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Cystidium
Cystidium
Cystidium
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Two chrysocystidia on gill face of Hypholoma lateritium, mounted in KOH.

A cystidium (pl.: cystidia) is a relatively large cell found on the sporocarp of a basidiomycete (for example, on the surface of a mushroom gill), often between clusters of basidia. Since cystidia have highly varied and distinct shapes that are often unique to a particular species or genus, they are a useful micromorphological characteristic in the identification of basidiomycetes. In general, the adaptive significance of cystidia is not well understood.

Classification

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Metuloid-type cystidium of Inocybe, stained with Congo red

By position

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Cystidia may occur on the edge of a lamella (or analogous hymenophoral structure) (cheilocystidia), on the face of a lamella (pleurocystidia), on the surface of the cap (dermatocystidia or pileocystidia), on the margin of the cap (circumcystidia) or on the stipe (caulocystidia). Especially the pleurocystidia and cheilocystidia are important for identification within many genera. Sometimes the cheilocystidia give the gill edge a distinct colour which is visible to the naked eye or with a hand lens.

By morphology

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Chrysocystidia are cystidia whose contents contain a distinct refractive yellow body, that becomes more deeply yellow when exposed to ammonia or other alkaline compounds. Chrysocystidia are characteristic of many (though not all) members of the agaric family Strophariaceae.

Gloeocystidia have an oily or granular appearance under the microscope. Like gloeohyphae, they may be yellowish or clear (hyaline) and can sometimes selectively be coloured by sulphovanillin or other reagents.[1] Metuloids are thick-walled cystidia with an apex having any of several distinct shapes.[2]

References

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Cystidium

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A cystidium (plural: ) is a large, sterile, specialized cell found on the —the spore-bearing surface—of fruiting bodies in basidiomycete fungi, such as mushrooms, boletes, and crust fungi. These cells are typically elongated, club-shaped, or , often with thick walls, and often project prominently beyond the surrounding basidia (the spore-producing cells), making them key microscopic features for species identification. Unlike basidia, cystidia do not produce spores and can vary in size from 20–60 μm, accumulating and featuring abundant smooth in their . Cystidia are classified into several types based on their location and morphology, which contribute to their taxonomic importance. Pleurocystidia occur on the faces of in gilled mushrooms or on the walls of pores in boletes, while cheilocystidia are positioned along the edges of or pores, often exhibiting an excretory role that results in beaded droplets on gill margins. Pileocystidia appear on the surface, caulocystidia on the stem, and other variants include chrysocystidia with yellowish refractive contents, metuloids (thick-walled pleurocystidia with crystal encrustations), and skeletocystidia (projecting ends of skeletal hyphae). These structures arise from the gill trama during fruit body development and can be binucleate or multinucleate, connecting opposing hymenial surfaces in some . The functions of cystidia remain partially understood but are multifaceted, supporting both developmental and ecological roles in basidiomycetes. They commonly act as spacing organs to separate basidia and prevent crowding during spore maturation, aid in stabilizing gill structures during cap expansion, and facilitate moisture evaporation or the release of volatile compounds to enable ballistic spore discharge. Ultrastructural studies indicate a secretory capacity, with large amounts of smooth endoplasmic reticulum suggesting involvement in producing unknown secretions. Additionally, in some species such as , cystidia provide a defensive function against herbivores, such as collembolans, by increasing arthropod mortality and deterring grazing on spore surfaces, thereby protecting basidiospores from predation and damage.

Introduction

Definition

A cystidium is a sterile, non-spore-producing cell that arises within the —the fertile, spore-bearing layer—of basidiomycete sporocarps, such as the gills (lamellae) or pores of mushrooms. These cells are typically larger and morphologically distinct from the surrounding fertile structures, often projecting above the hymenial surface to form prominent, elongated or inflated elements. In basidiomycetes, cystidia contribute to the structural diversity of the reproductive layer but do not participate in spore production. Unlike basidia, which are the specialized, club-shaped cells in the responsible for , , and the formation of basidiospores on sterigmata, cystidia remain sterile throughout their development and lack reproductive function. Similarly, cystidia differ from paraphyses, which are shorter, club-shaped sterile filaments that arise as branches among basidia, providing support without projecting significantly beyond the hymenial plane; in contrast, cystidia are highly inflated and often extend outward, sometimes inserting into opposing hymenia in developing gills. These distinctions highlight cystidia's role as specialized, non-reproductive elements amid the fertile tissue. The plural form of cystidium is cystidia, and these structures are characteristically larger than adjacent hymenial cells, with typical lengths ranging from 20 to 100 µm, though variations occur depending on species and type. This size disparity aids in their identification under microscopy and underscores their prominence in the hymenium.

