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Lichen

January 26, 2023

For other uses, see Lichen (disambiguation).

A lichen (/ˈlkən/ LY-kən, UK also /ˈlɪən/ LITCH-ən) is a composite organism that arises from algae or cyanobacteria living among filaments of multiple fungi species[1] in a mutualistic relationship.[2][3][4] Lichens have properties different from those of their component organisms. They come in many colors, sizes, and forms and are sometimes plant-like, but are not plants. They may have tiny, leafless branches (fruticose); flat leaf-like structures (foliose); grow crust-like, adhering tightly to a surface (substrate) like a thick coat of paint (crustose);[5] have a powder-like appearance (leprose); or other growth forms.[6]

A tree covered with leafy foliose lichens and shrubby fruticose lichens
Common lichen growth forms
Letharia vulpina, wolf lichen, grows like a multiple-branched tuft or leafless mini-shrub, so it has a fruticose growth form.
Flavoparmelia caperata has leaf-like structures, so it is foliose.
Caloplaca marina grows like an orange crust coating the rock, so it is crustose.
Caloplaca thallincola [sv] grows like a crust, and in a pattern that radiates outward from the center, so it has a crustose placodioid growth form.
Pannaria lurida forms small leaf-like scales crustose below but free at the tips, so it is squamulose.
Chrysothrix chlorina grows like powder dusted on the rock so it is leprose.
Collema nigrescens is gelatinous, without internal structure for its parts.

A macrolichen is a lichen that is either bush-like or leafy; all other lichens are termed microlichens.[2] Here, "macro" and "micro" do not refer to size, but to the growth form.[2] Common names for lichens may contain the word moss (e.g., "reindeer moss", "Iceland moss"), and lichens may superficially look like and grow with mosses, but they are not closely related to mosses or any plant.[4]: 3  Lichens do not have roots that absorb water and nutrients as plants do,[7]: 2  but like plants, they produce their own nutrition by photosynthesis.[8] When they grow on plants, they do not live as parasites, but instead use the plant's surface as a substrate.

Lichens occur from sea level to high alpine elevations, in many environmental conditions, and can grow on almost any surface.[8] They are abundant growing on bark, leaves, mosses, or other lichens[7] and hanging from branches "living on thin air" (epiphytes) in rainforests and in temperate woodland. They grow on rock, walls, gravestones, roofs, exposed soil surfaces, rubber, bones, and in the soil as part of biological soil crusts. Various lichens have adapted to survive in some of the most extreme environments on Earth: arctic tundra, hot dry deserts, rocky coasts, and toxic slag heaps. They can even live inside solid rock, growing between the grains.

It is estimated that 6–8% of Earth's land surface is covered by lichens.[9] There are about 20,000 known species.[10] Some lichens have lost the ability to reproduce sexually, yet continue to speciate.[7][11] They can be seen as being relatively self-contained miniature ecosystems, where the fungi, algae, or cyanobacteria have the potential to engage with other microorganisms in a functioning system that may evolve as an even more complex composite organism.[12][13][14][15] Lichens may be long-lived, with some considered to be among the oldest living things.[4][16] They are among the first living things to grow on fresh rock exposed after an event such as a landslide. The long life-span and slow and regular growth rate of some species can be used to date events (lichenometry).

Etymology and pronunciation

The English word lichen derives from the Greek λειχήν leichēn ("tree moss, lichen, lichen-like eruption on skin") via Latin lichen.[17][18][19] The Greek noun, which literally means "licker", derives from the verb λείχειν leichein, "to lick".[20][21] In American English, "lichen" is pronounced the same as the verb "liken" (/ˈlkən/). In British English, both this pronunciation and one rhyming with "kitchen" (/ˈlɪən/) are used.[22][23][24]

Anatomy and morphology

Growth forms

Main article: Lichen growth forms

Lichens grow in a wide range of shapes and forms (morphologies). The shape of a lichen is usually determined by the organization of the fungal filaments.[25] The nonreproductive tissues, or vegetative body parts, are called the thallus. Lichens are grouped by thallus type, since the thallus is usually the most visually prominent part of the lichen. Thallus growth forms typically correspond to a few basic internal structure types. Common names for lichens often come from a growth form or color that is typical of a lichen genus.

Common groupings of lichen thallus growth forms are:

  1. fruticose[26][27][28] – growing like a tuft or multiple-branched leafless mini-shrub, upright or hanging down, 3-dimensional branches with nearly round cross section (terete) or flattened
  2. foliose[26][27] – growing in 2-dimensional, flat, leaf-like lobes
  3. crustose[5][26][27] – crust-like, adhering tightly to a surface (substrate) like a thick coat of paint
  4. squamulose[28] – formed of small leaf-like scales crustose below but free at the tips
  5. leprose[29] – powdery
  6. gelatinous – jelly-like
  7. filamentous – stringy or like matted hair
  8. byssoid – wispy, like teased wool
  9. structureless

There are variations in growth types in a single lichen species, grey areas between the growth type descriptions, and overlapping between growth types, so some authors might describe lichens using different growth type descriptions.

When a crustose lichen gets old, the center may start to crack up like old-dried paint, old-broken asphalt paving, or like the polygonal "islands" of cracked-up mud in a dried lakebed. This is called being rimose or areolate, and the "island" pieces separated by the cracks are called areolas.[26] The areolas appear separated, but are (or were)[citation needed] connected by an underlying prothallus or hypothallus.[29] When a crustose lichen grows from a center and appears to radiate out, it is called crustose placodioid. When the edges of the areolas lift up from the substrate, it is called squamulose.[30]: 159 [28]

These growth form groups are not precisely defined. Foliose lichens may sometimes branch and appear to be fruticose. Fruticose lichens may have flattened branching parts and appear leafy. Squamulose lichens may appear where the edges lift up. Gelatinous lichens may appear leafy when dry.[30]: 159  Means of telling them apart in these cases are in the sections below.

Structures involved in reproduction often appear as discs, bumps, or squiggly lines on the surface of the thallus.[7]: 4  The thallus is not always the part of the lichen that is most visually noticeable. Some lichens can grow inside solid rock between the grains (endolithic lichens), with only the sexual fruiting part visible growing outside the rock.[26] These may be dramatic in color or appearance.[26] Forms of these sexual parts are not in the above growth form categories.[26] The most visually noticeable reproductive parts are often circular, raised, plate-like or disc-like outgrowths, with crinkly edges, and are described in sections below.

Color

Lichens come in many colors.[7]: 4  Coloration is usually determined by the photosynthetic component.[25] Special pigments, such as yellow usnic acid, give lichens a variety of colors, including reds, oranges, yellows, and browns, especially in exposed, dry habitats.[31] In the absence of special pigments, lichens are usually bright green to olive gray when wet, gray or grayish-green to brown when dry.[31] This is because moisture causes the surface skin (cortex) to become more transparent, exposing the green photobiont layer.[31] Different colored lichens covering large areas of exposed rock surfaces, or lichens covering or hanging from bark can be a spectacular display when the patches of diverse colors "come to life" or "glow" in brilliant displays following rain.

Different colored lichens may inhabit different adjacent sections of a rock face, depending on the angle of exposure to light.[31] Colonies of lichens may be spectacular in appearance, dominating much of the surface of the visual landscape in forests and natural places, such as the vertical "paint" covering the vast rock faces of Yosemite National Park.[32]

Color is used in identification.[33]: 4  The color of a lichen changes depending on whether the lichen is wet or dry.[33] Color descriptions used for identification are based on the color that shows when the lichen is dry.[33] Dry lichens with a cyanobacterium as the photosynthetic partner tend to be dark grey, brown, or black.[33]

The underside of the leaf-like lobes of foliose lichens is a different color from the top side (dorsiventral), often brown or black, sometimes white. A fruticose lichen may have flattened "branches", appearing similar to a foliose lichen, but the underside of a leaf-like structure on a fruticose lichen is the same color as the top side. The leaf-like lobes of a foliose lichen may branch, giving the appearance of a fruticose lichen, but the underside will be a different color from the top side.[29]

The sheen on some jelly-like gelatinous lichens is created by mucilaginous secretions.[25]

Internal structure

 
The cyanobacterium Hyella caespitosa with fungal hyphae in the lichen Pyrenocollema halodytes[further explanation needed]

A lichen consists of a simple photosynthesizing organism, usually a green alga or cyanobacterium, surrounded by filaments of a fungus. Generally, most of a lichen's bulk is made of interwoven fungal filaments,[34] but this is reversed in filamentous and gelatinous lichens.[25] The fungus is called a mycobiont. The photosynthesizing organism is called a photobiont. Algal photobionts are called phycobionts.[35] Cyanobacteria photobionts are called cyanobionts.[35]

The part of a lichen that is not involved in reproduction, the "body" or "vegetative tissue" of a lichen, is called the thallus. The thallus form is very different from any form where the fungus or alga are growing separately. The thallus is made up of filaments of the fungus called hyphae. The filaments grow by branching then rejoining to create a mesh, which is called being "anastomosed". The mesh of fungal filaments may be dense or loose.

Generally, the fungal mesh surrounds the algal or cyanobacterial cells, often enclosing them within complex fungal tissues that are unique to lichen associations. The thallus may or may not have a protective "skin" of densely packed fungal filaments, often containing a second fungal species,[1] which is called a cortex. Fruticose lichens have one cortex layer wrapping around the "branches". Foliose lichens have an upper cortex on the top side of the "leaf", and a separate lower cortex on the bottom side. Crustose and squamulose lichens have only an upper cortex, with the "inside" of the lichen in direct contact with the surface they grow on (the substrate). Even if the edges peel up from the substrate and appear flat and leaf-like, they lack a lower cortex, unlike foliose lichens. Filamentous, byssoid, leprose,[29] gelatinous, and other lichens do not have a cortex, which is called being ecorticate.[36]

 
Schematic cross section of foliose lichen:
(a) The cortex is the outer layer of tightly woven fungus filaments (hyphae)
(b) This photobiont layer has photosynthesizing green algae
(c) Loosely packed hyphae in the medulla
(d) A tightly woven lower cortex
(e) Anchoring hyphae called rhizines where the fungus attaches to the substrate

Fruticose, foliose, crustose, and squamulose lichens generally have up to three different types of tissue, differentiated by having different densities of fungal filaments.[34] The top layer, where the lichen contacts the environment, is called a cortex.[34] The cortex is made of densely tightly woven, packed, and glued together (agglutinated) fungal filaments.[34] The dense packing makes the cortex act like a protective "skin", keeping other organisms out, and reducing the intensity of sunlight on the layers below.[34] The cortex layer can be up to several hundred micrometers (μm) in thickness (less than a millimeter).[37] The cortex may be further topped by an epicortex of secretions, not cells, 0.6–1 μm thick in some lichens.[37] This secretion layer may or may not have pores.[37]

Below the cortex layer is a layer called the photobiontic layer or symbiont layer.[27][34] The symbiont layer has less densely packed fungal filaments, with the photosynthetic partner embedded in them.[34] The less dense packing allows air circulation during photosynthesis, similar to the anatomy of a leaf.[34] Each cell or group of cells of the photobiont is usually individually wrapped by hyphae, and in some cases penetrated by a haustorium.[25] In crustose and foliose lichens, algae in the photobiontic layer are diffuse among the fungal filaments, decreasing in gradation into the layer below. In fruticose lichens, the photobiontic layer is sharply distinct from the layer below.[25]

The layer beneath the symbiont layer is called the medulla. The medulla is less densely packed with fungal filaments than the layers above. In foliose lichens, there is usually, as in Peltigera,[30]: 159  another densely packed layer of fungal filaments called the lower cortex.[29][34] Root-like fungal structures called rhizines (usually)[30]: 159  grow from the lower cortex to attach or anchor the lichen to the substrate.[2][29] Fruticose lichens have a single cortex wrapping all the way around the "stems" and "branches".[30] The medulla is the lowest layer, and may form a cottony white inner core for the branchlike thallus, or it may be hollow.[30]: 159  Crustose and squamulose lichens lack a lower cortex, and the medulla is in direct contact with the substrate that the lichen grows on.

In crustose areolate lichens, the edges of the areolas peel up from the substrate and appear leafy. In squamulose lichens the part of the lichen thallus that is not attached to the substrate may also appear leafy. But these leafy parts lack a lower cortex, which distinguishes crustose and squamulose lichens from foliose lichens.[34] Conversely, foliose lichens may appear flattened against the substrate like a crustose lichen, but most of the leaf-like lobes can be lifted up from the substrate because it is separated from it by a tightly packed lower cortex.[29]

Gelatinous,[30]: 159  byssoid, and leprose lichens lack a cortex (are ecorticate), and generally have only undifferentiated tissue, similar to only having a symbiont layer.[citation needed]

In lichens that include both green algal and cyanobacterial symbionts, the cyanobacteria may be held on the upper or lower surface in small pustules called cephalodia.

Pruinia is a whitish coating on top of an upper surface.[38] An epinecral layer is "a layer of horny dead fungal hyphae with indistinct lumina in or near the cortex above the algal layer".[38]

In August 2016, it was reported that some macrolichens have more than one species of fungus in their tissues.[1]

Physiology

Symbiotic relation

Main article: Symbiosis in lichens

Lichens are fungi that have discovered agriculture

— Trevor Goward[39]

A lichen is a composite organism that emerges from algae or cyanobacteria living among the filaments (hyphae) of the fungi in a mutually beneficial symbiotic relationship. The fungi benefit from the carbohydrates produced by the algae or cyanobacteria via photosynthesis. The algae or cyanobacteria benefit by being protected from the environment by the filaments of the fungi, which also gather moisture and nutrients from the environment, and (usually) provide an anchor to it. Although some photosynthetic partners in a lichen can survive outside the lichen, the lichen symbiotic association extends the ecological range of both partners, whereby most descriptions of lichen associations describe them as symbiotic. Both partners gain water and mineral nutrients mainly from the atmosphere, through rain and dust. The fungal partner protects the alga by retaining water, serving as a larger capture area for mineral nutrients and, in some cases, provides minerals obtained from the substrate. If a cyanobacterium is present, as a primary partner or another symbiont in addition to a green alga as in certain tripartite lichens, they can fix atmospheric nitrogen, complementing the activities of the green alga.

