost continuous layer which is thrown into ridges and troughs to give a wavy appearance.     

Morphological characteristics of sclerotia formed from hyphae of <Emphasis Type="Italic">Grifola umbellata</Emphasis> under artificial conditions

The morphological characteristics of sclerotia were induced in cultures of the fungus Grifola umbellata by introducing an unidentified companion fungus were studied by light microscope, scanning and transmission electron microscope (SEM and TEM). Light microscope and SEM investigations of developing sclerotia revealed that aerial mycelial hyphae diminished with age, and mature sclerotia had two tissue layers, the rind and medulla. The medulla was comprised of thin and thick-walled hyphae of varying diameter. The thick-walled cells always formed below the hyphal tips. Retraction of the cytoplasm was accompanied by the thickening of cell wall. There were crystalline initials in the newly formed sclerotium. Crystalline initials were always formed in the tip of medullary hyphae and were not of regular shape. A series of changes occurred in the cells in which the crystalline initials would be formed, such as enlargement of size, formation of one or several large vacuoles. Crystalline initials developed via amorphous materials in the cytoplasm deposited in the vacuoles. At last crystalline initials was released by degradation of the cell wall.     

Changes during development in the permeability of sclerotia ofSclerotinia minor to an apoplastic tracer

Summary Sclerotia ofSclerotinia minor produced in culture are permeable to the apoplastic tracer sulphorhodamine G (SR) in early stages of their development, but become impermeable as the rind differentiates at the onset of maturation. Reduction in permeability corresponds with deposition of the dark brown pigment in the rind cell walls rather than initiation of the rind as a distinct surface layer. Fluorochrome permeation into cut sclerotia indicates that, while the rind is the primary barrier, the walls and extracellular matrix of the cortex and medulla of mature sclerotia also impede SR movement. Some cells take up fluorochrome into the protoplast. This indicates enhanced proton pumping activity at the cell surface, which suppresses ionisation of the fluorochrome, allowing it to cross the plasma membrane and accumulate in the hyphae. In intact sclerotia such hyphae are very rare and were detected only at one stage of development. However, in cut sclerotia at the two earliest stages of development most of the hyphae near the cut surface accumulated SR and it is possible that this is due to proton pumping activity induced by wounding.Abbreviations ECM extracellular matrix - SR sulphorhodamine G     

蜜环菌侵染后猪苓菌核防御结构的发生及功能

蜜环菌通过猪苓菌核表皮侵染菌核时,菌核表皮下层的菌丝具特异的拮抗反应,如细胞中有结晶颗粒出现,厚壁菌丝形成,部分薄壁菌丝有质壁分离现象。蜜环菌的侵染诱导了菌核防御结构的发生:离侵染点一定距离的部位出现由少量木质化菌丝和厚壁菌丝形成的疏松带状;蜜环菌侵入后,上述菌丝增多并紧密排列形成菌核的初级隔离腔,入侵的蜜环菌和部分菌核被隔离在腔中;在初级隔离腔形成的同时,外围的次级隔离腔开始发育。蜜环菌菌索和皮层菌丝分枝可突破初、次级隔离腔的壁,再以菌索产生的侵染带侵染菌核较外部的最后防线即三级隔离腔。本文较系统的阐述了蜜环菌侵染后菌核各防御结构的发生特点及功能。     

The structure and histochemistry of sclerotia ofSclerotinia minor Jagger

Summary A detailed histochemical investigation was carried out on rind, cortical and medullary hyphae of sclerotia ofSclerotinia minor Jagger. Four developmental stages, including mature sclerotia, were studied. The walls and septa of all hyphae contained chitin and -1,3 glucans, while those of the rind contained in addition, a melanin-like pigment. An extracellular matrix, which accumulated around cortical and medullary hyphae, consisted primarily of -1,3 glucans, although another polysaccharide, which could not be identified by histochemical methods, was also present. Phenolic material was deposited around the extracellular matrix and in the few interhyphal spaces that remained at maturity. Glycogen was present throughout the cytoplasm of hyphae of the cortex and medulla, at all stages of their differentiation. Polyphosphate granules were laid down within small vacuoles and as sclerotia matured, became most common in the cortical region. Protein bodies developed rapidly in cortical and medullary hyphae until at maturity, they were the most obvious interhyphal feature. These bodies were either round or elongated in shape, the elongated ones often lying parallel to the long axis of the hyphae, and in close association with strands of endoplasmic reticulum. No lipid reserves were detected.Mrs. S.Lowry.     

