Lecideaceae: Difference between revisions
add |
add subsection on Pedogenesis |
||
Line 18: | Line 18: | ||
}} |
}} |
||
The '''Lecideaceae''' are a [[family (biology)|family]] of [[lichen]]s in the order [[Lecideales]] ([[Ascomycota]], class [[Lecanoromycetes]]). It contains about 30 genera about roughly 250 species. A major distinguishing characteristic of the family is the {{lichengloss|lecanoroid}} form of the [[ascomata|fruiting bodies]]: typically circular, dark, and without a {{lichengloss|thalline margin}}. Most species in the family are lichenised with [[green algae]], although a few species, scattered amongst several genera, are [[lichenicolous fungus|lichenicolous]]–they live on other lichens. Lecideaceae lichens tend to grow [[saxicolous lichen|on rocks]], [[lignicolous lichen|wood]], and [[terricolous lichen|soil]]. The largest genus in the family, ''[[Lecidea]]'', was once a loosely circumscribed [[wastebasket taxon]] containing hundreds of [[morphology (biology)|morphologically]] similar species with generally crustose thalli, photobiont-free apothecial margins and translucent, single-celled {{lichengloss|ascospores}}. The overall [[taxonomy (biology)|taxonomy]] and classification within the family has been made more accurate with recent [[molecular phylogenetics]] studies. |
The '''Lecideaceae''' are a [[family (biology)|family]] of [[lichen]]s in the order [[Lecideales]] ([[Ascomycota]], class [[Lecanoromycetes]]). It contains about 30 genera and about roughly 250 species. A major distinguishing characteristic of the family is the {{lichengloss|lecanoroid}} form of the [[ascomata|fruiting bodies]]: typically circular, dark, and without a {{lichengloss|thalline margin}}. Most species in the family are lichenised with [[green algae]], although a few species, scattered amongst several genera, are [[lichenicolous fungus|lichenicolous]]–they live on other lichens. Lecideaceae lichens tend to grow [[saxicolous lichen|on rocks]], [[lignicolous lichen|wood]], and [[terricolous lichen|soil]]. The largest genus in the family, ''[[Lecidea]]'', was once a loosely circumscribed [[wastebasket taxon]] containing hundreds of [[morphology (biology)|morphologically]] similar species with generally crustose thalli, photobiont-free apothecial margins and translucent, single-celled {{lichengloss|ascospores}}. The overall [[taxonomy (biology)|taxonomy]] and classification within the family has been made more accurate with recent [[molecular phylogenetics]] studies. |
||
==Systematics== |
==Systematics== |
||
Line 110: | Line 110: | ||
There are 17 species of [[lichenicolous fungus|lichenicolous]] (lichen-dwelling) fungi and lichens in the Lecideaceae. These species are distributed amongst the genera ''Bellemerea'', ''Cecidonia'', ''Immersaria'', ''Lecidea'', and ''Poeltiaria''. In some of these cases of lichenicolous lichens, such as ''[[Bellemerea cupreoatra]]'' and ''[[Poeltiaria coromandelica]]'', the juvenile lichen is facultatively lichenicolous but becomes independent as an adult.<ref name="Diederich et al. 2018"/> |
There are 17 species of [[lichenicolous fungus|lichenicolous]] (lichen-dwelling) fungi and lichens in the Lecideaceae. These species are distributed amongst the genera ''Bellemerea'', ''Cecidonia'', ''Immersaria'', ''Lecidea'', and ''Poeltiaria''. In some of these cases of lichenicolous lichens, such as ''[[Bellemerea cupreoatra]]'' and ''[[Poeltiaria coromandelica]]'', the juvenile lichen is facultatively lichenicolous but becomes independent as an adult.<ref name="Diederich et al. 2018"/> |
||
===Pedogenesis=== |
|||
Several ''Lecidea''species contribute to the [[weathering]] processes on rock surfaces, known as ''[[pedogenesis]]''. These saxicolous species extend their [[hypha]]e into rock crevices, gradually detaching, incorporating, and expelling rock flakes. ''[[Lecidea auriculata]]'', an example of a {{lichengloss|euendolithic}} lichen, actively bores into and inhabits the mineral matrix within rocks. In specific arctic alpine environments, surfaces colonized by these lichens weather at rates estimated to be 25-50 times faster than those caused by other natural processes.<ref name="McCarroll & Viles 1995"/> The weathering impact of ''Lecidea auriculata'' on the [[Little Ice Age]] moraines of the glacier [[Storbreen]] in [[Jotunheimen]], central southern Norway, has been documented. Its degradative activity is limited, however, by its ecological range, predominantly to areas with minimal snow cover.<ref name="Matthews & Owen 2008"/> Species of ''Lecidea'' have also been observed degrading a variety of substances including [[granite]],<ref name="De los Ríos et al. 2005"/> [[magaliesberg quartzite]],<ref name="Cooks & Otto 1990"/> serpentinized ultramafic rocks,<ref name="Favero-Longo et al. 2005"/> and volcanic [[andesite]].<ref name="Ascaso et al. 1990"/> Research on ''[[Lecidea tesselata]]'', found on desert rocks in western North America, identified key biomolecules aiding survival and chemical biodeterioration using [[Raman spectroscopy]]. It accumulates [[calcium oxalate]] monohydrate, the UV protectant [[scytonemin]], and [[haematite]] to withstand high UV radiation levels.<ref name="Edwards et al. 2004"/> In addition to natural materials, ''Lecidea'' species affect man-made objects. Sekishu [[roof tile]]s are a traditional Japanese housing component that are covered with an opaque reddish brown glaze consisting of an alkali [[feldspar]]-type X-ray amorphous glass, a surface that is unlikely to be affected by normal chemical weathering. The tiles tend to get colonised by ''Lecidea'', which, after about 7–10 years, results in the appearance of corrosion pits up to 50 µm deep.<ref name="Watanabe & Kitagawa 2004"/><ref name="Watanabe et al. 2006"/> Although research often focuses on ''Lecidea'' within the family Lecideaceae, similar weathering effects have been documented in the genus ''Porpidia''.<ref name="Watanabe & Kitagawa 2004b"/><ref name="Prieto et al. 2010"/> |
|||
==Conservation== |
==Conservation== |
||
Line 119: | Line 122: | ||
<ref name="Acharius 1803">{{cite book |last=Acharius |first=E. |year=1803 |title=Methodus qua Omnes Detectos Lichenes Secundum Organa Carpomorpha ad Genera, Species et Varietates Redigere atque Observationibus Illustrare Tentavit Erik Acharius |page=32 |location=Stockholm |publisher=impensis F.D.D. Ulrich, typis C.F. Marquard |language=la |url=https://www.biodiversitylibrary.org/page/44218122}}</ref> |
<ref name="Acharius 1803">{{cite book |last=Acharius |first=E. |year=1803 |title=Methodus qua Omnes Detectos Lichenes Secundum Organa Carpomorpha ad Genera, Species et Varietates Redigere atque Observationibus Illustrare Tentavit Erik Acharius |page=32 |location=Stockholm |publisher=impensis F.D.D. Ulrich, typis C.F. Marquard |language=la |url=https://www.biodiversitylibrary.org/page/44218122}}</ref> |
||
<ref name="Ascaso et al. 1990">{{cite journal |last1=Acaso |first1=C. |last2=Sancho |first2=L.G. |last3=Rodriguez-Pascual |first3=C. |year=1990 |title=The weathering action of saxicolous lichens in martime Antarctica |journal=Polar Biology |volume=11 |pages=33–39 |url=https://digital.csic.es/bitstream/10261/31464/1/PolarBiolpdf.pdf}}</ref> |
|||