In three different lineages the fungal partner has independently lost the mitochondrial gene atp9, which has key functions in mitochondrial energy production. The loss makes the fungi completely dependent on their symbionts.[40]

The algal or cyanobacterial cells are photosynthetic and, as in plants, they reduce atmospheric carbon dioxide into organic carbon sugars to feed both symbionts. Phycobionts (algae) produce sugar alcohols (ribitol, sorbitol, and erythritol), which are absorbed by the mycobiont (fungus).[35] Cyanobionts produce glucose.[35] Lichenized fungal cells can make the photobiont "leak" out the products of photosynthesis, where they can then be absorbed by the fungus.[7]: 5 

It appears many, probably the majority, of lichen also live in a symbiotic relationship with an order of basidiomycete yeasts called Cyphobasidiales. The absence of this third partner could explain why growing lichen in the laboratory is difficult. The yeast cells are responsible for the formation of the characteristic cortex of the lichen thallus, and could also be important for its shape.[41]

The lichen combination of alga or cyanobacterium with a fungus has a very different form (morphology), physiology, and biochemistry than the component fungus, alga, or cyanobacterium growing by itself, naturally or in culture. The body (thallus) of most lichens is different from those of either the fungus or alga growing separately. When grown in the laboratory in the absence of its photobiont, a lichen fungus develops as a structureless, undifferentiated mass of fungal filaments (hyphae). If combined with its photobiont under appropriate conditions, its characteristic form associated with the photobiont emerges, in the process called morphogenesis.[4] In a few remarkable cases, a single lichen fungus can develop into two very different lichen forms when associating with either a green algal or a cyanobacterial symbiont. Quite naturally, these alternative forms were at first considered to be different species, until they were found growing in a conjoined manner.[citation needed]

Evidence that lichens are examples of successful symbiosis is the fact that lichens can be found in almost every habitat and geographic area on the planet.[12] Two species in two genera of green algae are found in over 35% of all lichens, but can only rarely be found living on their own outside of a lichen.[42]

In a case where one fungal partner simultaneously had two green algae partners that outperform each other in different climates, this might indicate having more than one photosynthetic partner at the same time might enable the lichen to exist in a wider range of habitats and geographic locations.[12]

At least one form of lichen, the North American beard-like lichens, are constituted of not two but three symbiotic partners: an ascomycetous fungus, a photosynthetic alga, and, unexpectedly, a basidiomycetous yeast.[43]

Phycobionts can have a net output of sugars with only water vapor.[35] The thallus must be saturated with liquid water for cyanobionts to photosynthesize.[35]

Algae produce sugars that are absorbed by the fungus by diffusion into special fungal hyphae called appressoria or haustoria in contact with the wall of the algal cells.[44] The appressoria or haustoria may produce a substance that increases permeability of the algal cell walls, and may penetrate the walls.[44] The algae may contribute up to 80% of their sugar production to the fungus.[44]

Ecology

Lichen associations may be examples of mutualism or commensalism, but the lichen relationship can be considered parasitic[45] under circumstances where the photosynthetic partner can exist in nature independently of the fungal partner, but not vice versa. Photobiont cells are routinely destroyed in the course of nutrient exchange. The association continues because reproduction of the photobiont cells matches the rate at which they are destroyed.[45] The fungus surrounds the algal cells,[8] often enclosing them within complex fungal tissues unique to lichen associations. In many species the fungus penetrates the algal cell wall,[8] forming penetration pegs (haustoria) similar to those produced by pathogenic fungi that feed on a host.[28][46] Cyanobacteria in laboratory settings can grow faster when they are alone rather than when they are part of a lichen.

Miniature ecosystem and holobiont theory

Symbiosis in lichens is so well-balanced that lichens have been considered to be relatively self-contained miniature ecosystems in and of themselves.[12][13] It is thought that lichens may be even more complex symbiotic systems that include non-photosynthetic bacterial communities performing other functions as partners in a holobiont.[14][15]

Many lichens are very sensitive to environmental disturbances and can be used to cheaply[8] assess air pollution,[47][48][49] ozone depletion, and metal contamination. Lichens have been used in making dyes, perfumes,[50] and in traditional medicines. A few lichen species are eaten by insects[8] or larger animals, such as reindeer.[51] Lichens are widely used as environmental indicators or bio-indicators. When air is very badly polluted with sulphur dioxide, there may be no lichens present; only some green algae can tolerate those conditions. If the air is clean, then shrubby, hairy and leafy lichens become abundant. A few lichen species can tolerate fairly high levels of pollution, and are commonly found in urban areas, on pavements, walls and tree bark. The most sensitive lichens are shrubby and leafy, while the most tolerant lichens are all crusty in appearance. Since industrialisation, many of the shrubby and leafy lichens such as Ramalina, Usnea and Lobaria species have very limited ranges, often being confined to the areas which have the cleanest air.

Lichenicolous fungi

Some fungi can only be found living on lichens as obligate parasites. These are referred to as lichenicolous fungi, and are a different species from the fungus living inside the lichen; thus they are not considered to be part of the lichen.[52]

Reaction to water

Moisture makes the cortex become more transparent.[7]: 4  This way, the algae can conduct photosynthesis when moisture is available, and is protected at other times. When the cortex is more transparent, the algae show more clearly and the lichen looks greener.

Metabolites, metabolite structures and bioactivity

Lichens can show intense antioxidant activity.[53][54] Secondary metabolites are often deposited as crystals in the apoplast.[55] Secondary metabolites are thought to play a role in preference for some substrates over others.[55]

Sometimes lichens contain structures made from fungal metabolites, for example crustose lichens sometimes have a polysaccharide[clarification needed] layer in the cortex.[citation needed]

Growth rate

Lichens often have a regular but very slow growth rate of less than a millimeter per year.

In crustose lichens, the area along the margin is where the most active growth is taking place.[30]: 159  Most crustose lichens grow only 1–2 mm in diameter per year.

Life span

Lichens may be long-lived, with some considered to be among the oldest living organisms.[4][16] Lifespan is difficult to measure because what defines the "same" individual lichen is not precise.[56] Lichens grow by vegetatively breaking off a piece, which may or may not be defined as the "same" lichen, and two lichens can merge, then becoming the "same" lichen.[56] An Arctic species called "map lichen" (Rhizocarpon geographicum) has been dated at 8,600 years, apparently the world's oldest living organism.[57]

Response to environmental stress

Unlike simple dehydration in plants and animals, lichens may experience a complete loss of body water in dry periods.[8] Lichens are capable of surviving extremely low levels of water content (poikilohydric).[58]: 5–6  They quickly absorb water when it becomes available again, becoming soft and fleshy.[8]

In tests, lichen survived and showed remarkable results on the adaptation capacity of photosynthetic activity within the simulation time of 34 days under Martian conditions in the Mars Simulation Laboratory (MSL) maintained by the German Aerospace Center (DLR).[59][60]

The European Space Agency has discovered that lichens can survive unprotected in space. In an experiment led by Leopoldo Sancho from the Complutense University of Madrid, two species of lichen—Rhizocarpon geographicum and Xanthoria elegans—were sealed in a capsule and launched on a Russian Soyuz rocket 31 May 2005. Once in orbit, the capsules were opened and the lichens were directly exposed to the vacuum of space with its widely fluctuating temperatures and cosmic radiation. After 15 days, the lichens were brought back to earth and were found to be unchanged in their ability to photosynthesize.[61][62]

Reproduction and dispersal

Vegetative reproduction

 
Xanthoparmelia sp. with dark-colored reproductive structures (disc-like apothecia) at center, surrounded by a pale coloured vegetative thallus.

Many lichens reproduce asexually, either by a piece breaking off and growing on its own (vegetative reproduction) or through the dispersal of diaspores containing a few algal cells surrounded by fungal cells.[2] Because of the relative lack of differentiation in the thallus, the line between diaspore formation and vegetative reproduction is often blurred. Fruticose lichens can easily[citation needed] fragment, and new lichens can grow from the fragment (vegetative reproduction).[citation needed] Many lichens break up into fragments when they dry, dispersing themselves by wind action, to resume growth when moisture returns.[63][64] Soredia (singular: "soredium") are small groups of algal cells surrounded by fungal filaments that form in structures called soralia, from which the soredia can be dispersed by wind.[2] Isidia (singular: "isidium") are branched, spiny, elongated, outgrowths from the thallus that break off for mechanical dispersal.[2] Lichen propagules (diaspores) typically contain cells from both partners, although the fungal components of so-called "fringe species" rely instead on algal cells dispersed by the "core species".[65]

Sexual reproduction

 
Disc-like apothecia (left) and thallus (right) on a foliose lichen

Structures involved in reproduction often appear as discs, bumps, or squiggly lines on the surface of the thallus.[7]: 4  Though it has been argued that sexual reproduction in photobionts is selected against, there is strong evidence that suggests meiotic activities (sexual reproduction) in Trebouxia.[66][67] Many lichen fungi reproduce sexually like other fungi, producing spores formed by meiosis and fusion of gametes. Following dispersal, such fungal spores must meet with a compatible algal partner before a functional lichen can form.

Some lichen fungi belong to the phylum Basidiomycota (basidiolichens) and produce mushroom-like reproductive structures resembling those of their nonlichenized relatives.

Most lichen fungi belong to Ascomycetes (ascolichens). Among the ascolichens, spores are produced in spore-producing structures called ascomata.[7] The most common types of ascomata are the apothecium (plural: apothecia) and perithecium (plural: perithecia).[7]: 14  Apothecia are usually cups or plate-like discs located on the top surface of the lichen thallus. When apothecia are shaped like squiggly line segments instead of like discs, they are called lirellae.[7]: 14  Perithecia are shaped like flasks that are immersed in the lichen thallus tissue, which has a small hole for the spores to escape the flask, and appear like black dots on the lichen surface.[7]: 14 

The three most common spore body types are raised discs called apothecia (singular: apothecium), bottle-like cups with a small hole at the top called perithecia (singular: perithecium), and pycnidia (singular: pycnidium), shaped like perithecia but without asci (an ascus is the structure that contains and releases the sexual spores in fungi of the Ascomycota).[68]

The apothecium has a layer of exposed spore-producing cells called asci (singular: ascus), and is usually a different color from the thallus tissue.[7]: 14  When the apothecium has an outer margin, the margin is called the exciple.[7]: 14  When the exciple has a color similar to colored thallus tissue the apothecium or lichen is called lecanorine, meaning similar to members of the genus Lecanora.[7]: 14  When the exciple is blackened like carbon it is called lecideine meaning similar to members of the genus Lecidea.[7]: 14  When the margin is pale or colorless it is called biatorine.[7]: 14 

 
Crust-like thallus with pseudopodetia

A "podetium" (plural: podetia) is a lichenized stalk-like structure of the fruiting body rising from the thallus, associated with some fungi that produce a fungal apothecium.[27] Since it is part of the reproductive tissue, podetia are not considered part of the main body (thallus), but may be visually prominent.[27] The podetium may be branched, and sometimes cup-like. They usually bear the fungal pycnidia or apothecia or both.[27] Many lichens have apothecia that are visible to the naked eye.[2]

Most lichens produce abundant sexual structures.[69] Many species appear to disperse only by sexual spores.[69] For example, the crustose lichens Graphis scripta and Ochrolechia parella produce no symbiotic vegetative propagules. Instead, the lichen-forming fungi of these species reproduce sexually by self-fertilization (i.e. they are homothallic). This breeding system may enable successful reproduction in harsh environments.[69]

Mazaedia (singular: mazaedium) are apothecia shaped like a dressmaker's pin in pin lichens, where the fruiting body is a brown or black mass of loose ascospores enclosed by a cup-shaped exciple, which sits on top of a tiny stalk.[7]: 15 

Taxonomy and classification

Lichens are classified by the fungal component. Lichen species are given the same scientific name (binomial name) as the fungus species in the lichen. Lichens are being integrated into the classification schemes for fungi. The alga bears its own scientific name, which bears no relationship to that of the lichen or fungus.[70] There are about 13,500–17,000 identified lichen species.[44] Nearly 20% of known fungal species are associated with lichens.[44]

"Lichenized fungus" may refer to the entire lichen, or to just the fungus. This may cause confusion without context. A particular fungus species may form lichens with different algae species, giving rise to what appear to be different lichen species, but which are still classified (as of 2014) as the same lichen species.[71]

Formerly, some lichen taxonomists placed lichens in their own division, the Mycophycophyta, but this practice is no longer accepted because the components belong to separate lineages. Neither the ascolichens nor the basidiolichens form monophyletic lineages in their respective fungal phyla, but they do form several major solely or primarily lichen-forming groups within each phylum.[72] Even more unusual than basidiolichens is the fungus Geosiphon pyriforme, a member of the Glomeromycota that is unique in that it encloses a cyanobacterial symbiont inside its cells. Geosiphon is not usually considered to be a lichen, and its peculiar symbiosis was not recognized for many years. The genus is more closely allied to endomycorrhizal genera. Fungi from Verrucariales also form marine lichens with the brown algae Petroderma maculiforme,[73] and have a symbiotic relationship with seaweed (such as rockweed) and Blidingia minima, where the algae are the dominant components. The fungi is thought to help the rockweeds to resist desiccation when exposed to air.[74][75] In addition, lichens can also use yellow-green algae (Heterococcus) as their symbiotic partner.[76]

Lichens independently emerged from fungi associating with algae and cyanobacteria multiple times throughout history.[77]

Fungi

The fungal component of a lichen is called the mycobiont. The mycobiont may be an Ascomycete or Basidiomycete.[10] The associated lichens are called either ascolichens or basidiolichens, respectively. Living as a symbiont in a lichen appears to be a successful way for a fungus to derive essential nutrients, since about 20% of all fungal species have acquired this mode of life.[78]

Thalli produced by a given fungal symbiont with its differing partners may be similar,[citation needed] and the secondary metabolites identical,[citation needed] indicating[citation needed] that the fungus has the dominant role in determining the morphology of the lichen. But the same mycobiont with different photobionts may also produce very different growth forms.[71] Lichens are known in which there is one fungus associated with two or even three algal species.

