Trebouxia arboricola

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Trebouxia arboricola
Scientific classification OOjs UI icon edit-ltr.svg
(unranked): Viridiplantae
Division: Chlorophyta
Class: Trebouxiophyceae
Order: Trebouxiales
Family: Trebouxiaceae
Genus: Trebouxia
Species:
T. arboricola
Binomial name
Trebouxia arboricola
Puymaly, 1924
Synonyms [1]

Trebouxia arboricola is a symbiotic species of green alga in the family Trebouxiaceae. Described as new to science in 1924, it is usually found in association with different species of lichen-forming fungi and has a broad global distribution.

Contents

Taxonomy

The alga was formally described as a new species in 1924 by the French phycologist André Henri Laurent de Puymaly. [2] The type specimen was associated with the foliose lichen Xanthoria parietina . [1] Trebouxia arboricola is the type species of the genus Trebouxia , which was circumscribed by Puymaly in 1924. [3]

In a comprehensive molecular phylogenetics analysis published in 2016, it was discovered that the lichen photobionts Trebouxia arboricola and Trebouxia gigantea constitute a complex clade encompassing 34 distinct operational taxonomic units (OTUs). This finding suggests that what is currently known as T. arboricola and T. gigantea may actually represent a group of 34 potentially distinct species, each with its unique genetic identity. [4]

Distribution

Trebouxia arboricola has a wide global distribution. It has been reported in the Arctic and Atlantic Islands, including Iceland. In Europe, its presence spans across Britain, France, Germany, Romania, Russia (European regions), Spain, Switzerland, Ukraine, and the Ural Mountains. In South America, the species is found in Argentina. The Middle East records include Israel, while in South-west Asia, it has been reported from Uttar Pradesh. Its Asian distribution covers China and Taiwan. Under the synonym Trebouxia humicola, the species was recorded in Europe and Asia. [1]

Ecology

In a study of bark-inhabiting lichens from the Physcietum adscendentis sociological unit (a set of lichen taxa that commonly associate together), researchers identified Trebouxia arboricola as the photobiont in several lichen species. This identification was achieved through axenic cultures and sequence comparisons of internal transcribed spacer DNA. Trebouxia arboricola was found in association with Lecania cyrtella , Candelaria concolor , Candelariella cf. reflexa, Lecanora species, Lecidella elaeochroma , in addition to Xanthoria parietina. The study also suggested the existence of a free-living population of Trebouxia arboricola, based on its frequent occurrence as a photobiont in pioneer lichens growing on smooth bark. Additionally, it was observed that the photobionts from Xanthoria parietina were morphologically and genetically distinct from those in Physcia adscendens and Phaeophyscia orbicularis . [5] In a 2013 study, researchers found that Xanthoria parietina from various locations in France and Switzerland associates with diverse genotypes of Trebouxia decolorans , while saxicolous (rock-dwelling) specimens specifically associate with Trebouxia arboricola. [6]

Oribatid mites inhabiting the lichen Xanthoria parietina were found in one study to aid in the dispersal of the lichen's photobiont, Trebouxia arboricola, through their faeces, suggesting a potential method for the vegetative dispersal of this alga. [7]

Trebouxia arboricola was studied as part of the first investigation of aerophytic (i.e., deriving moisture and nutrients from the air and rain) cryptogams on monuments in Bulgaria. In Koprivshtitsa, the alga was found in both free-living and lichenised states on granite monuments, alongside other green algae like Apatococcus lobatus . Culture studies confirmed the presence of T. arboricola, providing the first documented evidence of its occurrence in Bulgaria in a free-living (non-lichenised) state. [8]

Preservation and longevity

Research on the Xanthoria parietina and Trebouxia arboricola showed that both organisms die off after about 3 years of room temperature storage, evident from colour changes and a decrease in chlorophyll fluorescence in Trebouxia cells. When stored desiccated at −20 °C (−4 °F), both the fungus and T. arboricola remained viable for up to 13 years, showing the effectiveness of cryopreservation for long-term storage of viable lichen thalli, including T. arboricola, for experimental studies. [9]

The predominance of Trebouxia arboricola in areas with different levels of carbon monoxide (CO) in Peninsular Malaysia suggests that this species is resilient to air pollution. Its widespread presence and ability to thrive in varying CO concentrations make it a potential candidate for monitoring air quality, as changes in its population density could indicate alterations in air pollution levels. [10]

Related Research Articles

<span class="mw-page-title-main">Lichen</span> Symbiosis of fungi with algae or cyanobacteria

Beginning in 1867, a lichen was understood as a symbiosis of an algae or cyanobacteria, living among filaments of multiple fungi species. In 2016, new research by T. Spribille et al. revealed a third partner, a yeast imbedded in the lichen cortex or "skin."

