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Imleria badia

August 29, 2023

Imleria badia
I. badia under beech and oak
Scientific classification
Domain: Eukaryota
Kingdom: Fungi
Division: Basidiomycota
Class: Agaricomycetes
Order: Boletales
Family: Boletaceae
Genus: Imleria
Species:
I. badia
Binomial name
Imleria badia
(Fr.) Vizzini (2014)
Synonyms[1]
  • Boletus castaneus ß badius Fr. (1818)
  • Boletus castaneus var. badius (Fr.) Fr. (1828)
  • Boletus badius (Fr.) Fr. (1832)
  • Rostkovites badia (Fr.) P.Karst. (1881)
  • Viscipellis badia (Fr.) Quél. (1886)
  • Ixocomus badius (Fr.) Quél. (1888)
  • Suillus badius (Fr.) Kuntze (1898)
  • Xerocomus badius (Fr.) E.-J.Gilbert (1931)
Imleria badia
Pores on hymenium
Cap is convex
Hymenium is adnate
Stipe is bare
Spore print is olive to olive-brown
Ecology is mycorrhizal
Edibility is choice

Imleria badia, commonly known as the bay bolete, is an edible, pored mushroom found in Eurasia and North America, where it grows in coniferous or mixed woods on the ground or on decaying tree stumps, sometimes in prolific numbers. Both the common and scientific names refer to the bay- or chestnut-coloured cap, which is almost spherical in young specimens before broadening and flattening out to a diameter up to 15 cm (6 in). On the cap underside are small yellowish pores that turn dull blue-grey when bruised. The smooth, cylindrical stipe, measuring 4–9 cm (1+123+12 in) long by 1–2 cm (1234 in) thick, is coloured like the cap, but paler. Some varieties have been described from eastern North America, differing from the main type in both macroscopic and microscopic morphology.

First described scientifically by Elias Fries in 1818, the bay bolete was reclassified as Xerocomus badius in 1931, and it is still listed thus in several sources. Modern molecular phylogenetic studies show Xerocomus to be polyphyletic (not descended from a common ancestor), and the bay bolete is not particularly closely related to species in that genus. Often considered a poor relation of the cep (Boletus edulis), I. badia is nevertheless regarded as a choice edible mushroom by some authors, such as food expert Antonio Carluccio, and is sold in markets in Europe and central Mexico. Its mushrooms are less often infested by maggots than other boletes. Several European studies have demonstrated that the mushroom can bioaccumulate some trace metals from the soil, such as mercury, cobalt, and nickel. Additionally, the mushroom contains a pigment that concentrates radioactive caesium; specimens collected in Europe following the 1986 Chernobyl disaster contained several times more caesium-137 than those collected before the incident.

Taxonomy Edit

The bay bolete was first named as Boletus castaneus ß badius (i.e. a subspecies of Boletus castaneus) by Elias Magnus Fries in 1818.[nb 1] Fries later renamed it as a variety of Boletus castaneus in 1828,[2] before assigning it distinct species status in his 1832 work Elenchus Fungorum.[3] The fungus has been transferred to several genera in its taxonomic history: Rostkovites by Petter Karsten in 1881;[4] Viscipellis and Ixocomus by Lucien Quélet in 1886 and 1888, respectively;[5][6] and Suillus by Otto Kuntze in 1898.[7] In 1931, Edouard-Jean Gilbert reclassified it in the genus Xerocomus,[8] and many sources still list it thus.[9] Review of Xerocomus strongly suggested it was polyphyletic, and the genus was not accepted by some mycologists. The stickiness of its wet cap distinguishes the species from others classified in Xerocomus, and hence it was left in Boletus until Alfredo Vizzini placed it in its own genus in 2014.[10][11] Genetic analysis published in 2013 shows that Imleria badia is related to B. pallidus and B. glabellus; the three species form a clade known informally as the badius clade within a larger group (informally called anaxoboletus) in the suborder Boletineae. Other clades within the group include the Tylopilus, porcini (= Boletus sensu stricto) and Strobilomyces clades, as well as two other groups composed of members of various genera including Xerocomus (the taxa designated as Xerocomus species in this clade are not Xerocomus species and require new taxonomic designations) and Xerocomellus.[12]

 
Both the common and scientific names refer to the bay cap colour.

The species Boletus limatulus, originally published by Charles Christopher Frost in 1874,[13] was later redescribed, "with a slight tinge of irritation at the time, energy and gasoline spent", as a variety of I. badia by Wally Snell in 1945 (as Xerocomus badius var. limatulus).[14] The taxon name comes from the Latin limatulus, "rather polished" or "refined".[15] Varieties glaber and macrostipitatus were described from Nova Scotia, Canada, in 1976.[16]

The starting date of fungal taxonomy had been set as January 1, 1821, to coincide with the date of the works of Swedish naturalist Elias Magnus Fries, the "father of mycology". Rolf Singer argued that setting the starting date earlier to Christiaan Persoon's 1801 publication of Synopsis would make a name change necessary, as he had originally given what is now known as Royoporus badius the combination Boletus badius Pers. and if the bay bolete was classified in the genus Boletus, the name would be unavailable and the names Boletus glutinosus Krombh. or B. spadiceus Krombh. (non Fr.) would have to be used instead.[17]

The species name is the Latin adjective badia, meaning "chestnut brown".[18] The common name is likewise derived from the colour of the cap, likened to the coat of a bay horse. Alternate common names of a similar derivation include bay-brown bolete and bay-capped bolete,[19] and it is known as bolet bai in French.[20] It is also known as the false cep.[19] Variety glaber was named for its smooth (Latin: glaber, "without hairs") stipe, and macrostipitatus for its large (Latin: macro, "large") stipe.[16]

Description Edit

 
With wet and sticky cap
 
The pore surface stains bluish-grey when injured.