Although each lichen thallus generally appears homogeneous, some evidence seems to suggest that the fungal component may consist of more than one genetic individual of that species.[citation needed]

Two or more fungal species can interact to form the same lichen.[79]

The following table lists the orders and families of fungi that include lichen-forming species.

Photobionts

The photosynthetic partner in a lichen is called a photobiont. The photobionts in lichens come from a variety of simple prokaryotic and eukaryotic organisms. In the majority of lichens the photobiont is a green alga (Chlorophyta) or a cyanobacterium. In some lichens both types are present; in such cases, the alga is typically the primary partner, with the cyanobacteria being located in cryptic pockets.[80] Algal photobionts are called phycobionts, while cyanobacterial photobionts are called cyanobionts.[35] According to one source, about 90% of all known lichens have phycobionts, and about 10% have cyanobionts,[35] while another source states that two thirds of lichens have green algae as phycobiont, and about one third have a cyanobiont.[28] Approximately 100 species of photosynthetic partners from 40[35] genera and five distinct classes (prokaryotic: Cyanophyceae; eukaryotic: Trebouxiophyceae, Phaeophyceae, Chlorophyceae) have been found to associate with the lichen-forming fungi.[81]

Common algal photobionts are from the genera Trebouxia, Trentepohlia, Pseudotrebouxia, or Myrmecia. Trebouxia is the most common genus of green algae in lichens, occurring in about 40% of all lichens. "Trebouxioid" means either a photobiont that is in the genus Trebouxia, or resembles a member of that genus, and is therefore presumably a member of the class Trebouxiophyceae.[27] The second most commonly represented green alga genus is Trentepohlia.[28] Overall, about 100 species of eukaryotes are known to occur as photobionts in lichens. All the algae are probably able to exist independently in nature as well as in the lichen.[79]

A "cyanolichen" is a lichen with a cyanobacterium as its main photosynthetic component (photobiont).[82] Most cyanolichen are also ascolichens, but a few basidiolichen like Dictyonema and Acantholichen have cyanobacteria as their partner.[83]

The most commonly occurring cyanobacterium genus is Nostoc.[79] Other[28] common cyanobacterium photobionts are from Scytonema.[10] Many cyanolichens are small and black, and have limestone as the substrate.[citation needed] Another cyanolichen group, the jelly lichens of the genera Collema or Leptogium are gelatinous and live on moist soils. Another group of large and foliose species including Peltigera, Lobaria, and Degelia are grey-blue, especially when dampened or wet. Many of these characterize the Lobarion communities of higher rainfall areas in western Britain, e.g., in the Celtic rain forest. Strains of cyanobacteria found in various cyanolichens are often closely related to one another.[84] They differ from the most closely related free-living strains.[84]

The lichen association is a close symbiosis. It extends the ecological range of both partners but is not always obligatory for their growth and reproduction in natural environments, since many of the algal symbionts can live independently. A prominent example is the alga Trentepohlia, which forms orange-coloured populations on tree trunks and suitable rock faces. Lichen propagules (diaspores) typically contain cells from both partners, although the fungal components of so-called "fringe species" rely instead on algal cells dispersed by the "core species".[65]

The same cyanobiont species can occur in association with different fungal species as lichen partners.[85] The same phycobiont species can occur in association with different fungal species as lichen partners.[35] More than one phycobiont may be present in a single thallus.[35]

A single lichen may contain several algal genotypes.[86][87] These multiple genotypes may better enable response to adaptation to environmental changes, and enable the lichen to inhabit a wider range of environments.[88]

Controversy over classification method and species names

There are about 20,000 known lichen species.[10] But what is meant by "species" is different from what is meant by biological species in plants, animals, or fungi, where being the same species implies that there is a common ancestral lineage.[10] Because lichens are combinations of members of two or even three different biological kingdoms, these components must have a different ancestral lineage from each other. By convention, lichens are still called "species" anyway, and are classified according to the species of their fungus, not the species of the algae or cyanobacteria. Lichens are given the same scientific name (binomial name) as the fungus in them, which may cause some confusion. The alga bears its own scientific name, which has no relationship to the name of the lichen or fungus.[70]

Depending on context, "lichenized fungus" may refer to the entire lichen, or to the fungus when it is in the lichen, which can be grown in culture in isolation from the algae or cyanobacteria. Some algae and cyanobacteria are found naturally living outside of the lichen. The fungal, algal, or cyanobacterial component of a lichen can be grown by itself in culture. When growing by themselves, the fungus, algae, or cyanobacteria have very different properties than those of the lichen. Lichen properties such as growth form, physiology, and biochemistry, are very different from the combination of the properties of the fungus and the algae or cyanobacteria.

The same fungus growing in combination with different algae or cyanobacteria, can produce lichens that are very different in most properties, meeting non-DNA criteria for being different "species". Historically, these different combinations were classified as different species. When the fungus is identified as being the same using modern DNA methods, these apparently different species get reclassified as the same species under the current (2014) convention for classification by fungal component. This has led to debate about this classification convention. These apparently different "species" have their own independent evolutionary history.[2][71]

There is also debate as to the appropriateness of giving the same binomial name to the fungus, and to the lichen that combines that fungus with an alga or cyanobacterium (synecdoche). This is especially the case when combining the same fungus with different algae or cyanobacteria produces dramatically different lichen organisms, which would be considered different species by any measure other than the DNA of the fungal component. If the whole lichen produced by the same fungus growing in association with different algae or cyanobacteria, were to be classified as different "species", the number of "lichen species" would be greater.

Diversity

The largest number of lichenized fungi occur in the Ascomycota, with about 40% of species forming such an association.[70] Some of these lichenized fungi occur in orders with nonlichenized fungi that live as saprotrophs or plant parasites (for example, the Leotiales, Dothideales, and Pezizales). Other lichen fungi occur in only five orders in which all members are engaged in this habit (Orders Graphidales, Gyalectales, Peltigerales, Pertusariales, and Teloschistales). Overall, about 98% of lichens have an ascomycetous mycobiont.[89] Next to the Ascomycota, the largest number of lichenized fungi occur in the unassigned fungi imperfecti, a catch-all category for fungi whose sexual form of reproduction has never been observed.[citation needed] Comparatively few basidiomycetes are lichenized, but these include agarics, such as species of Lichenomphalia, clavarioid fungi, such as species of Multiclavula, and corticioid fungi, such as species of Dictyonema.

Identification methods

Lichen identification uses growth form, microscopy and reactions to chemical tests.

The outcome of the "Pd test" is called "Pd", which is also used as an abbreviation for the chemical used in the test, para-phenylenediamine.[27] If putting a drop on a lichen turns an area bright yellow to orange, this helps identify it as belonging to either the genus Cladonia or Lecanora.[27]

Evolution and paleontology

The fossil record for lichens is poor.[90] The extreme habitats that lichens dominate, such as tundra, mountains, and deserts, are not ordinarily conducive to producing fossils.[90][91] There are fossilized lichens embedded in amber. The fossilized Anzia is found in pieces of amber in northern Europe and dates back approximately 40 million years.[92] Lichen fragments are also found in fossil leaf beds, such as Lobaria from Trinity County in northern California, USA, dating back to the early to middle Miocene.[93]

The oldest fossil lichen in which both symbiotic partners have been recovered is Winfrenatia, an early zygomycetous (Glomeromycotan) lichen symbiosis that may have involved controlled parasitism,[citation needed] is permineralized in the Rhynie Chert of Scotland, dating from early Early Devonian, about 400 million years ago.[94] The slightly older fossil Spongiophyton has also been interpreted as a lichen on morphological[95] and isotopic[96] grounds, although the isotopic basis is decidedly shaky.[97] It has been demonstrated that Silurian-Devonian fossils Nematothallus[98] and Prototaxites[99] were lichenized. Thus lichenized Ascomycota and Basidiomycota were a component of Early Silurian-Devonian terrestrial ecosystems.[100][101] Newer research suggests that lichen evolved after the evolution of land plants.[102]

The ancestral ecological state of both Ascomycota and Basidiomycota was probably saprobism, and independent lichenization events may have occurred multiple times.[103][104] In 1995, Gargas and colleagues proposed that there were at least five independent origins of lichenization; three in the basidiomycetes and at least two in the Ascomycetes.[105] Lutzoni et al. (2001) suggest lichenization probably evolved earlier and was followed by multiple independent losses. Some non-lichen-forming fungi may have secondarily lost the ability to form a lichen association. As a result, lichenization has been viewed as a highly successful nutritional strategy.[106][107]

Lichenized Glomeromycota may extend well back into the Precambrian. Lichen-like fossils consisting of coccoid cells (cyanobacteria?) and thin filaments (mucoromycotinan Glomeromycota?) are permineralized in marine phosphorite of the Doushantuo Formation in southern China. These fossils are thought to be 551 to 635 million years old or Ediacaran.[108] Ediacaran acritarchs also have many similarities with Glomeromycotan vesicles and spores.[109] It has also been claimed that Ediacaran fossils including Dickinsonia,[110] were lichens,[111] although this claim is controversial.[112] Endosymbiotic Glomeromycota comparable with living Geosiphon may extend back into the Proterozoic in the form of 1500 million year old Horodyskia[113] and 2200 million year old Diskagma.[114] Discovery of these fossils suggest that fungi developed symbiotic partnerships with photoautotrophs long before the evolution of vascular plants, though the Ediacaran lichen hypothesis is largely rejected due to an inappropriate definition of lichens based on taphonomy and substrate ecology.[115] However, a 2019 study by the same scientist who rejected the Ediacaran lichen hypothesis, Nelsen, used new time-calibrated phylogenies to conclude that there is no evidence of lichen before the existence of vascular plants.[116]

Lecanoromycetes, one of the most common classes of lichen-forming fungi, diverged from its ancestor, which may have also been lichen forming, around 258 million years ago, during the late Paleozoic period. However, the closely related clade Euritiomycetes appears to have become lichen-forming only 52 million years ago, during the early Cenozoic period.[117]

Ecology and interactions with environment

Substrates and habitats

 
Lichens on a limestone statue on a tower of Regensburg Cathedral

Lichens cover about 7% of the planet's surface and grow on and in a wide range of substrates and habitats, including some of the most extreme conditions on earth.[118] They are abundant growing on bark, leaves, and hanging from epiphyte branches in rain forests and in temperate woodland. They grow on bare rock, walls, gravestones, roofs, and exposed soil surfaces. They can survive in some of the most extreme environments on Earth: arctic tundra, hot dry deserts, rocky coasts, and toxic slag heaps. They can live inside solid rock, growing between the grains, and in the soil as part of a biological soil crust in arid habitats such as deserts. Some lichens do not grow on anything, living out their lives blowing about the environment.[2]

When growing on mineral surfaces, some lichens slowly decompose their substrate by chemically degrading and physically disrupting the minerals, contributing to the process of weathering by which rocks are gradually turned into soil. While this contribution to weathering is usually benign, it can cause problems for artificial stone structures. For example, there is an ongoing lichen growth problem on Mount Rushmore National Memorial that requires the employment of mountain-climbing conservators to clean the monument.[119]

Lichens are not parasites on the plants they grow on, but only use them as a substrate. The fungi of some lichen species may "take over" the algae of other lichen species.[8][120] Lichens make their own food from their photosynthetic parts and by absorbing minerals from the environment.[8] Lichens growing on leaves may have the appearance of being parasites on the leaves, but they are not. Some lichens in Diploschistes parasitise other lichens. Diploschistes muscorum starts its development in the tissue of a host Cladonia species.[46]: 30 [28]: 171 

In the arctic tundra, lichens, together with mosses and liverworts, make up the majority of the ground cover, which helps insulate the ground and may provide forage for grazing animals. An example is "reindeer moss", which is a lichen, not a moss.[8]

There are only two species of known permanently submerged lichens; Hydrothyria venosa is found in fresh water environments, and Verrucaria serpuloides is found in marine environments.[121]

A crustose lichen that grows on rock is called a saxicolous lichen.[27][30]: 159  Crustose lichens that grow on the rock are epilithic, and those that grow immersed inside rock, growing between the crystals with only their fruiting bodies exposed to the air, are called endolithic lichens.[26][30]: 159 [82] A crustose lichen that grows on bark is called a corticolous lichen.[30]: 159  A lichen that grows on wood from which the bark has been stripped is called a lignicolous lichen.[36] Lichens that grow immersed inside plant tissues are called endophloidic lichens or endophloidal lichens.[26][30]: 159  Lichens that use leaves as substrates, whether the leaf is still on the tree or on the ground, are called epiphyllous or foliicolous.[35] A terricolous lichen grows on the soil as a substrate. Many squamulous lichens are terricolous.[30]: 159  Umbilicate lichens are foliose lichens that are attached to the substrate at only one point.[26] A vagrant lichen is not attached to a substrate at all, and lives its life being blown around by the wind.

Lichens and soils

In addition to distinct physical mechanisms by which lichens break down raw stone, recent studies indicate lichens attack stone chemically, entering newly chelated minerals into the ecology.

The lichen exudates, which have powerful chelating capacity, the widespread occurrence of mineral neoformation, particularly metal oxalates, together with the characteristics of weathered substrates, all confirm the significance of lichens as chemical weathering agents.[122]

Over time, this activity creates new fertile soil from lifeless stone.

