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Cortinarius

Cortinarius is a of gilled mushrooms commonly known as webcaps, in the family Cortinariaceae (, ), recognized as one of the largest and most species-rich genera of fungi, with over 3,000 described species and estimates suggesting up to 5,000 or more worldwide. These mushrooms are characterized by their rusty brown , ornamented spores, and a distinctive cobweb-like (cortina) that connects the cap margin to the stem in young specimens, often leaving remnants as a ring zone on the mature stipe. Ecologically, species of Cortinarius are predominantly ectomycorrhizal, forming symbiotic associations with a wide range of vascular plants, including trees like , , and , which contributes to their global distribution from tropical to and regions. They typically grow terrestrially in forests and woodlands, with many species exhibiting specialized host preferences or limited ecological niches, such as montane or coastal ecosystems. Morphologically diverse, caps range from dry and silky to slimy or hygrophanous, and stems may feature universal veils in some subgenera, though identification remains challenging due to subtle differences and ongoing taxonomic revisions informed by . Notably, while many Cortinarius species are inedible or bitter, certain ones contain potent toxins like orellanine, a nephrotoxin that causes delayed kidney failure in humans and animals, with symptoms appearing days to weeks after ingestion; examples include the deadly Cortinarius orellanus and Cortinarius speciosissimus. This toxicity underscores the genus's importance in mycology, as it highlights risks in mushroom foraging and drives research into chemical defenses and phylogenetics to better delineate safe from hazardous species.

Taxonomy

Etymology

The genus name Cortinarius is derived from the Latin word cortina, meaning "" or "", in reference to the that enshrouds the gills of immature fruiting bodies. This protective structure, known as the cortina, often appears as a web-like connecting the margin to the stipe. Common names for species in this , such as "webcap" or "cortinar", stem from the fibrous, veil-like remnants that persist on mature specimens. The genus was formally established by Swedish mycologist Elias Magnus Fries in 1838, when he elevated it from subgenus status under in his seminal work Epicrisis Systematis Mycologici.

Phylogenetic history

The genus Cortinarius was first formally established by the Swedish mycologist Elias Magnus Fries in his seminal work Epicrisis Systematis Mycologici (1836–1838), where it was defined primarily on morphological traits such as the presence of a cortina—a silky, web-like —and the production of rusty-brown . This classification built on earlier observations by Persoon (1801) but emphasized Fries's system of tribes within the , placing Cortinarius as a core element of the series Cortinariae based on macroscopic and microscopic features like pileus structure and spore ornamentation. Fries's morphological approach dominated for over a century, leading to the description of numerous species but also highlighting the genus's complexity due to its high diversity and variability. The advent of in the early 2000s revolutionized the understanding of Cortinarius, revealing that several previously segregated genera were phylogenetically nested within it, prompting their synonymization. Studies employing DNA sequences from the (ITS) and large subunit (LSU) ribosomal RNA regions demonstrated the of genera like Rozites, Dermocybe, and Thaxterogaster. For instance, Peintner et al. (2002) analyzed ITS data from sequestrate and gilled taxa, concluding that Thaxterogaster—a secotioid group distinguished by its enclosed basidiomata—formed a monophyletic within Cortinarius, leading to new combinations and the sinking of the genus. Similarly, the same study extended this to Rozites, whose membranous (e.g., in R. caperata) was shown to be a convergent trait, justifying its inclusion in Cortinarius Telamonia. Dermocybe, recognized for its pigments and bright colors, was also integrated as a section or subgenus within Cortinarius based on evidence that its lineage was deeply embedded in the core . Key multigene analyses further solidified the of Cortinarius sensu lato. Peintner et al. (2004) integrated ITS and partial LSU sequences from over 100 specimens across global collections, confirming the genus's and outlining major infrageneric clades while supporting the synonymies of the aforementioned genera; their tree topologies showed low divergence among core lineages but clear nesting of segregates. Building on this, Garnica et al. (2005) combined morphological data with molecular markers (ITS, LSU, and partial RPB1) from 200+ and North American taxa, providing a comprehensive framework for supraspecific that reinforced the expanded circumscription of Cortinarius and identified 15 major clades, emphasizing ectomycorrhizal associations as a unifying ecological . These studies shifted the estimated count to over 2,000 worldwide, highlighting the need for integrative . As of 2022 reviews, Cortinarius remains placed in the family Cortinariaceae (Agaricales, Agaricomycetes, Basidiomycota), a monophyletic group characterized by corticate hymenia and primarily ectomycorrhizal lifestyles. While Liimatainen et al. (2022) proposed a major revision based on genomic data (including whole-genome phylogenies and 15+ loci), splitting Cortinarius into ten genera—including reinstating Thaxterogaster and Dermocybe—this has not gained universal acceptance due to ongoing debates over resolution and sampling. Recent critiques argue for retaining the broad genus pending denser sampling and standardized barcoding, maintaining the post-2000s consensus on its monophyly.