<i>Xanthoria parietina</i> Species of lichen

Xanthoria parietina is a foliose lichen in the family Teloschistaceae. It has wide distribution, and many common names such as common orange lichen, yellow scale, maritime sunburst lichen and shore lichen. It can be found near the shore on rocks or walls, and also on inland rocks, walls, or tree bark. It was chosen as a model organism for genomic sequencing by the US Department of Energy Joint Genome Institute (JGI).

Vernon Ahmadjian was a distinguished professor at Clark University in Worcester, Massachusetts. He specialized in the symbiosis of lichens, and wrote several books and numerous publications on the subject.

<i>Trebouxia</i> Genus of algae

Trebouxia is a unicellular green alga. It is a photosynthetic organism that can exist in almost all habitats found in polar, tropical, and temperate regions. It can either exist in a symbiotic relationship with fungi in the form of lichen or it can survive independently as a free-living organism alone or in colonies. Trebouxia is the most common photobiont in extant lichens. It is a primary producer of marine, freshwater and terrestrial ecosystems. It uses carotenoids and chlorophyll a and b to harvest energy from the sun and provide nutrients to various animals and insects.

<span class="mw-page-title-main">Teloschistaceae</span> Family of lichen-forming fungi

The Teloschistaceae are a large family of mostly lichen-forming fungi belonging to the class Lecanoromycetes in the division Ascomycota. The family has a cosmopolitan distribution, although its members occur predominantly in temperate regions. Most members are lichens that either live on rock or on bark, but about 40 species are lichenicolous – meaning they are non-lichenised fungi that live on other lichens. Many members of the Teloschistaceae are readily identifiable by their vibrant orange to yellow hue, a result of their frequent anthraquinone content. The presence of these anthraquinone pigments, which confer protection from ultraviolet light, enabled this group to expand from shaded forest habitats to harsher environmental conditions of sunny and arid ecosystems during the Late Cretaceous.

<span class="mw-page-title-main">Verrucariaceae</span> Family of mostly lichenised fungi

Verrucariaceae is a family of lichens and a few non-lichenised fungi in the order Verrucariales. The lichens have a wide variety of thallus forms, from crustose (crust-like) to foliose (bushy) and squamulose (scaly). Most of them grow on land, some in freshwater and a few in the sea. Many are free-living but there are some species that are parasites on other lichens, while one marine species always lives together with a leafy green alga.

<i>Punctelia</i> Genus of foliose lichens

Punctelia is a genus of foliose lichens belonging to the large family Parmeliaceae. The genus, which contains about 50 species, was segregated from genus Parmelia in 1982. Characteristics that define Punctelia include the presence of hook-like to thread-like conidia, simple rhizines, and point-like pseudocyphellae. It is this last feature that is alluded to in the vernacular names speckled shield lichens or speckleback lichens.

<span class="mw-page-title-main">Cephalodium</span> Morphological structure found in some lichens

A cephalodium (pl. cephalodia) is a small gall-like structure found in some lichens. They occur only lichens which contain both cyanobacterial and green algal partners. Cephalodia can occur within the tissues of the lichen, or on its upper or lower surface. Lichens with cephalodia can fix nitrogen, and may be an important contributor of nitrogen to the ecosystem.