Characterization of the Sclerotinia sclerotiorum cell wall proteome

We used a proteomic analysis to identify cell wall proteins released from Sclerotinia sclerotiorum hyphal and sclerotial cell walls via a trifluoromethanesulfonic acid (TFMS) digestion. Cell walls from hyphae grown in Vogel's glucose medium (a synthetic medium lacking plant materials), from hyphae grown in potato dextrose broth and from sclerotia produced on potato dextrose agar were used in the analysis. Under the conditions used, TFMS digests the glycosidic linkages in the cell walls to release intact cell wall proteins. The analysis identified 24 glycosylphosphatidylinositol (GPI)‐anchored cell wall proteins and 30 non‐GPI‐anchored cell wall proteins. We found that the cell walls contained an array of cell wall biosynthetic enzymes similar to those found in the cell walls of other fungi. When comparing the proteins in hyphal cell walls grown in potato dextrose broth with those in hyphal cell walls grown in the absence of plant material, it was found that a core group of cell wall biosynthetic proteins and some proteins associated with pathogenicity (secreted cellulases, pectin lyases, glucosidases and proteases) were expressed in both types of hyphae. The hyphae grown in potato dextrose broth contained a number of additional proteins (laccases, oxalate decarboxylase, peroxidase, polysaccharide deacetylase and several proteins unique to Sclerotinia and Botrytis) that might facilitate growth on a plant host. A comparison of the proteins in the sclerotial cell wall with the proteins in the hyphal cell wall demonstrated that sclerotia formation is not marked by a major shift in the composition of cell wall protein. We found that the S. sclerotiorum cell walls contained 11 cell wall proteins that were encoded only in Sclerotinia and Botrytis genomes.     

Scanning Electron Microscopy of Sclerotia of Sclerotinia trifoliorum and Related Species

The microanatomy of immature 'white', 'slightly pigmented' and mature, 1-month-old 'black' sclerotia of Sclerotinia trifoliorum , S. sclerotiorum , and S. minor were studied by scanning electron microscopy (SEM). A surface mycelial network was present over sclerotia at maturity. Also dried exudate on the superficial, sclerotial cells at maturity was observed. At this stage of morphogenesis an outer layer of the wall of medullary hyphae was synthesized. Two zones (i.e., rind and medulla) of hyphal tissue in sections of mature sclerotia were distinguished. The wall of rind cells was thick and one-layered, whereas the wall of medullary hyphae was thick and bi-layered.
No lacunac (intercellular spaces) in sclerotial rind were found but the sclerotial medulla appeared to be lacunate in all three species. At the SEM level the structural organization of sclerotia of S. trifoliorum was identical to that one of sclerotia of S. sclerotiorum and S. minor. Thus, in the conducted investigation of the sclerotial stromata, a unique, structural characteristic of taxonomic importance to distinguish S. trifoliorum from the other Sclerotinia species was not found. Observations on the sclerotial morphogenesis in S. trifoliorum and the related species agree with and supplement the light and transmission electron microscope studies of other researchers.     

植物病原真菌的菌核研究进展

真菌菌核是相关真菌在特殊环境下由营养体菌丝交织和聚集形成的具有抵御恶劣环境能力的休眠结构,在真菌生活史及病原真菌的病害循环中具有重要的生物学和生态学意义。许多引起严重植物病害的病原真菌能够形成菌核,这类真菌通过菌核度过逆境。菌核在适宜条件下萌发形成子囊盘和孢子或菌丝,造成植物的侵染。本文从形成菌核的真菌种类、生物学特性、黑色素及分子生物学等方面进行综述,旨在为深入研究真菌菌核及其在真菌学、植物病理学及药用真菌学等领域应用提供研究思路和参考依据。     

How many fungi make sclerotia?