Selected species

The genus Cortinarius is one of the most diverse in the fungal kingdom, comprising over 3,000 described worldwide. Many exhibit striking colors and forms that aid in their recognition by mycologists, though identification requires careful examination due to subtle morphological variations. These fungi are ecologically significant as primary mycorrhizal associates in forest ecosystems. One notable species is Cortinarius violaceus, known for its striking violet-capped fruiting bodies covered in fibrous scales, which form mycorrhizal associations primarily with beech (Fagus) trees in temperate woodlands. Cortinarius rubellus, commonly called the fool's webcap, features a bright reddish-brown cap and stem, often growing in coniferous or mixed forests. The deadly webcap () is characterized by its ochre-brown, silky cap. In contrast, , the gypsy mushroom, is distinguished by its wrinkled, tan to ochre cap and common occurrence in deciduous forests, where it forms mycorrhizae with oaks and other hardwoods.

Description

Macroscopic features

The fruitbodies of Cortinarius species are agaricoid mushrooms characterized by a central stipe supporting a pileus with lamellae, typically exhibiting a rusty brown that distinguishes the . The pileus () measures 3–15 cm in diameter, starting convex and expanding to plano-convex or nearly flat with age; its surface is often hygrophanous, showing color changes as it dries, and ranges in color from various shades of brown, yellow, , or . The cap texture varies widely, being dry and silky-fibrillose in some species or viscid and gelatinous in others, particularly in subgenera like Myxacium. The lamellae (gills) are adnate to adnexate, close to moderately spaced, and initially concealed by the cortina; they mature to a hue from deposition, with edges often paler or concolorous. The stipe () is 5–20 cm long and 0.5–3 cm thick, usually cylindrical but sometimes clavate or with a bulbous base; it is often fibrillose or scaly from remnants of the cortina, forming a zonate or annular region, and matches or contrasts with the cap color. The defining macroscopic feature is the cortina, a that is membranous to web-like, connecting the pileus margin to the stipe apex in young specimens and leaving rusty stains from falling spores as it ruptures. Cortinarius species grow terrestrially, often solitary to gregarious in forested habitats.

Microscopic features

The microscopic features of Cortinarius species are essential for precise , particularly in distinguishing subgenera and resolving cryptic taxa, as macroscopic traits can overlap significantly. Spores are typically rusty-brown in mass, forming a diagnostic of rusty to cinnamon-brown, which arises from the pigmentation of the walls and is a key generic character. Their shape ranges from to subglobose or broadly ovoid, with dimensions commonly 7–12 µm in length and 5–8 µm in width, though variation occurs across species (e.g., 6.1–7.5 × 4.9–5.9 µm in C. griseoaurantinus). Ornamentation is usually present, featuring verrucose walls with isolated nodules, , or short lines up to 1.5 µm tall, though some are nearly smooth; this reaction (blue in Melzer's reagent) aids in confirmation. Basidia are consistently 4-spored, clavate to cylindrical, and measure 25–40 µm in length by 7–10 µm in width, with thin walls and to subhyaline contents; sterigmata are typically 2–4 µm long. Clamp connections are present at basal , a standard trait in the . Cystidia vary by subgenus and : pleurocystidia are often absent, as in C. yonganensis and many sequestrate forms, but cheilocystidia may occur as ventricose to lageniform structures, 50–100 µm long, sometimes brown in KOH. Exceptions like C. violaceus feature prominent facial and marginal cystidia. Pigments are predominantly intracellular, contributing to color and sometimes under UV light; in subgenus Dermocybe, anthraquinones such as austrovenetin and xanthorin produce bright to hues in hyphae, with photochemical properties linked to . These pigments dissolve in KOH to yield cinnamon-brown solutions in most species.

Habitat and

Global distribution

The genus Cortinarius exhibits a , occurring on all continents except , spanning from arctic-alpine zones to subtropical highlands in both hemispheres. Its highest species diversity is concentrated in the temperate regions of the , where ecological conditions favor the proliferation of ectomycorrhizal associations in forested environments. In , over 1,000 species of Cortinarius have been described, rendering it a hotspot for the genus, with abundant occurrences in diverse forest types across the continent. hosts significant diversity as well, estimated at around 500 species, particularly in the , where the genus thrives in coniferous and mixed woodlands. In contrast, the supports fewer species overall, though endemic clades are notable in , including sequestrate forms adapted to native ecosystems, and in South America's Andean regions, where at least 250 species have been recorded in forested areas. The distribution of Cortinarius is strongly influenced by temperate climatic conditions, with the genus largely absent from lowland tropical regions but present in highland and subtropical areas where cooler temperatures prevail. A 2024 study indicates that is causing mismatches in ectomycorrhizal partnerships, as host trees shift ranges faster than fungi like Cortinarius, potentially limiting fungal distributions.