Lichens may be important in contributing nitrogen to soils in some deserts through being eaten, along with their rock substrate, by snails, which then defecate, putting the nitrogen into the soils.[123] Lichens help bind and stabilize soil sand in dunes.[2] In deserts and semi-arid areas, lichens are part of extensive, living biological soil crusts, essential for maintaining the soil structure.[2] Lichens have a long fossil record in soils dating back 2.2 billion years.[114]

Ecological interactions

Lichens are pioneer species, among the first living things to grow on bare rock or areas denuded of life by a disaster.[2] Lichens may have to compete with plants for access to sunlight, but because of their small size and slow growth, they thrive in places where higher plants have difficulty growing. Lichens are often the first to settle in places lacking soil, constituting the sole vegetation in some extreme environments such as those found at high mountain elevations and at high latitudes.[124] Some survive in the tough conditions of deserts, and others on frozen soil of the Arctic regions.[125]

A major ecophysiological advantage of lichens is that they are poikilohydric (poikilo- variable, hydric- relating to water), meaning that though they have little control over the status of their hydration, they can tolerate irregular and extended periods of severe desiccation. Like some mosses, liverworts, ferns and a few resurrection plants, upon desiccation, lichens enter a metabolic suspension or stasis (known as cryptobiosis) in which the cells of the lichen symbionts are dehydrated to a degree that halts most biochemical activity. In this cryptobiotic state, lichens can survive wider extremes of temperature, radiation and drought in the harsh environments they often inhabit.

 
Lichens suppress the growth of mosses and higher plants around them

Lichens do not have roots and do not need to tap continuous reservoirs of water like most higher plants, thus they can grow in locations impossible for most plants, such as bare rock, sterile soil or sand, and various artificial structures such as walls, roofs, and monuments. Many lichens also grow as epiphytes (epi- on the surface, phyte- plant) on plants, particularly on the trunks and branches of trees. When growing on plants, lichens are not parasites; they do not consume any part of the plant nor poison it. Lichens produce allelopathic chemicals that inhibit the growth of mosses. Some ground-dwelling lichens, such as members of the subgenus Cladina (reindeer lichens), produce allelopathic chemicals that leach into the soil and inhibit the germination of seeds, spruce and other plants.[126] Stability (that is, longevity) of their substrate is a major factor of lichen habitats. Most lichens grow on stable rock surfaces or the bark of old trees, but many others grow on soil and sand. In these latter cases, lichens are often an important part of soil stabilization; indeed, in some desert ecosystems, vascular (higher) plant seeds cannot become established except in places where lichen crusts stabilize the sand and help retain water.

Lichens may be eaten by some animals, such as reindeer, living in arctic regions. The larvae of a number of Lepidoptera species feed exclusively on lichens. These include common footman and marbled beauty. They are very low in protein and high in carbohydrates, making them unsuitable for some animals. The Northern flying squirrel uses it for nesting, food and winter water.

Effects of air pollution

 
Some lichens, like the foliose Lobaria pulmonaria, are sensitive to air pollution.

If lichens are exposed to air pollutants at all times, without any deciduous parts, they are unable to avoid the accumulation of pollutants. Also lacking stomata and a cuticle, lichens may absorb aerosols and gases over the entire thallus surface from which they may readily diffuse to the photobiont layer.[127] Because lichens do not possess roots, their primary source of most elements is the air, and therefore elemental levels in lichens often reflect the accumulated composition of ambient air. The processes by which atmospheric deposition occurs include fog and dew, gaseous absorption, and dry deposition.[128] Consequently, many environmental studies with lichens emphasize their feasibility as effective biomonitors of atmospheric quality.[127][129][130][131][132][133]

Not all lichens are equally sensitive to air pollutants, so different lichen species show different levels of sensitivity to specific atmospheric pollutants.[134] The sensitivity of a lichen to air pollution is directly related to the energy needs of the mycobiont, so that the stronger the dependency of the mycobiont on the photobiont, the more sensitive the lichen is to air pollution.[135] Upon exposure to air pollution, the photobiont may use metabolic energy for repair of its cellular structures that would otherwise be used for maintenance of its photosynthetic activity, therefore leaving less metabolic energy available for the mycobiont. The alteration of the balance between the photobiont and mycobiont can lead to the breakdown of the symbiotic association. Therefore, lichen decline may result not only from the accumulation of toxic substances, but also from altered nutrient supplies that favor one symbiont over the other.[127]

This interaction between lichens and air pollution has been used as a means of monitoring air quality since 1859, with more systematic methods developed by William Nylander in 1866.[2]

Human use

Further information: Ethnolichenology
 
Iwatake (Umbilicaria esculenta) gathering at Kumano in Kishū, by Hiroshige II

Food

Main article: Edible lichen

Lichens are eaten by many different cultures across the world. Although some lichens are only eaten in times of famine, others are a staple food or even a delicacy. Two obstacles are often encountered when eating lichens: lichen polysaccharides are generally indigestible to humans, and lichens usually contain mildly toxic secondary compounds that should be removed before eating. Very few lichens are poisonous, but those high in vulpinic acid or usnic acid are toxic.[136] Most poisonous lichens are yellow.

In the past, Iceland moss (Cetraria islandica) was an important source of food for humans in northern Europe, and was cooked as a bread, porridge, pudding, soup, or salad. Bryoria fremontii (edible horsehair lichen) was an important food in parts of North America, where it was usually pitcooked. Northern peoples in North America and Siberia traditionally eat the partially digested reindeer lichen (Cladina spp.) after they remove it from the rumen of caribou or reindeer that have been killed. Rock tripe (Umbilicaria spp. and Lasalia spp.) is a lichen that has frequently been used as an emergency food in North America, and one species, Umbilicaria esculenta, (iwatake in Japanese) is used in a variety of traditional Korean and Japanese foods.

Lichenometry

Main article: Lichenometry
 
Lichen grown in a Mickey Mouse shape
 
13 years later

Lichenometry is a technique used to determine the age of exposed rock surfaces based on the size of lichen thalli. Introduced by Beschel in the 1950s,[137] the technique has found many applications. it is used in archaeology, palaeontology, and geomorphology. It uses the presumed regular but slow rate of lichen growth to determine the age of exposed rock.[32]: 9 [138] Measuring the diameter (or other size measurement) of the largest lichen of a species on a rock surface indicates the length of time since the rock surface was first exposed. Lichen can be preserved on old rock faces for up to[citation needed] 10,000 years, providing the maximum age limit of the technique, though it is most accurate (within 10% error) when applied to surfaces that have been exposed for less than 1,000 years.[139] Lichenometry is especially useful for dating surfaces less than 500 years old, as radiocarbon dating techniques are less accurate over this period.[140] The lichens most commonly used for lichenometry are those of the genera Rhizocarpon (e.g. the species Rhizocarpon geographicum, map lichen) and Xanthoria.

Biodegradation

Lichens have been shown to degrade polyester resins, as can be seen in archaeological sites in the Roman city of Baelo Claudia in Spain.[141] Lichens can accumulate several environmental pollutants such as lead, copper, and radionuclides.[142] Some species of lichen, such as Parmelia sulcata (called a hammered shield lichen, among other names) and Lobaria pulmonaria (lung lichen), and many in the Cladonia genus, have been shown to produce serine proteases capable of the degradation of pathogenic forms of prion protein (PrP), which may be useful in treating contaminated environmental reservoirs.[143][144][145]

Dyes

Many lichens produce secondary compounds, including pigments that reduce harmful amounts of sunlight and powerful toxins that deter herbivores or kill bacteria. These compounds are very useful for lichen identification, and have had economic importance as dyes such as cudbear or primitive antibiotics.

A pH indicator (which can indicate acidic or basic substances) called litmus is a dye extracted from the lichen Roccella tinctoria ("dyer's weed")[146] by boiling. It gives its name to the well-known litmus test.

Traditional dyes of the Scottish Highlands for Harris tweed[2] and other traditional cloths were made from lichens, including the orange Xanthoria parietina ("common orange lichen") and the grey foliaceous Parmelia saxatilis common on rocks and known colloquially as "crottle".

There are reports dating almost 2,000 years old of lichens being used to make purple and red dyes.[147] Of great historical and commercial significance are lichens belonging to the family Roccellaceae, commonly called orchella weed or orchil. Orcein and other lichen dyes have largely been replaced by synthetic versions.

Traditional medicine and research

Historically, in traditional medicine of Europe, Lobaria pulmonaria was collected in large quantities as "lungwort", due to its lung-like appearance (the "doctrine of signatures" suggesting that herbs can treat body parts that they physically resemble). Similarly, Peltigera leucophlebia ("ruffled freckled pelt") was used as a supposed cure for thrush, due to the resemblance of its cephalodia to the appearance of the disease.[28]

Lichens produce metabolites being researched for their potential therapeutic or diagnostic value.[148] Some metabolites produced by lichens are structurally and functionally similar to broad-spectrum antibiotics while few are associated respectively to antiseptic similarities.[149] Usnic acid is the most commonly studied metabolite produced by lichens.[149] It is also under research as a bactericidal agent against Escherichia coli and Staphylococcus aureus.[150]

Aesthetic appeal

 
Pine forest with Cladonia lichen ground-cover

Colonies of lichens may be spectacular in appearance, dominating the surface of the visual landscape as part of the aesthetic appeal to visitors of Yosemite National Park, Sequoia National Park, and the Bay of Fires.[32]: 2  Orange and yellow lichens add to the ambience of desert trees, tundras, and rocky seashores. Intricate webs of lichens hanging from tree branches add a mysterious aspect to forests. Fruticose lichens are used in model railroading[151] and other modeling hobbies as a material for making miniature trees and shrubs.

In literature

In early Midrashic literature, the Hebrew word "vayilafeth" in Ruth 3:8 is explained as referring to Ruth entwining herself around Boaz like lichen.[152] The 10th century Arab physician, Al-Tamimi, mentions lichens dissolved in vinegar and rose water being used in his day for the treatment of skin diseases and rashes.[153]

The plot of John Wyndham's science fiction novel Trouble with Lichen revolves around an anti-aging chemical extracted from a lichen.

History

 
"Lichenes" fancifully drawn by Ernst Haeckel to emphasize his ideas of symmetry in his Artforms of Nature, 1904

Although lichens had been recognized as organisms for quite some time, it was not until 1867, when Swiss botanist Simon Schwendener proposed his dual theory of lichens, that lichens are a combination of fungi with algae or cyanobacteria, whereby the true nature of the lichen association began to emerge.[154] Schwendener's hypothesis, which at the time lacked experimental evidence, arose from his extensive analysis of the anatomy and development in lichens, algae, and fungi using a light microscope. Many of the leading lichenologists at the time, such as James Crombie and Nylander, rejected Schwendener's hypothesis because the common consensus was that all living organisms were autonomous.[154]

Other prominent biologists, such as Heinrich Anton de Bary, Albert Bernhard Frank, Beatrix Potter, Melchior Treub and Hermann Hellriegel were not so quick to reject Schwendener's ideas and the concept soon spread into other areas of study, such as microbial, plant, animal and human pathogens.[154][155][156] When the complex relationships between pathogenic microorganisms and their hosts were finally identified, Schwendener's hypothesis began to gain popularity. Further experimental proof of the dual nature of lichens was obtained when Eugen Thomas published his results in 1939 on the first successful re-synthesis experiment.[154]

In the 2010s, a new facet of the fungi-algae partnership was discovered. Toby Spribille and colleagues found that many types of lichen that were long thought to be ascomycete-algae pairs were actually ascomycete-basidiomycete-algae trios.[1][157]

Gallery

  •  

    Lobaria pulmonaria, tree lungwort, lung lichen, lung moss; Upper Bavaria, Germany

  •  

    Cladonia macilenta var. bacillaris 'Lipstick Cladonia'

  •  

    Usnea australis, a fruticose form, growing on a tree branch

  •  

    Hypogymnia cf. tubulosa with Bryoria sp. and Tuckermannopsis sp. in the Canadian Rockies

  •  

    Letharia sp. with Bryoria sp. on pine branches near Blackpine Lake, Washington State

  •  

    Lobaria oregana, commonly called 'Lettuce lichen', in the Hoh Rainforest, Washington State

  •  

    A lichen growing on a rock in a Brazilian cloud forest

  •  

    Xanthoparmelia cf. lavicola, a foliose lichen, on basalt.

  •  

    Map lichen (Rhizocarpon geographicum) on rock

  •  

    Physcia millegrana (a foliose lichen), with an unlichenized polypore fungus (bottom right), on a fallen log.

  •  

    Reindeer moss (Cladonia rangiferina)

  •  

    Crustose lichens on limestone in Alta Murgia-Southern Italy

  •  

    Cladonia cf. cristatella, a lichen commonly referred to as 'British Soldiers'. Notice the red tips.

  •  

    A crusty crustose lichen on a wall

  •  

    Lichen on a lilac bush

  •  

    Foliose lichens on rock growing outward and dying in the center. These lichens are at least several decades old.

  •  

    Xanthoria sp. lichen on volcanic rock in Craters of the Moon National Monument (Idaho, USA)

  •  

    Lecanora cf. muralis lichen on the banks of the Bega canal in Timișoara, Romania

  •  

    Microscopic view of lichen growing on a piece of concrete dust.[note 1]

See also

Notes

  1. ^ This was scraped from a dry, concrete-paved section of a drainage ditch. This entire image covers a square that is approximately 1.7 millimeters on a side. The numbered ticks on the scale represent distances of 230 micrometers, or slightly less than 0.25 millimeter.