Etymology and History

The term cystidium originates from New Latin, formed by combining the Greek root kystis (κύστις), meaning "bladder" or "sac," which alludes to the often inflated or sac-like appearance of these fungal structures, with the diminutive suffix -idium (from Greek -idion), indicating a small version of such a form. The concept of the cystidium was first formally introduced in mycological literature by French botanist and mycologist Joseph Henri Léveillé in his 1837 paper Sur le hymenium des champignons, where he coined the term alongside basidium to describe sterile, enlarged cells protruding from the hymenium of basidiomycete fruiting bodies, particularly in hymenomycetes. This innovation built on earlier 19th-century observations by figures like Elias Magnus Fries, who emphasized macroscopic and basic microscopic features in fungal taxonomy but did not yet employ the specific terminology. By the late 19th and early 20th centuries, as compound light microscopy became more accessible, descriptions of cystidia gained prominence in studies of fungal morphology, with mycologists such as Paul Hennings incorporating them into detailed species accounts from regions like Africa and South America. Over time, the usage of cystidium evolved from purely descriptive roles in 19th-century morphological accounts to a cornerstone of systematic . As microscopy techniques advanced, finer resolution of cystidial variations became possible, leading to their routine integration into taxonomic keys for precise species differentiation in basidiomycetes. This shift underscored their value beyond mere description, establishing cystidia as essential diagnostic characters in modern fungal identification.

Occurrence

In Basidiomycetes

Cystidia are primarily found in the hymenium, the fertile spore-producing layer of basidiomycete fruiting bodies, where they occur as sterile cells embedded or projecting among the basidia. This layer is prominently developed in structures such as the gills of agarics, the pores of boletes, and the smooth, hydnoid, or labyrinthine surfaces of corticioid fungi. In these contexts, cystidia contribute to the hymenial architecture, often extending beyond the basidia to form part of the spore-bearing surface. Their occurrence is widespread and prevalent among Hymenomycetes, the subclass encompassing most mushroom-forming basidiomycetes, including diverse groups like agarics and boletes, where they are a common feature aiding in species identification and ecological adaptation. In contrast, cystidia are absent or rare in Gasteromycetes, the group of fungi with enclosed or gasteroid fruiting bodies, such as and earthstars, where the often disintegrates or remains internalized without differentiated sterile elements. Representative examples of genera featuring prominent cystidia include , with its encrusted or refractive types in the gill ; , where they form morphogenetic fields influencing hymenial patterning; and certain species, such as those exhibiting gloeocystidia in the hymenial layer. Developmentally, cystidia originate from undifferentiated hyphal tips within the subhymenium, the generative layer beneath the , during the maturation of the sporocarp (fruiting body). These tips initially resemble basidial initials but diverge into sterile, elongated cells rather than spore-producing structures, a process driven by localized inhibition and hyphal branching patterns that ensure patterned distribution in the maturing . Unlike basidia, cystidia remain sterile throughout development, lacking the capacity for and spore formation.