<span class="mw-page-title-main">Lichen growth forms</span> Gross morphological classification

Lichens are symbiotic organisms made up of multiple species: a fungus, one or more photobionts and sometimes a yeast. They are regularly grouped by their external appearance – a characteristic known as their growth form. This form, which is based on the appearance of vegetative part of the lichen, varies depending on the species and the environmental conditions it faces. Those who study lichens (lichenologists) have described a dozen of these forms: areolate, byssoid, calicioid, cladoniform, crustose, filamentous, foliose, fruticose, gelatinous, leprose, placoidioid and squamulose. Traditionally, crustose (flat), foliose (leafy) and fruticose (shrubby) are considered to be the three main forms. In addition to these more formalised, traditional growth types, there are a handful of informal types named for their resemblance to the lichens of specific genera. These include alectorioid, catapyrenioid, cetrarioid, hypogymnioid, parmelioid and usneoid.

Lichen anatomy and physiology is very different from the anatomy and physiology of the fungus and/or algae and/or cyanobacteria that make up the lichen when growing apart from the lichen, either naturally, or in culture. The fungal partner is called the mycobiont. The photosynthetic partner, algae or cyanobacteria, is called the photobiont. The body of a lichens that does not contain reproductive parts of the fungus is called the thallus. The thallus is different from those of either the fungus or alga growing separately. The fungus surrounds the algal cells, often enclosing them within complex fungal tissues unique to lichen associations. In many species the fungus penetrates the algal cell wall, forming penetration pegs or haustoria similar to those produced by pathogenic fungi. Lichens are capable of surviving extremely low levels of water content (poikilohydric). However, the re-configuration of membranes following a period of dehydration requires several minutes at least.

<span class="mw-page-title-main">Symbiosis in lichens</span>

Symbiosis in lichens is the mutually beneficial symbiotic relationship of green algae and/or blue-green algae (cyanobacteria) living among filaments of a fungus, forming lichen.

<i>Ramalina menziesii</i> Species of lichen

Ramalina menziesii, the lace lichen or fishnet, is a pale yellowish-green to grayish-green fruticose lichen. It grows up to a meter long, hanging from bark and twigs in a distinctive net-like or lace-like pattern that is unlike any other lichen in North America. It becomes a deeper green when wet. Apothecia are lecanorine. Lace lichen is an important food source for deer in the Coast Range of California, and a source of nest material for birds. It is highly variable in its growth form, with branches sometimes so slender as to appear like strands, sometimes tiny, and sometimes large with broadly flattened branches.

Rosmarie Honegger is a Swiss lichenologist and Emeritus Professor at the University of Zurich.

<i>Pulchrocladia retipora</i> Species of fruticose lichen

Pulchrocladia retipora, commonly known as the coral lichen, is a species of fruticose lichen in the family Cladoniaceae. Found predominantly in Australasia, its habitats range from the Australian Capital Territory to New Zealand's North and South Islands, and even the Pacific region of New Caledonia, where it grows in coastal and alpine heathlands. The lichen features coral-like branches and subbranches with numerous intricate, netlike perforations. It is known by multiple names, with some sources referring to it by its synonym Cladia retipora, or the common name lace lichen.

<i>Xanthoria aureola</i> Species of lichen-forming fungus

Xanthoria aureola, commonly known as the seaside sunburst lichen, is a lichenized species of fungus in the family Teloschistaceae and phylum Ascomycota. X. aureola can be recognized by its bright yellow-orange pigmentation and abundant strap-shaped lobes. It is usually found growing on exposed, nutrient-rich rocks in sunny, maritime habitats. It is largely restricted to European coasts, stretching from Portugal to Norway.

Trebouxia decolorans is a widespread and common symbiotic species of green alga that is found in association with different species of lichen-forming fungi. Some lichens in which it is the photobiont partner are Xanthoria parietina and Anaptychia ciliaris.

<i>Anaptychia ciliaris</i> Species of lichen

Anaptychia ciliaris, commonly known as the great ciliated lichen or eagle's claws, is a species of fruticose lichen in the family Physciaceae. It is predominantly found in Northern Europe, with its range extending to European Russia, the Caucasus, Central and Southern Europe, the Canary Islands, and some parts of Asia. First mentioned in botanical literature by Italian botanist Fabio Colonna in 1606, the species was formally described by Carl Linnaeus in 1753, who highlighted its unique physical characteristics such as its grey colour, its unusual leafy form with linear fringe-like segments, and the presence of hair-like structures. This lichen is adaptable in its choice of substrates, mostly growing on tree barks, and less commonly on rocks.

