Thielavia terricola

Pseudothielavia terricola is a fungal species of the phylum Ascomycota, order Chaetomiaceae, and genus Pseudothielavia. Pseudothielavia terricola is widely distributed, especially in the tropical region of the world - with documented appearances in Africa, Southern Europe, and Asia.[1] The species is mainly found in soil, but can also be found on other materials such as animal dung.[1]. The species was first assigned to the genus Coniothyrium in 1927, but was soon re-assigned to the genus Thielavia which endured for almost 90 years.[2] Recently, through intensive phylogenetic research and reassessment, the species was designated to a brand new genus, Pseudothielavia; The etymology of Pseudothielavia means similar to the genus Thielavia - the high resemblance was what contributed to the species assignment to the genus Thielavia 9 decades ago.[3] The fungus is mesophilic, grows abundantly in a pH level between 3.9-6, and is able to utilize multiple carbohydrates to support its growth.[1] Mature Pseudothielavia terricola colonies in culture is dark brown in colour and spread out.[1][2] Pseudothielavia terricola synthesizes a variety of compounds, two of which are Thielavin A & B. Thielavin A & B were determined to be strong inhibitors of prostaglandin synthesis which subsequently boasts the species' clinical research value in prostaglandin dysregulation.[4]

Pseudothielavia terricola
Scientific classification
Kingdom:
Division:
Subdivision:
Class:
Order:
Genus:
Pseudothielavia
Species:
P. terricola
Binomial name
Pseudothielavia terricola
(J.C. Gilman & E.V. Abbott) X. Wei Wang & Houbraken (2019)
Synonyms
  • Thielavia terricola C.W. Emmons (1930) *Anixiopsis japonicaK.Saito & K.Minoura (1948)*Coniothyrium terricola J.C.Gilman & E.V.Abbott (1927)

History and taxonomy

The present species was first isolated in culture and described by J.C.Gilman and E.V.Abbott of the Department of Dermatology of the College of Physicians and Surgeons of Columbia University from soil in 192.7.[2] The isolated culture was kept at the Dermatology department of the university under the label Coniothyrium terricola Gilman and Abbott, No. 172.2[2] The soil sample of which the fungi was isolated came from the American Type Culture Collection; With soil obtained from Iowa, USA.[2] The species - first designated in the genus Coniothyrium - was soon determined to belong to the genus Thielavia by Chester W. Emmons in 1930; When the crushed culture mounts of the species was shown to Dr. B.O.Dodge of the New York Botanical Garden - which recognized the fungi as a species he isolated long time ago under the label 'Thielavia n.sp.'[2] Emmons took the culture of Dr.Dodge, germinated the ascospores in new media, and compared it to culture no.1722; The two cultures displayed identical growth and morphological features - which contributed to the species' assignment of the genus Thielavia in 1930.[2] In 2019, a new study was published by Xincun Wang and his team at the Westerdijk Fungal Biodiversity Institute which phylogenetically reassesed all members of the genus Thielavia through genetic sequencing.[3] In the newly published study, the fungus Thielavia terricola was reassigned a new genus - Pseudothielavia.[3] Currently, the name Pseudothielavia terricola holds the binomial authority of the fungi, while Coniothyrium terricola as well as Thielavia terricola are now considered as holotypes or synonyms of the species.[5]

The genus Coniothyrium and Thielavia may have been assigned to Pseudothielavia terricola due to similar defining characteristics that highly resmbles the fungi. Coniothyrium in the broad sense. is defined to be unicellular, smooth thin cell wall, pale-brown conidium, and a pycnidia structure with globose cavity.[1][2] Thielavia, on the other hand, is defined to have a non-ostiolate, glabose, setose ascomata, a brown thin cell wall, ellipsoidal to clavate asci, and unicellular, brown, single-germ pored ascospores[1][2] As will be demonstrated in the subsequent Growth and morphology section, defining characteristics of Coniothyrium coincides partially with Pseudothielavia terricola while defining characteristics of Thielavia fits Pseudothielavia terricola almost perfectly.[1][2] However, following the recent phylogenetic re-assessment of the genus Thielavia, Wang and his team discovered that, Pseudothielavia terricola, although morphologically similar to the genus thielavia, should not be assigned to Thielavia sensu stricto due to genetic and subtle morphological differences.[3] Thus, Wang and his team assigned a new genus - Pseudothielavia (Mycobank: MB829872[5])- to species that closely resembles the genus Thielavia but is genetically and morphologically distinct from the genus, which includes Pseudothielavia terricola[3]

Growth and morphology

Pseudothielavia terricola is a mesophilic fungus, with an optimal growth temperature of 37°C, a minimum growing temperature of 15°C and a highest of 46°C.[1][2] Acidity and basicity also contribute greatly to the proper growth of the species, the fungi grows most well in a pH range between 3.9 - 6, and terminates growth in environment with a pH higher than 7.9 or lower than 2.9.[1] As for nutrition, the species is capable of breaking down various types of carbohydrates - such as chitin, cellulose, and poly-/tri-/di-/monosaccharides -, alcohol, nitrate, ammonium, and nitrogen-containing compounds to support its growth.[1]