<ref name="Awasthi & Singh 1977">{{cite journal |last1=Awasthi |first1=Dharani Dhar |last2=Singh |first2=Krishna Pal |title=''Heppsora'', a new lichen genus from India |journal=The Bryologist |volume=80 |issue=3 |year=1977 |doi=10.2307/3242031 |jstor=3242031 |pages=536–538}}</ref> |
<ref name="Awasthi & Singh 1977">{{cite journal |last1=Awasthi |first1=Dharani Dhar |last2=Singh |first2=Krishna Pal |title=''Heppsora'', a new lichen genus from India |journal=The Bryologist |volume=80 |issue=3 |year=1977 |doi=10.2307/3242031 |jstor=3242031 |pages=536–538}}</ref> |
||
Line 141: | Line 146: | ||
<ref name="Coleine et al. 2018">{{cite journal |last1=Coleine |first1=Claudia |last2=Stajich |first2=Jason E. |last3=Zucconi |first3=Laura |last4=Onofri |first4=Silvano |last5=Pombubpa |first5=Nuttapon |last6=Egidi |first6=Eleonora |last7=Franks |first7=Ashley |last8=Buzzini |first8=Pietro |last9=Selbmann |first9=Laura |title=Antarctic cryptoendolithic fungal communities are highly adapted and dominated by Lecanoromycetes and Dothideomycetes |journal=Frontiers in Microbiology |volume=9 |year=2018 |pmid=30008702 |pmc=6033990 |doi=10.3389/fmicb.2018.01392 |doi-access=free |pages=1–14}}</ref> |
<ref name="Coleine et al. 2018">{{cite journal |last1=Coleine |first1=Claudia |last2=Stajich |first2=Jason E. |last3=Zucconi |first3=Laura |last4=Onofri |first4=Silvano |last5=Pombubpa |first5=Nuttapon |last6=Egidi |first6=Eleonora |last7=Franks |first7=Ashley |last8=Buzzini |first8=Pietro |last9=Selbmann |first9=Laura |title=Antarctic cryptoendolithic fungal communities are highly adapted and dominated by Lecanoromycetes and Dothideomycetes |journal=Frontiers in Microbiology |volume=9 |year=2018 |pmid=30008702 |pmc=6033990 |doi=10.3389/fmicb.2018.01392 |doi-access=free |pages=1–14}}</ref> |
||
<ref name="Cooks & Otto 1990">{{cite journal |last1=Cooks |first1=J. |last2=Otto |first2=E. |year=1990 |title=The weathering effects of the lichen ''Lecidea'' aff. ''sarcogynoides'' (Koerb.) on magaliesberg quartzite |journal=Earth Surface Processes and Landforms |volume=15 |issue=6 |pages=491–500 |doi=10.1002/esp.3290150602}}</ref> |
|||
<ref name="De los Ríos et al. 2005">{{cite journal |last1=De los Ríos |first1=A. |last2=Sancho |first2=L.G. |last3=Grube |first3=M. |last4=Wierzchos |first4=J. |last5=Ascaso |first5=C. |year=2005 |title=Endolithic growth of two ''Lecidea'' lichens in granite from continental Antarctica detected by molecular and microscopy techniques |journal=New Phytologist |volume=165 |pages=181–190 |doi=10.1111/j.1469-8137.2004.01199.x |url=https://nph.onlinelibrary.wiley.com/doi/pdf/10.1111/j.1469-8137.2004.01199.x}}</ref> |
|||
<ref name="Diederich et al. 2018">{{cite journal |last1=Diederich |first1=Paul |last2=Lawrey |first2=James D. |last3=Ertz |first3=Damien |title=The 2018 classification and checklist of lichenicolous fungi, with 2000 non-lichenized, obligately lichenicolous taxa |journal=The Bryologist |volume=121 |issue=3 |year=2018 |pages=373–374 |doi=10.1639/0007-2745-121.3.340 |url=https://www.researchgate.net/publication/328374342}}</ref> |
<ref name="Diederich et al. 2018">{{cite journal |last1=Diederich |first1=Paul |last2=Lawrey |first2=James D. |last3=Ertz |first3=Damien |title=The 2018 classification and checklist of lichenicolous fungi, with 2000 non-lichenized, obligately lichenicolous taxa |journal=The Bryologist |volume=121 |issue=3 |year=2018 |pages=373–374 |doi=10.1639/0007-2745-121.3.340 |url=https://www.researchgate.net/publication/328374342}}</ref> |
||
<ref name="Edwards et al. 2004">{{cite book |last1=Edwards |first1=HowellG.M. |last2=Jorge Villar |first2=Susana E. |last3=Seaward |first3=Mark R.D. |last4=St. Clair |first4=Larry L. |year=2004 |chapter=Raman spectroscopy of rock biodeterioration by the lichen ''Lecidea tessellata'' flörke in a desert environment, Utah, USA |editor-last1=St.Clair |editor-first1=L.L. |editor-last2=Seaward |editor-first2=M.R.D. |title=Biodeterioration of Stone Surfaces. |publisher=Springer |location=Dordrecht |doi=10.1007/978-1-4020-2845-8_13}}</ref> |
|||
<ref name="Ekman 2001">{{cite journal |last=Ekman |first=Stefan |title=Molecular phylogeny of the Bacidiaceae (Lecanorales, lichenized Ascomycota) |journal=Mycological Research |volume=105 |issue=7 |year=2001 |doi=10.1017/S0953756201004269 |pages=783–797}}</ref> |
<ref name="Ekman 2001">{{cite journal |last=Ekman |first=Stefan |title=Molecular phylogeny of the Bacidiaceae (Lecanorales, lichenized Ascomycota) |journal=Mycological Research |volume=105 |issue=7 |year=2001 |doi=10.1017/S0953756201004269 |pages=783–797}}</ref> |
||
<ref name="Favero-Longo et al. 2005">{{cite journal |first1=Sergio E. |last1=Favero-Longo |first2=Daniele |last2=Castelli |first3=Ornella |last3=Salvadori |first4=Elena |last4=Belluso |first5=Rosanna |last5=Piervittori |year=2005 |title=Pedogenetic action of the lichens ''Lecidea atrobrunnea'', ''Rhizocarpon geographicum'' gr. and ''Sporastatia testudinea'' on serpentinized ultramafic rocks in an alpine environment |journal=International Biodeterioration & Biodegradation |volume=56 |issue=1 |pages=17–27 |isbn=978-90-481-6724-1 |doi=10.1016/j.ibiod.2004.11.006}}</ref> |
|||
<ref name="Frank‐Kamenetskaya et al. 2021">{{cite journal |first1=Olga V. |last1=Frank‐Kamenetskaya1 |first2=Marina S. |last2=Zelenskaya |first3=Alina R. |last3=Izatulina1 |first4=Oleg S. |last4=Vereshchagin |first5=Dmitry Yu. |last5=Vlasov |first6=Dmitry E. |last6=Himelbrant |first7=Dmitrii V. |last7=Pankin |year=2021 |title=Copper oxalate formation by lichens and fungi |journal=Scientific Reports |volume=11 |page=e24329 |doi=10.1038/s41598-021-03600-5 |doi-access=free}}</ref> |
<ref name="Frank‐Kamenetskaya et al. 2021">{{cite journal |first1=Olga V. |last1=Frank‐Kamenetskaya1 |first2=Marina S. |last2=Zelenskaya |first3=Alina R. |last3=Izatulina1 |first4=Oleg S. |last4=Vereshchagin |first5=Dmitry Yu. |last5=Vlasov |first6=Dmitry E. |last6=Himelbrant |first7=Dmitrii V. |last7=Pankin |year=2021 |title=Copper oxalate formation by lichens and fungi |journal=Scientific Reports |volume=11 |page=e24329 |doi=10.1038/s41598-021-03600-5 |doi-access=free}}</ref> |
||
Line 201: | Line 214: | ||
<ref name="Massalongo 1860">{{cite journal |last=Massalongo |first=A.B. |year=1860 |title=Esame comparativo di alcune genere di licheni |trans-title=Comparative examination of some lichen genera |journal=Atti dell'Istituto Veneto Scienze |volume=5 |pages=247–276}}</ref> |
<ref name="Massalongo 1860">{{cite journal |last=Massalongo |first=A.B. |year=1860 |title=Esame comparativo di alcune genere di licheni |trans-title=Comparative examination of some lichen genera |journal=Atti dell'Istituto Veneto Scienze |volume=5 |pages=247–276}}</ref> |
||
<ref name="Matthews & Owen 2008">{{cite journal |last1=Matthews |first=John A. |last2=Owen |first2=Geraint |year=2008 |title=Endolithic lichens, rapid biological weathering and Schmidt Hammer r-values on recently exposed rock surfaces: Storbreen glacier foreland, Jotunheimen, Norway |journal=Geografiska Annaler |volume=90 |issue=4 |pages=287–297 |doi=10.1111/j.1468-0459.2008.00346.x |jstor=40204904}}</ref> |
|||
<ref name="McCarroll & Viles 1995">{{cite journal |last1=McCarroll |first1=Danny |last2=Viles |first2=Heather |year=1995 |title=Rock-weathering by the lichen ''Lecidea auriculata'' in an arctic alpine environment |journal=Earth Surface Processes and Landforms |volume=20 |issue=3 |pages=199–206 |doi=10.1002/esp.3290200302}}</ref> |