References

  1. ^ a b c d Spribille, Toby; Tuovinen, Veera; Resl, Philipp; Vanderpool, Dan; Wolinski, Heimo; Aime, M. Catherine; Schneider, Kevin; Stabentheiner, Edith; Toome-Heller, Merje (21 July 2016). "Basidiomycete yeasts in the cortex of ascomycete macrolichens". Science. 353 (6298): 488–92. Bibcode:2016Sci...353..488S. doi:10.1126/science.aaf8287. ISSN 0036-8075. PMC 5793994. PMID 27445309.
  2. ^ a b c d e f g h i j k l m n o . Australian National Botanic Gardens. Archived from the original on 2 July 2014. Retrieved 10 October 2014.
  3. ^ Introduction to Lichens – An Alliance between Kingdoms 22 August 2014 at the Wayback Machine. University of California Museum of Paleontology.
  4. ^ a b c d e Brodo, Irwin M. and Duran Sharnoff, Sylvia (2001) Lichens of North America. ISBN 978-0300082494.
  5. ^ a b Galloway, D.J. (13 May 1999). . Australian National Botanic Gardens. Archived from the original on 6 December 2014.
  6. ^ Margulis, Lynn; Barreno, EVA (2003). "Looking at Lichens". BioScience. 53 (8): 776. doi:10.1641/0006-3568(2003)053[0776:LAL]2.0.CO;2.
  7. ^ a b c d e f g h i j k l m n o p q r Sharnoff, Stephen (2014) Field Guide to California Lichens, Yale University Press. ISBN 978-0-300-19500-2
  8. ^ a b c d e f g h i j k Speer, Brian R; Ben Waggoner (May 1997). "Lichens: Life History & Ecology". University of California Museum of Paleontology. from the original on 2 May 2015. Retrieved 28 April 2015.
  9. ^ Asplund, Johan; Wardle, David A. (11 October 2016). "How lichens impact on terrestrial community and ecosystem properties". Biological Reviews. 92 (3): 1720–1738. doi:10.1111/brv.12305. hdl:11250/2578209. ISSN 1464-7931. PMID 27730713. S2CID 25453156.
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Further reading

  • Jorgensen, Per M., and Lücking, Robert (April 2018). "The 'Rustici Pauperrimi': A Linnaean Myth about Lichens Rectified". The Linnean 34(1), pp. 9–12.
 
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Look up lichen in Wiktionary, the free dictionary.

