Superregnum: Eukaryota
Regnum: Fungi
Subregnum: Dikarya
Divisio: Ascomycota
Subdivisio: Pezizomycotina
Classis: Lecanoromycetes
Subclassis: Lecanoromycetidae
Ordo: Lecanorales
Familia: Ramalinaceae
Genera: Aciculopsora – Adelolecia – Arthrosporum – Auriculora – Bacidia - Bacidina - Bacidiopsora – Badimia – Bellicidia – Bibbya – Catinaria – Cenozosia - Cliostomum - Compsocladium– Coppinsidea – Crocynia – Echidnocymbium - Eschatogonia - Frutidella – Heppsora - Japewia - Jarmania – Kiliasia – Krogia – Lueckingia – Megalaria – Micareopsis – Niebla – Physcidia – Pseudohepatica – Pseudolepraria – Ramalina – Ramalinopsis – Rolfidium – Squamacidia – Stirtoniella – Tamasia – Tasmidella – Tibellia – Toninia – Toniniopsis – Triclinum – Tylocliostomum – Vandenboomia – Vermilacinia - Waynea – Wolseleyidea
Name
Ramalinaceae C. Agardh, 1821
Synonyms
Crocyniaceae M. Choisy ex Hafellner, 1984
Megalariaceae Hafellner, 1984
References
C. Agardh [as 'Ramalineae' ], Aphor. bot. (Lund): 93 (1821)
Agardh, C.A. (1821) Aphorismi botanici. Lundae. pp. (Mattick Rec.# 33159 – Literature on Lichens)
Cannon, P.F. & P.M. Kirk. 2007. Fungal Families of the World. CAB International, 456 pp. (Bacidiaceae p. 32)
Galloway, D.J.; Hafellner, J.; Elix, J.A. 2005: Stirtoniella, a new genus for Catillaria kelica (Lecanorales: Ramalinaceae). Lichenologist, 37: 261–271. (RLL List # 199 / Rec. # 27022 – Recent Literature on Lichens) (doi:10.1017/S002428290501501X)
Lumbsch, H.T. & Huhndorf, S.M. (ed.) 2007: Outline of Ascomycota – 2007. Myconet 13: 1–58. (RLL List # 210 / Rec. # 30164 – Recent Literature on Lichens) (Outline of Ascomycota – 2007)
Watson, W. (1929) The classification of lichens I. New Phytologist 28: 1–36. (Mattick Rec.# 17033 – Literature on Lichens)
Links
Index Fungorum
MycoBank
Vernacular names
The Ramalinaceae are a family of lichen-forming fungi in the order Lecanorales. First proposed by Carl Adolph Agardh in 1821, the family now comprises 63 genera and about 750 species. Ramalinaceae lichens exhibit diverse growth forms, including crustose, fruticose, squamulose, leprose, and byssoid thalli, and form symbiotic relationships primarily with green algae of the genus Trebouxia. The family is characterised by pale-coloured thalli, apothecia (fruiting bodies) that are typically pale but may darken with age, and ascospores that vary in shape and septation.
Members of the Ramalinaceae are found in a wide range of habitats worldwide, from coastal fog deserts to boreal, temperate, and tropical forests. Some genera, such as Namibialina, Vermilacinia, and Niebla, are endemic to specific coastal desert regions, whilst others like Ramalina have an almost worldwide distribution. Several species within the family face conservation challenges due to their limited distributions and specific environmental threats, with some being listed as vulnerable or critically endangered on the IUCN Red List.
