Tuckermannopsis ciliaris
Tuckermannopsis ciliaris | |
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Scientific classification | |
Domain: | Eukaryota |
Kingdom: | Fungi |
Division: | Ascomycota |
Class: | Lecanoromycetes |
Order: | Lecanorales |
Family: | Parmeliaceae |
Genus: | Tuckermannopsis |
Species: | T. ciliaris
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Binomial name | |
Tuckermannopsis ciliaris | |
Synonyms[1] | |
Tuckermannopsis ciliaris is a species of corticolous (bark-dwelling), foliose lichen in the family Parmeliaceae.[2] It was first described by Erik Acharius in 1810, initially classified in the genus Cetraria.The species was later reclassified into the genera Nephromopsis and then Tuckermannopsis, with some researchers proposing that certain cetrarioid genera, including Tuckermannopsis, should be merged into Nephromopsis. However, this suggestion was disputed, and both names, Tuckermannopsis ciliaris and Nephromopsis ciliaris, are used in recent literature to refer to this species.
Tuckermannopsis ciliaris is widely distributed across North America and the Old World, found on coniferous trees such as pines and birches, with varying frequencies and habitats across different regions. The thallus grows in irregular shapes or rosettes up to 5 cm (2 in) in diameter, with olive-green to greenish-brown coloration and elongated lobes featuring black, hair-like cilia along their edges. Both apothecia (sexual fruiting bodies) and pycnidia (asexual fruiting bodies) also occur along the edges of the lobes.
The chemical properties of T. ciliaris include the presence of olivetoric and physodic acids in the medulla. Chemical spot tests for these lichen products can help distinguish T. ciliaris from several similar species.
Taxonomy
[edit]The lichen was formally described in 1810 by the Swedish lichenologist Erik Acharius, who initially classified it in Cetraria, the namesake genus of the cetrarioid lichens. Cetrarioid lichens are characterised by erect, foliose thalli, and apothecia and pycnidia on the margins of the lobes. In his original description, Acharius summarised the main characteristics of the new species, noting the thallus as pale brownish with a whitish, reticulated-lacunose underside. He described the lobes as crisped and ciliate, with margins adorned by thick, black cilia or granules. The thallus was cartilaginous and became more reticulated-lacunose with age. The apothecia were slightly elevated and dark brownish, with a raised, crenate margin. He highlighted that Cetraria ciliaris resembled the variety ulophylla of Cetraria sepincola but was much larger and more solid.[3]
In 1899, Auguste-Marie Hue proposed putting the species in genus Nephromopsis.[4] Christian August Frege thought it was more appropriate in the genus Platysma, and moved it there in an 1812 publication.[5] Vilmos Kőfaragó-Gyelnik transferred the taxon to the genus Tuckermannopsis in 1933.[6]
In 1963, Mason Hale identified three chemical strains within the Cetraria ciliaris group in North America, distinguished by their production of alectoronic acid, olivetoric acid, and protolichesteric acid. This study emphasised the importance of chemical characteristics in distinguishing morphologically identical species and laid the groundwork for further chemical taxonomy in this group of lichens.[7] Building on this, a study by William and Chicita Culberson in 1967 on the Cetraria ciliaris species complex identified several species within the group, each distinguished by its unique chemical composition and geographic distribution. The study revealed that Cetraria ciliaris produces olivetoric and physodic acids and is found in eastern North America and Finland. The species is morphologically similar to Cetraria halei, which produces alectoronic acid and has a broader geographic distribution, including the Old World from Finland through the Soviet Union to Japan. Despite the morphological similarities, these species are chemically distinct and occupy slightly different ecological niches. A key aspect of the study was the finding that environmental factors do not significantly influence the chemical composition of these lichens. Instead, the chemical profiles are genetically determined, underscoring the importance of chemical characteristics in lichen taxonomy.[8]
Using a "temporal phylogenetic" approach to study the evolution of the Parmeliaceae, researchers proposed that certain genera, including Tuckermannopsis, should be merged with Nephromopsis.[9] However, this suggestion was later disputed,[10] and the change in classification has not been universally accepted, particularly by some North American lichenologists.[11] Consequently, both names, Tuckermannopsis ciliaris and Nephromopsis ciliaris, have been used in recent literature to refer to this species.