Distribution Across Fungal Groups

Cystidium-like structures are rare in , where true cystidia as found in basidiomycetes are absent, but analogous features known as cystidioid cells occur in the apothecia of certain species. These cystidioid cells, often resembling elongated or club-shaped sterile hyphae, are reported in genera such as , Helvella, and . For instance, in Morchella iberica, acroparaphyses are described as cystidioid, consisting of 1-3 elements with club-shaped apical cells measuring 100–110 × 20–30 µm. Similarly, Helvella cystidiata features prominent cystidioid elements on the ascomatal surface, aiding in taxonomic identification within the Helvellaceae family. In , cystidioid emanating hyphae appear predominantly at the apices of pseudoparenchymatous tissues. These structures differ from basidiomycete cystidia by their association with asci rather than basidia and lack the typical hymenial projection, serving primarily morphological roles rather than equivalent functions. In Zygomycota and Chytridiomycota, cystidia or comparable hymenial sterile elements are entirely absent, as these groups lack the complex fruiting bodies and layered spore-producing tissues characteristic of higher fungi. Zygomycetes produce coenocytic hyphae and sporangia with sporangiospores, occasionally featuring sterile columellae or apophyses within sporangia, but these are morphologically distinct from projecting cystidia, being internal supportive structures rather than external sterile hyphae. Chytridiomycetes, primarily aquatic and primitive, form simple thalli with zoosporangia and discharge zoospores via an operculum or papilla, without any documented sterile hyphal projections analogous to cystidia; their reproductive structures emphasize motility over hymenial differentiation. This absence reflects the evolutionary divergence of these basal fungal lineages from the Dikarya, where advanced fruiting bodies with sterile elements evolved./24%3A_Fungi/24.02%3A_Classifications_of_Fungi/24.2D%3A_Zygomycota-_The_Conjugated_Fungi) Within subgroups beyond the typical hymenomycetes and gasteromycetes, cystidia are less prevalent, but analogous sterile cells appear in certain parasitic lineages such as (Pucciniales) and smuts (Ustilaginales). In fungi, uredinial and aecial layers often include paraphyses—sterile, clavate or cylindrical hyphae interspersed among —that project from the sorus and resemble cystidia in form and position. For example, grass rust species like those in exhibit capitate or thick-walled uredinial paraphyses, 39–62 µm long, which aid in dispersal and identification. These structures are intra-soral and septate, differing from agaric cystidia by their association with dikaryotic infection stages rather than a persistent . In smuts, telial sori may contain bundles of multicellular sterile hyphae, termed elaters, which permeate the mass and project outward, facilitating spore liberation; these are noted in species like and Tilletia, where they form dirty white strands amid brown . Such variations highlight adaptations in these biotrophic basidiomycetes, where sterile elements support without forming the elaborate cystidia of free-living forms.

Classification

By Position

Cystidia are classified by their position within the fungal sporocarp, particularly in the hymenophore and external surfaces of basidiomycete fruiting bodies such as mushrooms. This positional categorization highlights how cystidia integrate into specific tissues, influencing their structural and ecological roles. The primary distinctions occur in lamellate (gill-bearing) structures, where cystidia arise from the hymenial layer, as well as on the (pileus), stalk (stipe), and . Cheilocystidia are located on the edge or margin of the s (lamellae), often forming a fringe-like arrangement that protects the developing basidia and s. These sterile cells project outward, sometimes secreting droplets that bead along the gill margins, serving an excretory function to maintain hydration or deter herbivores. Cystidia, including cheilocystidia, contribute to spacing basidia apart and preventing overcrowding during spore maturation. Pleurocystidia occur on the faces or surfaces of the gills, protruding among the basidia to integrate into the fertile hymenial layer. They may extend to influence discharge by acting as spacers or air traps that facilitate ballistic ejection. In Strobilurus ohshimae, pleurocystidia help protect basidiospores from predation by collembolans, though they are often less dense than edge cystidia and show variable efficacy. Beyond the hymenophore, cystidia appear on external surfaces for broader protective roles. Pileocystidia are found on the (pileus) surface, contributing to the dermal layer and shielding against environmental stress or . Caulocystidia occupy the stalk (stipe) surface, similarly providing mechanical defense. Dermatocystidia represent a general term for cystidia in the , encompassing pileo- and caulocystidia, which in Russula bella exhibit toxicity to collembolans, reducing damage to the fruiting body. The position of cystidia carries functional implications tied to sporocarp architecture. Those on gill edges, like cheilocystidia, primarily aid maturation by spacing and excreting to optimize conditions, while face-positioned pleurocystidia support efficient discharge through and predation deterrence. Surface cystidia, such as pileo- and caulocystidia, extend protection to the entire sporocarp, maintaining against biotic threats.