Symbiotic associations

Cortinarius species are predominantly ectomycorrhizal fungi, forming mutualistic associations with the roots of various trees, where they create a fungal sheath (Hartig net) around short roots to facilitate nutrient exchange. These fungi commonly partner with conifers such as Pinus species and Picea abies, as well as broadleaf trees including Quercus, Betula, and Fagus, enhancing the hosts' access to soil resources in forest ecosystems. In return, the trees supply the fungi with carbohydrates derived from photosynthesis, primarily in the form of simple sugars, which support fungal growth and hyphal expansion. The diversity of these associations varies by ; for instance, species in subgenus Phlegmacium often form ectomycorrhizae specifically with like Picea, though some also associate with Betula in environments. Cortinarius fungi provide essential nutrients to their hosts, particularly and , by mobilizing these elements from through enzymatic activity (e.g., phosphatases and peroxidases) and extending the root system's reach via extraradical hyphae. This exchange is crucial in nutrient-poor soils, where the fungi degrade complex organic compounds to release bioavailable forms. Ecologically, Cortinarius plays a pivotal role in forest nutrient cycling by promoting the turnover of and influencing dynamics, often acting as indicators of undisturbed, healthy conditions due to their to environmental perturbations. Their presence and diversity signal robust ectomycorrhizal networks that support overall biodiversity and productivity.

Toxicity

Primary toxins

The primary toxins in certain Cortinarius species are bipyridyl compounds, notably orellanine and its related derivative orelline, which are responsible for the characteristic observed in poisonings. Orellanine (C₁₀H₈N₂O₆) is a tetrahydroxybipyridine N-oxide, first isolated from C. orellanus in 1962, while orelline is a monodeoxo derivative formed through photochemical degradation or of orellanine above 267°C. These toxins exhibit up to 150–160°C but are sensitive to UV light, with orelline displaying turquoise under UV excitation at 400 nm ( at 450 nm) due to keto–enol tautomerism, aiding in their identification. Concentrations vary significantly, with orellanine levels reaching up to 14 mg/g dry weight in C. orellanus caps and 9 mg/g in C. speciosissimus. The nephrotoxic mechanism of orellanine involves the generation of (ROS) through mono-electronic reduction, leading to , depletion of renal , and hypoxic conditions in proximal tubular cells. It inhibits activity, disrupting protein, RNA, and DNA synthesis, and non-competitively inhibits , culminating in tubular and acute renal failure with a delayed onset of 2–20 days post-ingestion. Orelline, in contrast, is generally nontoxic and lacks significant nephrotoxic effects. The LD₅₀ for orellanine in mice is 12.5 mg/kg (intraperitoneal) and 90 mg/kg (oral), with lethal doses estimated at 100–200 g of fresh mushrooms. Detection of orellanine relies on methods such as (TLC), which produces characteristic navy blue spots for orellanine and light blue for orelline, or (HPLC) with UV or electrochemical detectors for quantification in tissues and biological fluids. A simple ferric chloride color test yields a dark gray-blue reaction specific to orellanine. is not uniform across the ; only select like C. orellanus, C. rubellus, C. speciosissimus, and C. rainierensis produce significant orellanine levels (up to 9400 mg/kg in caps), while many others are nontoxic. Toxin production is environmentally dependent, influenced by factors such as geographic region (higher in vs. North American populations), developmental stage (higher in caps than stipes or spores), and inter-/intraspecific variations, with concentrations as low as 900 mg/kg in spores of C. rubellus.

Toxic species and symptoms

Among the most notorious toxic species in the genus Cortinarius are C. orellanus (deadly webcap) and C. rubellus (fool's webcap), both of which contain the nephrotoxin orellanine and can cause severe, delayed-onset acute renal failure in humans. Ingestion of these mushrooms leads to orellanine-induced kidney damage, with a fatality rate of 10-30% in untreated cases requiring or transplantation. Symptoms typically emerge 2-17 days post-ingestion (average 8 days), beginning with gastrointestinal effects such as intense , , and , followed by renal manifestations including flank pain, or , , and due to . Liver involvement is rare, with normal hepatic enzyme levels observed in affected patients. Cortinarius poisonings have also been documented in animals, particularly livestock like sheep, where C. speciosissimus (a synonym for C. rubellus) causes similar renal failure, with clinical signs including , reduced urine output, and elevated serum creatinine. Misidentification poses significant risks, as toxic Cortinarius species are sometimes confused with mushrooms due to similarities in appearance and habitat. Globally, approximately 100 human cases of orellanine poisoning have been reported since the 1950s, predominantly in , highlighted by a 1952 outbreak in involving 102 victims of C. orellanus with 11 fatalities.

