Suillus brevipes

Suillus brevipes
Suillus brevipes 98931.jpg
Scientific classification
S. brevipes
Binomial name
Suillus brevipes

Boletus brevipes Peck
Boletus viscosus Frost
Rostkovites brevipes (Peck) Murrill

Suillus brevipes
View the Mycomorphbox template that generates the following list
Mycological characteristics
pores on hymenium
cap is convex or flat
hymenium is adnate or decurrent
stipe is bare
spore print is brown
ecology is mycorrhizal
edibility: edible

Suillus brevipes is a species of fungus in the Boletaceae family. First described by American mycologists in the late 19th century, it is commonly known as the stubby-stalk or the short-stemmed slippery Jack. The fruit bodies (mushrooms) produced by the fungus are characterized by a chocolate to reddish-brown cap covered with a sticky layer of slime, and a short whitish stem that does not have either a partial veil or prominent dark or colored glandular dots. The cap can reach a diameter of about 10 cm (3.9 in), while the stem is up to 6 cm (2.4 in) long and 2 cm (0.8 in) thick. Like other bolete mushrooms, S. brevipes produces spores in a vertically arranged layer of spongy tubes with openings that form a layer of small yellowish pores on the underside of the cap.

Suillus brevipes grows in a mycorrhizal association with various species of two- and three-needled pines, especially lodgepole and ponderosa pine. The fungus is found throughout North America, and has been introduced to several other countries via transplanted pines. In the succession of mycorrhizal fungi associated with the regrowth of jack pine after clearcutting or wildfires, S. brevipes is a multi-stage fungus, found during all stages of tree development. The mushrooms are edible, and are high in the essential fatty acid linoleic acid.


The species was first described scientifically as Boletus viscosus by American mycologist Charles Frost in 1874. In 1885, Charles Horton Peck, who had found specimens in pine woods of Albany County, New York, explained that the species name was a taxonomic homonym (Boletus viscosus was already in use for another species named by Ventenat in 1863[2]), and so renamed it to Boletus brevipes.[3][4] Its current name was assigned by German Otto Kuntze in 1898.[5] William Alphonso Murrill renamed it as Rostkovites brevipes in 1948;[6] the genus Rostkovites is now considered to be synonymous with Suillus.[7]

Agaricales specialist Rolf Singer included Suillus brevipes in the subsection Suillus of genus Suillus, an infrageneric (a taxonomic level below genus) grouping of species characterized by a cinnamon-brown spore print, and pores less than 1 mm wide.[8] Molecular phylogenetic analyses of ribosomal DNA sequences shows that the most closely related species to Suillus brevipes include S. luteus, S. pseudobrevipes, and S. weaverae (formerly Fuscoboletinus weaverae).[9]

The specific epithet is derived from the Latin brevipes, meaning "short-footed".[10] The mushroom is commonly known as the "stubby-stalk"[11] or the "short-stemmed slippery Jack".[12]


The cap flesh is white or pale yellow, and does not change color when cut.
The pores on the underside of the cap are minute, typically 2–3 per millimeter.

The cap is deep brown to reddish-brown, later fading to tan with age, and it does not bruise with handling. The cap surface is smooth, and, depending on the moisture in the environment, may range from sticky to the touch to slimy. Depending on its maturity, the cap shape may range from spherical to broadly convex. The cap is medium sized, 5–10 cm (2.0–3.9 in) wide,[13] and the cap cuticle can be peeled from the surface. The tubes are yellow, becoming olive-green with age, and they have an attachment to the stem that ranges from adnate (with most of the tube fused to the stem) to decurrent (with the tubes broadly attached, but running somewhat down the length of the stem). They are typically up to 1 cm (0.4 in) deep, and there are about 1–2 tube mouths (pores) per millimeter.[14] The pores are pale yellow, round, 1–2 mm wide, and do not change color when bruised.[15]

The stem is white to pale yellow, dry, solid, not bruising, and pruinose (having a very fine whitish powder on the surface). A characteristic feature of many Suillus species are the glandular dots found on the stem—clumps of hyphal cell ends through which the fungus secretes various metabolic wastes, leaving a sticky or resinous "dot". In S. brevipes, the form of the glandular dots is variable: they may be absent, slightly underdeveloped or obscurely formed with age. The stem is usually short in comparison to the diameter of the cap, typically 2–6 cm (0.8–2.4 in) long and 1–2 cm (0.4–0.8 in) thick. It is either of equal width throughout, or may taper downwards; its surface bears minute puncture holes at maturity, and is it slightly fibrous at the base.[16] The flesh of the mushroom is initially white, but turns pale yellow in age. The odor and taste are mild. The spore print is cinnamon-brown.[17]