By Morphology

Cystidia in basidiomycetes are categorized morphologically by their overall form, wall characteristics, and internal features, providing key identifiers for taxonomic purposes independent of their location within the fruiting body. This classification emphasizes shapes ranging from simple elongated structures to more complex inflated or constricted forms, with dimensions typically spanning 10–150 µm in length. Wall thickness varies from thin (0.5–1 µm) to moderately thick (up to 5 µm), influencing their appearance under , while apices may be acute, rounded, or beaked. Leptocystidia represent one of the most common morphological types, characterized by thin walls (typically 0.5–1 µm thick) and an elongated, smooth profile without visible contents. They are often cylindrical or , with lengths of 30–60 µm and widths of 5–10 µm, projecting prominently and aiding in species differentiation through their simplicity and lack of encrustation or pigmentation. For instance, in genera like , leptocystidia exhibit these traits, appearing and non-refractive under light microscopy. Gloeocystidia, in contrast, feature thin walls (around 0.5–1 µm) but are distinguished by their oily, granular, or resinous contents, which appear highly refractive and often yellowish under light microscopy. These cystidia adopt irregular tubular, sinuous, or vesicular shapes, with sizes varying from 20–80 µm long and 5–15 µm wide, the contents contributing to a gloeoporous texture in the . Representative examples occur in corticioid fungi such as Gloeocystidiellum. Other morphological variants include utriform cystidia, which are urn- or leather bottle-shaped with a central constriction and rounded base, often 20–50 µm long and 10–20 µm wide at the bulge, featuring thin to moderately thick walls (1–3 µm). Vesiculose cystidia display a bladder-like, inflated form, broadly spherical or ovoid with thin walls (<1 µm) and dimensions up to 30–60 µm in diameter, emphasizing overall expansion. Ampulliform cystidia resemble flasks, with a broad basal portion narrowing to a thin, sometimes encrusted neck and beaked apex, measuring 25–70 µm long and 8–15 µm wide, walls 1–4 µm thick; these are evident in fossil records and modern poroid species like Quatsinoporites. Apex variations across types—acute for pointed projections, rounded for blunt ends, or beaked for elongated tips—further refine morphological distinctions, with wall thickness influencing durability and microscopic visibility. Additional morphological types include chrysocystidia, which contain yellowish refractive contents visible under microscopy; metuloids, which are thick-walled pleurocystidia often encrusted with crystals; and skeletocystidia, which are the projecting ends of skeletal hyphae typically found in polypores and crust fungi. These variants enhance taxonomic utility by providing distinct microscopic characters.

Structure

Cellular Morphology

Cystidia are typically large, sterile cells that project erectly or flexuously from the hymenial surface, arising terminally from subhymenial hyphae in basidiomycete fruit bodies. These projections often exhibit a narrowed basal portion embedded within the gill or hymenium, expanding outward to form an elongated body that extends into the inter-gill space or beyond the fertile layer. The overall shape can be subcylindrical, subulate, or fusiform, with the external surface featuring smooth walls or encrustations of crystalline or resinous material, particularly at the apex. The cell walls of cystidia are generally hyaline (transparent) but can range to pigmented in certain taxa, providing optical clarity or subtle coloration under microscopy. These walls are composed primarily of chitin microfibrils intertwined with β-glucans, forming a rigid yet flexible structure typical of basidiomycete hyphal elements. Septation is rare, with most cystidia remaining coenocytic (aseptate) throughout their development, distinguishing them from segmented hyphae. Dimensionally, cystidia vary by species but often display elongated forms with length-to-width ratios around 5:1 to 10:1, typically 20–100 µm long and 5–20 µm wide. The base is commonly clavate or inflated where it connects to the parent hypha, while the apex may taper to a pointed or rounded tip, sometimes encrusted for added protection or identification utility. These morphological features vary by species but consistently emphasize projection and differentiation from surrounding basidia.

Internal Composition

The interior of cystidia typically exhibits a vacuolated or granular cytoplasm, with scattered small to large vacuoles that increase in number and size as the cell matures, often imparting a lobed appearance to the protoplasm. The cytoplasm is typically binucleate or multinucleate. In gloeocystidia, specialized subtypes of cystidia, the cytoplasm frequently contains dense, staining contents that appear oily, resinous, or granular under light microscopy, including refractive yellowish droplets suggestive of lipid accumulations and crystalline or globular inclusions. Chemically, cystidial walls and contents often display reactivity to common mycological stains, such as amyloid reactions where structures turn blue-black upon exposure to iodine-based Melzer's reagent, indicating the presence of chitin or other polysaccharides. Many cystidia are also cyanophilous, staining deep blue with cotton blue in lactic acid, which highlights chitinous walls in basidia, spores, and hyphae including cystidia. Incrustations of crystals, frequently calcium oxalate, are common on the inner or outer walls, particularly in apical regions, and may dissolve or change color in potassium hydroxide (KOH). At the ultrastructural level, transmission electron microscopy (TEM) reveals electron-dense inclusions within cystidia, such as coated vesicles with dense cores near the plasma membrane and exudate containing opaque threads or spherical bodies in a translucent matrix, consistent with storage compounds or secretory products. Abundant smooth tubular endoplasmic reticulum, Golgi apparatus with unstacked cisternae, and multivesicular bodies are distributed throughout the binucleate cytoplasm, supporting roles in lipid or protein synthesis and exocytosis. These features are conserved across species like and S. granulatus, highlighting phylogenetic consistency in cystidial cytology.