Uses

Edibility

While the genus Cortinarius contains many toxic , a few are considered and are foraged in select regions. Cortinarius praestans, known as the goliath webcap, is regarded as a choice with a meaty texture and nutty flavor similar to certain species, particularly valued in Central European markets like those in and . Cortinarius caperatus, the gypsy mushroom, is another highly prized with a mild, pleasant taste that pairs well with stronger-flavored fungi; it is the only Cortinarius species commonly collected for culinary use. Preparation of edible Cortinarius species requires thorough cooking to break down potential irritants and improve digestibility; consumption raw is not recommended, as it may cause gastrointestinal upset. Common methods include in or , breading and , or incorporating into stews, with the gypsy mushroom often sliced and cooked for 15-20 minutes to ensure tenderness. Due to the genus's complexity, and preparation are not advised for novices without expert guidance. Nutritionally, Cortinarius species offer high protein content, averaging around 19% on a dry weight basis, making them a valuable plant-based protein source, though they are low in calories (typically 20-40 kcal per 100g fresh weight) and fat (<1g per 100g). They also provide carbohydrates (about 49% dry weight) and essential minerals, contributing to their role in regional diets. In European cuisines, such as Italian and Finnish, these mushrooms feature in traditional dishes like risottos or forest soups, where they add earthy depth alongside staples like porcini. Foraging Cortinarius edibles carries significant risks, as many toxic lookalikes, such as deadly webcaps containing orellanine, share similar habitats and features like rusty-brown spores and web-like veils; accurate identification by experts is essential to avoid severe damage. These are commonly foraged in , particularly in northern and central woodlands, but remain rare in the , limiting their cultural significance there.

Non-culinary applications

Species of the genus Cortinarius have been utilized in non-culinary contexts, primarily for their pigment-producing capabilities and potential bioactive compounds. One prominent application is in natural , where certain species yield vibrant colors for s. For instance, Cortinarius sanguineus produces blood-red pigments derived from anthraquinones, which have been extracted for dyeing wool and other fibers, offering shades ranging from yellow to deep red depending on mordants and processing methods. These pigments are noted for their light fastness and brightness in red, blue, and green hues, making them valuable in traditional practices. In the , European dyers documented recipes using Cortinarius species, such as boiling the fruiting bodies in water with mordants like or iron to achieve durable reds and oranges on , reflecting early interest in fungal sources for colorants before synthetic dyes dominated. Beyond dyeing, some Cortinarius species show promise in medicinal research due to their bioactive metabolites. For example, contains compounds like cortinarin A and , which exhibit and properties in preliminary studies, potentially aiding in reducing inflammation and . from related species, such as Cortinarius purpurascens, have also demonstrated antioxidant effects that may support cardiovascular health, though human applications remain unexplored. Additionally, Cortinarius mushrooms serve as bioindicators for environmental monitoring, particularly for heavy metal contamination in soils. Species like Cortinarius caperatus and others in the genus accumulate metals such as mercury, cadmium, lead, and copper in their fruiting bodies at levels far exceeding those in surrounding substrates, enabling assessment of pollution in forest ecosystems. This bioaccumulation trait highlights their role in ecotoxicology, though it raises concerns about their suitability for any harvest. Despite these applications, research on Cortinarius remains preliminary, with few clinical trials validating medicinal claims and ongoing concerns about sustainability. Overharvesting for dyes or indicators could deplete populations in mycorrhizal habitats, as fruiting bodies represent only a fraction of the underground mycelium network essential for forest health. Further studies are needed to balance utilization with conservation, emphasizing ethical sourcing and cultivation alternatives.