Microscopic characteristics

The spores are elliptical to oblong, smooth, and have dimensions of 7–10 by 3–4 µm.[15] The spore-bearing cells, the basidia, are thin-walled, club-shaped to roughly cylindrical, and measure 2–25 by 5–7 µm. They bear either two or four spores. The pleurocystidia (cystidia that are found on the face of a gill) are roughly cylindrical with rounded ends, thin-walled, and 40–55 by 5–8 µm. The cells often have brown contents, and in the presence of 2% potassium hydroxide (KOH) will appear hyaline (translucent) or vinaceous (red wine-colored); in Melzer's reagent they become pale yellow or brown. The cheilocystidia (cystidia found on the edge of a gill) are 30–60 by 7–10 µm, club-shaped to almost cylindrical, thin-walled, with brown incrusting material at the base, and arranged like a bundle of fibers. In KOH they appear hyaline, and are pale yellow in Melzer's reagent. Caulocystidia (found on the stem) are 60–90 by 7–9 µm, mostly cylindrical with rounded ends, and arranged in bundles with brown pigment particles at the base. The caulocystidia stain vinaceous in KOH. The cuticle of the cap is made of a layer of interwoven gelatinous hyphae that are individually 2–5 µm thick; the gelatinous hyphae are responsible for the sliminess of the cuticle.[16] There are no clamp connections in the hyphae.[15]


Sources recommend peeling off the slimy cap cuticle before eating the mushroom.

Like many species of the genus Suillus, S. brevipes is edible, and the mushroom is considered choice by some.[17] The odor is mild, and the taste mild or slightly acidic.[10] Field guides typically recommended to remove the slimy cap cuticle, and, in older specimens, the tube layer before consumption.[10][18] The mushrooms are common in the diet of grizzly bears in Yellowstone National Park.[19]

The fatty acid composition of S. brevipes fruit bodies has been analyzed. The cap contained a higher lipid content than the stem—18.4% of the dry weight, compared to 12.4%. In the cap, linoleic acid made up 50.7% of the total lipids (65.7% in the stem), oleic acid was 29.9% (12.4% in the stem), followed by palmitic acid at 10.5% (12.6% in the stem).[20] Linoleic acid—a member of the group of essential fatty acids called omega-6 fatty acids—is an essential dietary requirement for humans.[21]

Similar species

Several Suillus species which grow under pines could be confused with S. brevipes. S. granulatus has a longer stem, and distinct raised granules on the stem. S. brevipes is differentiated from S. albidipes by not having a cottony roll of velar tissue (derived from a partial veil) at the margin when young. S. pallidiceps is by distinguished its pale yellow cap color; and S. albivelatus has a veil.[15] S. pungens has a characteristic pungent odor, compared to the mild smell of S. brevipes, and like S. granulatus, has glandular dots on the stem.[17]


S. brevipes appears early in the succession of mycorrhizal fungi during the regrowth of pine after wildfire.

Suillus brevipes is a mycorrhizal fungus, and it develops a close symbiotic association with the roots of various tree species, especially pine. The underground mycelia form a sheath around the tree rootlets, and the fungal hyphae penetrate between the cortical cells of the root, forming ectomycorrhizae. In this way, the fungus can supply the tree with minerals, while the tree reciprocates by supplying carbohydrates created by photosynthesis. In nature, it associates with two- and three-needle pines, especially lodgepole and ponderosa pine. Under controlled laboratory conditions, the fungus has been shown to form ectomycorrhizae with ponderosa, lodgepole,[22] loblolly, eastern white,[23][24] patula,[25] pond,[26] radiata,[27] and red pines.[24] In vitro mycorrhizal associations formed with non-pine species include Pacific madrone, bearberry,[28] western larch, Sitka spruce, and coast Douglas-fir.[29] Fungal growth is inhibited by the presence of high levels of the heavy metals cadmium (350 ppm), lead (200 ppm), and nickel (20 ppm).[30]