Imleria badia fruit bodies have a chestnut to dark brown cap, which is almost spherical in young specimens before broadening and flattening out to a diameter of up to 15 cm (6 in). The cap margin is acute, and cap surface velvety when young and slightly sticky when wet or old.[20] The cap cuticle is difficult to separate from the flesh underneath.[21] On the cap undersurface, the pores are initially cream to pale yellow, but become greenish yellow or olive with age. They stain dull blue to bluish-grey when bruised or cut, and are easily removed from the flesh.[20] The pores are initially circular, becoming more angular with age,[22] and number about one or two per millimetre. The tubes are 0.8–1.5 cm (3858 in) long,[23] and are adnate to depressed around the area of attachment to the stipe.[24]

The flesh is mostly whitish or yellowish in some places; underneath the cap cuticle, it is brownish-pink or reddish brown.[25] Initially firm, it begins to soften under the cap in older mushrooms.[19] In some parts of the cap, such as the junction of the cap and the stipe,[21] the flesh stains pale blue when injured or exposed to air, particularly in damp weather.[19] This change is sometimes faint,[20] and not persistent, as it eventually reverts to its original colour.[21] The stipe is 4–9 cm (1+123+12 in) long by 1–2 cm (1234 in) thick, and is similar in colour to the cap but paler, and sometimes with a rose-coloured tinge.[23] Its surface has faint longitudinal ridges, a fine powdering,[16] and fine reticulations (a net-like pattern of ridges) at the apex.[24] It often has a whitish region at the base[23] and the top,[21] and white mycelium at the base.[16] Unlike the bulbous stipe of many other boletes, the stipe of B. badius remains relatively slim and cylindrical.[26] The flesh of the stipe gets tougher with age.[19] Its smell has been described as fruity.[20]

The spore print is olive to olive-brown.[24] The smooth spores are somewhat oblong to slightly ventricose (fattened in the middle), and measure 10–14 by 4–5 µm.[23] The basidia (spore-bearing cells) are four-spored and measure 25–35 by 8–10 µm. Pleurocystidia (cystidia found on the faces of the tubes) are fuse-shaped and ventricose, with dimensions of 50–60 by 10–14 µm.[22]

Variety B. b. macrostipitatus differs from the main form by its grey-orange cap, shorter stipe measuring 5–7 cm (2–3 in), longer spores (15–18 by 4–5 µm), and longer pleurocystidia (30–55 by 10–14 µm).[23] The variety B. b. glaber has a smooth (glabrous) stipe, and smaller pleurocystidia (35–40 by 10–15 µm) and cheilocystidia (25–30 by 9–12 µm).[16]

Several chemical tests can be used to help identify the mushroom. A drop of ammonium hydroxide solution turns the cap cuticle a greenish to bluish colour. Application of iron(II) sulphate solution causes the flesh to stain a dull bluish-green, while the pores turn golden brown with a drop of dilute potassium hydroxide.[23]

Similar species Edit

The similar colouration may cause confusion with Boletus projectellus, but the latter species is usually more robust, and has a reticulated stipe. Additionally, B. projectellus has the largest spores in the Boletaceae, up to about 30 µm in diameter. Another lookalike is Austroboletus gracilis, but this species does not have a blue bruising reaction, and its pore surface is initially white before turning pinkish.[27] Compared to I. badia, B. subtomentosus fruit bodies have narrower stipes, paler brown, dry caps,[28] and wider pores that do not stain blue on bruising. This latter species is not as good to eat.[19] In western North America, I. badia is replaced by the similar B. zelleri, which also grows both on the ground and on rotten wood.[29] The European species Xerocomus bubalinus can be mistaken for I. badia, but it has a paler yellow-brown cap flushed with pinkish-red, and is not sticky when wet.[30]

Ecology, distribution and habitat Edit

 
The mushrooms often appear in huge numbers, allowing for large collections.

Although the bay bolete is predominantly a mycorrhizal species, it does have some saprophytic tendencies and may be able to use this lifestyle in certain circumstances.[21] The ectomycorrhizae formed between I. badia and spruce (Picea abies) have active hyphal sheaths and a higher potential to store nitrogen, phosphorus, potassium, magnesium, iron, and zinc than other mycorrhizal types, indicating the fungus is well adapted to acidic stands and its mycorrhizae are very efficient in uptake and storage of macronutrients.[31] Mycorrhizae with Monterey pine (Pinus radiata) have also been described.[32]

The bay bolete is common in coniferous and less commonly mixed woodlands in Europe, from the British Isles, where it is abundant throughout from August to November,[33] east to the Black Sea Region in Turkey.[34] In Asia, the species has been recorded from Jordan[35] mainland China,[36] and Taiwan.[22] The North American distribution extends from eastern Canada west to Minnesota and south to North Carolina, where the mushroom fruits from July to November.[37] It also grows in central Mexico.[38] The variety B. b. macrostipitatus is found from eastern Canada south to Maine and New York state,[23] while variety B. b. glaber is known from the Atlantic Maritime Ecozone of eastern Canada.[39] Fruit bodies appear singly or scattered on the ground, or on decaying tree stumps, and can be well hidden by pine needles and ferns. Fruiting tends to peak three or four days after rain during warm weather.[40] They can be prolific, especially in highland areas that are humid and shady.[21] It is commonly found under white pine, spruce, and hemlock,[25] and also occurs under deciduous trees, especially beech.[21] It can also occur in grassy or mossy areas at or near forest margins;[20] Italian restaurateur and cook Antonio Carluccio recalled picking them in the grounds of Blenheim Palace.[40] It does not occur on calcareous (chalky) soils.[26]