Infrageneric classification

Subgenera overview

The genus Cortinarius is traditionally classified into approximately 10 subgenera, a number that remains fluid due to ongoing phylogenetic revisions integrating with . These subgenera are delineated primarily by characteristics such as type (often a cortina or fibrillose remnants), ornamentation (ranging from finely verrucose to coarsely roughened), and preferences, including mycorrhizal associations with specific trees in temperate to ecosystems. Subgenus Cortinarius exemplifies the genus's namesake feature with a classic web-like cortina that leaves fibrillose zones on the stipe, paired with rusty-brown spores exhibiting moderate verrucose ornamentation; species typically inhabit temperate forests, forming ectomycorrhizae with deciduous and coniferous trees. Subgenus Dermocybe stands out for its vivid yellow, orange, or red hues imparted by pigments, a dry to felty pileus and stipe with duplex pileipellis, and finely verrucose spores; many taxa preferentially associate with in northern temperate zones, though distributions span both hemispheres. Subgenus Myxacium is defined by viscid to glutinous caps (and often stipites) that yield a slimy , large amygdaloid or citriform spores greater than 10 μm with coarse ornamentation, and terrestrial occurrences in diverse ectomycorrhizal partnerships across forests of varying compositions.

Key phylogenetic clades

Molecular phylogenetic studies using multigene datasets, including the nuclear ribosomal (nrITS), largest subunit (RPB1), and second largest subunit (RPB2), have revealed significant within traditional infrageneric classifications of Cortinarius, such as older , prompting a reevaluation of major evolutionary lineages. These analyses from the , involving hundreds of , demonstrated that morphological groupings like subgenera Telamonia and Phlegmacium are not monophyletic, with species distributed across multiple clades supported by bootstrap values often exceeding 90%. One prominent , corresponding to subgenus Telamonia, comprises slender basidiomata with dry pilei and stipes, exhibiting diverse ectomycorrhizal associations with broadleaf and coniferous trees. This includes numerous European species, such as C. trivialis and C. flexipes, and is strongly supported (bootstrap 97–100%) in multi-locus phylogenies. It represents the most species-rich lineage within Cortinarius stricto, with broad morphological variation but consistent dry adaptations. A second major aligns with subgenus Phlegmacium, featuring robust, viscid to glutinous pilei and a preference for ectomycorrhizal with , particularly in northern temperate forests. This group shows high diversity in production, including orellanine derivatives in species like C. rubellus, and receives robust support (bootstrap 88–100%) from nrITS, RPB1, and RPB2 data. Recent proposals have elevated Phlegmacium to , though this remains debated due to unresolved backbone relationships. A 2024 analysis contested this split, recommending that Cortinarius remain a single pending further resolution of phylogenetic conflicts. The third key clade corresponds to subgenus Leprocybe, characterized by scaly or tomentose pilei and a distribution skewed toward southern temperate and subtropical regions, often associating with Nothofagus or eucalypts. Species in this clade, such as C. leprosus, display greenish or yellowish hues and are supported (bootstrap 93–97%) in phylogenomic analyses incorporating additional loci like MCM7 and TEF1. A 2022 taxonomic revision integrated thousands of species (over 3,000 described) into these and related clades using expanded multi-gene datasets (up to 80 loci), refining boundaries and proposing new combinations while highlighting ongoing phylogenetic uncertainties in Cortinarius s.l.