During the regrowth of pine trees after disturbance like clearcutting or wildfire, there appears an orderly sequence of mycorrhizal fungi as one species is replaced by another. A study on the ecological succession of ectomycorrhizal fungi in Canadian jack pine forests following wildfire concluded that S. brevipes is a multi-stage fungus. It appears relatively early during tree development; fruit bodies were common in 6-year old tree stands, and the fungus colonized the highest proportion of root tips. The fungus persists throughout the life of the tree, having been found in tree stands that were 41, 65, and 122 years old. There is, however, a relative reduction in the prevalence of the fungus with increasing stand age, which may be attributed to increased competition from other fungi, and a change in habitat brought about by closure of the forest canopy.[31] Generally, S. brevipes responds favorably to silvicultural practices such as thinning and clearcutting. A 1996 study demonstrated that fruit bodies increased in abundance as the severity of disturbance increased.[32] It has been suggested that the thick-walled, wiry rhizomorphs produced by the fungus may serve as an adaptation that helps it to survive and remain viable for a period of time following disturbance.[33]

Habitat and distribution

Suillus brevipes grows singly, scattered, or in groups on the ground in late summer and autumn. A common—and sometimes abundant—mushroom, it occurs over most of North America (including Hawaii[34]),[13] south to Mexico,[35] and north to Canada.[36] This species has been found in Puerto Rico growing under planted Pinus caribaea, where it is thought to have been introduced inadvertently from North Carolina by the USDA Forest Service in 1955.[37][38] Other introductions have also occurred in exotic pine plantations in Argentina, India, New Zealand,[39][40] Japan, and Taiwan.[41]