January 26, 2023
lichen, other, uses, disambiguation, lichen, kən, also, litch, composite, organism, that, arises, from, algae, cyanobacteria, living, among, filaments, multiple, fungi, species, mutualistic, relationship, have, properties, different, from, those, their, compon. For other uses see Lichen disambiguation A lichen ˈ l aɪ k en LY ken UK also ˈ l ɪ tʃ en LITCH en is a composite organism that arises from algae or cyanobacteria living among filaments of multiple fungi species 1 in a mutualistic relationship 2 3 4 Lichens have properties different from those of their component organisms They come in many colors sizes and forms and are sometimes plant like but are not plants They may have tiny leafless branches fruticose flat leaf like structures foliose grow crust like adhering tightly to a surface substrate like a thick coat of paint crustose 5 have a powder like appearance leprose or other growth forms 6 A tree covered with leafy foliose lichens and shrubby fruticose lichens Common lichen growth formsLetharia vulpina wolf lichen grows like a multiple branched tuft or leafless mini shrub so it has a fruticose growth form Flavoparmelia caperata has leaf like structures so it is foliose Caloplaca marina grows like an orange crust coating the rock so it is crustose Caloplaca thallincola sv grows like a crust and in a pattern that radiates outward from the center so it has a crustose placodioid growth form Pannaria lurida forms small leaf like scales crustose below but free at the tips so it is squamulose Chrysothrix chlorina grows like powder dusted on the rock so it is leprose Collema nigrescens is gelatinous without internal structure for its parts A macrolichen is a lichen that is either bush like or leafy all other lichens are termed microlichens 2 Here macro and micro do not refer to size but to the growth form 2 Common names for lichens may contain the word moss e g reindeer moss Iceland moss and lichens may superficially look like and grow with mosses but they are not closely related to mosses or any plant 4 3 Lichens do not have roots that absorb water and nutrients as plants do 7 2 but like plants they produce their own nutrition by photosynthesis 8 When they grow on plants they do not live as parasites but instead use the plant s surface as a substrate Lichens occur from sea level to high alpine elevations in many environmental conditions and can grow on almost any surface 8 They are abundant growing on bark leaves mosses or other lichens 7 and hanging from branches living on thin air epiphytes in rainforests and in temperate woodland They grow on rock walls gravestones roofs exposed soil surfaces rubber bones and in the soil as part of biological soil crusts Various lichens have adapted to survive in some of the most extreme environments on Earth arctic tundra hot dry deserts rocky coasts and toxic slag heaps They can even live inside solid rock growing between the grains It is estimated that 6 8 of Earth s land surface is covered by lichens 9 There are about 20 000 known species 10 Some lichens have lost the ability to reproduce sexually yet continue to speciate 7 11 They can be seen as being relatively self contained miniature ecosystems where the fungi algae or cyanobacteria have the potential to engage with other microorganisms in a functioning system that may evolve as an even more complex composite organism 12 13 14 15 Lichens may be long lived with some considered to be among the oldest living things 4 16 They are among the first living things to grow on fresh rock exposed after an event such as a landslide The long life span and slow and regular growth rate of some species can be used to date events lichenometry Contents 1 Etymology and pronunciation 2 Anatomy and morphology 2 1 Growth forms 2 2 Color 2 3 Internal structure 3 Physiology 3 1 Symbiotic relation 3 2 Ecology 3 2 1 Miniature ecosystem and holobiont theory 3 2 2 Lichenicolous fungi 3 3 Reaction to water 3 4 Metabolites metabolite structures and bioactivity 3 5 Growth rate 3 6 Life span 3 7 Response to environmental stress 4 Reproduction and dispersal 4 1 Vegetative reproduction 4 2 Sexual reproduction 5 Taxonomy and classification 5 1 Fungi 5 2 Photobionts 5 3 Controversy over classification method and species names 5 4 Diversity 5 5 Identification methods 5 6 Evolution and paleontology 6 Ecology and interactions with environment 6 1 Substrates and habitats 6 2 Lichens and soils 6 3 Ecological interactions 6 4 Effects of air pollution 7 Human use 7 1 Food 7 2 Lichenometry 7 3 Biodegradation 7 4 Dyes 7 5 Traditional medicine and research 7 6 Aesthetic appeal 7 7 In literature 8 History 9 Gallery 10 See also 11 Notes 12 References 13 Further readingEtymology and pronunciation EditThe English word lichen derives from the Greek leixhn leichen code ell promoted to code el tree moss lichen lichen like eruption on skin via Latin lichen 17 18 19 The Greek noun which literally means licker derives from the verb leixein leichein code ell promoted to code el to lick 20 21 In American English lichen is pronounced the same as the verb liken ˈ l aɪ k en In British English both this pronunciation and one rhyming with kitchen ˈ l ɪ tʃ en are used 22 23 24 Anatomy and morphology EditGrowth forms Edit Main article Lichen growth forms Lichens grow in a wide range of shapes and forms morphologies The shape of a lichen is usually determined by the organization of the fungal filaments 25 The nonreproductive tissues or vegetative body parts are called the thallus Lichens are grouped by thallus type since the thallus is usually the most visually prominent part of the lichen Thallus growth forms typically correspond to a few basic internal structure types Common names for lichens often come from a growth form or color that is typical of a lichen genus Common groupings of lichen thallus growth forms are fruticose 26 27 28 growing like a tuft or multiple branched leafless mini shrub upright or hanging down 3 dimensional branches with nearly round cross section terete or flattened foliose 26 27 growing in 2 dimensional flat leaf like lobes crustose 5 26 27 crust like adhering tightly to a surface substrate like a thick coat of paint squamulose 28 formed of small leaf like scales crustose below but free at the tips leprose 29 powdery gelatinous jelly like filamentous stringy or like matted hair byssoid wispy like teased wool structurelessThere are variations in growth types in a single lichen species grey areas between the growth type descriptions and overlapping between growth types so some authors might describe lichens using different growth type descriptions When a crustose lichen gets old the center may start to crack up like old dried paint old broken asphalt paving or like the polygonal islands of cracked up mud in a dried lakebed This is called being rimose or areolate and the island pieces separated by the cracks are called areolas 26 The areolas appear separated but are or were citation needed connected by an underlying prothallus or hypothallus 29 When a crustose lichen grows from a center and appears to radiate out it is called crustose placodioid When the edges of the areolas lift up from the substrate it is called squamulose 30 159 28 These growth form groups are not precisely defined Foliose lichens may sometimes branch and appear to be fruticose Fruticose lichens may have flattened branching parts and appear leafy Squamulose lichens may appear where the edges lift up Gelatinous lichens may appear leafy when dry 30 159 Means of telling them apart in these cases are in the sections below Structures involved in reproduction often appear as discs bumps or squiggly lines on the surface of the thallus 7 4 The thallus is not always the part of the lichen that is most visually noticeable Some lichens can grow inside solid rock between the grains endolithic lichens with only the sexual fruiting part visible growing outside the rock 26 These may be dramatic in color or appearance 26 Forms of these sexual parts are not in the above growth form categories 26 The most visually noticeable reproductive parts are often circular raised plate like or disc like outgrowths with crinkly edges and are described in sections below Color Edit Lichens come in many colors 7 4 Coloration is usually determined by the photosynthetic component 25 Special pigments such as yellow usnic acid give lichens a variety of colors including reds oranges yellows and browns especially in exposed dry habitats 31 In the absence of special pigments lichens are usually bright green to olive gray when wet gray or grayish green to brown when dry 31 This is because moisture causes the surface skin cortex to become more transparent exposing the green photobiont layer 31 Different colored lichens covering large areas of exposed rock surfaces or lichens covering or hanging from bark can be a spectacular display when the patches of diverse colors come to life or glow in brilliant displays following rain Different colored lichens may inhabit different adjacent sections of a rock face depending on the angle of exposure to light 31 Colonies of lichens may be spectacular in appearance dominating much of the surface of the visual landscape in forests and natural places such as the vertical paint covering the vast rock faces of Yosemite National Park 32 Color is used in identification 33 4 The color of a lichen changes depending on whether the lichen is wet or dry 33 Color descriptions used for identification are based on the color that shows when the lichen is dry 33 Dry lichens with a cyanobacterium as the photosynthetic partner tend to be dark grey brown or black 33 The underside of the leaf like lobes of foliose lichens is a different color from the top side dorsiventral often brown or black sometimes white A fruticose lichen may have flattened branches appearing similar to a foliose lichen but the underside of a leaf like structure on a fruticose lichen is the same color as the top side The leaf like lobes of a foliose lichen may branch giving the appearance of a fruticose lichen but the underside will be a different color from the top side 29 The sheen on some jelly like gelatinous lichens is created by mucilaginous secretions 25 Internal structure Edit The cyanobacterium Hyella caespitosa with fungal hyphae in the lichen Pyrenocollema halodytes further explanation needed A lichen consists of a simple photosynthesizing organism usually a green alga or cyanobacterium surrounded by filaments of a fungus Generally most of a lichen s bulk is made of interwoven fungal filaments 34 but this is reversed in filamentous and gelatinous lichens 25 The fungus is called a mycobiont The photosynthesizing organism is called a photobiont Algal photobionts are called phycobionts 35 Cyanobacteria photobionts are called cyanobionts 35 The part of a lichen that is not involved in reproduction the body or vegetative tissue of a lichen is called the thallus The thallus form is very different from any form where the fungus or alga are growing separately The thallus is made up of filaments of the fungus called hyphae The filaments grow by branching then rejoining to create a mesh which is called being anastomosed The mesh of fungal filaments may be dense or loose Generally the fungal mesh surrounds the algal or cyanobacterial cells often enclosing them within complex fungal tissues that are unique to lichen associations The thallus may or may not have a protective skin of densely packed fungal filaments often containing a second fungal species 1 which is called a cortex Fruticose lichens have one cortex layer wrapping around the branches Foliose lichens have an upper cortex on the top side of the leaf and a separate lower cortex on the bottom side Crustose and squamulose lichens have only an upper cortex with the inside of the lichen in direct contact with the surface they grow on the substrate Even if the edges peel up from the substrate and appear flat and leaf like they lack a lower cortex unlike foliose lichens Filamentous byssoid leprose 29 gelatinous and other lichens do not have a cortex which is called being ecorticate 36 Schematic cross section of foliose lichen a The cortex is the outer layer of tightly woven fungus filaments hyphae b This photobiont layer has photosynthesizing green algae c Loosely packed hyphae in the medulla d A tightly woven lower cortex e Anchoring hyphae called rhizines where the fungus attaches to the substrate Fruticose foliose crustose and squamulose lichens generally have up to three different types of tissue differentiated by having different densities of fungal filaments 34 The top layer where the lichen contacts the environment is called a cortex 34 The cortex is made of densely tightly woven packed and glued together agglutinated fungal filaments 34 The dense packing makes the cortex act like a protective skin keeping other organisms out and reducing the intensity of sunlight on the layers below 34 The cortex layer can be up to several hundred micrometers mm in thickness less than a millimeter 37 The cortex may be further topped by an epicortex of secretions not cells 0 6 1 mm thick in some lichens 37 This secretion layer may or may not have pores 37 Below the cortex layer is a layer called the photobiontic layer or symbiont layer 27 34 The symbiont layer has less densely packed fungal filaments with the photosynthetic partner embedded in them 34 The less dense packing allows air circulation during photosynthesis similar to the anatomy of a leaf 34 Each cell or group of cells of the photobiont is usually individually wrapped by hyphae and in some cases penetrated by a haustorium 25 In crustose and foliose lichens algae in the photobiontic layer are diffuse among the fungal filaments decreasing in gradation into the layer below In fruticose lichens the photobiontic layer is sharply distinct from the layer below 25 The layer beneath the symbiont layer is called the medulla The medulla is less densely packed with fungal filaments than the layers above In foliose lichens there is usually as in Peltigera 30 159 another densely packed layer of fungal filaments called the lower cortex 29 34 Root like fungal structures called rhizines usually 30 159 grow from the lower cortex to attach or anchor the lichen to the substrate 2 29 Fruticose lichens have a single cortex wrapping all the way around the stems and branches 30 The medulla is the lowest layer and may form a cottony white inner core for the branchlike thallus or it may be hollow 30 159 Crustose and squamulose lichens lack a lower cortex and the medulla is in direct contact with the substrate that the lichen grows on In crustose areolate lichens the edges of the areolas peel up from the substrate and appear leafy In squamulose lichens the part of the lichen thallus that is not attached to the substrate may also appear leafy But these leafy parts lack a lower cortex which distinguishes crustose and squamulose lichens from foliose lichens 34 Conversely foliose lichens may appear flattened against the substrate like a crustose lichen but most of the leaf like lobes can be lifted up from the substrate because it is separated from it by a tightly packed lower cortex 29 Gelatinous 30 159 byssoid and leprose lichens lack a cortex are ecorticate and generally have only undifferentiated tissue similar to only having a symbiont layer citation needed In lichens that include both green algal and cyanobacterial symbionts the cyanobacteria may be held on the upper or lower surface in small pustules called cephalodia Pruinia is a whitish coating on top of an upper surface 38 An epinecral layer is a layer of horny dead fungal hyphae with indistinct lumina in or near the cortex above the algal layer 38 In August 2016 it was reported that some macrolichens have more than one species of fungus in their tissues 1 Physiology EditSymbiotic relation Edit Main article Symbiosis in lichens Lichens are fungi that have discovered agriculture Trevor Goward 39 A lichen is a composite organism that emerges from algae or cyanobacteria living among the filaments hyphae of the fungi in a mutually beneficial symbiotic relationship The fungi benefit from the carbohydrates produced by the algae or cyanobacteria via photosynthesis The algae or cyanobacteria benefit by being protected from the environment by the filaments of the fungi which also gather moisture and nutrients from the environment and usually provide an anchor to it Although some photosynthetic partners in a lichen can survive outside the lichen the lichen symbiotic association extends the ecological range of both partners whereby most descriptions of lichen associations describe them as symbiotic Both partners gain water and mineral nutrients mainly from the atmosphere through rain and dust The fungal partner protects the alga by retaining water serving as a larger capture area for mineral nutrients and in some cases provides minerals obtained from the substrate If a cyanobacterium is present as a primary partner or another symbiont in addition to a green alga as in certain tripartite lichens they can fix atmospheric nitrogen complementing the activities of the green alga In three different lineages the fungal partner has independently lost the mitochondrial gene atp9 which has key functions in mitochondrial energy production The loss makes the fungi completely dependent on their symbionts 40 The algal or cyanobacterial cells are photosynthetic and as in plants they reduce atmospheric carbon dioxide into organic carbon sugars to feed both symbionts Phycobionts algae produce sugar alcohols ribitol sorbitol and erythritol which are absorbed by the mycobiont fungus 35 Cyanobionts produce glucose 35 Lichenized fungal cells can make the photobiont leak out the products of photosynthesis where they can then be absorbed by the fungus 7 5 It appears many probably the majority of lichen also live in a symbiotic relationship with an order of basidiomycete yeasts called Cyphobasidiales The absence of this third partner could explain why growing lichen in the laboratory is difficult The yeast cells are responsible for the formation of the characteristic cortex of the lichen thallus and could also be important for its shape 41 The lichen combination of alga or cyanobacterium with a fungus has a very different form morphology physiology and biochemistry than the component fungus alga or cyanobacterium growing by itself naturally or in culture The body thallus of most lichens is different from those of either the fungus or alga growing separately When grown in the laboratory in the absence of its photobiont a lichen fungus develops as a structureless undifferentiated mass of fungal filaments hyphae If combined with its photobiont under appropriate conditions its characteristic form associated with the photobiont emerges in the process called morphogenesis 4 In a few remarkable cases a single lichen fungus can develop into two very different lichen forms when associating with either a green algal or a cyanobacterial symbiont Quite naturally these alternative forms were at first considered to be different species until they were found growing in a conjoined manner citation needed Evidence that lichens are examples of successful symbiosis is the fact that lichens can be found in almost every habitat and geographic area on the planet 12 Two species in two genera of green algae are found in over 35 of all lichens but can only rarely be found living on their own outside of a lichen 42 In a case where one fungal partner simultaneously had two green algae partners that outperform each other in different climates this might indicate having more than one photosynthetic partner at the same time might enable the lichen to exist in a wider range of habitats and geographic locations 12 At least one form of lichen the North American beard like lichens are constituted of not two but three symbiotic partners an ascomycetous fungus a photosynthetic alga and unexpectedly a basidiomycetous yeast 43 Phycobionts can have a net output of sugars with only water vapor 35 The thallus must be saturated with liquid water for cyanobionts to photosynthesize 35 Algae produce sugars that are absorbed by the fungus by diffusion into special fungal hyphae called appressoria or haustoria in contact with the wall of the algal cells 44 The appressoria or haustoria may produce a substance that increases permeability of the algal cell walls and may penetrate the walls 44 The algae may contribute up to 80 of their sugar production to the fungus 44 Ecology Edit Lichen associations may be examples of mutualism or commensalism but the lichen relationship can be considered parasitic 45 under circumstances where the photosynthetic partner can exist in nature independently of the fungal partner but not vice versa Photobiont cells are routinely destroyed in the course of nutrient exchange The association continues because reproduction of the photobiont cells matches the rate at which they are destroyed 45 The fungus surrounds the algal cells 8 often enclosing them within complex fungal tissues unique to lichen associations In many species the fungus penetrates the algal cell wall 8 forming penetration pegs haustoria similar to those produced by pathogenic fungi that feed on a host 28 46 Cyanobacteria in laboratory settings can grow faster when they are alone rather than when they are part of a lichen Miniature ecosystem and holobiont theory Edit Symbiosis in lichens is so well balanced that lichens have been considered to be relatively self contained miniature ecosystems in and of themselves 12 13 It is thought that lichens may be even more complex symbiotic systems that include non photosynthetic bacterial communities performing other functions as partners in a holobiont 14 15 Many lichens are very sensitive to environmental disturbances and can be used to cheaply 8 assess air pollution 47 48 49 ozone depletion and