|||
<ref name="McCune et al. 2017">{{cite journal |last1=McCune |first1=Bruce |last2=Curtis |first2=Marc J. |last3=Di Meglio |first3=Joseph |title=New taxa and a case of ephemeral spore production in Lecideaceae from western North America |journal=The Bryologist |volume=120 |issue=2 |year=2017 |doi=10.1639/0007-2745-120.2.115 |pages=115–124}}</ref> |
<ref name="McCune et al. 2017">{{cite journal |last1=McCune |first1=Bruce |last2=Curtis |first2=Marc J. |last3=Di Meglio |first3=Joseph |title=New taxa and a case of ephemeral spore production in Lecideaceae from western North America |journal=The Bryologist |volume=120 |issue=2 |year=2017 |doi=10.1639/0007-2745-120.2.115 |pages=115–124}}</ref> |
||
Line 211: | Line 228: | ||
<ref name="Poelt & Vězda 1981">{{cite book |last1=Poelt |first1=J. |last2=Vězda |first2=A. |year=1981 |title=Bestimmungsschlüssel europäischer Flechten. Ergänzungsheft II |trans-title=Identification key to European lichens. Supplement II |series=Bibliotheca Lichenologica |volume=16 |page=364 |publisher=J. Cramer |location=Vaduz |language=de |isbn=978-3-7682-1162-8}}</ref> |
<ref name="Poelt & Vězda 1981">{{cite book |last1=Poelt |first1=J. |last2=Vězda |first2=A. |year=1981 |title=Bestimmungsschlüssel europäischer Flechten. Ergänzungsheft II |trans-title=Identification key to European lichens. Supplement II |series=Bibliotheca Lichenologica |volume=16 |page=364 |publisher=J. Cramer |location=Vaduz |language=de |isbn=978-3-7682-1162-8}}</ref> |
||
<ref name="Prieto et al. 2010">{{cite journal |last1=Prieto |first=B. |last2=Edwards |first2=H.G.M. |last3=Seaward |first3=M.R.D. |title=A Fourier transform-Raman spectroscopic study of lichen strategies on granite monuments |journal=Geomicrobiology Journal |volume=17 |issue=1 |pages=55–60 |doi=10.1080/014904500270495}}</ref> |
|||
<ref name="Rambold 1989">{{cite journal |last=Rambold |first=G. |year=1989 |title=A Monograph of the Saxicolous Lecideoid Lichens of Australia (excl. Tasmania) |journal=Bibliotheca Lichenologica |volume=34 |location=Berlin/Stuttgart |publisher=J. Cramer |page=239 |isbn=978-3-443-58013-1}}</ref> |
<ref name="Rambold 1989">{{cite journal |last=Rambold |first=G. |year=1989 |title=A Monograph of the Saxicolous Lecideoid Lichens of Australia (excl. Tasmania) |journal=Bibliotheca Lichenologica |volume=34 |location=Berlin/Stuttgart |publisher=J. Cramer |page=239 |isbn=978-3-443-58013-1}}</ref> |
||
Line 229: | Line 248: | ||
<ref name="Vogel 1955">{{cite journal |last=Vogel |first=S. |year=1955 |title=Niedere "Fensterpflanzen" in der südafrikanischen Wüste |trans-title=Lower 'window plants' in the South African desert |journal=Beiträge zur Biologie der Pflanzen |volume=31 |page=104 |language=de}}</ref> |
<ref name="Vogel 1955">{{cite journal |last=Vogel |first=S. |year=1955 |title=Niedere "Fensterpflanzen" in der südafrikanischen Wüste |trans-title=Lower 'window plants' in the South African desert |journal=Beiträge zur Biologie der Pflanzen |volume=31 |page=104 |language=de}}</ref> |
||
<ref name="Watanabe & Kitagawa 2004">{{cite journal |last1=Watanabe |first1=Katsuaki |last2=Kitagawa |first2=Ryuji |year=2006 |title=Dissolution process of ''sekishu'' roof liles affected by crustose lichen ''Lecidea'' sp. grown on their surfaces |journal=Clay Science |volume=12 |issue=S2 |pages=240–244 |url=https://www.jstage.jst.go.jp/article/jcssjclayscience1960/12/Supplement2/12_Supplement2_240/_pdf}}</ref> |
|||
<ref name="Watanabe & Kitagawa 2004b">{{cite journal |last1=Watanabe |first1=Katsuaki |last2=Kitagawa |first2=Ryuji |year=2004 |title=Alteration mechanism of biotite in granitic rock caused by crustose lichen ''Porpidia'' |journal=Clay Science |volume=12 |issue=4 |pages=249–257 |doi=10.11362/jcssjclayscience1960.12.249}}</ref> |
|||
<ref name="Watanabe et al. 2006">{{cite journal |last1=Watanabe |first1=K. |last2=Ohfuji |first2=H. |last3=Ando |first3=J. |last4=Kitagawa |first4=R. |year=2006 |title=Elemental behaviour during the process of corrosion of sekishu glazed roof-tiles affected by ''Lecidea'' s.lat. sp. (crustose lichen) |journal=Clay Minerals |volume=41 |issue=4 |pages=819–826 |doi=10.1180/0009855064140221}}</ref> |
|||
<ref name="Wijayawardene et al. 2022">{{cite journal |display-authors=6 |last1=Wijayawardene |first1=N.N. |last2=Hyde |first2=K.D. |last3=Dai |first3=D.Q. |last4=Sánchez-García |first4=M. |last5=Goto |first5=B.T. |last6=Saxena |first6=R.K. |last7=Erdoğdu |first7=M. |last8=Selçuk |first8=F. |last9=Rajeshkumar |first9=K.C. |last10=Aptroot |first10=A. |last11=Błaszkowski |first11=J. |last12=Boonyuen |first12=N. |last13=da Silva |first13=G. |last14=de Souza |first14=F.A. |last15=Dong |first15=W. |last16=Ertz |first16=D. |last17=Haelewaters |first17=D. |last18=Jones |first18=E.B. |last19=Karunarathna |first19=S.C. |last20=Kirk |first20=P.M. |last21=Kukwa |first21=M. |last22=Kumla |first22=J. |last23=Leontyev |first23=D.V. |last24=Lumbsch |first24=H.T. |last25=Maharachchikumbura |first25=S.S.N. |last26=Marguno |first26=F. |last27=Martínez-Rodríguez |first27=P. |last28=Mešić |first28=A. |last29=Monteiro |first29=J.S. |last30=Oehl |first30=F. |last31=Pawłowska |first31=J. |last32=Pem |first32=D. |last33=Pfliegler |first33=W.P. |last34=Phillips |first34=A.J.L. |last35=Pošta |first35=A. |last36=He |first36=M.Q. |last37=Li |first37=J.X. |last38=Raza |first38=M. |last39=Sruthi |first39=O.P. |last40=Suetrong |first40=S. |last41=Suwannarach |first41=N. |last42=Tedersoo |first42=L. |last43=Thiyagaraja |first43=V. |last44=Tibpromma |first44=S. |last45=Tkalčec |first45=Z. |last46=Tokarev |first46=Y.S. |last47=Wanasinghe |first47=D.N. |last48=Wijesundara |first48=D.S.A. |last49=Wimalaseana |first49=S.D.M.K. |last50=Madrid |first50=H. |last51=Zhang |first51=G.Q. |last52=Gao |first52=Y. |last53=Sánchez-Castro |first53=I. |last54=Tang |first54=L.Z. |last55=Stadler |first55=M. |last56=Yurkov |first56=A. |last57=Thines |first57=M. |year=2022 |title=Outline of Fungi and fungus-like taxa – 2021 |journal=Mycosphere |volume=13 |issue=1 |pages=53–453 |doi=10.5943/mycosphere/13/1/2 |url=https://www.researchgate.net/publication/358798332|doi-access=free |hdl=10481/76378 |hdl-access=free}}</ref> |
<ref name="Wijayawardene et al. 2022">{{cite journal |display-authors=6 |last1=Wijayawardene |first1=N.N. |last2=Hyde |first2=K.D. |last3=Dai |first3=D.Q. |last4=Sánchez-García |first4=M. |last5=Goto |first5=B.T. |last6=Saxena |first6=R.K. |last7=Erdoğdu |first7=M. |last8=Selçuk |first8=F. |last9=Rajeshkumar |first9=K.C. |last10=Aptroot |first10=A. |last11=Błaszkowski |first11=J. |last12=Boonyuen |first12=N. |last13=da Silva |first13=G. |last14=de Souza |first14=F.A. |last15=Dong |first15=W. |last16=Ertz |first16=D. |last17=Haelewaters |first17=D. |last18=Jones |first18=E.B. |last19=Karunarathna |first19=S.C. |last20=Kirk |first20=P.M. |last21=Kukwa |first21=M. |last22=Kumla |first22=J. |last23=Leontyev |first23=D.V. |last24=Lumbsch |first24=H.T. |last25=Maharachchikumbura |first25=S.S.N. |last26=Marguno |first26=F. |last27=Martínez-Rodríguez |first27=P. |last28=Mešić |first28=A. |last29=Monteiro |first29=J.S. |last30=Oehl |first30=F. |last31=Pawłowska |first31=J. |last32=Pem |first32=D. |last33=Pfliegler |first33=W.P. |last34=Phillips |first34=A.J.L. |last35=Pošta |first35=A. |last36=He |first36=M.Q. |last37=Li |first37=J.X. |last38=Raza |first38=M. |last39=Sruthi |first39=O.P. |last40=Suetrong |first40=S. |last41=Suwannarach |first41=N. |last42=Tedersoo |first42=L. |last43=Thiyagaraja |first43=V. |last44=Tibpromma |first44=S. |last45=Tkalčec |first45=Z. |last46=Tokarev |first46=Y.S. |last47=Wanasinghe |first47=D.N. |last48=Wijesundara |first48=D.S.A. |last49=Wimalaseana |first49=S.D.M.K. |last50=Madrid |first50=H. |last51=Zhang |first51=G.Q. |last52=Gao |first52=Y. |last53=Sánchez-Castro |first53=I. |last54=Tang |first54=L.Z. |last55=Stadler |first55=M. |last56=Yurkov |first56=A. |last57=Thines |first57=M. |year=2022 |title=Outline of Fungi and fungus-like taxa – 2021 |journal=Mycosphere |volume=13 |issue=1 |pages=53–453 |doi=10.5943/mycosphere/13/1/2 |url=https://www.researchgate.net/publication/358798332|doi-access=free |hdl=10481/76378 |hdl-access=free}}</ref> |
