Stachybotrys Explained

Stachybotrys is a genus of molds, hyphomycetes or asexually reproducing, filamentous fungi, now placed in the family Stachybotryaceae. The genus was erected by August Carl Joseph Corda in 1837. Historically, it was considered closely related to the genus Memnoniella,^[1] ^[2] because the spores are produced in slimy heads rather than in dry chains. Recently, the synonymy of the two genera is generally accepted.^[3] Most Stachybotrys species inhabit materials rich in cellulose. The genus has a widespread distribution and contained about 50 species in 2008.^[4] There are 88 records of Stachybotrys on Species Fungorum (in 2023), of which 33 species have DNA sequence data in GenBank. Species in the genus are commonly found in soil, plant litter (hay, straw, cereal grains, and decaying plant debris) and air and a few species have been found from damp paper, cotton, linen, cellulose-based building materials water-damaged indoor buildings, and air ducts from both aquatic and terrestrial habitats (Izabel et al. 2010;^[5] Lombard et al. 2016;^[6] Hyde et al. 2020a).^[7]

The name of Stachybotrys is derived from the Greek words σταχυς stakhus (ear of grain, stalk, stick; metaphorically, progeny) and βότρυς botrus (cluster or bunch as in grapes, trusses).

The most infamous species, Stachybotrys chartarum (previously known as Stachybotrys atra) and Stachybotrys chlorohalonata, are known as black mold or toxic black mold in the U.S., and are frequently associated with poor indoor air quality that arises after fungal growth on water-damaged building materials.^[8] Stachybotrys chemotypes are toxic, with one producing trichothecene mycotoxins including satratoxins, and another that produces atranones.^[9] However, the association of Stachybotrys mold with specific health conditions is not well proven and there exists a debate within the scientific community.^[10] ^[11] ^[12]

Conidia

Conidia are in slimy masses, smooth to coarsely rough, dark olivaceous to brownish black, obovoid, later becoming ellipsoid with age, 10–13 × 5–7 mm. Phialides are obovate or ellipsoidal, colorless early then turning to olivaceous with maturity, smooth, 12–14 × 5–7 mm, in clusters of 5 to 9 phialides. Conidiophores are simple, erect, smooth to rough, colorless to olivaceous, slightly enlarged apically, mostly unbranched but occasionally branched. Conidia of Stachybotrys are very characteristic and can be confidently identified in spore count samples. This genus is closely related to Memnoniella. Species of Memnoniella may occasionally develop Stachybotrys-like conidia, and vice versa.

Detection

Four distinctive microbial volatile organic compounds (MVOCs) – 1-butanol, 3-methyl-1-butanol, 3-methyl-2-butanol, and thujopsene – were detected on rice cultures, and only one (1-butanol) was detected on gypsum board cultures.^[13]

Pathogenicity

Symptoms of Stachybotrys exposure in humans

A controversy began in the early 1990s after analysis of two infant deaths and multiple cases in children from the poor areas of Cleveland, Ohio, United States, due to pulmonary hemorrhage were initially linked to exposure to heavy amounts of Stachybotrys chartarum. Subsequent and extensive reanalysis of the cases by the United States Centers for Disease Control and Prevention have failed to find any link between the deaths and the mold exposure.^[14] ^[15]

Species

As accepted by Species Fungorum (as of July 2023);^[16]