Most fungi produce some type of durable microscopic structure such as a spore that is important for dispersal and/or survival under adverse conditions, but many species also produce dense aggregations of tissue called sclerotia. These structures help fungi to survive challenging conditions such as freezing, desiccation, microbial attack, or the absence of a host. During studies of hypogeous fungi we encountered morphologically distinct sclerotia in nature that were not linked with a known fungus. These observations suggested that many unrelated fungi with diverse trophic modes may form sclerotia, but that these structures have been overlooked. To identify the phylogenetic affiliations and trophic modes of sclerotium-forming fungi, we conducted a literature review and sequenced DNA from fresh sclerotium collections. We found that sclerotium-forming fungi are ecologically diverse and phylogenetically dispersed among 85 genera in 20 orders of Dikarya, suggesting that the ability to form sclerotia probably evolved ≥14 different times in fungi.     

Structural aspects of Douglas-fir [Pseudotsuga menziesii (Mirb.) Franco] tuberculate ectomycorrhizae

Summary Tubercles of Pseudotsuga menziesii consisted of clusters of ectomycorrhizae surrounded by a peridiumlike rind. Energy dispersive spectroscopy demonstrated that crystals found in the zone of loose hyphae extending from the inner rind to the mantle of each root probably contain calcium oxalate. Inner mantle and Hartig net hyphae showed a labyrinthine branching pattern and stored carbohydrates and protein. The Hartig net formed up to inner cortical cells which had thickened, darkly stained walls. Bacteria were located either along with hyphae within the rind or as colonies on the surface of the tubercle.     

Reserve substances inPaxillus involutus sclerotia

Summary The ectomycorrhizal fungus,Paxillus involutus, produces sclerotia in culture. These can be induced to form on agar medium by exposing mycelium grown at 25°C to various temperatures between6°C and 15°C. Sclerotia formed at 10°C and above were large and covered with drops of exudate, while those formed at 6°C or 8°C were very small and did not produce an exudate. Mature sclerotia were bounded by a compact rind and contained abundant storage reserves. Histochemistry of the larger sclerotia showed large quantities of protein stored as protein bodies in the cytoplasm, lipid present as small droplets, glycogen granules stored in the cytoplasm and polyphosphate present as small granules in the cytoplasm and in the protein bodies. Energy dispersive X-ray microanalysis confirmed the presence of phosphate in the granules and was used to map its distribution throughout the sclerotium. The smaller sclerotia induced at 8°C and below on the same medium had the same basic structure and composition, but lacked the complex phenolic cell network found in large sclerotia, and had abundant extracellular polysaccharides. The rind was not well developed and these small sclerotia are interpreted to have been arrested at an early stage of development.     

猪苓菌丝形成菌核结构的特点

对猪苓(Grifola umbellata(Pers.)Pilat)菌丝在人工条件下形成菌核及繁殖过程、人工菌核与野生菌核及培养基上未形成菌核的猪苓菌丝的显微结构进行了系统研究.研究证明:人工菌核的结构与野生菌核的结构相似,均具有菌髓和皮层结构.人工菌核中的菌丝与培养基表面未形成菌核的猪苓菌丝存在着显著的差异,人工菌核是由培养基上纯培养的菌丝分化为膨大菌丝再由此形成有高度组织分化的猪苓菌核.     

猪苓菌丝形成菌核结构的特点(英文)

对猪苓(Grifolaumbellata(Pers.)Pilat)菌丝在人工条件下形成菌核及繁殖过程、人工菌核与野生菌核及培养基上未形成菌核的猪苓菌丝的显微结构进行了系统研究。研究证明人工菌核的结构与野生菌核的结构相似,均具有菌髓和皮层结构。人工菌核中的菌丝与培养基表面未形成菌核的猪苓菌丝存在着显著的差异,人工菌核是由培养基上纯培养的菌丝分化为膨大菌丝再由此形成有高度组织分化的猪苓菌核。     

The sclerotia of Coprinus lagopus

Summary Sclerotia of Coprinus lagopus were produced in the laboratory and observed microscopically from initiation to maturity. Isolated bulbous hyphal cells appeared below or on the agar surface as the primary sclerotial initials. Short interhyphal cells had expanded lateral walls and increased in number at their isolated locations, and were surrounded by a thick network of normal mycelium. Increasing in numbers, the bulbous cells developed a tightly compact colony devoid of agar if submerged below the agar surface and lacked normal hyphal filaments. The outer cells thickened formed cell lumina and developed as a protective rind to the mature sclerotium.     