See also


  1. ^ "Suillus brevipes (Peck) Kuntze 1898". MycoBank. International Mycological Association. Retrieved 2010-09-01.
  2. ^ "Boletus viscosus Vent. 1863". MycoBank. International Mycological Association. Retrieved 2010-09-01.
  3. ^ Peck CH. (1885). "Report of the Botanist (1884)". Annual Report on the New York State Museum of Natural History. 38: 110.
  4. ^ Halling RE. (1983). "Boletes described by Charles C. Frost". Mycologia. 75 (1): 70–92. doi:10.2307/3792925. JSTOR 3792925.
  5. ^ Kuntze O. (1898). Revisio Generum Plantarum (in German). 3. Leipzig: A. Felix. p. 535. Retrieved 2010-09-01.
  6. ^ Murrill WA. (1948). Lloydia. 11: 29. Missing or empty |title= (help)
  7. ^ Kirk PM, Cannon PF, Minter DW, Stalpers JA. (2008). Dictionary of the Fungi (10th ed.). Wallingford, CT: CABI. p. 607. ISBN 0-85199-826-7.CS1 maint: multiple names: authors list (link)
  8. ^ Singer R. (1986). The Agaricales in Modern Taxonomy (4th ed.). Koenigstein, Germany: Koeltz Scientific Books. p. 756. ISBN 3-87429-254-1.
  9. ^ Kretzer A, Li Y, Szaro T, Bruns TD. (1996). "Internal transcribed spacer sequences from 38 recognized species of Suillus sensu lato: Phylogenetic and taxonomic implications". Mycologia. 88 (5): 776–85. doi:10.2307/3760972. JSTOR 3760972.CS1 maint: multiple names: authors list (link)
  10. ^ a b c Evenson VS. (1997). Mushrooms of Colorado and the Southern Rocky Mountains. Boulder, CO: Westcliffe Publishers. p. 158. ISBN 978-1-56579-192-3. Retrieved 2010-09-01.
  11. ^ McKnight VB, McKnight KH. (1987). A Field Guide to Mushrooms, North America. Boston: Houghton Mifflin. p. plate 11. ISBN 0-395-91090-0.
  12. ^ Arora D. (1986). Mushrooms Demystified: a Comprehensive Guide to the Fleshy Fungi. Berkeley, CA: Ten Speed Press. pp. 501–502. ISBN 0-89815-169-4.
  13. ^ a b Miller HR, Miller OK. (2006). North American Mushrooms: a Field Guide to Edible and Inedible Fungi. Guilford, CT: Falcon Guide. p. 357. ISBN 0-7627-3109-5. Retrieved 2010-09-01.
  14. ^ Healy RA, Huffman DR, Tiffany LH, Knaphaus G. (2008). Mushrooms and Other Fungi of the Midcontinental United States (Bur Oak Guide). Iowa City, IA: University of Iowa Press. p. 171. ISBN 1-58729-627-6. Retrieved 2009-09-17.CS1 maint: multiple names: authors list (link)
  15. ^ a b c d Tylukti EE. (1987). Mushrooms of Idaho and the Pacific Northwest. Vol. 2. Non-gilled Hymenomycetes. Moscow, ID: The University of Idaho Press. ISBN 0-89301-097-9.
  16. ^ a b Grund DW, Harrison AK. (1976). Nova Scotian Boletes. Lehre, Germany: J. Cramer. pp. 176–78. ISBN 3-7682-1062-6.
  17. ^ a b c Orr DB, Orr RT. (1979). Mushrooms of Western North America. Berkeley, CA: University of California Press. pp. 88–90. ISBN 0-520-03656-5.
  18. ^ Weber NS, Smith AH. (1980). The Mushroom Hunter's Field Guide. Ann Arbor, MI: University of Michigan Press. p. 98. ISBN 0-472-85610-3. Retrieved 2010-09-01.
  19. ^ Mattson DJ, Podruzny SR, Haroldson MA. (2002). "Consumption of fungal sporocarps by Yellowstone Grizzly Bears" (PDF). Ursus. 13: 95–103.CS1 maint: multiple names: authors list (link)
  20. ^ Sumner JL. (1973). "The fatty acid composition of Basidiomycetes". New Zealand Journal of Botany. 11: 435–42.
  21. ^ Russo GL. (2009). "Dietary n-6 and n-3 polyunsaturated fatty acids: from biochemistry to clinical implications in cardiovascular prevention". Biochemical Pharmacology. 77 (6): 937–46. doi:10.1016/j.bcp.2008.10.020. PMID 19022225.
  22. ^ Grand LF. (1968). "Conifer associated and mycorrhizal syntheses of some Pacific Northwest Suillus species". Forest Science. 14 (3): 304–12.
  23. ^ Doak KB. (1934). "Fungi that produce ectotrophic mycorrhizae". Phytopathology. 24: 7.
  24. ^ a b Palm ME, Stewart EL. (1984). "In vitro synthesis of mycorrhizae between presumed specific and nonspecific Pinus + Suillus combinations". Mycologia. 76 (4): 579–600. doi:10.2307/3793215. JSTOR 3793215.
  25. ^ Mohan V, Natarajan K, Ingleby K. (1993). "Anatomical studies on ectomycorrhizas .2. The ectomycorrhizas produced by Amanita muscaria, Laccaria laccata and Suillus brevipes on Pinus patula". Mycorrhiza. 3 (1): 43–49. ISSN 0940-6360.CS1 maint: multiple names: authors list (link)
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  28. ^ Molina R, Trappe JM. (1982). "Lack of mycorrhizal specificity by the ericaceous hosts Arbutus menzeniesii and Arctostaphylos uva-ursi". New Phytologist. 90: 495–509. doi:10.1111/j.1469-8137.1982.tb04482.x.
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  30. ^ McCreight JD, Schroeder DB. (1982). "Inhibition of growth of nine ectomycorrhizal fungi by cadmium, lead, and nickel in vitro". Environmental and Experimental Botany. 60 (9): 1601–5.
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  32. ^ Kropp BR, Albee S. (1996). "The effects of silvicultural treatments on occurrence of mycorrhizal sporocarps in a Pinus contorta forest: A preliminary study". Biological conservation. 78 (3): 313–18. doi:10.1016/S0006-3207(96)00140-1.
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  34. ^ Hemmes DE, Desjardin D. (2002). Mushrooms of Hawai'i: An Identification Guide. Berkeley, CA: Ten Speed Press. p. 31. ISBN 1-58008-339-0. Retrieved 2009-09-17.
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  38. ^ Vozzo JA. (1971). "Field inoculations with mycorrhizal fungi". In Hacskaylo E (ed.). Mycorrhizae, proceedings of the first North American conference on mycorrhizae. April 1969. Forest Service Misc. Publication 1189. US Department of Agriculture. pp. 187–96.
  39. ^ Read DJ. (2000). "The mycorrhizal status of Pinus". In Richardson DM (ed.). Ecology and Biogeography of Pinus. Cambridge, UK: Cambridge University Press. p. 333. ISBN 978-0-521-78910-3. Retrieved 2009-09-17.
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