Revision as of 00:40, 17 March 2024
Lecideaceae | |
---|---|
Lecidea fuscoatra is the type species of the type genus of family Lecideaceae. | |
Scientific classification | |
Domain: | Eukaryota |
Kingdom: | Fungi |
Division: | Ascomycota |
Class: | Lecanoromycetes |
Order: | Lecideales |
Family: | Lecideaceae Chevall. (1826) |
Type genus | |
Lecidea Ach. (1803)
| |
Genera | |
See text | |
Synonyms[1] | |
The Lecideaceae are a family of lichens in the order Lecideales (Ascomycota, class Lecanoromycetes). It contains about 30 genera and about roughly 250 species. A major distinguishing characteristic of the family is the lecanoroid form of the fruiting bodies: typically circular, dark, and without a thalline margin. Most species in the family are lichenised with green algae, although a few species, scattered amongst several genera, are lichenicolous–they live on other lichens. Lecideaceae lichens tend to grow on rocks, wood, and soil. The largest genus in the family, Lecidea, was once a loosely circumscribed wastebasket taxon containing hundreds of morphologically similar species with generally crustose thalli, photobiont-free apothecial margins and translucent, single-celled ascospores. The overall taxonomy and classification within the family has been made more accurate with recent molecular phylogenetics studies.
Systematics
Historical taxonomy
The first member of the present-day Lecideaceae to be formally described was Lichen fusco-ater, later known as Lecidea fuscoatra.[2] The Swedish lichenologist Erik Acharius proposed genus Lecidea in 1803, with Lecidea fuscoatra as the type.[3] This was of several dozen lichen species described by the Swedish taxonomist Carl Linnaeus in his influential 1753 treatise Species Plantarum.[4] The family Lecideaceae was originally proposed by the French botanist François Fulgis Chevallier in his 1826 work Flore générale des environs de Paris; his original spelling of the name was Lecideae. Chevallier's short diagnosis of the family included several characteristics emphasising the form and texture of their reproductive structures and crust. He noted their apothecia (fruiting bodies) to be initially somewhat concave, evolving over time into flat or convex forms that resemble small dishes or patellae, each bordered by a distinct margin. This margin may appear similar to or integrated with a crust, which gradually fades as it ages. Chevallier described the crust itself as membranous, varying from smooth to cracked surfaces, and in some instances, spreading out in a soft, powdery (leprose-farinaceous) manner.[5]
In Josef Hafellner's 1984 work Studien in Richtung einer natürlicheren Gliederung der Sammelfamilien Lecanoraceae und Lecideaceae,[6] he used ascus structure as a major systematic character, dividing these two larger families into numerous, smaller families. However, his proposed families (Koerberiellaceae, Lecidomataceae, Mycobilimbiaceae, and Porpidiaceae) have since been folded into Lecidiaceae;[1] later research showed that ascus structure is not a consistent taxonomic character. For example, Buschbom and Mueller showed in 2004 that Porpidiaceae was not monophyletic unless the Lecideaceae was also included, and that the ascus types used to distinguish between the two families turned out to be modifications of the same basic type.[7] This finding was corroborated in 2006 by Miadłikowska and colleagues, who further showed that the family ought to be reclassified from the order Lecanorales to an uncertain (incertae sedis) provisional placement in the subclass Lecanoromycetidae.[8] Early molecular work suggested that the family was monophyletic.[9][8]
Classification
The conventional classification of lichen-producing fungi has faced challenges due to the reliance on readily observable traits for defining taxonomic groups, which often led to the creation of unnatural groupings of species. An example of this is seen with the genus Lecidea, which by the 1930s, had grown to become one of the largest lichen genera, including around 1200 species. This polyphyletic assemblage of similar-looking species was largely as a result of Alexander Zahlbruckner's influential multi-volume work Catalogus lichenum universalis, which tended to fit any species with crustose thallus, biatorine or lecideine apothecia and simple ascospores into this wastebasket taxon.[10] However, several studies using morphological and chemical characters demonstrated that Lecidea, in the sense of Zahlbruckner, was polyphyletic.[11][12][13][14][15] Nearing the end of the twentieth century, researchers had a better idea of the limits of the genus and many taxa were moved to different new and preexisting genera. By 2011, more than 160 genera from various families included species previously classified within Lecidea.[10] In the most recent (2008) edition of the Dictionary of the Fungi, Lecidea was estimated to contain 427 species, although it was acknowledged that only about 100 of these qualified as Lecidea in the strict sense (sensu stricto).[16] In this cases, sensu stricto in the sense of Hertel means saxicolous lichens with certain anatomical characters, such as excipulum, paraphyses and apical ascus structures.[10]
The order Lecideales was proposed by Edvard August Vainio in 1934, in the fourth volume of his work Lichenographica Fennica.[17] The order was generally neglected in later classifications as the family was historically classified in the order Lecanorales. The order was resurrected in 2011 by Schmull and colleagues, who redefined the type genus to include only Lecidea sensu stricto. They used molecular phylogenetics to show that this group of species, defined by morphology and including the type species (Lecidea fuscoatra) and a few Porpidia, species, formed a monophyletic clade.[10] Molecular phylogenetics analysis shows the order Lecideales as a sister group to the Peltigerales.[18]
Etymology
As is standard practice in botanical nomenclature,[19] the name Lecideaceae is based on the name of the type genus, Lecidea, with the ending -aceae indicating the rank of family. The genus name comprises the Greek word λέκος (lékos), meaning "plate" or "small shield", and the suffix "-ídes", indicating similarity. This alludes to the lecideine apothecia, which are usually somewhat circular and lack a thalline margin.[20]
Description