The respiration of sclerotia of Sclerotium rolfsii

Summary The respiration of sclerotia ofS. rolfsii was investigated using the Warburg constant-volume respirometer to measure oxygen uptake. The effects of age of sclerotia, pH, and temperature were studied. Sclerotia produced on prune agar were ideal for respirometric studies, being uniformly round and of approximately equal size. On a dry weight basis, the respiration rates of sclerotia were considerably less than those of vegetative mycelium. Sclerotia showed a decrease in respiration with increasing age. This was accompanied by morphological changes in the outer hyphal rind of the sclerotium during maturation. The respiration rate of sclerotia was approximately the same at 30° and 40° C, but was significantly lower at 45° C. Respiration of sclerotia was not markedly affected by normally encountered hydrogen-ion concentrations. However, a pH of 8.0 markedly repressed oxygen uptake. Sclerotia produced in rye grain cultures were chemically analyzed. The nitrogen content was 4.7 %, the petroleum-ether-soluble lipid content was 0.7 %, and the crude glycogen content was 14.2 % of the oven dry weight of the sclerotia.Contribution No. 345 from The Department of Botany. Portion of a thesis presented by the senior author in partial fullfillment for the M.S. degree.     

Changes of the cytoplasmic ultrastructure during development of sclerotia in Claviceps purpurea (Fr.) Tul.

The development of sclerotia of Claviceps purpurea was investigated by light and electron microscopy. During the first days after infection sterigma and conidiospores are formed. The spores show a moderately developed vacuolar system, they are thick walled and contain about 20% lipid (related to the cell volume) embedded in glycogen. The sterigma are cylindrical unicellular hyphae with electron dense cytoplasm and isolated strongly contrasted lipid droplets. In maturing sclerotia the hyphae become septated with increasingly thick cell walls and a large lipid content. The lipid forms small droplets in young cells, while in the mature sclerotium it occurs in the form of very large drops, occupying the major part of the cell. Simultaneously the composition of the lipid is changed. The mature cells have several nuclei. They are partially connected by osmiophilic substances, forming a network of intercellular spaces.Abbreviations HEPES N-2-hydroxyethylpiperazine-N'-2-ethanesulfonic acid - DMSO Dimethylsulfoxide     

Ultrastructural basis of sclerotial survival in soil

The ultrastructure of developing and mature sclerotia ofSclerotium rolfsii was studied with a scanning electron microscope. The mature sclerotium is disconnected from the mycelium and well differentiated. The rind is composed of rather thick-walled empty cells. The cortex cells are large and almost completely filled with vesicles, whereas the medullar cells are smaller and some of them are very thickwalled.     

Cytological Studies on the Process of Armillaria Mellea Infection Through the Sclerotia of Grifola Umbellata

Adhering to the sclerotium of Grifola umbellata, Armillaria mellea could invade the sclerotium in a manner of rhizomorph without capsule, after which the sclerotium formed a deep coloured stereoscopic septate cavity outside of the rhizomorph. At the early stage of infection, segmentation was visualized either in the cortex or the apex of A. mellea rhizomorph to form a new rhizomorph which penetrated another parts of G. umbellata sclerotium. At the late stage of infection, the cortical hyphae of A. mellea rhizomorph produced a branch to invade the wall of the septate cavity of G. umbellata sclerotium and, in a manner of hyphae, it could further form new rhizomorph after its penetration through that wall. An alternate way of expanding A. mellea infection in sclerotium was to form a invading band which was composed of a few rolls of round ceils derived from cortical hyphae of A. mellea rhizomorph. The band could invade sclerotia to a farther distance and then could connect with each other.