I. badia fruit bodies are less affected by insects than other boletes.[27] Orbatid mites such as Carabodes femoralis, Nothrus silvestris and Oribatula tibialis eat them,[41] as do squirrels.[40] Several microbial pathogens can damage the fruit bodies, and have had an effect on populations in China, including soft rot caused by Pseudomonas aeruginosa, and black mould caused by Mucor, Sepedonium, Paecilomyces, and Diasporangium species.[36]

Uses Edit

 
Dried in Poland

Often considered a poor relation of the cep (Boletus edulis), the bay bolete is nevertheless highly regarded as a choice edible mushroom by some authors such as Carluccio. In central Mexico, it is collected from Izta-Popo Zoquiapan National Park and sold in neighbouring markets.[38] It may cause an allergic reaction in some people,[42] and the blue discolouration upon bruising can be offputting,[40] although the staining disappears from white flesh when it is cooked.[43] The flavour is milder than its better-known relative. Younger specimens are best for eating, though more mature ones can be suitable for cutting up and drying. The tendency for the pores to absorb water means that wiping rather than washing is recommended before use in the kitchen.[40] Unlike most boletes, I. badia can be eaten raw (though only young mushrooms should be used). Otherwise it can be fried in butter, or used with meat or fish recipes. Mushrooms can also be frozen, dried,[40] or pickled in cider vinegar, wine, or extra virgin olive oil,[44] and later used in sauces or soups.[40]

The fruit bodies can be used to make mushroom dyes. Depending on the mordant used, colours ranging from yellow, orange, gold, and green-brown can be obtained. Without mordant, a yellow colour is produced.[45]

Research Edit

In laboratory experiments, extracts of I. badia fruit bodies have been shown to have significant antioxidative properties in vitro.[46] Fruit bodies contain the compound theanine,[47] an amino acid and a glutamic acid analogue found in green tea.[48] Efforts have been made to establish a protocol for producing theanine by growing the fungus mycelium using submerged fermentation.[49] Several indole compounds have been detected in fruit bodies. Unprocessed mushrooms contain tryptophan (0.68 mg per 100 g dry weight), tryptamine (0.47), serotonin (0.52), kynurenine sulphate (1.96), and kynurenic acid (1.57). Due to their temperature sensitivity, cooking significantly changes the contents and composition of indole compounds: cooked mushrooms contained tryptophan (1.74 mg/100 g dw), 5-methyltryptophan (6.55), melatonin (0.71), and indoleacetonitrile (2.07).[50] Fruit body extracts have been shown to slow the growth of certain tumour cell lines in cell culture.[48][51]

Polish studies found that although the mushroom bioaccumulates mercury and cobalt from the soil, occasional consumption of mushrooms should not cause maximum allowable intake doses to be exceeded.[52][53] Similar conclusions about safety were made in a Polish study of the mushroom's ability to accumulate organochlorine compounds.[54] Different methods of preparation for consumption affect the leaching rate of cadmium, lead, and mercury.[55] After the 1986 Chernobyl disaster, several studies showed I. badia bioaccumulates radioactive caesium, 137Cs.[56] 137Cs is produced in nuclear power plants following the chain decay of 235U to 137Te, and has a half-life of thirty years. A German study showed that mushrooms collected from 1986 to 1988 had radiocaesium contents that were 8.3 to 13.6 times greater than mushrooms collected before the accident in 1985.[57] This caesium-sequestering effect is caused by a brown pigment, the polyphenol compound norbadione A, which is related to a family of mushroom pigments known as pulvinic acids.[58] Norbadione A has been investigated for its ability to provide a protective effect against the damaging effects of ionizing radiation. Tests with cell cultures and mice show that although it has some protective effect, it is toxic to cells in higher doses.[59] A new series of alkali chelators based on the structure of norbadione A has been reported.[60] The mushroom may have potential as a bioremediation agent to clean up contaminated sites.[61]

See also Edit

Notes Edit

  1. ^ Though he wrote, "forte distincta species; sed ex unico a me viso specimine distinguere potui, neque debui" (Perhaps a distinct species, but I could not state it definitely from the only specimen I have seen, nor should I.)

References Edit

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  56. ^ Elstner EF, Fink R, Höll W, Lengfelder E, Ziegler H (1987). "Natural and Chernobyl-caused radioactivity in mushrooms, mosses and soil-samples of defined biotops in SW Bavaria". Oecologia. 73 (1): 553–58. Bibcode:1987Oecol..73..553E. doi:10.1007/bf00379415. JSTOR 4218406. PMID 28311973. S2CID 6354011.
  57. ^ Paulus W, Reisinger A (1990). [The influence of the Chernobyl accident on radiocesium content in fruitbodies of the ectomycorrhizal fungi Lactarius rufus and Xerocomus badius collected in the Fichtelgebirge, East Germany] (PDF). Zeitschrift für Mykologie (in German). 56 (2): 279–84. Archived from the original (PDF) on 2015-09-23. Retrieved 2013-07-07.
  58. ^ Aumann DC, Clooth G, Steffan B, Steglich W (1989). "Complexation of cesium-137 by the cap pigments of the bay boletus (Xerocomus badius)". Angewandte Chemie International Edition in English. 28 (4): 453–54. doi:10.1002/anie.198904531.
  59. ^ Le Roux A, Josset E, Benzina S, Nadal B, Desage-El Murr M, Heurtaux B, Taran F, Denis J-M, Le Gall T, Meunier S, Bischoff P (2012). "Evaluation of the radioprotective potential of the polyphenol norbadione A". Letters in Drug Design & Discovery. 9 (1): 48–53. doi:10.2174/157018012798192900.
  60. ^ Korovitch A, Le Roux A, Barbault F, Hémadi M, Ha-Duong N-T, Lion C, Wagner A, El Hage Chahine J-M (2013). "A new series of Cs+, K+ and Na+ chelators: Synthesis, kinetics, thermodynamics and modeling". Inorganica Chimica Acta. 394: 45–57. doi:10.1016/j.ica.2012.08.009.
  61. ^ Stamets P. (2011). Mycelium Running: How Mushrooms Can Help Save the World. Berkeley: Ten Speed Press. p. 105. ISBN 978-1-60774-124-4.