Description
[edit]Tuckermannopsis ciliaris is a foliose lichen that typically forms loosely attached, irregular to rosette-shaped growths, reaching up to about 8 cm (3 in) in diameter.[12][13] Its colour ranges from olive-green to greenish-brown.[14] The lobes comprising the thallus (the main body of the lichen) are elongated and range from 1 to 4 mm in width, with a slightly wrinkled surface. These lobes often have scattered, long, black, hair-like structures called cilia along their edges;[12] the cilia are simple (unbranched), and measure up to 7 long.[15] The upper surface of the thallus varies in color from pale to dark greenish-brown, and it lacks pseudocyphellae, which are tiny pores sometimes found in lichens.[12] The medulla is white.[15]
The lower surface of the thallus ranges in color from brown to blackish and has a somewhat wrinkled texture.[12] There are simple brown rhizines (small, rootlike structures) in the central part of the thallus that measure 1.5–3 long.[15] The reproductive structures of the lichen, the apothecia, are found along the edges and sides of the lobes and can grow up to 3 mm in diameter. These apothecia produce spores that are roughly spherical and measure 4 to 5 μm in both length and width.[12]
Additionally, Tuckermannopsis ciliaris has small, black, protruding structures along the margins called pycnidia, which produce conidia (asexual spores). The conidia are dumbbell-shaped and measure approximately 5 μm in length and 1 μm in width.[12]
Chemistry
[edit]The expected results of standard chemical spot tests for Tuckermannopsis ciliaris are K−, C−, KC+ (reddish), and P− in the medulla;[15] all spot tests are negative on the cortex.[14] The species produces olivetoric and physodic acids in the medulla and atranorin in the cortex. The joint occurrence of olivetoric acid and its corresponding depsidone, physodic acid, was the first known example of such a relationship, supporting the theory of the origin of depsidones from depsides.[8]
Similar species
[edit]Tuckermannopsis ciliaris can be easily confused with some other species due to its morphology and presence of cilia. One such species is Nephromopsis ahtii, which shares a similar appearance and the presence of cilia. However, Tuckermannopsis ciliaris can be distinguished by the presence of atranorin and olivetoric acids as secondary metabolites.[15]
Another species that resembles Tuckermannopsis ciliaris is Nephromopsis chlorophylla. While it has a similar thallus colour and size, it lacks cilia and contains protolichesterinic acid in its thallus, which sets it apart from Tuckermannopsis ciliaris.[15] Two other potential lookalikes, Tuckermannopsis orbata and Tuckermannopsis fendleri, can be distinguished from T. ciliaris by their C− medulla.[14]
Tuckermannopsis americana is an alectoronic acid-α-collatolic acid chemotype of T. ciliaris. It is usually treated as a distinct species,[16][17] although some sources treat the two species as one.[12][13] Tuckermannopsis americana is C− in the medulla, but shows a positive UV+ (bluish-white) reaction because of the alectoronic acid.[17]
Habitat and distribution
[edit]Tuckermannopsis ciliaris is distributed across a wide range of regions. In North America, it is found from southeastern Canada to the Lake States and south throughout the Appalachian Mountains and associated foothills.[8] It is generally common in appropriate habitats in northern North America, except for the Great Plains region.[14] In the Old World, it is distributed from Finland through Russia to Japan.[8] In Finland, it is considered rare or possibly extinct, and has a conservation status of "regionally extinct" in the Finnish red list.[13] It was reported as new to India in 2022, where it is considered rare.[15] The species typically grows on the trunks and branches of pines and other conifers.[8] In the Nordic countries, it has only been recorded growing on birch bark.[12]
Uses
[edit]Tuckermannopsis ciliaris is an auxiliary component of a hair tint that was patented in Korea in 2004.[18][19]
References
[edit]- ^ "GSD Species Synonymy. Current Name: Tuckermannopsis ciliaris (Ach.) Gyeln., Acta Faun. Fl. Univers., Ser. 2, Bot. 1(nos 5-6): 6 (1933)". Species Fungorum. Retrieved 13 June 2024.
- ^ "Tuckermannopsis ciliaris (Ach.) Gyeln". Catalogue of Life. Species 2000: Leiden, the Netherlands. Retrieved 13 June 2024.
- ^ Acharius, E. (1810). Lichenographia Universalis (in Latin). Gottingen: Justus Friedrich Danckwerts. p. 508.
- ^ Hue, A.-M. (1899). "Lichenes extra-Europaei". Nouvelles archives du Muséum d'histoire naturelle, Paris. 1 (in Latin). 4: 216.