References

  1. [1]
    The genus Cortinarius should not (yet) be split | IMA Fungus
    Aug 13, 2024 · The genus Cortinarius (Agaricales, Basidiomycota) is one of the most species-rich fungal genera, with thousands of species reported.
  2. [2]
    The Genus Cortinarius (MushroomExpert.Com)
    Cortinarius is the largest mushroom genus, with young cortina, rusty brown spore print, and rusty brown mature gills. They are terrestrial and mycorrhizal.
  3. [3]
    Cortinarius - an overview | ScienceDirect Topics
    Cortinarius is a mushroom genus with 2000-3000 species, some containing orellanine, a nephrotoxin. They are hard to identify and have a cobwebby veil.
  4. [4]
    Cortinarius decipiens, Sepia Webcap mushroom - First Nature
    Etymology. The generic name Cortinarius is a reference to the partial veil or cortina (meaning a curtain) that covers the gills when caps are immature. In ...
  5. [5]
    Webcaps (Genus Cortinarius) - iNaturalist
    A common feature among all species in the genus Cortinarius is that young specimens have a cortina (veil) between the cap and the stem, hence the name, meaning ...
  6. [6]
    The genus Cortinarius should not (yet) be split - PMC - NIH
    Aug 13, 2024 · Fries (1838) subdivided Cortinarius, in which he placed 216 species encompassing six subgroups. ... Fries EM (1838) Epicrisis systematis ...
  7. [7]
    A framework for a phylogenetic classification in the genus ...
    Since Fries (1836–1838) introduced the genus Cortinarius, numerous mycologists have contributed to its systematics, describing new species or elaborating ...
  8. [8]
    Thaxterogaster is a taxonomic synonym of Cortinarius - ResearchGate
    Aug 6, 2025 · A good example is the secotioid genus Thaxterogaster, subsumed under Cortinarius (Peintner et al. 2002) . The sequestrate Arcangeliella and ...
  9. [9]
    Taming the beast: a revised classification of Cortinariaceae based ...
    Feb 23, 2022 · Family Cortinariaceae currently includes only one genus, Cortinarius, which is the largest Agaricales genus, with thousands of species ...
  10. [10]
    Enlargement of the knowledge of Cortinarius section Anomali ...
    Jun 11, 2023 · Cortinarius is a globally distributed agaricoid genus that has been well-studied in Europe and America with over 1000 described species.
  11. [11]
    Cortinarius violaceus, Violet Webcap mushroom - First Nature
    Odour/taste. The cut flesh of Cortinarius violaceus smells slightly of cedarwood; it has no significant taste.Missing: non- | Show results with:non-
  12. [12]
    Cortinarius violaceus (MushroomExpert.Com)
    Cortinarius violaceus is a deep purple mushroom with a dry, scaly cap, hairy stem, and unique cystidia on gills. It has a sweet odor and a rusty brown spore ...Missing: beech | Show results with:beech
  13. [13]
    https://www.first-nature.com/fungi/cortinarius-rubellus.php
  14. [14]
    The Deadly Webcaps: Comprehensive Identification Guide
    Jul 12, 2024 · All the species within this group are highly toxic. They cause irreversible kidney failure that may lead to death.
  15. [15]
    Cortinarius rubellus, Deadly Webcap mushroom - First Nature
    Not surprisingly, the specific epithet rubellus simply means reddish, in the same sense that a red fox is actually reddish brown.Missing: bright | Show results with:bright
  16. [16]
    https://www.first-nature.com/fungi/cortinarius-caperatus.php
  17. [17]
    North American Cortinarius Mushrooms: Identification, Habitat, and ...
    Oct 15, 2024 · The Cortinarius family, commonly known as webcaps, is a big family of mushrooms with some very dangerous members, like the deadly webcap.
  18. [18]
    Cortinarius caperatus (MushroomExpert.Com)
    Cap: 4–12 cm across; convex, becoming broadly convex, somewhat bell-shaped, or nearly flat; dry; often wrinkled; when young with a grayish to whitish, Kleenex- ...
  19. [19]
    Cortinarius caperatus, Gypsy Mushroom - First Nature
    A prized edible in countries where it occurs in numbers, The Gypsy is not gregarious. In Britain it is very rare and usually appears only in very small ...Missing: Europe | Show results with:Europe<|control11|><|separator|>
  20. [20]
    Cortinarius section Bicolores and section Saturnini (Basidiomycota ...
    Obtusi, Balaustini, Illumini – form a strongly supported monophyletic clade in all published molecular studies (Peintner et al. 2004, Stensrud et al. 2014) ...
  21. [21]
    https://www.fs.usda.gov/pnw/pubs/gtr572/partb3.pdf
  22. [22]
    https://www.mdpi.com/1424-2818/15/4/553
  23. [23]
    [PDF] Cortinarius barlowensis Ammirati and Moser sp. nov., ined.
    BASIDIA 33-41 x 7-8.9 µm, more or less clavate, hyaline or pale yellow, 4 spored. CYSTIDIA absent. CLAMP CONNECTIONS present. SPORES ellipsoid to broadly ...Missing: microscopic | Show results with:microscopic
  24. [24]
    DNA Barcoding Data Reveal Important Overlooked Diversity of ...
    New infrageneric classifications of Cortinarius based on multigene phylogenetic analyses were proposed by Garnica et al. [74] and Soop et al. [75]. Recently, ...