External links Edit

  •   Media related to Imleria badia at Wikimedia Commons
  •   Data related to Imleria badia at Wikispecies
  • Imleria badia in Index Fungorum

August 29, 2023
imleria, badia, badia, under, beech, oakscientific, classificationdomain, eukaryotakingdom, fungidivision, basidiomycotaclass, agaricomycetesorder, boletalesfamily, boletaceaegenus, imleriaspecies, badiabinomial, name, vizzini, 2014, synonyms, boletus, castane. Imleria badiaI badia under beech and oakScientific classificationDomain EukaryotaKingdom FungiDivision BasidiomycotaClass AgaricomycetesOrder BoletalesFamily BoletaceaeGenus ImleriaSpecies I badiaBinomial nameImleria badia Fr Vizzini 2014 Synonyms 1 Boletus castaneus ss badius Fr 1818 Boletus castaneus var badius Fr Fr 1828 Boletus badius Fr Fr 1832 Rostkovites badia Fr P Karst 1881 Viscipellis badia Fr Quel 1886 Ixocomus badius Fr Quel 1888 Suillus badius Fr Kuntze 1898 Xerocomus badius Fr E J Gilbert 1931 Imleria badiaMycological characteristicsPores on hymeniumCap is convexHymenium is adnateStipe is bareSpore print is olive to olive brownEcology is mycorrhizalEdibility is choice Imleria badia commonly known as the bay bolete is an edible pored mushroom found in Eurasia and North America where it grows in coniferous or mixed woods on the ground or on decaying tree stumps sometimes in prolific numbers Both the common and scientific names refer to the bay or chestnut coloured cap which is almost spherical in young specimens before broadening and flattening out to a diameter up to 15 cm 6 in On the cap underside are small yellowish pores that turn dull blue grey when bruised The smooth cylindrical stipe measuring 4 9 cm 1 1 2 3 1 2 in long by 1 2 cm 1 2 3 4 in thick is coloured like the cap but paler Some varieties have been described from eastern North America differing from the main type in both macroscopic and microscopic morphology First described scientifically by Elias Fries in 1818 the bay bolete was reclassified as Xerocomus badius in 1931 and it is still listed thus in several sources Modern molecular phylogenetic studies show Xerocomus to be polyphyletic not descended from a common ancestor and the bay bolete is not particularly closely related to species in that genus Often considered a poor relation of the cep Boletus edulis I badia is nevertheless regarded as a choice edible mushroom by some authors such as food expert Antonio Carluccio and is sold in markets in Europe and central Mexico Its mushrooms are less often infested by maggots than other boletes Several European studies have demonstrated that the mushroom can bioaccumulate some trace metals from the soil such as mercury cobalt and nickel Additionally the mushroom contains a pigment that concentrates radioactive caesium specimens collected in Europe following the 1986 Chernobyl disaster contained several times more caesium 137 than those collected before the incident Contents 1 Taxonomy 2 Description 2 1 Similar species 3 Ecology distribution and habitat 4 Uses 5 Research 6 See also 7 Notes 8 References 9 External linksTaxonomy EditThe bay bolete was first named as Boletus castaneus ss badius i e a subspecies of Boletus castaneus by Elias Magnus Fries in 1818 nb 1 Fries later renamed it as a variety of Boletus castaneus in 1828 2 before assigning it distinct species status in his 1832 work Elenchus Fungorum 3 The fungus has been transferred to several genera in its taxonomic history Rostkovites by Petter Karsten in 1881 4 Viscipellis and Ixocomus by Lucien Quelet in 1886 and 1888 respectively 5 6 and Suillus by Otto Kuntze in 1898 7 In 1931 Edouard Jean Gilbert reclassified it in the genus Xerocomus 8 and many sources still list it thus 9 Review of Xerocomus strongly suggested it was polyphyletic and the genus was not accepted by some mycologists The stickiness of its wet cap distinguishes the species from others classified in Xerocomus and hence it was left in Boletus until Alfredo Vizzini placed it in its own genus in 2014 10 11 Genetic analysis published in 2013 shows that Imleria badia is related to B pallidus and B glabellus the three species form a clade known informally as the badius clade within a larger group informally called anaxoboletus in the suborder Boletineae Other clades within the group include the Tylopilus porcini Boletus sensu stricto and Strobilomyces clades as well as two other groups composed of members of various genera including Xerocomus the taxa designated as Xerocomus species in this clade are not Xerocomus species and require new taxonomic designations and Xerocomellus 12 Both the common and scientific names refer to the bay cap colour The species Boletus limatulus originally published by Charles Christopher Frost in 1874 13 was later redescribed with a slight tinge of irritation at the time energy and gasoline spent as a variety of I badia by Wally Snell in 1945 as Xerocomus badius var limatulus 14 The taxon name comes from the Latin limatulus rather polished or refined 15 Varieties glaber and macrostipitatus were described from Nova Scotia Canada in 1976 16 The starting date of fungal taxonomy had been set as January 1 1821 to coincide with the date of the works of Swedish naturalist Elias Magnus Fries the father of mycology Rolf Singer argued that setting the starting date earlier to