Systematics
Taxonomy
The family was proposed by the Swedish botanist Carl Adolph Agardh in 1821.[2] According to the nomenclatural authority Index Fungorum, while Agardh initially classified it as an "ordo" (order), he used it in a way that suggested a family ranking, referring to it as "Ramalineae". The first explicit use of Ramalinaceae as a family name came from Antoine Laurent Apollinaire Fée in 1824, but this was not considered valid under Article 32.1(b) of the nomenclature rules, meaning it was not accompanied by a description or diagnosis or a reference to a previously published description or diagnosis. The first correctly spelled use of the family name Ramalinaceae in accordance with Article 18.4 (i.e., with the ending -aceae) is attributed to Watson in a 1929 publication.[3][4]
In 2018, Sonja Kistenich and colleagues published a large-scale molecular phylogenetic analysis of the family. The study demonstrated five well‐supported clades in the Ramalinaceae; they are named after the largest genera within them, viz. the Bacidia-, Biatora‐, Ramalina‐, Rolfidium‐, and Toninia‐groups. The genera Bacidia, Phyllopsora, Physcidia and Toninia were found to be polyphyletic and split into segregates. The study also traced the character evolution of the morphological and ecological nature of the Ramalinaceae ancestor. The ancestor probably arose from moist, temperate forests growing on the bark of trees with a crustose growth form and reproduced mainly by forming apothecia and long, multi-septate spores.[5]
A 2020 study by Richard Spjut and colleagues provided further insights into the taxonomy of Ramalinaceae, particularly focusing on the fruticose genera. The research revealed that the fruticose genera within Ramalinaceae are not monophyletic (derived from a single ancestor) but form two distinct lineages: 1) Ramalina + Namibialina and 2) Vermilacinia + Niebla. These lineages are nested within accessions of the crustose genus Cliostomum.[6]
The divergence between these two main lineages occurred approximately 48 million years ago. Ramalina began to spread worldwide around 43 million years ago, whilst its sister genus Namibialina, newly described in this study, radiated later (about 19–20 million years ago) in the coastal deserts of southwest Africa. Vermilacinia and Niebla, which diverged around 30 million years ago, are primarily found in coastal deserts of the New World.[6]
The study highlighted challenges in delimiting species boundaries within Niebla and Vermilacinia, indicating that more data are required for a comprehensive understanding. Notably, the taxonomy proposed by Spjut (1996) for Niebla was not fully corroborated by molecular data, whereas that for saxicolous Vermilacinia received substantial support. The research also led to the description of new Vermilacinia species.[6]
Regarding the genus Ramalina, the study examined 50 identified species out of an estimated total of 230. Species lacking secondary metabolites (except usnic acid) were resolved at the base of the phylogenetic tree but did not form a monophyletic group. Some clades corresponded to the production of specific secondary metabolites, although these were not always autapomorphies. The study also resulted in the recognition or resurrection of several Ramalina species, including R. krogiae and R. lusitanica.[6]
Synonymy
Some genera now classified in the Ramalinaceae were considered by past authors to be distinctive enough to warrant inclusion in their own family. These historical family names are considered synonymous with Ramalinaceae:[1]
Bacidiaceae Walt.Watson (1929)
Biatoraceae A.Massal. ex Stizenb. (1862)
Catinariaceae Hale ex Hafellner (1984)
Crocyniaceae M.Choisy ex Hafellner (1984)
Lecaniaceae Walt.Watson (1929)
Megalariaceae Hafellner (1984)
Phyllopsoraceae Zahlbr. (1905)
Etymology
As is standard practice in botanical nomenclature,[7] the name Ramalinaceae is based on the name of the type genus, Ramalina, with the ending -aceae indicating the rank of family. The genus name, assigned by the mycologist Erik Acharius in 1809,[8] comprises the Latin word ramus meaning 'branch' and ramalis, meaning 'pertaining to a branch or having branches', and -ina, a suffix that denotes similarity. It refers to the typically fruticose, highly branched thalli characteristic of many Ramalina species.[9]
Description
The Ramalinaceae consists of lichen-forming fungi with a highly varied appearance. The thallus, which is the body of the lichen, can take different forms such as crusty (crustose), bushy (fruticose), scale-like (squamulose), or even granular (leprose) or cottony (byssoid). A few species within this family also grow on other lichens (lichenicolous). The colouration of these lichens tends to be pale, and some species may develop small reproductive structures called isidia or soralia that help with vegetative reproduction. The lichen's photobiont partner, which is the photosynthetic organism living within the fungus, is of the chlorococcoid type, meaning it consists of green algae that are spherical or slightly elongated.[10]
Ramalinaceae lichens reproduce sexually via apothecia (fruiting bodies), which are usually pale and may appear black with age. These apothecia may sit directly on the thallus surface or occasionally have short stalks. The edge of the apothecium (the margin) typically lacks a thallus-like covering, but a structural layer called the exciple is often present, though it may disappear over time as the lichen matures. The disc of the apothecium can range from flat to strongly convex.[10]