- ^ C.A., Frege (1812). Deutsches Botanisches Taschenbuch, für Liebhaber der deutschen Pflanzenkunde [German Botanical Handbook, for Enthusiasts of German Botany] (in German). Vol. 2. Zeitz: Wilhelm Webel. p. 162. doi:10.3931/e-rara-62931.
- ^ Gyelnik, V. (1933). "Lichenes varii novi critique". Acta Pro Fauna et Flora Universalis Botanici (Bucuresti). 2. 1 (5–6): 3–10.
- ^ Hale, Mason E. (1963). "Populations of chemical strains in the lichen Cetraria ciliaris". Brittonia. 15 (2): 126–133. Bibcode:1963Britt..15..126H. doi:10.2307/2805398. JSTOR 2805398.
- ^ a b c d e Culberson, William Louis; Culberson, Chicita F. (1967). "A new taxonomy for the Cetraria ciliaris group". The Bryologist. 70 (2): 158–166. doi:10.2307/3240940. JSTOR 3240940.
- ^ Divakar, Pradeep K.; Crespo, Ana; Kraichak, Ekaphan; Leavitt, Steven D.; Singh, Garima; Schmitt, Imke; Lumbsch, H. Thorsten (2017). "Using a temporal phylogenetic method to harmonize family- and genus-level classification in the largest clade of lichen-forming fungi". Fungal Diversity. 84: 101–117. doi:10.1007/s13225-017-0379-z.
- ^ Lücking, Robert (2019). "Stop the abuse of time! Strict temporal banding is not the future of rank-based classifications in Fungi (including lichens) and other organisms". Critical Reviews in Plant Sciences. 38 (3): 199–253. Bibcode:2019CRvPS..38..199L. doi:10.1080/07352689.2019.1650517.
- ^ McCune, Bruce; Geiser, Linda (2023). Macrolichens of the Pacific Northwest (3 ed.). Corvallis: Oregon State University Press. p. 98. ISBN 978-0-87071-251-7.
- ^ a b c d e f g h Thell, A.; Thor, G.; Ahti, T. (2011). "Parmelia". In Thell, Arne; Moberg, Roland (eds.). Nordic Lichen Flora. Vol. 4. Svenska Botaniska Föreningen. pp. 83–89. ISBN 978-91-85221-24-0.
- ^ a b c Stenroos, Soili; Ahti, Teuovo; Lohtander, Katileena; Myllys, Leena (2011). Suomen jäkäläopas [Finnish Lichen Guide] (in Finnish). Helsinki: Kasvimuseo, Luonnontieteellinen keskusmuseo. p. 453. ISBN 978-952-10-6804-1. OCLC 767578333.
- ^ a b c d Tripp, Erin A.; Lendemer, James C. (2020). Field Guide to the Lichens of Great Smoky Mountains National Park. Knoxville: The University of Tennessee Press. pp. 444–445. ISBN 978-1-62190-514-1.
- ^ a b c d e f g Mishra, Gaurav K.; Nayaka, Sanjeeva; Upreti, Dalip K.; Kondratyuk, Sergii Y.; Thell, Arne; Kärnefelt, Ingvar (2022). "Cetrarioid lichens from India revised, including Nephromopsis awasthii sp. nov. and new records". Mycotaxon. 137 (2): 283–334 [310–311]. doi:10.5248/137.283.
- ^ Brodo, Irwin M.; Sharnoff, Sylvia Duran; Sharnoff, Stephen (2001). Lichens of North America. Yale University Press. p. 692. ISBN 978-0-300-08249-4.
- ^ a b McMullin, R. Troy (2023). Lichens. The Macrolichens of Ontario and the Great Lakes Region of the United States. Firefly Books. p. 504. ISBN 978-0-228-10369-1.
- ^ kr 100453679, Jin, Grace Sook, "Hair tint composition containing Lawsonia alba as a main component and one or more auxiliary components selected from Centaurum erythraea, Rhei Rhizoma powder, lichen Cetraria ciliaris and Variolaria", issued 2004-10-21
- ^ Xu, Maonian; Heidmarsson, Starri; Olafsdottir, Elin Soffia; Buonfiglio, Rosa; Kogej, Thierry; Omarsdottir, Sesselja (2016). "Secondary metabolites from cetrarioid lichens: Chemotaxonomy, biological activities and pharmaceutical potential". Phytomedicine. 23 (5): 441–459. doi:10.1016/j.phymed.2016.02.012. PMID 27064003.