Christiaan Persoon s 1801 publication of Synopsis would make a name change necessary as he had originally given what is now known as Royoporus badius the combination Boletus badius Pers and if the bay bolete was classified in the genus Boletus the name would be unavailable and the names Boletus glutinosus Krombh or B spadiceus Krombh non Fr would have to be used instead 17 The species name is the Latin adjective badia meaning chestnut brown 18 The common name is likewise derived from the colour of the cap likened to the coat of a bay horse Alternate common names of a similar derivation include bay brown bolete and bay capped bolete 19 and it is known as bolet bai in French 20 It is also known as the false cep 19 Variety glaber was named for its smooth Latin glaber without hairs stipe and macrostipitatus for its large Latin macro large stipe 16 Description Edit With wet and sticky cap The pore surface stains bluish grey when injured Imleria badia fruit bodies have a chestnut to dark brown cap which is almost spherical in young specimens before broadening and flattening out to a diameter of up to 15 cm 6 in The cap margin is acute and cap surface velvety when young and slightly sticky when wet or old 20 The cap cuticle is difficult to separate from the flesh underneath 21 On the cap undersurface the pores are initially cream to pale yellow but become greenish yellow or olive with age They stain dull blue to bluish grey when bruised or cut and are easily removed from the flesh 20 The pores are initially circular becoming more angular with age 22 and number about one or two per millimetre The tubes are 0 8 1 5 cm 3 8 5 8 in long 23 and are adnate to depressed around the area of attachment to the stipe 24 The flesh is mostly whitish or yellowish in some places underneath the cap cuticle it is brownish pink or reddish brown 25 Initially firm it begins to soften under the cap in older mushrooms 19 In some parts of the cap such as the junction of the cap and the stipe 21 the flesh stains pale blue when injured or exposed to air particularly in damp weather 19 This change is sometimes faint 20 and not persistent as it eventually reverts to its original colour 21 The stipe is 4 9 cm 1 1 2 3 1 2 in long by 1 2 cm 1 2 3 4 in thick and is similar in colour to the cap but paler and sometimes with a rose coloured tinge 23 Its surface has faint longitudinal ridges a fine powdering 16 and fine reticulations a net like pattern of ridges at the apex 24 It often has a whitish region at the base 23 and the top 21 and white mycelium at the base 16 Unlike the bulbous stipe of many other boletes the stipe of B badius remains relatively slim and cylindrical 26 The flesh of the stipe gets tougher with age 19 Its smell has been described as fruity 20 The spore print is olive to olive brown 24 The smooth spores are somewhat oblong to slightly ventricose fattened in the middle and measure 10 14 by 4 5 µm 23 The basidia spore bearing cells are four spored and measure 25 35 by 8 10 µm Pleurocystidia cystidia found on the faces of the tubes are fuse shaped and ventricose with dimensions of 50 60 by 10 14 µm 22 Variety B b macrostipitatus differs from the main form by its grey orange cap shorter stipe measuring 5 7 cm 2 3 in longer spores 15 18 by 4 5 µm and longer pleurocystidia 30 55 by 10 14 µm 23 The variety B b glaber has a smooth glabrous stipe and smaller pleurocystidia 35 40 by 10 15 µm and cheilocystidia 25 30 by 9 12 µm 16 Several chemical tests can be used to help identify the mushroom A drop of ammonium hydroxide solution turns the cap cuticle a greenish to bluish colour Application of iron II sulphate solution causes the flesh to stain a dull bluish green while the pores turn golden brown with a drop of dilute potassium hydroxide 23 Similar species Edit The similar colouration may cause confusion with Boletus projectellus but the latter species is usually more robust and has a reticulated stipe Additionally B projectellus has the largest spores in the Boletaceae up to about 30 µm in diameter Another lookalike is Austroboletus gracilis but this species does not have a blue bruising reaction and its pore surface is initially white before turning pinkish 27 Compared to I badia B subtomentosus fruit bodies have narrower stipes paler brown dry caps 28 and wider pores that do not stain blue on bruising This latter species is not as good to eat 19 In western North America I badia is replaced by the similar B zelleri which also grows both on the ground and on rotten wood 29 The European species Xerocomus bubalinus can be mistaken for I badia but it has a paler yellow brown cap flushed with pinkish red and is not sticky when wet 30 Ecology distribution and habitat Edit The mushrooms often appear in huge numbers allowing for large collections Although the bay bolete is predominantly a mycorrhizal species it does have some saprophytic tendencies and may be able to use this lifestyle in certain circumstances 21 The ectomycorrhizae formed between I badia and spruce Picea abies have active hyphal sheaths and a higher potential to store nitrogen phosphorus potassium magnesium iron and zinc than other mycorrhizal types indicating the fungus is well adapted to acidic stands and its mycorrhizae are very efficient in uptake and storage of macronutrients 31 Mycorrhizae