Within the apothecia, there are microscopic structures called paraphyses, which are unbranched or branched filaments that surround the spore-producing cells. The tips of these paraphyses are often swollen. The asci (spore-producing cells) are typically cylindrical to club-shaped. These asci belong to either the Bacidia or Biatora types, which are distinguished by specific staining patterns when exposed to iodine (K/I+), showing a dark blue reaction. Each ascus usually contains eight spores. The ascospores, which are the fungal reproductive units, can vary widely in shape, from broadly elliptical to thread-like. They may be divided by one or more walls (septate) or lack divisions entirely (aseptate), and they are colourless without a surrounding layer.[10]
Additionally, members of this family may produce asexual reproductive structures known as pycnidia, which are embedded in the lichen tissue or sit on the surface. These structures release conidia (asexual spores), which also come in various shapes, sometimes with internal divisions (septate).[10]
Photobiont
Species in the Ramalinaceae form symbiotic relationships with photobionts, primarily green algae from the genus Trebouxia. A 2024 study focusing on the Ramalina farinacea group identified two main photobiont Species: Trebouxia jamesii and T. lynnae.[11] These photobionts show distinct geographical distributions and ecological preferences. T. jamesii is predominantly found in continental Europe and Mediterranean islands, displaying a preference for inland areas. In contrast, T. lynnae is more common in Macaronesian archipelagos and coastal regions, showing better adaptation to warmer and more humid climates.[11]
The association between Ramalinaceae fungi and their photobionts varies in specificity. Some species, like Ramalina farinacea, can associate with both T. jamesii and T. lynnae, while others, such as the Canarian endemic R. alisiosae, show a strict association with T. lynnae. This flexibility in photobiont association may contribute to the ecological adaptability of these lichens, allowing them to thrive in diverse environments.[11]
A 2022 study on the Ramalina decipiens group found that about 50% of studied thalli showed co-occurrence of multiple algal species, though usually one species was dominant, accounting for about 94% of the algal cells in thalli with multiple species.[12] The island of origin and macroclimate had a greater influence on photobiont community structure than the specific Ramalina species, suggesting local adaptation of the photobionts.[12]
Multiple genetic variants (haplotypes) of T. jamesii have been identified, with some being widespread across Europe and others restricted to specific geographic regions. This genetic diversity in photobionts may further enhance the adaptive potential of the lichen symbiosis.[11] T. jamesii showed a preference for continental areas, while T. lynnae preferred coastal regions and islands, possibly due to differences in temperature tolerance and adaptation to salinity.[12]
Both T. jamesii and T. lynnae are known to form symbiotic relationships with lichens from other genera and families beyond Ramalinaceae, indicating their broader ecological importance.[11] The ability of some Ramalinaceae species to switch or adapt their photobiont partnerships may play a crucial role in their ability to colonise and survive in varied habitats. For example, Ramalina maderensis associates with different photobionts in different parts of its range, suggesting photobiont switching as a mechanism for expanding ecological niches.[12]
Despite the variation in photobiont associations, a study of the R. decipiens group found no evidence for trophic niche segregation among Ramalina species with respect to their photobionts, suggesting that photobiont association may not be a key driver of speciation in this group.[12]
Habitat and distribution
The Ramalinaceae family exhibits a diverse range of habitats and distributions, with several genera showing highly specialised ecological niches. Three fruticose genera—Namibialina, Vermilacinia, and Niebla—are endemic to coastal fog deserts. Namibialina is found in southwestern Africa, whilst Vermilacinia occurs along the Pacific coasts of South and North America. Niebla is restricted to North America. In contrast, Ramalina has a subcosmopolitan distribution, colonising a wide range of habitats from saxicolous sea-shores to trunks and branches in boreal, temperate, and tropical forests. Many species within these genera are found on coastal rocks in fog deserts, while others are epiphytic. Notably, there is evidence of micro-endemism, particularly in Niebla and saxicolous Vermilacinia species, with many taxa having very restricted geographical ranges. The distribution and speciation of these genera have been significantly influenced by fog conditions and climate changes since the Miocene. Some species exhibit disjunct distributions, such as Vermilacinia zebrina, which is found in both North America and Namibia.[6]
Genera
In a comprehensive molecular phylogeny of the family in which 6 existing genera were reduced to synonymy, Kistenich and colleagues accepted 39 genera in the Ramalinaceae.[5] Several genera have since been added, some newly proposed and some resurrected from previously disused names. As of October 2024, Species Fungorum (in the Catalogue of Life), accept 747 species distributed amongst 63 genera in the Ramalinaceae.[13]
Crocynia pyxinoides
Niebla cephalota
Toninia sedifolia
Ramalina darwiniana
Aciculopsora Aptroot & Trest (2006)[14] – 3 spp.