Stachybotrys aksuensis
Stachybotrys aloicola L. Lombard & Crous (2014)
Stachybotrys alternans Bonord. (1851)
Stachybotrys aurantius
Stachybotrys bambusicola
Stachybotrys biformis
Stachybotrys bisbyi
Stachybotrys breviuscula McKenzie (1991)
Stachybotrys chartarum (Ehrenb.) S. Hughes (1958)
Stachybotrys chlorohalonatus B. Andersen & Thrane (2003)
Stachybotrys clitoriae
Stachybotrys cordylines
Stachybotrys cylindrospora C.N. Jensen (1912)
Stachybotrys dakotensis
Stachybotrys dolichophialis L. Lombard & Crous (2016)
Stachybotrys echinatus
Stachybotrys elasticae
Stachybotrys freycinetiae McKenzie (1991)
Stachybotrys frondicola (K.D. Hyde, Goh, Joanne E. Taylor & J. Fröhl.) Yong Wang bis, K.D. Hyde, McKenzie, Y.L. Jiang & D.W. Li (2015)
Stachybotrys gamsii (K.D. Hyde, Goh, Joanne E. Taylor & J. Fröhl.) Yong Wang bis, K.D. Hyde, McKenzie, Y.L. Jiang & D.W. Li (2015)
Stachybotrys globosus
Stachybotrys guttulisporus
Stachybotrys havanensis
Stachybotrys humilis
Stachybotrys indicoides
Stachybotrys indicus
Stachybotrys jiangziensis
Stachybotrys kampalensis Hansf. (1943)
Stachybotrys kapiti Whitton, McKenzie & K.D. Hyde (2001)
Stachybotrys klebahnii
Stachybotrys leprosus
Stachybotrys levisporus
Stachybotrys limonisporus
Stachybotrys littoralis
Stachybotrys longistipitatus (D.W. Li, Chin S. Yang, Vesper & Haugland) D.W. Li, Chin S. Yang, Vesper & Haugland (2015)
Stachybotrys lunzinensis
Stachybotrys mangiferae P.C. Misra & S.K. Srivast. (1982)
Stachybotrys mexicanus J. Mena & Heredia (2009); Stachybotryaceae
Stachybotrys microspora (B.L. Mathur & Sankhla) S.C. Jong & E.E. Davis (1976)
Stachybotrys mohanramii
Stachybotrys musae
Stachybotrys nepalensis
Stachybotrys nephrodes McKenzie (1991)
Stachybotrys nephrospora Hansf. (1943)
Stachybotrys nielamuensis Y.M. Wu & T.Y. Zhang (2009)
Stachybotrys oenanthes M.B. Ellis (1971)
Stachybotrys pallescens
Stachybotrys pallidus
Stachybotrys palmae
Stachybotrys palmicola
Stachybotrys palmijunci
Stachybotrys parvisporus S. Hughes (1952)
Stachybotrys parvus
Stachybotrys proliferatus
Stachybotrys punctatus
Stachybotrys queenslandicus
Stachybotrys ramosus
Stachybotrys reniformis
Stachybotrys renisporoides
Stachybotrys renisporus
Stachybotrys reniverrucosus
Stachybotrys ruwenzoriensis Matsush. (1985)
Stachybotrys sacchari
Stachybotrys sansevieriae G.P. Agarwal & N.D. Sharma (1974)
Stachybotrys sinuatophorus Matsush. (1971)
Stachybotrys socia
Stachybotrys sphaerosporus
Stachybotrys stilboideus
Stachybotrys subcylindrosporus
Stachybotrys subreniformis
Stachybotrys subsylvaticus
Stachybotrys suthepensis Photita, P. Lumyong, K.D. Hyde & McKenzie (2003)
Stachybotrys taiwanensis
Stachybotrys terrestris
Stachybotrys thaxteri
Stachybotrys theobromae Hansf. (1943)
Stachybotrys variabilis
Stachybotrys verrucisporus
Stachybotrys verrucosus
Stachybotrys virgatus
Stachybotrys voglinoi
Stachybotrys waitakere Whitton, McKenzie & K.D. Hyde (2001)
Stachybotrys xanthosomatis
Stachybotrys xigazenensis
Stachybotrys yunnanensis
Stachybotrys yushuensis
Stachybotrys zeae
Stachybotrys zhangmuensis
Stachybotrys zingiberis
Stachybotrys zuckii

References

Notes

Further reading

Book: Progovitz, Richard F.. Black Mold: Your Health and Your Home. The Forager Press. 2003. 978-0-9743943-9-8.

External links

Web site: Facts about Stachybotrys chartarum and Other Molds . Centers for Disease Control and Prevention. https://web.archive.org/web/20191101164909/https://www.cdc.gov/mold/stachy.htm. 1 November 2019. live.