with Monterey pine Pinus radiata have also been described 32 The bay bolete is common in coniferous and less commonly mixed woodlands in Europe from the British Isles where it is abundant throughout from August to November 33 east to the Black Sea Region in Turkey 34 In Asia the species has been recorded from Jordan 35 mainland China 36 and Taiwan 22 The North American distribution extends from eastern Canada west to Minnesota and south to North Carolina where the mushroom fruits from July to November 37 It also grows in central Mexico 38 The variety B b macrostipitatus is found from eastern Canada south to Maine and New York state 23 while variety B b glaber is known from the Atlantic Maritime Ecozone of eastern Canada 39 Fruit bodies appear singly or scattered on the ground or on decaying tree stumps and can be well hidden by pine needles and ferns Fruiting tends to peak three or four days after rain during warm weather 40 They can be prolific especially in highland areas that are humid and shady 21 It is commonly found under white pine spruce and hemlock 25 and also occurs under deciduous trees especially beech 21 It can also occur in grassy or mossy areas at or near forest margins 20 Italian restaurateur and cook Antonio Carluccio recalled picking them in the grounds of Blenheim Palace 40 It does not occur on calcareous chalky soils 26 I badia fruit bodies are less affected by insects than other boletes 27 Orbatid mites such as Carabodes femoralis Nothrus silvestris and Oribatula tibialis eat them 41 as do squirrels 40 Several microbial pathogens can damage the fruit bodies and have had an effect on populations in China including soft rot caused by Pseudomonas aeruginosa and black mould caused by Mucor Sepedonium Paecilomyces and Diasporangium species 36 Uses Edit Dried in PolandOften considered a poor relation of the cep Boletus edulis the bay bolete is nevertheless highly regarded as a choice edible mushroom by some authors such as Carluccio In central Mexico it is collected from Izta Popo Zoquiapan National Park and sold in neighbouring markets 38 It may cause an allergic reaction in some people 42 and the blue discolouration upon bruising can be offputting 40 although the staining disappears from white flesh when it is cooked 43 The flavour is milder than its better known relative Younger specimens are best for eating though more mature ones can be suitable for cutting up and drying The tendency for the pores to absorb water means that wiping rather than washing is recommended before use in the kitchen 40 Unlike most boletes I badia can be eaten raw though only young mushrooms should be used Otherwise it can be fried in butter or used with meat or fish recipes Mushrooms can also be frozen dried 40 or pickled in cider vinegar wine or extra virgin olive oil 44 and later used in sauces or soups 40 The fruit bodies can be used to make mushroom dyes Depending on the mordant used colours ranging from yellow orange gold and green brown can be obtained Without mordant a yellow colour is produced 45 Research EditIn laboratory experiments extracts of I badia fruit bodies have been shown to have significant antioxidative properties in vitro 46 Fruit bodies contain the compound theanine 47 an amino acid and a glutamic acid analogue found in green tea 48 Efforts have been made to establish a protocol for producing theanine by growing the fungus mycelium using submerged fermentation 49 Several indole compounds have been detected in fruit bodies Unprocessed mushrooms contain tryptophan 0 68 mg per 100 g dry weight tryptamine 0 47 serotonin 0 52 kynurenine sulphate 1 96 and kynurenic acid 1 57 Due to their temperature sensitivity cooking significantly changes the contents and composition of indole compounds cooked mushrooms contained tryptophan 1 74 mg 100 g dw 5 methyltryptophan 6 55 melatonin 0 71 and indoleacetonitrile 2 07 50 Fruit body extracts have been shown to slow the growth of certain tumour cell lines in cell culture 48 51 Polish studies found that although the mushroom bioaccumulates mercury and cobalt from the soil occasional consumption of mushrooms should not cause maximum allowable intake doses to be exceeded 52 53 Similar conclusions about safety were made in a Polish study of the mushroom s ability to accumulate organochlorine compounds 54 Different methods of preparation for consumption affect the leaching rate of cadmium lead and mercury 55 After the 1986 Chernobyl disaster several studies showed I badia bioaccumulates radioactive caesium 137Cs 56 137Cs is produced in nuclear power plants following the chain decay of 235U to 137Te and has a half life of thirty years A German study showed that mushrooms collected from 1986 to 1988 had radiocaesium contents that were 8 3 to 13 6 times greater than mushrooms collected before the accident in 1985 57 This caesium sequestering effect is caused by a brown pigment the polyphenol compound norbadione A which is related to a family of mushroom pigments known as pulvinic acids 58 Norbadione A has been investigated for its ability to provide a protective effect against the damaging effects of ionizing radiation Tests with cell cultures and mice show that although it has some protective effect it is toxic to cells in higher doses 59 A new series of alkali chelators based on