Auriculora Kalb (1988)[15] – 1 sp.
Bacidia De Not. (1846)[16] – 230 spp.
Bacidiopsora Kalb (1988) – 6 spp.[note 1]
Bacidina Vězda (1991)[17] – 12 spp.
Badimia Vězda (1986)[18] – 20 spp.
Bellicidia Kistenich, Timdal, Bendiksby & Ekman (2018)[5] – 1 sp.
Biatora Fr. (1819)[19] – 42 spp.
Bibbya J.H.Willis (1956)[20] – 10 spp.
Bilimbia De Not. (1846)[16] – 6 spp.
Catinaria Vain. (1922)[21] – 6 spp.
Cenozosia A.Massal. (1845)[22] – 1 sp.
Cliomegalaria van den Boom & Alvarado (2019)[23] – 1 sp.
Cliostomum Fr. (1825)[24] – 25 spp.
Compsocladium I.M.Lamb (1956)[25] – 2 spp.
Coppinsidea S.Y.Kondr., Farkas & Lőkös (2019)[19] – 2 spp.
Crocynia (Ach.) A.Massal. (1860)[26] – 5 spp.[note 2]
Crustospathula Aptroot (1998)[28] – 5 spp.
Echidnocymbium Brusse (1987)[29] – 1 spp.
Eschatogonia Trevis. (1853)[30] – 7 spp.
Heppsora D.D.Awasthi & K.Singh (1977)[31] – 1 sp.
Herteliana P.James (1980)[32] – 4 spp.[note 3]
Ivanpisutia S.Y.Kondr., Lőkös & Hur (2015)[34] (resurrected) – 2 spp.
Jarmania Kantvilas (1996)[35] – 2 spp.
Kiliasia Hafellner (1984)[36] – 9 spp.
Krogia Timdal (2002)[37] – 7 spp.
Lecania A.Massal. (1853)[38] – 50 spp.
Lecaniella Jatta (1889)[39] (resurrected) – 2 spp.
Lithocalla Orange (2020)[40] – 2 spp.
Lopezaria Kalb & Hafellner (1990)[41] – 2 spp.[note 4]
Lueckingia Aptroot & Umaña (2006)[14] – 1 sp.
Megalaria Hafellner (1984)[36] –
Mycobilimbia Rehm (1980)[42] – 5 spp.
Myelorrhiza Verdon & Elix (1986)[43] – 2 spp.
Myrionora R.C.Harris (1988)[44] (resurrected) – 5 spp.
Namibialina Spjut & Sérus. (2020)[6] – 1 sp.[6]
Niebla Rundel & Bowler (1978)[45] – 23 spp.
Parallopsora Kistenich, Timdal & Bendiksby (2018)[5] – 3 spp.
Phyllopsora Müll.Arg. (1894)[46] – 75 spp.
Physcidia Tuck. (1862)[47] – 10 spp.
Pseudohepatica P.M.Jørg. (1993)[48] – 2 spp.
Pseudolepraria Kukwa, Jabłońska, Kosecka & Guzow-Krzem. (2023)[49] – 1 sp.
Ramalina Ach. (1809) – 230 spp.
Ramalinopsis (Zahlbr.) Follmann & Huneck (1969)[50] – 1 sp.[note 5]
Rolfidium Moberg (1986)[51] – 3 spp.
Schadonia Körb. (1859)[52] – 4 spp.[note 6]
Scutula Tul. (1852)[54] – 43 spp.
Squamacidia Brako (1989)[55] – 1 sp.
Stirtoniella D.J.Galloway, Hafellner & Elix (2005)[56] – 1 sp.