Family Lecideaceae comprises lichens with a range of growth forms from crust-like (crustose) to scale-like (squamulose).[1] In rare instances, the thallus may be absent.[21] These organisms establish a symbiotic relationship primarily with green algae (chlorococcoid photobionts), and in some instances (such as in the genus Amygdalaria), they also engage with cyanobacteria within specialised structures called cephalodia. The reproductive structures (ascomata) of these lichens are typically apothecia, which can either sit prominently on the surface (sessile) or be partially embedded (immersed) within the thallus. These apothecia may resemble those found in the genera Lecidea and Aspicilia (lecideine or aspicilioid).[1] Most genera in Lecideaceae have lecideine apothecia; exceptions are Bellemerea, Koerberiella, and Lecaimmeria, which have lecanorine apothecia.[22] The structure and position of the ascocarp in Cyclohymenia epilithica appear to be unique among Lecideaceae: this lichen has a central sterile column surrounded by a ring-shaped hymenium.[23]
The internal framework (hamathecium) of these reproductive structures is made up of paraphyses, which are sparingly branched and interconnected (anastomosing). These structures are amyloid, and stain blue with iodine.[1] Paraphyses are usually swollen at the tips, and often pigmented.[21] The asci, or spore-bearing cells, are partially split (semifissitunicate) and feature an amyloid structure at the tip (apical tholus) and amyloid walls, housing a pale central area and a darker top or ring-like structure. These asci are club-shaped (clavate) to cylindrical.[1]
Lecideaceae lichens typically produce eight spores per ascus. These ascospores are non-septate, cylindrical to ellipsoid in shape, hyaline, and non-amyoid. The conidiomata of Lecideaceae are in the form of pycnidia;[1] these structures tend to be dark-walled and immersed in the thallus.[21] The conidia are non-septate and can be cylindrical, rod-shaped (bacilliform), or thread-like (filiform).[1]
Identifying species within the largest Lecideaceae genus, Lecidea, is challenging due to similarities in morphology, anatomical structures, and chemical compositions with many other genera, especially Lecidella in the family Lecanoraceae, and Porpidia in the Lecideaceae. The main distinctions between Lecidea and Lecidella include Lecidella's typically grey, granular thallus with black, blue-black, or white-grey lower thallus; reproductive structures such as soredia, isidia, and blastidia; common presence of conidiomata; Lecanora-type asci; paraphyses that are not fused and easily dispersed; and secondary metabolites including xanthones, orcinol depsidones, β-orcinol depsides, and triterpenoids. Lecidea and Porpidia, both belonging to the Lecideaceae, differ in that Porpidia has soredia, isidia, and blastidia; conidiomata; Porpidia-type asci apex; spores with a halo; fused and branched paraphyses; and secondary metabolites like confluentic acid, norstictic acid, hypostictic acid, 2'-O-methylmicrophyllinnic acid, and 2'-O-methylperlatolic acid. Due to the subtle morphological differences among these genera, distinguishing them based solely on morphology and chemical components is difficult.[24]
Photobionts
In a 1971 study, Margalith Galun and colleagues examined the mycobiont–photobiont relationship in three Lecidea species (Lecidea olivacea, Lecidea opaca, and Lecidea decipiens) by using electron microscopy. The photobionts for the first two are Trebouxia, while it is Myrmecia for the third. They found that the contact between the symbionts ranged from intracellular fungal invasion in the primitively organised thallus to a looser association of wall-to-wall attachment in the more highly differentiated growth forms.[25] Trebouxia arboricola has been identified as a common photobiont in the Lediceaceae.[26]
Chemistry
Secondary metabolites (lichen products) found in Lecideaceae lichens include depsides and depsidones.[1] The main genus Lecidea produces several secondary metabolites: confluentic acid, norstictic acid, hypostictic acid, gyrophoric acid, planaic acid, 2'-O-methylanziaic, 2'-O-methylmicrophyllinnic acid, 2'-O-methylperlatolic acid, and 4'-O-demethylplanaic acid.[24]
In the lichen Lecidea lactea, the depsidone norstictic acid is involved in immobilising copper (Cu), forming a Cu2+–norstictic acid complex. Similarly, psoromic acid, which shares a chemical similarity with norstictic acid, is suggested to sequester Cu2+ through chelation in Lecidea bullata. These species belong to the Lecideion inops alliance, a community of lichen species that are adapted to survive on copper-rich substrates and may show a distinct green colouration in parts of the thallus or apothecia due to copper deposits.[27] A subsequent investigation identified crystals of moolooite, a copper oxalate compound, within Lecidea inops found growing on chalcopyrite ore. This finding confirms the lichen's ability to biomineralise this compound under suitable environmental conditions.[28]
Genera
In the seventh edition (2001) of the Dictionary of the Fungi, Lecideaceae was estimated to contain 9 genera and 441 species;[29] by the next edition (2008), these numbers had changed to 7 genera and 436 species. In this latter work, the largest genus Lecidea was estimated to contain about 427 species, although it was acknowledged that only about 100 of these qualified as Lecidea sensu stricto.[16] According to a 2022 estimate, the Lecideaceae comprise 29 genera and about 260 species.[30] As of February 2024[update], Species Fungorum (in the Catalogue of Life) accept 29 genera and 244 species in Lecideaceae.[31] Many of these genera are monospecific or small genera, with fewer than five species.[22] The following list indicates the genus name, the taxonomic authority, year of publication, and the number of species:[30]
- Amygdalaria Norman (1852)[32] – 11 spp.
- Bahianora Kalb (1984)[33] – 1 sp.
- Bellemerea Hafellner & Cl.Roux (1984)[34] – 10 spp.
- Bryobilimbia Fryday, Printzen & S.Ekman (2014)[35] – 6 spp.
- Catarrhospora Brusse (1994)[36] – 2 spp.
- Cecidonia Triebel & Rambold (1988)[37] – 2 spp.
- Clauzadea Hafellner & Bellem. (1984)[6] – 7 spp.
- Cryptodictyon A.Massal. (1860)[38] – 2 spp.
- Cyclohymenia McCune & M.J.Curtis (2017)[23] – 1 sp.
- Eremastrella S.Vogel (1955)[39] – 2 spp.
- Farnoldia Hertel (1983)[12] – 6 spp.
- Immersaria Rambold & Pietschm. (1989)[40] – 8 spp.
- Koerberiella Stein (1879) – 2 spp.
- Labyrintha Malcolm, Elix & Owe-Larss. (1995)[41] – 1 sp.
- Lecaimmeria C.M.Xie, Lu L.Zhang & Li S.Wang (2022)[22] – 11 spp.
- Lecidea Ach. (1803)[3] – ca. 100 spp.
- Lecidoma Gotth.Schneid. & Hertel (1981)[42] – 1 sp.
- Lopacidia Kalb (1984)[33] – 1 sp.
- Melanolecia Hertel (1981)[43] – 7 spp.
- Pachyphysis R.C.Harris & Ladd (2007)[44] – 1 sp.
- Paraporpidia Rambold & Pietschm. (1989)[40] – 3 spp.
- Poeltiaria Hertel (1984)[13] – 8 spp.
- Poeltidea Hertel & Hafellner (1984)[13] – 3 spp.
- Porpidia Körb. (1855)[45] – 51 spp.
- Porpidinia Timdal (2010)[46] – 2 spp.
- Pseudopannaria (B.de Lesd.) Zahlbr. (1924)[47] – 1 sp.
- Rhizolecia Hertel (1984)[13] – 1 sp.
- Romjularia Timdal (2007)[48] – 1 sp.
- Schizodiscus Brusse (1988)[49] – 1 sp.
- Stenhammarella Hertel (1967)[50] – 1 sp.
- Stephanocyclos Hertel (1983)[51] – 1 sp.
- Xenolecia Hertel (1984)[13] – 2 spp.