Functions

Protective Mechanisms

Cystidia in basidiomycete fruit bodies serve as mechanical barriers that physically deter small herbivores, particularly collembolans such as Ceratophysella denisana and Mitchellania horrida, from accessing and consuming basidia and spores. In species like Russula bella, projecting cystidia significantly increase collembolan mortality, with experiments showing higher death rates on intact cystidia compared to those where cystidia were destroyed (P < 0.05), and median survival times as short as 36 seconds for M. horrida. Field observations revealed that 97% of dead collembolans were found on gill regions rich in cystidia, suggesting these structures entrap or impale grazers, thereby protecting basidiospores. Similarly, in Strobilurus ohshimae, intact cystidia reduce collembolan presence on gills and increase mortality, preventing access to spore-producing tissues. This mechanical defense is crucial, as collembolan grazing damages nearly 100% of ingested basidiospores, rendering them non-viable. Certain cystidia, particularly gloeocystidia, employ chemical deterrence through secretions that discourage grazing by microfauna. In genera like Sphaerobolus, gloeocystidia release amorphous secretions that solidify upon contact, encapsulating and immobilizing mycophagous nematodes, acting as an antifeedant mechanism to safeguard hyphal systems and fruit body surfaces. These secretions halt further feeding and lead to the death of the herbivores, likely from starvation. The study on Sphaerobolus indicates that such defenses protect against fungus-feeding microfauna. Beyond direct defense, cystidia maintain optimal spacing between basidia to facilitate efficient spore discharge and prevent structural crowding in the hymenium. By projecting from the gill surfaces, they separate basidia, ensuring spores are propelled without interference from adjacent structures, which could otherwise cause collisions or adhesion during ballistic ejection. This spacing function is particularly evident during fruit body expansion, where cystidia keep hymenial layers apart, optimizing airflow and reducing the risk of spore fallout onto neighboring tissues. Experimental observations in species like Coprinus cinereus confirm that cystidia accumulate reserves and structurally support this separation, enhancing overall reproductive success.

Taxonomic Utility

Cystidia play a pivotal role in the taxonomic identification of basidiomycete fungi, particularly through the assessment of their presence or absence, along with variations in shape, size, and abundance, which form essential components of dichotomous keys for genera such as Russula and Lactarius. In Russula, for instance, the density of marginal cystidia is quantified into categories ranging from acystidiate (0 cystidia per mm²) to abundant (>3000 per mm²), providing a quantitative metric for distinguishing within subsections like Amoeninae. These features, often examined via light microscopy, enable precise delimitation at the generic and specific levels when integrated with macroscopic traits like ornamentation and preferences. The specificity of cystidia is enhanced when combined with their positional characteristics and internal contents, allowing for fine-scale species-level distinctions; for example, in Lactarius, the presence of pleurocystidia with refractive contents, alongside their fusiform or cylindrical morphology (typically 40–80 µm long), differentiates subsections within subgenus Russularia from closely related taxa. Similarly, utriform pleurocystidia, characterized by their bottle-shaped apex, are diagnostic for certain sections of Amanita, such as section Phalloideae, where they project from the gill surfaces and aid in separating lethal species like A. phalloides from morphologically similar allies. This multifaceted analysis underscores cystidia's utility in resolving cryptic diversity, particularly in ectomycorrhizal genera where spore prints alone are insufficient. Historically, cystidial morphology has been integral to 20th-century fungal monographs, as exemplified in Rolf Singer's comprehensive treatments of the Agaricales, where detailed descriptions of cystidial types—such as lageniform, fusoid, or capitate—served as cornerstone characters for ordinal and familial classifications. In modern taxonomy, while molecular phylogenetics, including multi-gene analyses of ITS and LSU regions, has refined higher-level relationships, cystidia remain indispensable for microscopy-based identifications and integrative approaches, ensuring morphological data complements DNA sequences in revising genera like Russula and Lactarius. This enduring relevance highlights their role in bridging classical and contemporary systematics, particularly for field mycologists relying on portable microscopes.

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