  25. [25]
    Morphological and molecular phylogenetic studies in South ...
    Aug 6, 2025 · The genus Cortinarius is inferred to be originally associated with angiosperms with a probable origin in late Cretaceous (Ryberg & Matheny 2011) ...Missing: sinking | Show results with:sinking
  26. [26]
    Eight new species of sequestrate Cortinarius from sub-alpine ...
    Microscopic characters such as spore shape, size, and ornamentation, and pileipellis structure (simplex vs duplex and size of hyphal elements) are essential for ...
  27. [27]
    Three new species of Cortinarius section Delibuti (Cortinariaceae ...
    Jan 17, 2024 · Peintner U, Moncalvo JM, Vilgalys R (2004) Toward a better understanding of the infrageneric relationships in Cortinarius (Agaricales ...
  28. [28]
    Climate change is moving tree populations away from the soil fungi ...
    May 27, 2024 · A study published in PNAS shows that trees, especially those in the far north, may be relocating to soils that don't have the fungal life to support them.
  29. [29]
    Ectomycorrhizal Fungi: Participation in Nutrient Turnover and ... - MDPI
    Ectomycorrhizal fungi (EcMF) are involved in soil nutrient cycling in forest ecosystems. These fungi can promote the uptake of nutrients (e.g., nitrogen (N) ...
  30. [30]
    Revised taxon definition in European Cortinarius subgenus ...
    Apr 5, 2024 · The phylogenetic analysis revealed that the diversity of dermocyboid Cortinarius spp. is generally very high with 32 European species intermixed ...
  31. [31]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC8148173/
  32. [32]
    Ectomycorrhizal Cortinarius species participate in enzymatic ...
    Apr 14, 2014 · As root-associated symbionts, ectomycorrhizal fungi play a central role in nutrient cycling, by linking the vegetation and the soil environment.
  33. [33]
    (PDF) Fleshy fungi forays in the vicinities of the YSU Mukhrino Field ...
    Aug 10, 2025 · Parasitic or Saprotrophic on deciduous trees (Betula, Populus, Ulmus) ... moss litter. Saprotrophic, on rich soil and rotten wood in deciduous.
  34. [34]
    Loose Ends in the Cortinarius Phylogeny - NIH
    May 5, 2021 · Our aim is to unravel the taxonomy of selected Cortinarius belonging to phlegmacioid and myxotelamonioid species based on morphological and molecular data.Missing: sinking | Show results with:sinking
  35. [35]
    Selecting fungal disturbance indicators to compare forest soil profile ...
    Ectomycorrhizal genera (e.g. Amphinema, Cortinarius, Piloderma, Russula) strongly indicate undisturbed soils. •. LEfSe comparison of stockpiled to immediately ...
  36. [36]
    Long-term clinical outcome for patients poisoned by the fungal ... - NIH
    Apr 3, 2017 · Accidental intake of mushrooms of the Cortinarius species (deadly webcap) may cause irreversible renal damage and the need for dialysis or ...Missing: ochre- brown delayed
  37. [37]
    Human and experimental toxicology of orellanine - PubMed
    The nephrotoxicity of Cortinarius orellanus is well known and was first recognized in the 1950s when this mushroom was identified as the cause of a mass ...
  38. [38]
    Mushroom Toxicity - StatPearls - NCBI Bookshelf - NIH
    Aug 7, 2023 · Mushroom poisonings may range from benign symptoms of generalized gastrointestinal upset to potentially devastating manifestations.
  39. [39]
    Mushroom Toxicity: Practice Essentials, Pathophysiology, Etiology
    Apr 26, 2023 · Cortinarius species that may contain small amounts of orellanine include Cortinarius gentilis, Cortinarius rainierensis, and Cortinarius ...<|control11|><|separator|>
  40. [40]
    Poisoning in sheep induced by the mushroom Cortinarius ... - PubMed
    Poisoning in sheep induced by the mushroom Cortinarius speciosissimus. Acta Vet Scand. 1979;20(1):148-50. doi: 10.1186/BF03546638.
  41. [41]
    Don't Pick Poison: When Gathering Mushrooms for Food in Michigan
    Nov 10, 2015 · Symptoms: Cortinarius poisoning is characterized by an extremely long delay. A minimum of three days, or as long as 10 days to three weeks, may ...Missing: orellanine | Show results with:orellanine
  42. [42]
    Cortinarius praestans, Goliath Webcap mushroom - First Nature
    This beautiful mushroom is a rare find in Britain but more common in some parts of mainland Europe, where 'the brave' consider it to be a good edible mushroom.
  43. [43]
    Cortinarius praestans - Ultimate-Mushroom.com
    This edible mushroom is found in Europe and it usually appears in small groups or singly, in broadleaf and conifer woodland on alkaline soil. The difficulty of ...
  44. [44]
    Cortinarius caperatus - California Fungi - MykoWeb
    It was once accepted in the segregate genus Rozites because of a membranous annulus rather than a cobwebby cortina seen in other Cortinarius species, but ...Missing: sunk | Show results with:sunk
  45. [45]
    Radiocaesium in Cortinarius spp. mushrooms in the regions of ... - NIH