In 2014, Alan Fryday and Hannes Hertel proposed to reduce the genera Labyrintha and Notolecidea to synonymy with Poeltidea and Poeltiaria respectively.[52]
Several genera once historically classified in the Lecideaceae have since been moved to other families in light of molecular phylogenetic studies. Examples include Bacidia, which was shown to belong in the Ramalinaceae, a family in the Lecanorales.[53] Heppsora was initially proposed for inclusion in the Lecideaceae based on its resemblance to Heppia and Psora,[54] but is now also in the Ramalinaceae.[30] Mycobilimbia is another example of a genus that was until recently placed in Lecideaceae[16] but is now in the Ramalinaceae.[30] In 2013, genus Hypocenomyce, a resident of the Lecideaceae for several decades, was shown to be extremely polyphyletic and split into four genera distributed amongst three families, none of which were Ledideaceae.[55] Roccellinastrum was included in the family following a 1983 emendation of the genus, but is now in the Pilocarpaceae.[30]
Habitat, distribution, and ecology
Lecideaceae lichens usually grow on bark, on soil, and on rocks. Collectively, the family has a cosmopolitan distribution.[1] The family is one of the most common in Antarctic cryptoendolithic communities.[56] Contrary to the typical habitats favoured by other North American species in the Lecideaceae, Cyclohymenia epilithica uniquely thrives in shaded environments in cool, moist, temperate climates.[23] The family has been less well-studied in the Southern Hemisphere in comparison to the Northern Hemisphere.[52]
There are 17 species of lichenicolous (lichen-dwelling) fungi and lichens in the Lecideaceae. These species are distributed amongst the genera Bellemerea, Cecidonia, Immersaria, Lecidea, and Poeltiaria. In some of these cases of lichenicolous lichens, such as Bellemerea cupreoatra and Poeltiaria coromandelica, the juvenile lichen is facultatively lichenicolous but becomes independent as an adult.[57]
Pedogenesis
Several Lecideaspecies contribute to the weathering processes on rock surfaces, known as pedogenesis. These saxicolous species extend their hyphae into rock crevices, gradually detaching, incorporating, and expelling rock flakes. Lecidea auriculata, an example of a euendolithic lichen, actively bores into and inhabits the mineral matrix within rocks. In specific arctic alpine environments, surfaces colonized by these lichens weather at rates estimated to be 25-50 times faster than those caused by other natural processes.[58] The weathering impact of Lecidea auriculata on the Little Ice Age moraines of the glacier Storbreen in Jotunheimen, central southern Norway, has been documented. Its degradative activity is limited, however, by its ecological range, predominantly to areas with minimal snow cover.[59] Species of Lecidea have also been observed degrading a variety of substances including granite,[60] magaliesberg quartzite,[61] serpentinized ultramafic rocks,[62] and volcanic andesite.[63] Research on Lecidea tesselata, found on desert rocks in western North America, identified key biomolecules aiding survival and chemical biodeterioration using Raman spectroscopy. It accumulates calcium oxalate monohydrate, the UV protectant scytonemin, and haematite to withstand high UV radiation levels.[64] In addition to natural materials, Lecidea species affect man-made objects. Sekishu roof tiles are a traditional Japanese housing component that are covered with an opaque reddish brown glaze consisting of an alkali feldspar-type X-ray amorphous glass, a surface that is unlikely to be affected by normal chemical weathering. The tiles tend to get colonised by Lecidea, which, after about 7–10 years, results in the appearance of corrosion pits up to 50 µm deep.[65][66] Although research often focuses on Lecidea within the family Lecideaceae, similar weathering effects have been documented in the genus Porpidia.[67][68]
Conservation
Two Lecideaceae species have been assessed for the global IUCN Red List: Lecidea mayeri (data deficient, 2023),[69] and Immersaria fuliginosa (vulnerable, 2020).[70] Lecidea mayeri is classified as data deficient due to the lack of information on its population, habitat, ecology, and potential threats. It is known only from the municipality of Angelópolis in the Antioquia Department in Colombia. More is known about Immersaria fuliginosa, found in two location on the Falkland Islands. It faces several threats that could rapidly lead to its decline and potential extinction, primarily due to its very limited distribution across just two locations with a total area of occupancy of 8 km2 (3.1 sq mi). The main threats include trampling by livestock, fires (both natural and anthropogenic), and the adverse effects of climatic changes, such as decreased summer rainfall and increased sunlight, which could negatively impact its survival. Conservation efforts are needed, including land protection and local education, to mitigate these threats and safeguard the species.[70]
References
- ^ a b c d e f g h i j Jaklitsch, Walter; Baral, Hans-Otto; Lücking, Robert; Lumbsch, H. Thorsten (2016). Frey, Wolfgang (ed.). Syllabus of Plant Families: Adolf Engler's Syllabus der Pflanzenfamilien. Vol. 1/2 (13 ed.). Berlin Stuttgart: Gebr. Borntraeger Verlagsbuchhandlung, Borntraeger Science Publishers. pp. 129–130. ISBN 978-3-443-01089-8. OCLC 429208213.
- ^ Linnaeus, Carl (1753). Species plantarum (in Latin). Vol. 2. Stockholm: Impensis Laurentii Salvii. p. 1140.
- ^ a b Acharius, E. (1803). Methodus qua Omnes Detectos Lichenes Secundum Organa Carpomorpha ad Genera, Species et Varietates Redigere atque Observationibus Illustrare Tentavit Erik Acharius (in Latin). Stockholm: impensis F.D.D. Ulrich, typis C.F. Marquard. p. 32.
- ^ Jørgensen, Per M. (1994). "Linnaean lichen names and their typification". Botanical Journal of the Linnean Society. 115 (4): 261–405. doi:10.1111/j.1095-8339.1994.tb01784.x.
- ^ Chevallier, François-Fulgis (1826). Flore Générale des Environs de Paris (in French). Vol. 1. Paris: imprimerie de Decourchant rue d'Erfurth nº. 1. p. 549.
- ^ a b Hafellner, J. (1984). "Studien in Richtung einer natürlichen Gliederung der Sammelfamilien Lecanoracae und Lecideaceae" [Studies towards a natural classification of the collective families Lecanoraceae and Lecideaceae]. Beihefte zur Nova Hedwigia (in German). 79: 241–371.
- ^ Buschbom, Jutta; Mueller, Gregory (2004). "Resolving evolutionary relationships in the lichen-forming genus Porpidia and related allies (Porpidiaceae, Ascomycota)". Molecular Phylogenetics and Evolution. 32 (1): 66–82. doi:10.1016/j.ympev.2003.11.012. PMID 15186798.
- ^ a b Miadlikowska, J.; Kauff, F.; Hofstetter, V.; Fraker, E.; Grube, M.; Hafellner, J.; Reeb, V.; Hodkinson, B.P.; Kukwa, M.; Lucking, R.; Hestmark, G.; Otalora, M.G.; Rauhut, A.; Budel, B.; Scheidegger, C.; Timdal, E.; Stenroos, S.; Brodo, I.; Perlmutter, G.B.; Ertz, D.; Diederich, P.; Lendemer, J.C.; May, P.; Schoch, C. L.; Arnold, A.E.; Gueidan, C.; Tripp, E.; Yahr, R.; Robertson, C.; Lutzoni, F. (2006). "New insights into classification and evolution of the Lecanoromycetes (Pezizomycotina, Ascomycota) from phylogenetic analyses of three ribosomal RNA- and two protein-coding genes". Mycologia. 98 (6): 1088–1103. doi:10.3852/mycologia.98.6.1088. PMID 17486983.
- ^ Peršoh, Derek; Beck, Andreas; Rambold, Gerhard (2004). "The distribution of ascus types and photobiontal selection in Lecanoromycetes (Ascomycota) against the background of a revised SSU nrDNA phylogeny". Mycological Progress. 3 (2): 103–121. Bibcode:2004MycPr...3..103P. doi:10.1007/s11557-006-0081-0.
- ^ a b c d Schmull, Michaela; Miadlikowska, Jolanta; Pelzer, Monika; Stocker-Wörgötter, Elfie; Hofstetter, Valerie; Fraker, Emily; Hodkinson, Brendan P.; Reeb, Valerie; Kukwa, Martin; Lumbsch, H. Thorsten; Kauff, Frank; Lutzoni, François (2011). "Phylogenetic affiliations of members of the heterogeneous lichen-forming fungi of the genus Lecidea sensu Zahlbruckner (Lecanoromycetes, Ascomycota)". Mycologia. 103 (5): 983–1003. doi:10.3852/10-234. PMID 21642348.
- ^ Poelt, Josef (1973). "Systematic evaluation of morphological characters". In Ahmadjian, Vernon; Hale, Mason E. (eds.). The Lichens. New York: Academic Press. pp. 91–115. ISBN 978-0-12-044950-7.
- ^ a b Hertel, H. (1983). "Über einige aus Lecidea und Melanolecia (Ascomycetes lichenisati) auszuschliessende Arten" [About some species to be excluded from Lecidea and Melanolecia (Ascomycetes lichenisati)]. Mitteilungen aus der Botanischen Staatssammlung München. 19: 441–447.