metal contamination Lichens have been used in making dyes perfumes 50 and in traditional medicines A few lichen species are eaten by insects 8 or larger animals such as reindeer 51 Lichens are widely used as environmental indicators or bio indicators When air is very badly polluted with sulphur dioxide there may be no lichens present only some green algae can tolerate those conditions If the air is clean then shrubby hairy and leafy lichens become abundant A few lichen species can tolerate fairly high levels of pollution and are commonly found in urban areas on pavements walls and tree bark The most sensitive lichens are shrubby and leafy while the most tolerant lichens are all crusty in appearance Since industrialisation many of the shrubby and leafy lichens such as Ramalina Usnea and Lobaria species have very limited ranges often being confined to the areas which have the cleanest air Lichenicolous fungi Edit Some fungi can only be found living on lichens as obligate parasites These are referred to as lichenicolous fungi and are a different species from the fungus living inside the lichen thus they are not considered to be part of the lichen 52 Reaction to water Edit Moisture makes the cortex become more transparent 7 4 This way the algae can conduct photosynthesis when moisture is available and is protected at other times When the cortex is more transparent the algae show more clearly and the lichen looks greener Metabolites metabolite structures and bioactivity Edit Lichens can show intense antioxidant activity 53 54 Secondary metabolites are often deposited as crystals in the apoplast 55 Secondary metabolites are thought to play a role in preference for some substrates over others 55 Sometimes lichens contain structures made from fungal metabolites for example crustose lichens sometimes have a polysaccharide clarification needed layer in the cortex citation needed Growth rate Edit Lichens often have a regular but very slow growth rate of less than a millimeter per year In crustose lichens the area along the margin is where the most active growth is taking place 30 159 Most crustose lichens grow only 1 2 mm in diameter per year Life span Edit Lichens may be long lived with some considered to be among the oldest living organisms 4 16 Lifespan is difficult to measure because what defines the same individual lichen is not precise 56 Lichens grow by vegetatively breaking off a piece which may or may not be defined as the same lichen and two lichens can merge then becoming the same lichen 56 An Arctic species called map lichen Rhizocarpon geographicum has been dated at 8 600 years apparently the world s oldest living organism 57 Response to environmental stress Edit Unlike simple dehydration in plants and animals lichens may experience a complete loss of body water in dry periods 8 Lichens are capable of surviving extremely low levels of water content poikilohydric 58 5 6 They quickly absorb water when it becomes available again becoming soft and fleshy 8 In tests lichen survived and showed remarkable results on the adaptation capacity of photosynthetic activity within the simulation time of 34 days under Martian conditions in the Mars Simulation Laboratory MSL maintained by the German Aerospace Center DLR 59 60 The European Space Agency has discovered that lichens can survive unprotected in space In an experiment led by Leopoldo Sancho from the Complutense University of Madrid two species of lichen Rhizocarpon geographicum and Xanthoria elegans were sealed in a capsule and launched on a Russian Soyuz rocket 31 May 2005 Once in orbit the capsules were opened and the lichens were directly exposed to the vacuum of space with its widely fluctuating temperatures and cosmic radiation After 15 days the lichens were brought back to earth and were found to be unchanged in their ability to photosynthesize 61 62 Reproduction and dispersal EditVegetative reproduction Edit Xanthoparmelia sp with dark colored reproductive structures disc like apothecia at center surrounded by a pale coloured vegetative thallus Many lichens reproduce asexually either by a piece breaking off and growing on its own vegetative reproduction or through the dispersal of diaspores containing a few algal cells surrounded by fungal cells 2 Because of the relative lack of differentiation in the thallus the line between diaspore formation and vegetative reproduction is often blurred Fruticose lichens can easily citation needed fragment and new lichens can grow from the fragment vegetative reproduction citation needed Many lichens break up into fragments when they dry dispersing themselves by wind action to resume growth when moisture returns 63 64 Soredia singular soredium are small groups of algal cells surrounded by fungal filaments that form in structures called soralia from which the soredia can be dispersed by wind 2 Isidia singular isidium are branched spiny elongated outgrowths from the thallus that break off for mechanical dispersal 2 Lichen propagules diaspores typically contain cells from both partners although the fungal components of so called fringe species rely instead on algal cells dispersed by the core species 65 Sexual reproduction Edit Disc like apothecia left and thallus right on a foliose lichen Structures involved in reproduction often appear as discs bumps or squiggly lines on the surface of the thallus 7 4 Though it has been argued that sexual reproduction in photobionts is selected against there is strong evidence that suggests meiotic activities sexual reproduction in Trebouxia 66 67 Many lichen fungi reproduce sexually like other fungi producing spores formed by meiosis and fusion of gametes Following dispersal such fungal spores must meet with a compatible algal partner before a functional lichen can form Some lichen fungi belong to the phylum Basidiomycota basidiolichens and produce mushroom like reproductive structures resembling those of their nonlichenized relatives Most lichen fungi belong to Ascomycetes ascolichens Among the ascolichens spores are produced in spore producing structures called ascomata 7 The most common types of ascomata are the apothecium plural apothecia and perithecium plural perithecia 7 14 Apothecia are usually cups or plate like discs located on the top surface of the lichen thallus When apothecia are shaped like squiggly line segments instead of like discs they are called lirellae 7 14 Perithecia are shaped like flasks that are immersed in the lichen thallus tissue which has a small hole for the spores to escape the flask and appear like black dots on the lichen surface 7 14 The three most common spore body types are raised discs called apothecia singular apothecium bottle like cups with a small hole at the top called perithecia singular perithecium and pycnidia singular pycnidium shaped like perithecia but without asci an ascus is the structure that contains and releases the sexual spores in fungi of the Ascomycota 68 The apothecium has a layer of exposed spore producing cells called asci singular ascus and is usually a different color from the thallus tissue 7 14 When the apothecium has an outer margin the margin is called the exciple 7 14 When the exciple has a color similar to colored thallus tissue the apothecium or lichen is called lecanorine meaning similar to members of the genus Lecanora 7 14 When the exciple is blackened like carbon it is called lecideine meaning similar to members of the genus Lecidea 7 14 When the margin is pale or colorless it is called biatorine 7 14 Crust like thallus with pseudopodetia A podetium plural podetia is a lichenized stalk like structure of the fruiting body rising from the thallus associated with some fungi that produce a fungal apothecium 27 Since it is part of the reproductive tissue podetia are not considered part of the main body thallus but may be visually prominent 27 The podetium may be branched and sometimes cup like They usually bear the fungal pycnidia or apothecia or both 27 Many lichens have apothecia that are visible to the naked eye 2 Most lichens produce abundant sexual structures 69 Many species appear to disperse only by sexual spores 69 For example the crustose lichens Graphis scripta and Ochrolechia parella produce no symbiotic vegetative propagules Instead the lichen forming fungi of these species reproduce sexually by self fertilization i e they are homothallic This breeding system may enable successful reproduction in harsh environments 69 Mazaedia singular mazaedium are apothecia shaped like a dressmaker s pin in pin lichens where the fruiting body is a brown or black mass of loose ascospores enclosed by a cup shaped exciple which sits on top of a tiny stalk 7 15 Taxonomy and classification EditLichens are classified by the fungal component Lichen species are given the same scientific name binomial name as the fungus species in the lichen Lichens are being integrated into the classification schemes for fungi The alga bears its own scientific name which bears no relationship to that of the lichen or fungus 70 There are about 13 500 17 000 identified lichen species 44 Nearly 20 of known fungal species are associated with lichens 44 Lichenized fungus may refer to the entire lichen or to just the fungus This may cause confusion without context A particular fungus species may form lichens with different algae species giving rise to what appear to be different lichen species but which are still classified as of 2014 as the same lichen species 71 Formerly some lichen taxonomists placed lichens in their own division the Mycophycophyta but this practice is no longer accepted because the components belong to separate lineages Neither the ascolichens nor the basidiolichens form monophyletic lineages in their respective fungal phyla but they do form several major solely or primarily lichen forming groups within each phylum 72 Even more unusual than basidiolichens is the fungus Geosiphon pyriforme a member of the Glomeromycota that is unique in that it encloses a cyanobacterial symbiont inside its cells Geosiphon is not usually considered to be a lichen and its peculiar symbiosis was not recognized for many years The genus is more closely allied to endomycorrhizal genera Fungi from Verrucariales also form marine lichens with the brown algae Petroderma maculiforme 73 and have a symbiotic relationship with seaweed such as rockweed and Blidingia minima where the algae are the dominant components The fungi is thought to help the rockweeds to resist desiccation when exposed to air 74 75 In addition lichens can also use yellow green algae Heterococcus as their symbiotic partner 76 Lichens independently emerged from fungi associating with algae and cyanobacteria multiple times throughout history 77 Fungi Edit The fungal component of a lichen is called the mycobiont The mycobiont may be an Ascomycete or Basidiomycete 10 The associated lichens are called either ascolichens or basidiolichens respectively Living as a symbiont in a lichen appears to be a successful way for a fungus to derive essential nutrients since about 20 of all fungal species have acquired this mode of life 78 Thalli produced by a given fungal symbiont with its differing partners may be similar citation needed and the secondary metabolites identical citation needed indicating citation needed that the fungus has the dominant role in determining the morphology of the lichen But the same mycobiont with different photobionts may also produce very different growth forms 71 Lichens are known in which there is one fungus associated with two or even three algal species Although each lichen thallus generally appears homogeneous some evidence seems to suggest that the fungal component may consist of more than one genetic individual of that species citation needed Two or more fungal species can interact to form the same lichen 79 The following table lists the orders and families of fungi that include lichen forming species Photobionts Edit The photosynthetic partner in a lichen is called a photobiont The photobionts in lichens come from a variety of simple prokaryotic and eukaryotic organisms In the majority of lichens the photobiont is a green alga Chlorophyta or a cyanobacterium In some lichens both types are present in such cases the alga is typically the primary partner with the cyanobacteria being located in cryptic pockets 80 Algal photobionts are called phycobionts while cyanobacterial photobionts are called cyanobionts 35 According to one source about 90 of all known lichens have phycobionts and about 10 have cyanobionts 35 while another source states that two thirds of lichens have green algae as phycobiont and about one third have a cyanobiont 28 Approximately 100 species of photosynthetic partners from 40 35 genera and five distinct classes prokaryotic Cyanophyceae eukaryotic Trebouxiophyceae Phaeophyceae Chlorophyceae have been found to associate with the lichen forming fungi 81 Common algal photobionts are from the genera Trebouxia Trentepohlia Pseudotrebouxia or Myrmecia Trebouxia is the most common genus of green algae in lichens occurring in about 40 of all lichens Trebouxioid means either a photobiont that is in the genus Trebouxia or resembles a member of that genus and is therefore presumably a member of the class Trebouxiophyceae 27 The second most commonly represented green alga genus is Trentepohlia 28 Overall about 100 species of eukaryotes are known to occur as photobionts in lichens All the algae are probably able to exist independently in nature as well as in the lichen 79 A cyanolichen is a lichen with a cyanobacterium as its main photosynthetic component photobiont 82 Most cyanolichen are also ascolichens but a few basidiolichen like Dictyonema and Acantholichen have cyanobacteria as their partner 83 The most commonly occurring cyanobacterium genus is Nostoc 79 Other 28 common cyanobacterium photobionts are from Scytonema 10 Many cyanolichens are small and black and have limestone as the substrate citation needed Another cyanolichen group the jelly lichens of the genera Collema or Leptogium are gelatinous and live on moist soils Another group of large and foliose species including Peltigera Lobaria and Degelia are grey blue especially when dampened or wet Many of these characterize the Lobarion communities of higher rainfall areas in western Britain e g in the Celtic rain forest Strains of cyanobacteria found in various cyanolichens are often closely related to one another 84 They differ from the most closely related free living strains 84 The lichen association is a close symbiosis It extends the ecological range of both partners but is not always obligatory for their growth and reproduction in natural environments since many of the algal symbionts can live independently A prominent example is the alga Trentepohlia which forms orange coloured populations on tree trunks and suitable rock faces Lichen propagules diaspores typically contain cells from both partners although the fungal components of so called fringe species rely instead on algal cells dispersed by the core species 65 The same cyanobiont species can occur in association with different fungal species as lichen partners 85 The same phycobiont species can occur in association with different fungal species as lichen partners 35 More than one phycobiont may be present in a single thallus 35 A single lichen may contain several algal genotypes 86 87 These multiple genotypes may better enable response to adaptation to environmental changes and enable the lichen to inhabit a wider range of environments 88 Controversy over classification method and species names Edit There are about 20 000 known lichen species 10 But what is meant by species is different from what is meant by biological species in plants animals or fungi where being the same species implies that there is a common ancestral lineage 10 Because lichens are combinations of members of two or even three different biological kingdoms these components must have a different ancestral lineage from each other By convention lichens are still called species anyway and are classified according to the species of their fungus not the species of the algae or cyanobacteria Lichens are given the same scientific name binomial name as the fungus in them which may cause some confusion The alga bears its own scientific name which has no relationship to the name of the lichen or fungus 70 Depending on context lichenized fungus may refer to the entire lichen or to the fungus when it is in the lichen which can be grown in culture in isolation from the algae or cyanobacteria Some algae and cyanobacteria are found naturally living outside of the lichen The fungal algal or cyanobacterial component of a lichen can be grown by itself in culture When growing by themselves the fungus algae or cyanobacteria have very different properties than those of the lichen Lichen properties such as growth form physiology and biochemistry are very different from the combination of the properties of the fungus and the algae or cyanobacteria The same fungus growing in combination with different algae or cyanobacteria can produce lichens that are very different in most properties meeting non DNA criteria for being different species Historically these different combinations were classified as different species When the fungus is identified as being the same using modern DNA methods these apparently different species get reclassified as the same species under the current 2014 convention for classification by fungal component This has led to debate about this classification convention These apparently different species have their own independent evolutionary history 2 71 There is also debate as to the appropriateness of giving the same binomial name to the fungus and to the lichen that combines that fungus with an alga or cyanobacterium synecdoche This is especially the case when combining the same fungus with different algae or cyanobacteria produces dramatically different lichen organisms which would be considered different species by any measure other than the DNA of the fungal component If the whole lichen produced by the same fungus growing in association with different algae or cyanobacteria were to be classified as different species the number of lichen species would be greater Diversity Edit The largest number of lichenized fungi occur in the Ascomycota with about 40 of species forming such an association 70 Some of these lichenized fungi occur in orders with nonlichenized fungi that live as saprotrophs or plant parasites for example the Leotiales Dothideales and Pezizales Other lichen fungi occur in only five orders in which all members are engaged in this habit Orders Graphidales Gyalectales Peltigerales Pertusariales and Teloschistales Overall about 98 of lichens have an ascomycetous mycobiont 89 Next to the Ascomycota the largest number of lichenized fungi occur in the unassigned fungi imperfecti a catch all category for fungi whose sexual form of reproduction has never been observed citation needed Comparatively few basidiomycetes are lichenized but these include agarics such as species of Lichenomphalia clavarioid fungi such as species of Multiclavula and corticioid fungi such as species of Dictyonema Identification methods Edit Lichen identification uses growth form microscopy and reactions to chemical tests The outcome of the Pd test is called Pd which is also used as an abbreviation for the chemical used in the test para phenylenediamine 27 If putting a drop on a lichen turns an area bright yellow to orange this helps identify it as belonging to either the genus Cladonia or Lecanora 27 Evolution and paleontology Edit The fossil record for lichens is poor 90 The extreme habitats that lichens dominate such as tundra mountains and deserts are not ordinarily conducive to producing fossils 90 91 There are fossilized lichens embedded in amber The fossilized Anzia is found in pieces of amber in northern Europe and dates back approximately 40 million years 92 Lichen fragments are also found in fossil leaf beds such as Lobaria from Trinity County in northern California USA dating back to the early to middle Miocene 93 The oldest fossil lichen in which both symbiotic partners have been recovered is Winfrenatia an early zygomycetous Glomeromycotan lichen symbiosis that may have involved controlled parasitism citation needed is permineralized in the Rhynie Chert of Scotland dating from early Early Devonian about 400 million years ago 94 The slightly older fossil Spongiophyton has also been interpreted as a lichen on morphological 95 and isotopic 96 grounds although the isotopic basis is decidedly shaky 97 It has been demonstrated that Silurian Devonian fossils Nematothallus 98 and Prototaxites 99 were lichenized Thus lichenized Ascomycota and Basidiomycota were a component of Early Silurian Devonian terrestrial ecosystems 100 101 Newer research suggests that lichen evolved after the evolution of land plants 102 The ancestral ecological state of both Ascomycota and Basidiomycota was probably saprobism and independent lichenization events may have occurred multiple times 103 104 In 1995 Gargas and colleagues proposed that there were at least five independent origins of lichenization three in the basidiomycetes and at least two in the Ascomycetes 105 Lutzoni et al 2001 suggest lichenization probably evolved earlier and was followed by multiple independent losses Some non lichen forming fungi may have secondarily lost the ability to form a lichen association As a result lichenization has been viewed as a highly successful nutritional strategy 106 107 Lichenized Glomeromycota may extend well back into the Precambrian Lichen like fossils consisting of coccoid cells cyanobacteria and thin filaments mucoromycotinan Glomeromycota are permineralized in marine phosphorite of the Doushantuo Formation in southern China These fossils are thought to be 551 to 635 