Tamasia Farkas (2023)[57] – 1 sp.
Tasmidella Kantvilas, Hafellner & Elix (1999)[58] – 1 sp.
Thalloidima A.Massal. (1852)[59] – 17 spp.
Thamnolecania (Vain.) Gyeln. (1933)[60] – 1 sp.
Tibellia Vězda & Hafellner (1992)[61] – 1 sp.
Toninia A.Massal. (1852)[59] – 85 spp.
Toniniopsis Frey (1926)[62] – 7 spp.
Tylocliostomum van den Boom & Magain (2020)[63] – 1 sp.
Vandenboomia S.Y.Kondr. (2019)[19] – 2 spp.
Vermilacinia Spjut & Hale (1995)[note 7]
Waynea Moberg (1990)[65] – 7 spp.
Wolseleyidea S.Y.Kondr., Farkas & Lőkös (2019)[19] – 3 spp.
Conservation
Ramalina menziesii, the state lichen of California, is assessed as Least Concern by the IUCN.
The conservation status of 12 Ramalinaceae species has been assessed for the global IUCN Red List. Several species in the family are facing conservation challenges due to their limited distributions and specific environmental threats.
Madeira archipelago endemics
In the Madeira archipelago, particularly on Porto Santo Island, multiple rock-dwelling Ramalina species are assessed as Vulnerable. R. portosantana,[66] R. erosa,[67] R. timdaliana,[68] R. confertula,[69] and R. jamesii each have restricted populations, ranging from 500 to 1,000 individuals across one to four locations. These species are primarily threatened by trampling and wildfires, which could swiftly devastate their entire populations.[70] Additionally, R. nematodes, although more abundant with twelve locations, is considered Near Threatened due to its very restricted area of occupancy and the potential impacts of the same threats.[71]
Galapagos endemics
In the Galapagos Islands, Ramalina fragilis is the rarest among the four endemic Ramalina species. Unlike its congeners that thrive on shrubs and trees, R. fragilis is adapted to rocky substrates. It faces unique threats such as flash floods during El Niño events, erosion, and rising sea levels, which are expected to reduce its population size, area of occupancy, and habitat quality by up to 40% over the next 45 years.[72]
California endemics
Niebla ramosissima, found solely on San Nicolas Island in Mediterranean California, is also listed as Vulnerable. Its limited distribution, confined to a single location with an area of occupancy up to 32 km², makes it susceptible to habitat transformation caused by invasive species and climate change, which could alter its natural sea-side low-shrub vegetation.[73]
Other species
Lecania vermispora is known from three locations with a total area of occupancy of 8 km². This species faces threats from livestock grazing and climatic changes, which could lead to its decline and potential extirpation. Consequently, it is listed as Vulnerable under criterion D2.[74]
Bacidia proposita is categorised as Critically Endangered. It is known from only one locality within the municipality of Honda, with an area of occupancy of 4 km². This site has experienced significant habitat loss due to logging and the expansion of urban, industrial, and agricultural frontiers. Despite recent surveys in similar habitats, the species has not been rediscovered, underscoring its precarious status.[75]
Conversely, Bacidia schweinitzii and Ramalina menziesii are assessed as Least Concern. Bacidia schweinitzii is widespread across eastern North America with scattered occurrences in eastern Asia, while Ramalina menziesii is common and locally abundant along the coastal regions of western North America. Neither species currently faces significant threats that would jeopardise their populations.[76][77]
Notes
Molecular phylogenetic analysis has indicated that the type species of Bacidiopsora is nested in Bacidia.[5]
Crocynia is nested within Phyllopsora; a proposal has been made to conserve the name Phyllopsora against Crocynia.[27]
Herteliana is included in the Cladoniaceae by some recent authors.[33]
Kistenich and colleagues (2018) suggest that Lopezaria is a synonym of Megalaria.[5]
Kistenich and colleagues (2018) suggest that Ramalinopsis can be reduced into synonymy with Ramalina.[5]
The placement of Schadonia within Ramalinaceae is uncertain, with recent studies suggesting it may belong in Pilocarpaceae or warrant its own family, Schadoniaceae, pending further phylogenetic research.[5][53]
Index Fungorum places Vermilacinia into synonymy with Ramalina.[64]
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