- ^ a b c d e Hertel, H. (1984). Über saxicole, lecideoide Flechten der Subantarktis [On saxicolous, lecideoid lichens of the Subantarctic]. Beihefte zur Nova Hedwigia (in German). Vol. 79. J. Cramer. pp. 399–499. ISBN 978-3-7682-5479-3.
- ^ Rambold, G. (1985). "Lecidea sect. Armeniacae: lecideoide Arten der Flechtengattungen Lecanora und Tephromela (Lecanorales)" [Lecidea section Armeniacae: lecideoid species of the lichen genera Lecanora and Tephromela (Lecanorales)]. Botanische Jahrbücher für Systematik, Pflanzengeschichte und Pflanzengeographie (in German). 107: 469–501.
- ^ Timdal, E. (1987). "Problems of generic delimitation among squamiform members of the Lecideaceae". In Peveling, Elisabeth (ed.). Progress and Problems in Lichenology in the Eighties: proceedings of an international symposium held at the University of Münster, 16.-21.3. 1986. Bibliotheca Lichenologica. Vol. 25. Lubrecht & Cramer. pp. 243–247. ISBN 978-3-443-58004-9.
- ^ a b c Kirk, Paul M.; Cannon, Paul F.; Minter, David W.; Stalpers, Joost A., eds. (2008). Dictionary of the Fungi (10th ed.). Wallingford, UK: CAB Europe. p. 366. ISBN 978-0-85199-826-8.
- ^ Vainio, Edvard August (1934). "Lichenographia Fennica IV. Lecideales 2" (PDF). Acta Societatis Pro Fauna et Flora Fennica (in Latin). 57 (2): 8.
- ^ Kraichak, Ekaphan; Huang, Jen-Pan; Nelsen, Matthew; Leavitt, Steven D.; Lumbsch, H. Thorsten (2018). "A revised classification of orders and families in the two major subclasses of Lecanoromycetes (Ascomycota) based on a temporal approach". Botanical Journal of the Linnean Society. 188 (3): 233–249. doi:10.1093/botlinnean/boy060.
- ^ Hawksworth, David L. (1974). Mycologist's Handbook. Kew: Commonwealth Mycological Institute. p. 39. ISBN 978-0-85198-300-4.
- ^ Ulloa, Miguel; Aguirre-Acosta, Elvira (2020). Illustrated Generic Names of Fungi. St. Paul, Minnesota: APS press. p. 210. ISBN 978-0-89054-618-5.
- ^ a b c Cannon, Paul F.; Kirk, Paul M. (2007). Fungal Families of the World. Wallingford: CAB International. p. 184. ISBN 978-0-85199-827-5. OCLC 60741230.
- ^ a b c Xie, Cong-Miao; Wang, Li-Song; Zhao, Zun-Tian; Zhang, Yan-Yun; Wang, Xin-Yu; Zhang, Lu-Lu (2022). "Revision of Immersaria and a new lecanorine genus in Lecideaceae (lichenised Ascomycota, Lecanoromycetes)". MycoKeys. 87: 99–132. doi:10.3897/mycokeys.87.72614. PMC 8863769. PMID 35210924.
- ^ a b c McCune, Bruce; Curtis, Marc J.; Di Meglio, Joseph (2017). "New taxa and a case of ephemeral spore production in Lecideaceae from western North America". The Bryologist. 120 (2): 115–124. doi:10.1639/0007-2745-120.2.115.
- ^ a b Jahamate, Aerguli; Abbas, Abudulla (2018). "The research progress of the genus Lecidea and identification of some Lecidea, Lecidella and Porpidia species in many areas". Botanical Research (in Chinese). 7 (2): 93–100.
- ^ Gallun, Margalith; Ben-Shaul, Y.; Paran, Navah (1971). "The fungus-alga association in the Lecideaceae: an ultrastructural study". New Phytologist. 70 (3): 483–485. doi:10.1111/j.1469-8137.1971.tb02549.x.
- ^ Beck, A.; Friedl, T.; Rambold, G. (1998). "Selectivity of photobiont choice in a defined lichen community: inferences from cultural and molecular studies". New Phytologist. 139 (4): 709–720. doi:10.1046/j.1469-8137.1998.00231.x.
- ^ Hauck, Markus; Huneck, Siegfried; Elix, John A.; Paul, Paul (2007). "Does secondary chemistry enable lichens to grow on iron-rich substrates?". Flora. 202: 471–478. doi:10.1016/j.flora.2006.08.007.
- ^ Frank‐Kamenetskaya1, Olga V.; Zelenskaya, Marina S.; Izatulina1, Alina R.; Vereshchagin, Oleg S.; Vlasov, Dmitry Yu.; Himelbrant, Dmitry E.; Pankin, Dmitrii V. (2021). "Copper oxalate formation by lichens and fungi". Scientific Reports. 11: e24329. doi:10.1038/s41598-021-03600-5.
{{cite journal}}
: CS1 maint: numeric names: authors list (link) - ^ Kirk, Paul M.; Cannon, Paul F.; David, J.C.; Stalpers, Joost A. (2001). "Teloschistaceae". Ainsworth & Bisby's Dictionary of the Fungi (9th ed.). Oxon, UK: CABI Bioscience. p. 274. ISBN 978-0-85199-377-5.
- ^ a b c d e Wijayawardene, N.N.; Hyde, K.D.; Dai, D.Q.; Sánchez-García, M.; Goto, B.T.; Saxena, R.K.; et al. (2022). "Outline of Fungi and fungus-like taxa – 2021". Mycosphere. 13 (1): 53–453. doi:10.5943/mycosphere/13/1/2. hdl:10481/76378.
- ^ "Lecideaceae". Catalogue of Life. Species 2000: Leiden, the Netherlands. Retrieved 11 February 2024.
- ^ Norman, J.M. (1852). "Conatus praemissus redactionis novae generum nonnullorum Lichenum in organis fructificationes vel sporis fundatae" [The effort put forward for the new edition of some genera of lichens based on fruiting bodies or spores]. Nytt Magazin for Naturvidenskapene (in Latin). 7: 213–252 [230].
- ^ a b Kalb, K. 1984. Lichenes Neotropici. 8: 301–350.
- ^ Clauzade, G.; Roux, C. (1984). "Les genres Aspicilia Massal. et Bellemerea Hafellner & Roux" [The genera Aspicilia Massal. and Bellemerea Hafellner & Roux] (PDF). Bulletin de la Société Botanique du Centre-Ouest (in Esperanto). 15: 127–141.
- ^ Fryday, Alan M.; Printzen, Christian; Ekman, Stefan (2014). "Bryobilimbia, a new generic name for Lecidea hypnorum and closely related species". The Lichenologist. 46 (1): 25–37. doi:10.1017/s0024282913000625.
- ^ Brusse, Franklin A. (1994). "A remarkable new lichen genus Catarrhospora (Ascomycotina, Porpidiaceae), from Cape Floral Kingdom, South Africa". Mycotaxon. 52 (2): 501–512.
- ^ Triebel, D.; Rambold, G. (1988). "Cecidonia und Phacopsis (Lecanorales): zwei lichenicole Pilzgattungen mit cecidogenen Arten" [Cecidonia and Phacopsis (Lecanorales): two lichenicolous fungal genera with gall-inducing species]. Nova Hedwigia (in German). 47 (3–4): 279–309.
- ^ Massalongo, A.B. (1860). "Esame comparativo di alcune genere di licheni" [Comparative examination of some lichen genera]. Atti dell'Istituto Veneto Scienze. 5: 247–276.
- ^ Vogel, S. (1955). "Niedere "Fensterpflanzen" in der südafrikanischen Wüste" [Lower 'window plants' in the South African desert]. Beiträge zur Biologie der Pflanzen (in German). 31: 104.
- ^ a b Rambold, G. (1989). "A Monograph of the Saxicolous Lecideoid Lichens of Australia (excl. Tasmania)". Bibliotheca Lichenologica. 34. Berlin/Stuttgart: J. Cramer: 239. ISBN 978-3-443-58013-1.
- ^ Malcolm, W.M.; Elix, J.A.; Owe-Larsson, B. (1995). "Labyrintha implexa (Porpidiaceae), a new genus and species from New Zealand". The Lichenologist. 27 (4): 241–248. doi:10.1006/lich.1995.0022.