the structure of norbadione A has been reported 60 The mushroom may have potential as a bioremediation agent to clean up contaminated sites 61 See also Edit Fungi portalList of North American boletesNotes Edit Though he wrote forte distincta species sed ex unico a me viso specimine distinguere potui neque debui Perhaps a distinct species but I could not state it definitely from the only specimen I have seen nor should I References Edit Synonymy Boletus badius Fr Fr Syst mycol Index alphab Lundae 56 1832 Index Fungorum CAB International Retrieved 2013 07 12 Fries EM 1828 Elenchus Fungorum in Latin Vol 1 Greifswald Ernestus Mauritius p 126 Fries EM 1821 Systema Mycologicum in Latin Vol 1 Lundin Ex Officina Berlingiana p 392 Karsten P 1881 Enumeratio Boletinearum et Polyporearum Fennicarum systemate novo dispositarum Revue Mycologique Toulouse in Latin 3 9 16 19 Quelet L 1886 Enchiridion Fungorum in Europa media et praesertim in Gallia Vigentium in Latin Lutetia Octave Dion p 156 Quelet L 1888 Flore mycologique de la France et des pays limitrophes in French Paris Octave Doin p 412 Kuntze O 1898 Revisio generum plantarum in German Vol 3 Leipzig A Felix p 535 Gilbert E J 1931 Les Livres du Mycologue Tome III Les Bolets in French Paris E Le Francois p 92 Noordeloos ME 2007 Hoe raak ik thuis in de boleten 7 De fluweelboleten Xerocomus van Nederland The genus Xerocomus in the Netherlands PDF Coolia in Dutch 50 1 1 20 Sutara J 2008 Xerocomus s l in the light of the present state of knowledge PDF Czech Mycology 60 1 29 62 doi 10 33585 cmy 60104 Vizzini A 12 June 2014 Nomenclatural novelties PDF Index Fungorum 147 1 ISSN 2049 2375 Nuhn ME Binder M Taylor AFS Halling RE Hibbett DS 2013 Phylogenetic overview of the Boletineae Fungal Biology 117 7 8 479 511 doi 10 1016 j funbio 2013 04 008 PMID 23931115 Frost CC 1874 Catalogue of boleti of New England with descriptions of new species Bulletin of the Buffalo Society of Natural Sciences 2 100 05 Snell WH 1945 Notes on boletes VII Mycologia 37 3 374 88 see pp 382 83 doi 10 2307 3754872 JSTOR 3754872 Simpson DP 1979 1854 Cassell s Latin Dictionary 5th ed London Cassell p 346 ISBN 978 0 304 52257 6 a b c d e Grund DW Harrison KA 1976 Nova Scotian Boletes Bibliotheca Mycologia Vol 47 Lehre J Cramer pp 116 118 ISBN 978 3 7682 1062 1 Singer R 1960 Persoon s Synopsis 1801 as starting point for all fungi Taxon 9 2 35 37 doi 10 2307 1217835 JSTOR 1217835 Nilson S Persson O 1977 Fungi of Northern Europe 1 Larger Fungi Excluding Gill Fungi Harmondsworth Penguin p 108 ISBN 978 0 14 063005 3 a b c d e f Lamaison J L Polese J M 2005 The Great Encyclopedia of Mushrooms Cologne Konemann p 26 ISBN 978 3 8331 1239 3 a b c d e f Zeitlmayr L 1976 Wild Mushrooms An Illustrated Handbook Hertfordshire Garden City Press pp 98 99 ISBN 978 0 584 10324 3 a b c d e f g Alessio CL 1985 BoletusDill ex L sensu lato in Italian Saronno Biella Giovanna pp 323 27 a b c Yeh K W Chen Z C 1981 The boletes of Taiwan II PDF Taiwania 26 1 100 15 doi 10 6165 tai 1981 26 100 ISSN 0372 333X Archived from the original PDF on 2018 04 25 Retrieved 2018 12 10 a b c d e f g Bessette AR Bessette A Roody WC 2000 North American Boletes A Color Guide to the Fleshy Pored Mushrooms Syracuse Syracuse University Press pp 96 97 ISBN 978 0 8156 0588 1 a b c Miller HR Miller OK Jr 2006 North American Mushrooms A Field Guide to Edible and Inedible Fungi Guilford Falcon Guides p 397 ISBN 978 0 7627 3109 1 a b Snell W Dick EA 1970 The Boleti of Northeastern North America Lehre J Cramer p 55 ISBN 978 0 85486 016 6 a b Haas H 1969 The Young Specialist looks at Fungi London Burke p 42 ISBN 978 0 222 79409 3 a b Roody WC 2003 Mushrooms of West Virginia and the Central Appalachians Lexington University Press of Kentucky p 315 ISBN 978 0 8131 9039 6 Roberts P Evans S 2011 The Book of Fungi Chicago University of Chicago Press p 328 ISBN 978 0 226 72117 0 Arora D 1986 Mushrooms Demystified A Comprehensive Guide to the Fleshy Fungi Berkeley Ten Speed Press p 519 ISBN 978 0 89815 169 5 Hills AE 2008 The genus Xerocomus A personal view with a key to the British species Field Mycology 9 3 77 96 doi 10 1016 S1468 1641 10 60416 1 Kottke I Qian XM Pritsch K Haug I Oberwinkler F 1998 Xerocomus badius Picea abies an ectomycorrhiza of high activity and element storage capacity in acidic soil Mycorrhiza 7 5 267 75 doi 10 1007 s005720050191 PMID 24578053 S2CID 24196528 Dunabeitia MK Hormilla S Salcedo I Pena JI 1996 Ectomycorrhizae synthesized between Pinus radiata and eight fungi associated with Pinus spp Mycologia 88 6 897 908 doi 10 2307 3761052 JSTOR 3761052 Phillips R 2006 Mushrooms London Pan MacMillan pp 276 77 ISBN 978 0 330 44237 4 Sesli E 2007 Preliminary checklist of macromycetes of the East and Middle Black Sea Regions of Turkey PDF Mycotaxon 99 71 74 Natour RM Salhab AS El Moumani AR Saba EF 1992 Wild mushroom in Jordan Dirasat Series B Pure and Applied Sciences 19 2 47 60 a b Guo YH Gui MY Wang LX Ye K 2004 Investigation report on diseases of wild Xerocomus badius in Yunnan province of China Edible Fungi of China in Chinese 23 2 48 51 ISSN 1003 8310 Phillips R 2005 Mushrooms and Other Fungi of North America Buffalo Firefly Books p 260 ISBN 978 1 55407 115 9 a b Dugan FM 2011 Conspectus of World Ethnomycology St Paul American Phytopathological Society p 78 