    Sep 6, 2016 · The greatest activity concentrations of 137Cs in mushrooms of the genus Cortinarius collected both in the Reggio Emilia in Italy and in the ...
  46. [46]
    Fried gypsy mushrooms - Toidublogi
    Aug 9, 2020 · One good way to eat these mushrooms is to bread them in flour and egg and fry in a pan in plenty of oil, sprinkle with herbs and cook hot or cold with various ...
  47. [47]
    [PDF] PROXIMATE ANALYSIS AND CHEMICAL COMPOSITION OF ...
    Cortinarius mushrooms have 19.47% crude protein, 48.60% carbohydrates, 6.80% crude fiber, 14.23% moisture, 5.23% ash, 7.63% fat, and contain alkaloids, ...
  48. [48]
    Effects of trophism on nutritional and nutraceutical potential of wild ...
    Cortinarius praestans revealed the highest total sugars content (61 g/100 g dw), with the highest levels of trehalose (60 g/100 g dw). Mushrooms have been ...<|separator|>
  49. [49]
    Cortinarius caperatus - The Global Fungal Red List Initiative
    Cortinarius caperatus is a widespread, edible, ectomycorrhizal webcap in northern Europe and North America but also less frequently distributed throughout the ...Missing: foraging | Show results with:foraging
  50. [50]
    Waterless Dyeing and In Vitro Toxicological Properties of ... - NIH
    Oct 26, 2022 · An example of an anthraquinone producer is bloodred webcap (Cortinarius sanguineus), a common fungus found in the coniferous forests of North ...
  51. [51]
    In Vitro Toxicity Assessment of Cortinarius sanguineus ... - MDPI
    May 21, 2024 · Anthraquinones are the second-largest group of synthetic dyes after azo dyes [1]. In history, red-producing anthraquinone dyes were obtained ...
  52. [52]
    Chemical profiling and characterisation of anthraquinone‐based ...
    Jan 22, 2025 · Anthraquinone dyes are known for their significant colour (brightness of shade in the red, blue and green areas) and light fastness ...
  53. [53]
    Yellow dye from the bloodred webcap fungus may be harmful to ...
    Jan 14, 2025 · The bloodred webcap (Cortinarius sanguineus) is a traditional textile-dyeing mushroom that produces up to 15 different anthraquinone dyes. " ...
  54. [54]
    Nature's Own Pharmacy: Mushroom-Based Chemical Scaffolds and ...
    It has also shown potential anti-inflammatory properties [91,92]. Violaceol-I and Violaceol-II are bioactive compounds that have been found to inhibit the ...
  55. [55]
    Novel polysaccharide identified from Cortinarius purpurascens ...
    The paper then explores the diverse mechanisms by which polysaccharides exert their effects in CVD, including their antioxidant activity, protection against ...
  56. [56]
    Concentrations of mercury, cadmium, lead and copper in fruiting ...
    Fruiting bodies of many mushroom species accumulate considerable levels of mercury, cadmium, lead, and copper. The element concentrations are primarily species ...
  57. [57]
    Bioaccumulation and Translocation Factors of Some Wild Growing ...
    Cultivated Agaricus bisporus possess the ability to bioaccumulate seven heavy metals (Pb, Cd, Hg, Fe, Cu, Mn, and Zn). The cultivated champignon mushroom A.
  58. [58]
    Understanding cultural significance, the edible mushrooms case
    For mushrooms, other cultural domains to include in a compound index could be the parts used, its medicinal role, its religious or ritual use and several ...
  59. [59]
    [PDF] Biology, Ecology, and Social Aspects of Wild Edible Mushrooms in ...
    Concerns center around destruction of forest habitat by repeated entry and harvest, gradual loss of the mushroom resource by potential overharvest, conflict ...
  60. [60]
    Multiple origins of sequestrate fungi related to Cortinarius ...
    Dec 1, 2001 · The monophyletic Dermocybe clade nests within the Cortinarius clade, which consists of a well-supported core clade including most of the known ...Missing: sunk | Show results with:sunk
  61. [61]
    [PDF] Cortinarius Ny.indd - MykoWeb
    Pinus, Quercus, Abies alba and Betula or mixed Fagus forests, mycorrhizal associate unknown, on calcareous soil; summer to autumn; very rare in temp.-hemib ...Missing: partners | Show results with:partners
  62. [62]
    Revised taxon definition in European Cortinarius subgenus ...
    Apr 5, 2024 · Dermocybe (Fr.) Trog includes brightly coloured Cortinarii with anthraquinone pigments. The chemotaxonomic approach has always been as important ...Missing: sunk | Show results with:sunk
  63. [63]
    Cortinarius - Alpental
    Dermocybe - The red, orange, yellow or olive-yellow gills have a special aura of brightness about them when young, and they have a stature or "look" about them ...
  64. [64]
    A phylogenetic approach to a global supraspecific taxonomy of ...
    Cortinarius is the most diverse and species-rich genus of macrofungi (cf. Niskanen et al. 2016). Historically, several systems of subgenera, sections, and other ...
  65. [65]
    https://doi.org/10.3767/persoonia.2019.42.10
  66. [66]
    https://doi.org/10.1007/s13225-022-00499-9