Mophologically, colonies grown on corn meal agar, malt extract agar, and oatmeal agar at 28°C display a well spread out uniform white mat in 14 days.[1] The colour of the colonies then darkens as time goes on, changing from white to brown to black - the color of maturity.[1][2][6] The black color is largely due to the dark-coloured spores that form as the fungi matures.[1][2][6] Ascomata of the fungi is a submerged globose cleistothecia color dark brown and is usually 60-200 μm in diameter[1][2][6] The ascomata of the fungi is encased with a brown, semi-transparent, pseudoparenchymatous, double membraned textura epidermoidea - thin and tightly packed peridium.[1][2][6] The peridium is also smooth walled and not bristly.[1][2] Inside the ascomata, the shape of the spore bearing asci of the fungi can range from pyriform to ovate to clavate to ellipsoidal[1][2][6] The asci of the fungi are also always 8-spored, and evanescent - disintegrating varying in size from 24x14 μm to 40-20μm[1][2] The Ascospores of the fungi are unicellular, brown-dark green in colour, and ellipsoidal. The ascospores of the fungi are also observed to only have germ pores at 1 end, with the other end being truncated.[1][2][6] The dimension of the ascospores range from 9x5 - 16x9 μm. The species present no anamorphic or asexual form.[1][2][6]

Physiology

In addition to the species' ability to metabolize various carbohydrates and other chemical compounds for its growth as previously mentioned; Pseudothielavia terricola also produce bioactive compounds that possess great clinical research value.[4] Thielavin A (C31H34O10)and B (C29H30O10) are two compounds that was isolated from Pseudothielavia terricola culture.[4] These two compounds were shown to be structurally similar to depsides - which consists of three hydroxybenzoic acid groups[4] Additionally, the melting point for the two compound was determined to be 235-236°C and 250°C respectively; They are insoluble in water but soluble in multiple organic solvents including methanol, ethanol, acetone, chloroform, and pyridine.[4] In a study published in 1981, Thielavin A and B were demonstrated to be novel inhibitors of Prostaglandin synthesis, targeting arachidonic acid - prostaglandin H2 conversion and prostaglandin H2-prostaglandin E2 conversion respectively.[4] Overproduction of prostaglandin in the human body has been linked to body pain, fever, inflammation and diarrhea, painful menstruation, arthritis, even certain forms of cancer. The discovery of Thielavin A and B in pseudothielavia terricola could prove useful in the field of clinical research targeting patients with prostaglandin dysregulation.[4]

Habitat and ecology

The fungi is a cosmopolitan species and is mainly found in soil, fecal matter, plant seeds, and roots of decaying plant.[1][2] The distribution of the species is noted to concentrate along the tropical region, with documented appearance in multiple parts of Africa - such as Sudan, Sierra Leone,and Nigeria -, Kuwait, Pakistan, India, Nepal, New Guinea, Japan and et cetera.[1] Distribution in regions distant from the tropics are also present, countries such as the Netherlands, Britain, and the United States also have been reported to show the presence of this species[1] In terms of habitat, the fungi have been reported to grow on a variety of soils. To list a few, the species have been found in forest soils, grassland, grass plots with Dichanthium annulatum, rice fields, and saline soil.[1] In addition, the species has been isolated from other miscellaneous material of plant and animal origin.[1] The species has been found on materials such as decaying strawberry plant, decaying Cordia dichotoma fruit, rhinoplane of barley, seeds of wheat and groundnuts, cotton, kernels of Arachis hypogaea, and the dung of various animals (Monkey, sheep, cow, elephant).[1]

gollark: > Chemotherapy is in simple terms killing cancer with radiation<@224206995257950220> No, that would be radiotherapy.
gollark: Chemotherapy is an entirely different thing too.
gollark: * highest energy per photon, intensity is different
gollark: From *IR*?
gollark: Probably.

References

  1. Domsch, K.H.; Gams, Walter; Andersen, Traute-heidi (1980). Compendium of soil fungi (2 ed.). London, UK: Academic Press. ISBN 9780122204029.
  2. Emmons, Chester W. (1930). "Coniothyrium terricola proves to a species of Thielavia". Bulletin of the Torrey Botanical Club. 57 (2): 123–126. doi:10.2307/2480593. JSTOR 2480593.
  3. Wang, X.Y.; Jos, Houbraken (2019). "Phylogenetic re-evaluation of Thielavia with the introduction of a new family Podisporeaceae". Studies in Mycology. 93: 155–252. doi:10.1016/j.simyco.2019.08.002. PMID 31824584.
  4. Kitahara, Nobuaki; Endo, Akira; Furuya, Kohei; Takahashi, Shuji (1981). "Thielavin A and B, New inhibitors of prostaglandin biosynthesis produced by Thielavia terricola". The Journal of Antibiotics. 34 (12): 1562–1568. doi:10.7164/antibiotics.34.1562. PMID 7333968.
  5. "Pseudothielavia terricola". Mycobank. Retrieved 7 December 2019.
  6. Watanabe, Tsuneo (2009). Pictorial Atlas of Soil and Seed Fungi: Morphologies of Cultured Fungi and Key to Species (3 ed.). Boca Raton, FL.: CRC. pp. 109–134. ISBN 978-1439804193.
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