Notes and References

Haugland. Richard A.. Vesper. Stephen J.. Harmon. Stephen M.. January–February 2001. Phylogenetic relationships of Memnoniella and Stachybotrys species and evaluation of morphological features for Memnoniella species identification. live. Mycologia. 93. 1. 54–65. 10.2307/3761605 . 3761605 . https://web.archive.org/web/20180719045835/https://zenodo.org/record/1235157/files/article.pdf . 19 July 2018. Zenodo.
Castlebury. Lisa A.. Rossman. Amy Y.. Sung. Gi-Ho. Hyten. Aimee S.. Spatafora. Joseph W.. August 2004. Multigene phylogeny reveals new lineage for Stachybotrys chartarum, the indoor air fungus. live. Mycological Research. 108. 8. 864–72. 10.1017/S0953756204000607 . 15449591 . https://web.archive.org/web/20191103022731/http://cordyceps.us/files/Castlebury_etal_2004.pdf . 3 November 2019.
Book: The Genera of Hyphomycetes. Seifert. Keith A.. Gams. Gareth. Morgan-Jones. Walter. Kendrick. Bryce. CBS Fungal Biodiversity Centre. 2011. 978-90-70351-85-4. CBS Biodiversity Series. Utrecht, the Netherlands. 1–997. 1571-8859.
Book: Dictionary of the Fungi. CABI. 2008. 978-0-85199-826-8. Paul M.. Kirk. 10th. Wallingford. 659. 2009285939. Cannon. Paul F.. Minter. David W.. Stalpers. Joost A..
Izabel . T.D.S.S. . Cruz . A.C.R.D. . Barbosa . F.R. . Ferreira . S.M.L. . Marques . M.F.O. . Gusmão . L.F.P. . The genus Stachybotrys anamorphic fungi) in the semi-arid region of Brazil. . Rev. Bras. Bot. . 2010 . 33 . 3 . 479–487. 10.1590/S0100-84042010000300010 . free .
Lombard . L. . Houbraken . J. . Decock . C. . Samson . R.A. . Meijer . M. . Réblová . M. . Groenewald . J.Z. . Crous . P.W. . Generic hyper-diversity in Stachybotriaceae. . Persoonia – Molecular Phylogeny and Evolution of Fungi . 2016 . 36 . 1 . 156–246. 10.3767/003158516X691582 . 27616791 . 4988370 .
Hyde . Kevin D. . Norphanphoun . C. . Maharachchikumbura . S.S.N. . Bhat . D.J. . Jones . E.B.G. . Bundhun . D. . Chen . Y.J. . Bao . D.F. . Boonmee . S. . Calabon . M.S. . Chaiwan . N. . Chethana . K.W.T. . Dai . D.Q. . Dayarathne . M.C. . Devadatha . B. . Dissanayake . A.J. . Dissanayake . L.S. . Doilom . M. . Dong . W. . Fan . X.L. . Goonasekara . I.D. . Hongsanan . S. . Huang . S.K. . Jayawardena . R.S. . Jeewon . R. . Karunarathna . A. . Konta . S. . Kumar . V. . Lin . C.G. . Liu . J.K. . Liu . N.G. . Luangsa-ard . J. . Lumyong . S. . Luo . Z.L. . Marasinghe . D.S. . McKenzie . E.H.C. . Niego . A.G.T. . Niranjan . M. . Perera . R.H. . Phukhamsakda . C. . Rathnayaka . A.R. . Samarakoon . M.C. . Samarakoon . S.M.B.C. . Sarma . V.V. . Senanayake . I.C. . Shang . Q.J. . Stadler . M. . Tibpromma . S. . Wanasinghe . D.N. . Wei . D.P. . Wijayawardene . N.N. . Xiao . Y.P. . Yang . J. . Zeng . X.Y. . Zhang . S.N. . Xiang . M.M. . Refined families of Sordariomycetes. . Mycosphere . 2020 . 11 . 305–1059 . 10.5943/mycosphere/11/1/7. 219808477 . 10033/622756 . free .
Nielsen. Kristian Fog. July 2003. Mycotoxin production by indoor molds. live. Fungal Genetics and Biology. 39. 2. 103–17. 10.1016/S1087-1845(03)00026-4. 12781669. https://web.archive.org/web/20170410001452/https://realtimelab.com/wp-content/uploads/2016/03/11.-Mycotoxin-production-by-indoor-molds.pdf. 10 April 2017.
Andersen. Birgitte. Nielsen. Kristian F.. Thrane. Ulf. Szaro. Tim. Taylor. John W.. Jarvis. Bruce B.. 2003. Molecular and phenotypic descriptions of Stachybotrys chlorohalonata sp. nov. and two chemotypes of Stachybotrys chartarum found in water-damaged buildings. live. Mycologia. 95. 6. 1227–38. 10.1080/15572536.2004.11833031. 21149024. 203881222. https://web.archive.org/web/20180917071455/https://nature.berkeley.edu/brunslab/papers/andersen2003.pdf. 17 September 2018. the University of California Berkeley.
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The Myth of Mycotoxins and Mold Injury. 31608429. 2019. Chang. C.. Gershwin. M. E.. Clinical Reviews in Allergy & Immunology. 57. 3. 449–455. 10.1007/s12016-019-08767-4. 204458646.
Web site: You Can Control Mold | CDC. 17 May 2021.
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Web site: Case Definition for Acute Idiopathic Pulmonary Hemorrhage in Infants. National Center for Environmental Health. live. https://web.archive.org/web/20011115003239/https://www.cdc.gov/nceh/asthma/acute/AIPHIcasedef.htm. 15 November 2001.
Centers for Disease Control and Prevention. Centers for Disease Control and Prevention. 10 March 2000. Update: Pulmonary Hemorrhage/Hemosiderosis Among Infants — Cleveland, Ohio, 1993–1996. live. Morbidity and Mortality Weekly Report. 49. 9. 180–4. 11795499. https://web.archive.org/web/20160520232605/https://www.cdc.gov/mmwr/preview/mmwrhtml/mm4909a3.htm. 20 May 2016.
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