ISBN 978 0 89054 395 5 Malloch D 2010 Fleshy fungi Basidiomycota of the Atlantic Maritime Ecozone In McAlpine DF Smith IM eds Assessment of Species Diversity in the Atlantic Maritime Ecozone Ottawa NRC Research Press p 121 ISBN 978 0 660 19835 4 a b c d e f g Carluccio A 2003 The Complete Mushroom Book London Quadrille pp 33 34 ISBN 978 1 84400 040 1 Schneider K Renker C Maraun M 2005 Oribatid mite Acari Oribatida feeding on ectomycorrhizal fungi Mycorrhiza 16 1 67 72 doi 10 1007 s00572 005 0015 8 PMID 16133254 S2CID 7299733 Bennink A de Vries B 2007 Allergie voor boleten Allergic to boletes PDF Coolia in Dutch 50 1 47 48 Laessoe T 2002 Mushrooms Smithsonian Handbooks 2nd ed London Dorling Kindersley Adult p 188 ISBN 978 0 7894 8986 9 Jordan P Wheeler S 2000 1995 The Practical Mushroom Encyclopedia London Southwater p 40 ISBN 978 1 84215 243 0 Bessette A Bessette AR 2001 The Rainbow Beneath my Feet A Mushroom Dyer s Field Guide Syracuse Syracuse University Press p 36 ISBN 978 0 8156 0680 2 Haghi AK 2011 Food Science Research and Technology Toronto CRC Press p 76 ISBN 978 1 926895 01 7 Casimir J Jadot J Renard M 1960 Separation et caracterisation de la N ethyl g glutamine a partir de Xerocomus badius Separation and characterization of N ethyl gamma glutamine from Xerocomus badius Biochimica et Biophysica Acta in French 39 3 462 68 doi 10 1016 0006 3002 60 90199 2 PMID 13808157 a b Rogers R 2012 The Fungal Pharmacy The Complete Guide to Medicinal Mushrooms and Lichens of North America Berkeley North Atlantic Books p 68 ISBN 978 1 58394 595 7 Li J Li P Liu F 2008 Production of theanine by Xerocomus badius mushroom using submerged fermentation LWT Food Science and Technology 41 5 883 99 doi 10 1016 j lwt 2007 05 020 Muszynska B Sulkowska Ziaja K 2012 Analysis of indole compounds in edible Basidiomycota species after thermal processing Food Chemistry 132 1 455 59 doi 10 1016 j foodchem 2011 11 021 PMID 26434315 Badalyan S 2012 Medicinal aspects of edible mycorrhizal mushrooms In Zambonelli A Bonito GM eds Edible Ectomycorrhizal Mushrooms Soil Biology Vol 34 Berlin Springer Verlag pp 317 34 ISBN 978 3 642 33822 9 Falandysz J Kojta AK Jarzynska G Drewnowska M Dryzalowska A Wydmanska D Kowalewska I Wacko A Szlosowska M Kannan K Szefer P 2012 Mercury in bay bolete Xerocomus badius Bioconcentration by fungus and assessment of element intake by humans eating fruiting bodies Food Additives and Contaminants 29 6 951 61 doi 10 1080 19440049 2012 662702 PMID 22416950 S2CID 5401125 Mleczek M Siwulski M Stuper Szablewska K Rissmann I Sobieralski K Golinski P 2013 Accumulation of elements by edible mushroom species Part I Problem of trace element toxicity in mushrooms Journal of Environmental Science and Health Part B 48 1 69 81 doi 10 1080 03601234 2012 716733 PMID 23030443 S2CID 21445417 Galgowska M Pietrzak Fiecko R Felkner Pozniakowska B 2012 Assessment of the chlorinated hydrocarbons residues contamination in edible mushrooms from the North Eastern part of Poland Food and Chemical Toxicology 50 11 4125 29 doi 10 1016 j fct 2012 07 039 PMID 22889896 Svoboda L Kalac P Spicka J Janouskova D 2002 Leaching of cadmium lead and mercury from fresh and differently preserved edible mushroom Xerocomus badius during soaking and boiling Food Chemistry 79 1 41 45 doi 10 1016 S0308 8146 02 00175 9 Elstner EF Fink R Holl W Lengfelder E Ziegler H 1987 Natural and Chernobyl caused radioactivity in mushrooms mosses and soil samples of defined biotops in SW Bavaria Oecologia 73 1 553 58 Bibcode 1987Oecol 73 553E doi 10 1007 bf00379415 JSTOR 4218406 PMID 28311973 S2CID 6354011 Paulus W Reisinger A 1990 Die Auswirkungen des Reaktorunfalls von Tschernobyl auf den Gehalt an radioaktivem Casium in den Fruchtkorpern der Mykorrhizapilzarten Lactarius rufus und Xerocomus badius im Fichtelgebirge The influence of the Chernobyl accident on radiocesium content in fruitbodies of the ectomycorrhizal fungi Lactarius rufus and Xerocomus badius collected in the Fichtelgebirge East Germany PDF Zeitschrift fur Mykologie in German 56 2 279 84 Archived from the original PDF on 2015 09 23 Retrieved 2013 07 07 Aumann DC Clooth G Steffan B Steglich W 1989 Complexation of cesium 137 by the cap pigments of the bay boletus Xerocomus badius Angewandte Chemie International Edition in English 28 4 453 54 doi 10 1002 anie 198904531 Le Roux A Josset E Benzina S Nadal B Desage El Murr M Heurtaux B Taran F Denis J M Le Gall T Meunier S Bischoff P 2012 Evaluation of the radioprotective potential of the polyphenol norbadione A Letters in Drug Design amp Discovery 9 1 48 53 doi 10 2174 157018012798192900 Korovitch A Le Roux A Barbault F Hemadi M Ha Duong N T Lion C Wagner A El Hage Chahine J M 2013 A new series of Cs K and Na chelators Synthesis kinetics thermodynamics and modeling Inorganica Chimica Acta 394 45 57 doi 10 1016 j ica 2012 08 009 Stamets P 2011 Mycelium Running How Mushrooms Can Help Save the World Berkeley Ten Speed Press p 105 ISBN 978 1 60774 124 4 External links Edit Media related to Imleria badia at Wikimedia Commons Data related to Imleria badia at Wikispecies Imleria badia in Index Fungorum Retrieved from https en wikipedia org w index php title Imleria badia amp oldid 1136217856, wikipedia, wiki, book, books, library,

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