million years old or Ediacaran 108 Ediacaran acritarchs also have many similarities with Glomeromycotan vesicles and spores 109 It has also been claimed that Ediacaran fossils including Dickinsonia 110 were lichens 111 although this claim is controversial 112 Endosymbiotic Glomeromycota comparable with living Geosiphon may extend back into the Proterozoic in the form of 1500 million year old Horodyskia 113 and 2200 million year old Diskagma 114 Discovery of these fossils suggest that fungi developed symbiotic partnerships with photoautotrophs long before the evolution of vascular plants though the Ediacaran lichen hypothesis is largely rejected due to an inappropriate definition of lichens based on taphonomy and substrate ecology 115 However a 2019 study by the same scientist who rejected the Ediacaran lichen hypothesis Nelsen used new time calibrated phylogenies to conclude that there is no evidence of lichen before the existence of vascular plants 116 Lecanoromycetes one of the most common classes of lichen forming fungi diverged from its ancestor which may have also been lichen forming around 258 million years ago during the late Paleozoic period However the closely related clade Euritiomycetes appears to have become lichen forming only 52 million years ago during the early Cenozoic period 117 Ecology and interactions with environment EditSubstrates and habitats Edit Lichens on a limestone statue on a tower of Regensburg Cathedral Lichens cover about 7 of the planet s surface and grow on and in a wide range of substrates and habitats including some of the most extreme conditions on earth 118 They are abundant growing on bark leaves and hanging from epiphyte branches in rain forests and in temperate woodland They grow on bare rock walls gravestones roofs and exposed soil surfaces They can survive in some of the most extreme environments on Earth arctic tundra hot dry deserts rocky coasts and toxic slag heaps They can live inside solid rock growing between the grains and in the soil as part of a biological soil crust in arid habitats such as deserts Some lichens do not grow on anything living out their lives blowing about the environment 2 When growing on mineral surfaces some lichens slowly decompose their substrate by chemically degrading and physically disrupting the minerals contributing to the process of weathering by which rocks are gradually turned into soil While this contribution to weathering is usually benign it can cause problems for artificial stone structures For example there is an ongoing lichen growth problem on Mount Rushmore National Memorial that requires the employment of mountain climbing conservators to clean the monument 119 Lichens are not parasites on the plants they grow on but only use them as a substrate The fungi of some lichen species may take over the algae of other lichen species 8 120 Lichens make their own food from their photosynthetic parts and by absorbing minerals from the environment 8 Lichens growing on leaves may have the appearance of being parasites on the leaves but they are not Some lichens in Diploschistes parasitise other lichens Diploschistes muscorum starts its development in the tissue of a host Cladonia species 46 30 28 171 In the arctic tundra lichens together with mosses and liverworts make up the majority of the ground cover which helps insulate the ground and may provide forage for grazing animals An example is reindeer moss which is a lichen not a moss 8 There are only two species of known permanently submerged lichens Hydrothyria venosa is found in fresh water environments and Verrucaria serpuloides is found in marine environments 121 A crustose lichen that grows on rock is called a saxicolous lichen 27 30 159 Crustose lichens that grow on the rock are epilithic and those that grow immersed inside rock growing between the crystals with only their fruiting bodies exposed to the air are called endolithic lichens 26 30 159 82 A crustose lichen that grows on bark is called a corticolous lichen 30 159 A lichen that grows on wood from which the bark has been stripped is called a lignicolous lichen 36 Lichens that grow immersed inside plant tissues are called endophloidic lichens or endophloidal lichens 26 30 159 Lichens that use leaves as substrates whether the leaf is still on the tree or on the ground are called epiphyllous or foliicolous 35 A terricolous lichen grows on the soil as a substrate Many squamulous lichens are terricolous 30 159 Umbilicate lichens are foliose lichens that are attached to the substrate at only one point 26 A vagrant lichen is not attached to a substrate at all and lives its life being blown around by the wind Lichens and soils EditIn addition to distinct physical mechanisms by which lichens break down raw stone recent studies indicate lichens attack stone chemically entering newly chelated minerals into the ecology The lichen exudates which have powerful chelating capacity the widespread occurrence of mineral neoformation particularly metal oxalates together with the characteristics of weathered substrates all confirm the significance of lichens as chemical weathering agents 122 Over time this activity creates new fertile soil from lifeless stone Lichens may be important in contributing nitrogen to soils in some deserts through being eaten along with their rock substrate by snails which then defecate putting the nitrogen into the soils 123 Lichens help bind and stabilize soil sand in dunes 2 In deserts and semi arid areas lichens are part of extensive living biological soil crusts essential for maintaining the soil structure 2 Lichens have a long fossil record in soils dating back 2 2 billion years 114 Ecological interactions Edit Lichens are pioneer species among the first living things to grow on bare rock or areas denuded of life by a disaster 2 Lichens may have to compete with plants for access to sunlight but because of their small size and slow growth they thrive in places where higher plants have difficulty growing Lichens are often the first to settle in places lacking soil constituting the sole vegetation in some extreme environments such as those found at high mountain elevations and at high latitudes 124 Some survive in the tough conditions of deserts and others on frozen soil of the Arctic regions 125 A major ecophysiological advantage of lichens is that they are poikilohydric poikilo variable hydric relating to water meaning that though they have little control over the status of their hydration they can tolerate irregular and extended periods of severe desiccation Like some mosses liverworts ferns and a few resurrection plants upon desiccation lichens enter a metabolic suspension or stasis known as cryptobiosis in which the cells of the lichen symbionts are dehydrated to a degree that halts most biochemical activity In this cryptobiotic state lichens can survive wider extremes of temperature radiation and drought in the harsh environments they often inhabit Lichens suppress the growth of mosses and higher plants around them Lichens do not have roots and do not need to tap continuous reservoirs of water like most higher plants thus they can grow in locations impossible for most plants such as bare rock sterile soil or sand and various artificial structures such as walls roofs and monuments Many lichens also grow as epiphytes epi on the surface phyte plant on plants particularly on the trunks and branches of trees When growing on plants lichens are not parasites they do not consume any part of the plant nor poison it Lichens produce allelopathic chemicals that inhibit the growth of mosses Some ground dwelling lichens such as members of the subgenus Cladina reindeer lichens produce allelopathic chemicals that leach into the soil and inhibit the germination of seeds spruce and other plants 126 Stability that is longevity of their substrate is a major factor of lichen habitats Most lichens grow on stable rock surfaces or the bark of old trees but many others grow on soil and sand In these latter cases lichens are often an important part of soil stabilization indeed in some desert ecosystems vascular higher plant seeds cannot become established except in places where lichen crusts stabilize the sand and help retain water Lichens may be eaten by some animals such as reindeer living in arctic regions The larvae of a number of Lepidoptera species feed exclusively on lichens These include common footman and marbled beauty They are very low in protein and high in carbohydrates making them unsuitable for some animals The Northern flying squirrel uses it for nesting food and winter water Effects of air pollution Edit Some lichens like the foliose Lobaria pulmonaria are sensitive to air pollution If lichens are exposed to air pollutants at all times without any deciduous parts they are unable to avoid the accumulation of pollutants Also lacking stomata and a cuticle lichens may absorb aerosols and gases over the entire thallus surface from which they may readily diffuse to the photobiont layer 127 Because lichens do not possess roots their primary source of most elements is the air and therefore elemental levels in lichens often reflect the accumulated composition of ambient air The processes by which atmospheric deposition occurs include fog and dew gaseous absorption and dry deposition 128 Consequently many environmental studies with lichens emphasize their feasibility as effective biomonitors of atmospheric quality 127 129 130 131 132 133 Not all lichens are equally sensitive to air pollutants so different lichen species show different levels of sensitivity to specific atmospheric pollutants 134 The sensitivity of a lichen to air pollution is directly related to the energy needs of the mycobiont so that the stronger the dependency of the mycobiont on the photobiont the more sensitive the lichen is to air pollution 135 Upon exposure to air pollution the photobiont may use metabolic energy for repair of its cellular structures that would otherwise be used for maintenance of its photosynthetic activity therefore leaving less metabolic energy available for the mycobiont The alteration of the balance between the photobiont and mycobiont can lead to the breakdown of the symbiotic association Therefore lichen decline may result not only from the accumulation of toxic substances but also from altered nutrient supplies that favor one symbiont over the other 127 This interaction between lichens and air pollution has been used as a means of monitoring air quality since 1859 with more systematic methods developed by William Nylander in 1866 2 Human use EditFurther information Ethnolichenology Iwatake Umbilicaria esculenta gathering at Kumano in Kishu by Hiroshige II Food Edit Main article Edible lichen Lichens are eaten by many different cultures across the world Although some lichens are only eaten in times of famine others are a staple food or even a delicacy Two obstacles are often encountered when eating lichens lichen polysaccharides are generally indigestible to humans and lichens usually contain mildly toxic secondary compounds that should be removed before eating Very few lichens are poisonous but those high in vulpinic acid or usnic acid are toxic 136 Most poisonous lichens are yellow In the past Iceland moss Cetraria islandica was an important source of food for humans in northern Europe and was cooked as a bread porridge pudding soup or salad Bryoria fremontii edible horsehair lichen was an important food in parts of North America where it was usually pitcooked Northern peoples in North America and Siberia traditionally eat the partially digested reindeer lichen Cladina spp after they remove it from the rumen of caribou or reindeer that have been killed Rock tripe Umbilicaria spp and Lasalia spp is a lichen that has frequently been used as an emergency food in North America and one species Umbilicaria esculenta iwatake in Japanese is used in a variety of traditional Korean and Japanese foods Lichenometry Edit Main article Lichenometry Lichen grown in a Mickey Mouse shape 13 years later Lichenometry is a technique used to determine the age of exposed rock surfaces based on the size of lichen thalli Introduced by Beschel in the 1950s 137 the technique has found many applications it is used in archaeology palaeontology and geomorphology It uses the presumed regular but slow rate of lichen growth to determine the age of exposed rock 32 9 138 Measuring the diameter or other size measurement of the largest lichen of a species on a rock surface indicates the length of time since the rock surface was first exposed Lichen can be preserved on old rock faces for up to citation needed 10 000 years providing the maximum age limit of the technique though it is most accurate within 10 error when applied to surfaces that have been exposed for less than 1 000 years 139 Lichenometry is especially useful for dating surfaces less than 500 years old as radiocarbon dating techniques are less accurate over this period 140 The lichens most commonly used for lichenometry are those of the genera Rhizocarpon e g the species Rhizocarpon geographicum map lichen and Xanthoria Biodegradation Edit Lichens have been shown to degrade polyester resins as can be seen in archaeological sites in the Roman city of Baelo Claudia in Spain 141 Lichens can accumulate several environmental pollutants such as lead copper and radionuclides 142 Some species of lichen such as Parmelia sulcata called a hammered shield lichen among other names and Lobaria pulmonaria lung lichen and many in the Cladonia genus have been shown to produce serine proteases capable of the degradation of pathogenic forms of prion protein PrP which may be useful in treating contaminated environmental reservoirs 143 144 145 Dyes Edit Many lichens produce secondary compounds including pigments that reduce harmful amounts of sunlight and powerful toxins that deter herbivores or kill bacteria These compounds are very useful for lichen identification and have had economic importance as dyes such as cudbear or primitive antibiotics A pH indicator which can indicate acidic or basic substances called litmus is a dye extracted from the lichen Roccella tinctoria dyer s weed 146 by boiling It gives its name to the well known litmus test Traditional dyes of the Scottish Highlands for Harris tweed 2 and other traditional cloths were made from lichens including the orange Xanthoria parietina common orange lichen and the grey foliaceous Parmelia saxatilis common on rocks and known colloquially as crottle There are reports dating almost 2 000 years old of lichens being used to make purple and red dyes 147 Of great historical and commercial significance are lichens belonging to the family Roccellaceae commonly called orchella weed or orchil Orcein and other lichen dyes have largely been replaced by synthetic versions Traditional medicine and research Edit Historically in traditional medicine of Europe Lobaria pulmonaria was collected in large quantities as lungwort due to its lung like appearance the doctrine of signatures suggesting that herbs can treat body parts that they physically resemble Similarly Peltigera leucophlebia ruffled freckled pelt was used as a supposed cure for thrush due to the resemblance of its cephalodia to the appearance of the disease 28 Lichens produce metabolites being researched for their potential therapeutic or diagnostic value 148 Some metabolites produced by lichens are structurally and functionally similar to broad spectrum antibiotics while few are associated respectively to antiseptic similarities 149 Usnic acid is the most commonly studied metabolite produced by lichens 149 It is also under research as a bactericidal agent against Escherichia coli and Staphylococcus aureus 150 Aesthetic appeal Edit Pine forest with Cladonia lichen ground cover Colonies of lichens may be spectacular in appearance dominating the surface of the visual landscape as part of the aesthetic appeal to visitors of Yosemite National Park Sequoia National Park and the Bay of Fires 32 2 Orange and yellow lichens add to the ambience of desert trees tundras and rocky seashores Intricate webs of lichens hanging from tree branches add a mysterious aspect to forests Fruticose lichens are used in model railroading 151 and other modeling hobbies as a material for making miniature trees and shrubs In literature Edit In early Midrashic literature the Hebrew word vayilafeth in Ruth 3 8 is explained as referring to Ruth entwining herself around Boaz like lichen 152 The 10th century Arab physician Al Tamimi mentions lichens dissolved in vinegar and rose water being used in his day for the treatment of skin diseases and rashes 153 The plot of John Wyndham s science fiction novel Trouble with Lichen revolves around an anti aging chemical extracted from a lichen History Edit Lichenes fancifully drawn by Ernst Haeckel to emphasize his ideas of symmetry in his Artforms of Nature 1904 Although lichens had been recognized as organisms for quite some time it was not until 1867 when Swiss botanist Simon Schwendener proposed his dual theory of lichens that lichens are a combination of fungi with algae or cyanobacteria whereby the true nature of the lichen association began to emerge 154 Schwendener s hypothesis which at the time lacked experimental evidence arose from his extensive analysis of the anatomy and development in lichens algae and fungi using a light microscope Many of the leading lichenologists at the time such as James Crombie and Nylander rejected Schwendener s hypothesis because the common consensus was that all living organisms were autonomous 154 Other prominent biologists such as Heinrich Anton de Bary Albert Bernhard Frank Beatrix Potter Melchior Treub and Hermann Hellriegel were not so quick to reject Schwendener s ideas and the concept soon spread into other areas of study such as microbial plant animal and human pathogens 154 155 156 When the complex relationships between pathogenic microorganisms and their hosts were finally identified Schwendener s hypothesis began to gain popularity Further experimental proof of the dual nature of lichens was obtained when Eugen Thomas published his results in 1939 on the first successful re synthesis experiment 154 In the 2010s a new facet of the fungi algae partnership was discovered Toby Spribille and colleagues found that many types of lichen that were long thought to be ascomycete algae pairs were actually ascomycete basidiomycete algae trios 1 157 Gallery Edit Lobaria pulmonaria tree lungwort lung lichen lung moss Upper Bavaria Germany Cladonia macilenta var bacillaris Lipstick Cladonia Usnea australis a fruticose form growing on a tree branch Hypogymnia cf tubulosa with Bryoria sp and Tuckermannopsis sp in the Canadian Rockies Letharia sp with Bryoria sp on pine branches near Blackpine Lake Washington State Lobaria oregana commonly called Lettuce lichen in the Hoh Rainforest Washington State A lichen growing on a rock in a Brazilian cloud forest Xanthoparmelia cf lavicola a foliose lichen on basalt Map lichen Rhizocarpon geographicum on rock Physcia millegrana a foliose lichen with an unlichenized polypore fungus bottom right on a fallen log Reindeer moss Cladonia rangiferina Crustose lichens on limestone in Alta Murgia Southern Italy Cladonia cf cristatella a lichen commonly referred to as British Soldiers Notice the red tips A crusty crustose lichen on a wall Lichen on a lilac bush Foliose lichens on rock growing outward and dying in the center These lichens are at least several decades old Xanthoria sp lichen on volcanic rock in Craters of the Moon National Monument Idaho USA Lecanora cf muralis lichen on the banks of the Bega canal in Timișoara Romania Microscopic view of lichen growing on a piece of concrete dust note 1 See also Edit Fungi portal Biology portalLichenology Lichens and nitrogen cycling Outline of lichens Symbiosis in lichensNotes Edit This was scraped from a dry concrete paved section of a drainage ditch This entire image covers a square that is approximately 1 7 millimeters on a side The numbered ticks on the scale 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Smith L 2010 An Analysis of Antiseptic and Antibiotic Properties of Variously Treated Mosses and Lichens Archived 20 August 2017 at the Wayback Machine University of Michigan Biological Station Bustinza F 1952 Antibacterial Substances from Lichens Economic Botany 6 4 402 406 doi 10 1007 bf02984888 S2CID 39335883 Themodelrailroader com Archived from the original on 15 October 2014 Retrieved 10 October 2014 Thus explained by Rabbi Enoch Zundel ben Joseph in his commentary Etz Yosef Tree of Joseph on Sefer Midrash Rabbah vol 2 New York 1987 s v Ruth Rabba 6 3 Zohar Amar and Yaron Serri The Land of Israel and Syria as Described by Al Tamimi Ramat Gan 2004 pp 56 108 109 ISBN 965 226 252 8 Hebrew a b c d Honegger R 2000 Simon Schwender 1829 1919 and the dual hypothesis in lichens Bryologist 103 2 307 313 doi 10 1639 0007 2745 2000 103 0307 SSATDH 2 0 CO 2 ISSN 0007 2745 JSTOR 3244159 S2CID 84580224 Treub Melchior 1873 Onderzoekingen over de natuur der lichenen Dissertation Leiden University Wakeford Tom 2002 Liaisons of Life From Hornworts to Hippos How the Unassuming Microbe Has Driven Evolution John Wiley amp Sons Incorporated ISBN 978 0 470 24400 5 OCLC 922973303 Yong Ed 21 July 2016 How a guy from a Montana trailer park overturned 150 years of biology The Atlantic archived from the original on 23 July 2017 retrieved 23 July 2017 Further reading EditJorgensen Per M and Lucking Robert April 2018 The Rustici Pauperrimi A Linnaean Myth about Lichens Rectified The Linnean 34 1 pp 9 12 Wikimedia Commons has media related to Lichens Look up lichen in Wiktionary the free dictionary Retrieved from https en wikipedia org w index php title Lichen amp oldid 1135104705, wikipedia, wiki, book, books, library,

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