- ^ Hertel, H. (1981). "Beiträge zur Kenntnis der Flechtenfamilie Lecideaceae VIII" [Contributions to the knowledge of the lichen family Lecideaceae VIII]. Herzogia (in German). 5 (3–4): 449–463. doi:10.1127/herzogia/5/1981/449.
- ^ Poelt, J.; Vězda, A. (1981). Bestimmungsschlüssel europäischer Flechten. Ergänzungsheft II [Identification key to European lichens. Supplement II]. Bibliotheca Lichenologica (in German). Vol. 16. Vaduz: J. Cramer. p. 364. ISBN 978-3-7682-1162-8.
- ^ Harris, Richard C.; Ladd, Douglas (2007). "New taxa of lichens and lichenicolous fungi from the Ozark Ecoregion" (PDF). Opuscula Philolichenum. 4: 57–68.
- ^ Körber, G.W. (1855). Systema lichenum Germaniae (in Latin). Breslau: Verlag von Trewendt & Granier. p. 221.
- ^ Timdal, E. (2010). "Porpidinia (Porpidiaceae), a new genus for Toninia tumidula". In Hafellner, Josef; Kärnefelt, Ingvar; Wirth, Volkmar (eds.). Diversity and Ecology of Lichens in Polar and Mountain Ecosystems. Bibliotheca Lichenologica. Vol. 104. J. Cramer. pp. 333–337. ISBN 978-3-443-58083-4.
- ^ Zahlbruckner, A. (1923). Catalogus Lichenum Universalis. Vol. 2. p. 686.
- ^ Timdal, E. (2007). "Romjularia". In Nash III, Thomas H.; Gries, Corinna; Bungartz, Frank (eds.). Lichen Flora of the Greater Sonoran Desert Region. Vol. 3. Tempe: Lichens Unlimited, Arizona State University. pp. 287–289.
- ^ Brusse, Franklin A. (1988). "Schizodiscus, a new porpidioid lichen genus from the Drakensberg". Bothalia. 18: 94–96. doi:10.4102/abc.v18i1.988.
- ^ Hertel, H. (1967). Revision einiger calciphiler Formenkreise der Flechtengattung Lecidea [Revision of some calciphilous species groups of the lichen genus Lecidea]. Beihefte zur Nova Hedwigia (in German). Vol. 24. J. Cramer. p. 124. ISBN 978-3-768-25424-3.
- ^ Hertel, Hannes. (1983). Lecideaceae exsiccatae, Fascicle V (München): no. 96.
- ^ a b Fryday, Alan M.; Hertel, Hannes (2014). "A contribution to the family Lecideaceae s. lat. (Lecanoromycetidae inc. sed. , lichenized Ascomycota) in the southern subpolar region; including eight new species and some revised generic circumscriptions". The Lichenologist. 46 (3): 389–412. doi:10.1017/S0024282913000704.
- ^ Ekman, Stefan (2001). "Molecular phylogeny of the Bacidiaceae (Lecanorales, lichenized Ascomycota)". Mycological Research. 105 (7): 783–797. doi:10.1017/S0953756201004269.
- ^ Awasthi, Dharani Dhar; Singh, Krishna Pal (1977). "Heppsora, a new lichen genus from India". The Bryologist. 80 (3): 536–538. doi:10.2307/3242031. JSTOR 3242031.
- ^ Bendiksby, Mika; Timdal, Einar (2013). "Molecular phylogenetics and taxonomy of Hypocenomyce sensu lato (Ascomycota: Lecanoromycetes): Extreme polyphyly and morphological/ecological convergence". Taxon. 62 (5): 940–956. doi:10.12705/625.18.
- ^ Coleine, Claudia; Stajich, Jason E.; Zucconi, Laura; Onofri, Silvano; Pombubpa, Nuttapon; Egidi, Eleonora; Franks, Ashley; Buzzini, Pietro; Selbmann, Laura (2018). "Antarctic cryptoendolithic fungal communities are highly adapted and dominated by Lecanoromycetes and Dothideomycetes". Frontiers in Microbiology. 9: 1–14. doi:10.3389/fmicb.2018.01392. PMC 6033990. PMID 30008702.
- ^ Diederich, Paul; Lawrey, James D.; Ertz, Damien (2018). "The 2018 classification and checklist of lichenicolous fungi, with 2000 non-lichenized, obligately lichenicolous taxa". The Bryologist. 121 (3): 373–374. doi:10.1639/0007-2745-121.3.340.
- ^ McCarroll, Danny; Viles, Heather (1995). "Rock-weathering by the lichen Lecidea auriculata in an arctic alpine environment". Earth Surface Processes and Landforms. 20 (3): 199–206. doi:10.1002/esp.3290200302.
- ^ Matthews, John A.; Owen, Geraint (2008). "Endolithic lichens, rapid biological weathering and Schmidt Hammer r-values on recently exposed rock surfaces: Storbreen glacier foreland, Jotunheimen, Norway". Geografiska Annaler. 90 (4): 287–297. doi:10.1111/j.1468-0459.2008.00346.x. JSTOR 40204904.
- ^ De los Ríos, A.; Sancho, L.G.; Grube, M.; Wierzchos, J.; Ascaso, C. (2005). "Endolithic growth of two Lecidea lichens in granite from continental Antarctica detected by molecular and microscopy techniques". New Phytologist. 165: 181–190. doi:10.1111/j.1469-8137.2004.01199.x.
- ^ Cooks, J.; Otto, E. (1990). "The weathering effects of the lichen Lecidea aff. sarcogynoides (Koerb.) on magaliesberg quartzite". Earth Surface Processes and Landforms. 15 (6): 491–500. doi:10.1002/esp.3290150602.
- ^ Favero-Longo, Sergio E.; Castelli, Daniele; Salvadori, Ornella; Belluso, Elena; Piervittori, Rosanna (2005). "Pedogenetic action of the lichens Lecidea atrobrunnea, Rhizocarpon geographicum gr. and Sporastatia testudinea on serpentinized ultramafic rocks in an alpine environment". International Biodeterioration & Biodegradation. 56 (1): 17–27. doi:10.1016/j.ibiod.2004.11.006. ISBN 978-90-481-6724-1.
- ^ Acaso, C.; Sancho, L.G.; Rodriguez-Pascual, C. (1990). "The weathering action of saxicolous lichens in martime Antarctica" (PDF). Polar Biology. 11: 33–39.
- ^ Edwards, HowellG.M.; Jorge Villar, Susana E.; Seaward, Mark R.D.; St. Clair, Larry L. (2004). "Raman spectroscopy of rock biodeterioration by the lichen Lecidea tessellata flörke in a desert environment, Utah, USA". In St.Clair, L.L.; Seaward, M.R.D. (eds.). Biodeterioration of Stone Surfaces. Dordrecht: Springer. doi:10.1007/978-1-4020-2845-8_13.
- ^ Watanabe, Katsuaki; Kitagawa, Ryuji (2006). "Dissolution process of sekishu roof liles affected by crustose lichen Lecidea sp. grown on their surfaces". Clay Science. 12 (S2): 240–244.
- ^ Watanabe, K.; Ohfuji, H.; Ando, J.; Kitagawa, R. (2006). "Elemental behaviour during the process of corrosion of sekishu glazed roof-tiles affected by Lecidea s.lat. sp. (crustose lichen)". Clay Minerals. 41 (4): 819–826. doi:10.1180/0009855064140221.
- ^ Watanabe, Katsuaki; Kitagawa, Ryuji (2004). "Alteration mechanism of biotite in granitic rock caused by crustose lichen Porpidia". Clay Science. 12 (4): 249–257. doi:10.11362/jcssjclayscience1960.12.249.
- ^ Prieto, B.; Edwards, H.G.M.; Seaward, M.R.D. "A Fourier transform-Raman spectroscopic study of lichen strategies on granite monuments". Geomicrobiology Journal. 17 (1): 55–60. doi:10.1080/014904500270495.
- ^ Moncada, B.; Simijaca, D.; Soto-Medina, E.; Coco, L.F.; Jaramillo, M. (2020). "Lecidea mayeri". IUCN Red List of Threatened Species. 2020. Retrieved 11 February 2024.
- ^ a b Fryday, A. (2020). "Immersaria fuliginosa". IUCN Red List of Threatened Species. 2020. Retrieved 11 February 2024.