Trebouxia gelatinosa is a common symbiotic species of green alga in the family Trebouxiaceae. Formally described as new to science in 1975, it is usually found in association with different species of lichen-forming fungi.

Asterochloris is a genus of green algae in the family Trebouxiophyceae. It is a common photobiont in lichen, occurring in the thalli of more than 20 lichen genera worldwide. Asterochloris is distinguishable from the morphologically similar genus Trebouxia, primarily due to its deeply lobed chloroplast, the placement of the chloroplast along the cell's periphery before the initiation of zoospore or aplanospore formation, and its tendency to primarily reproduce asexually through the production of aplanospores.

Asterochloris italiana is a species of green alga in the family Trebouxiaceae. It was first formally described by the phycologist Patricia A. Archibald in 1975, as a species of Trebouxia. It was transferred to the genus Asterochloris in 2010.

References

  1. 1 2 3 Guiry, M.D.; Guiry, G.M. "Trebouxia decolorans". AlgaeBase . World-wide electronic publication, National University of Ireland, Galway.
  2. Puymaly, A. de (1924). "Le Chlorococcum humicola (Nag.) Rabenh". Revue algologique (in French). 1: 107–114.
  3. Guiry, M.D.; Guiry, G.M. "Trebouxia". AlgaeBase . World-wide electronic publication, National University of Ireland, Galway.
  4. Leavitt, Steven D.; Kraichak, Ekaphan; Nelsen, Matthew P.; Altermann, Susanne; Divakar, Pradeep K.; Alors, David; Esslinger, Theodore L.; Crespo, Ana; Lumbsch, Thorsten (2015). "Fungal specificity and selectivity for algae play a major role in determining lichen partnerships across diverse ecogeographic regions in the lichen‐forming family Parmeliaceae (Ascomycota)". Molecular Ecology. 24 (14): 3779–3797. doi:10.1111/mec.13271. PMID   26073165. S2CID   28422129.
  5. Beck, A.; Friedl, T.; Rambold, G. (1998). "Selectivity of photobiont choice in a defined lichen community: inferences from cultural and molecular studies". New Phytologist. 139 (4): 709–720. doi: 10.1046/j.1469-8137.1998.00231.x .
  6. Nyati, Shyam; Werth, Silke; Honegger, Rosmarie (2013). "Genetic diversity of sterile cultured Trebouxia photobionts associated with the lichen-forming fungus Xanthoria parietina visualized with RAPD-PCR fingerprinting techniques" (PDF). The Lichenologist. 45 (6): 825–840. doi:10.1017/s0024282913000546. S2CID   46911371.
  7. Meier, Franz A.; Scherrer, Sandra; Honegger, Rosmarie (2002). "Faecal pellets of lichenivorous mites contain viable cells of the lichen-forming ascomycete Xanthoria parietina and its green algal photobiont, Trebouxia arboricola". Biological Journal of the Linnean Society. 76 (2): 259–268. doi: 10.1111/J.1095-8312.2002.TB02087.X .
  8. Gärtner, Georg; Stoyneva, Maya P. (2003). "First study of aerophytic cryptogams on monuments in Bulgaria". Berichte des Naturwissenschaftlich-Medizinischen Verein Innsbruck. 90: 73–83.
  9. Honegger, R. (2003). "The impact of different long‐term storage conditions on the viability of lichen‐forming ascomycetes and their green algal photobiont, Trebouxia spp". Plant Biology. 5 (3): 324–330. doi:10.1055/s-2003-40794. S2CID   260249529.
  10. Razli, Siti Aisyah; Abas, Azlan; Ismail, Asmida; Othman, Murnira; Mohtar, Anis Asma Ahmad; Baharudin, Nor Hafizah; Aiyub, Kadaruddin; Latif, Mohd Talib (2020). "Epiphytic microalgae as biological indicators for carbon monoxide concentrations in different areas of Peninsular Malaysia". Environmental Forensics. 23 (3–4): 314–323. doi:10.1080/15275922.2020.1850560. S2CID   230605897.
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