Ecological Study of Epiphytic Lichens on Pistachio (Pistacia atlantica) in Sub-Mediterranean Formations of the Utrish Reserve (North-Western Caucasus)

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The article presents the results of a study of epiphytic lichens growing on the Mediterranean-Western Asian species Atlantic pistachio (Pistacia atlantica) in the Utrish Nature Reserve, located in the Abrau Peninsula, Northwest Caucasus (Krasnodar Territory, Russia). Based on the material collected by the authors in 16 sites in 2014—2024, 184 epiphytic species from 102 genera were recorded, including 159 lichen species, 3 non-lichenized saprobic fungi, and 22 lichenicolous fungi. Predominating are the taxa with a crustose and squamose growth form or without a lichenized thallus (127 species), and the macrolichens with a foliose, fruticose or placoid growth form (57 species). A significant share of the species (40%) are rare and were found in 1-2 sites, whereas almost 10% of the widespread species were recorded in 15-16 sites. Fifty-two species are new to the lichen flora of the Utrish Reserve. Among them, 5 species (Bacidia iberica, Blastenia coralliza, Ochrolechia dalmatica, Pertusaria paramerae, Stigmidium hageniae) are new to Russia, 4 species (Catapyrenium psoromoides, Opegrapha lamyi, Phacothecium varium, Sphaerellothecium parietinarium) were found for the first time in the Caucasus, and 24 species and 6 genera (Dichoporis, Phacothecium, Piccolia, Reichlingia, Telogalla, Thelenella) are new to the Krasnodar Territory.

作者简介

I. Urbanavichene

Botanical Institute V. L. Komarov of the RAS

编辑信件的主要联系方式.
Email: urbanavichene@gmail.com
Prof. Popov Street, 2, St. Petersburg, 197376, Russia

G. Urbanavichus

Ural Federal University

Email: g.urban@mail.ru
Lenin Avenue, 51, Yekaterinburg, 620000, Russia

参考

  1. Adams D.B., Risser P.G. 1971. The effect of host specificity on the interspecific associations of bark lichens. – Bryologist. 74(4): 451–457. https://doi.org/10.2307/3241304
  2. Al-Saghir M.G., Porter D.M. 2012. Taxonomic Revision of the Genus Pistacia L. (Anacardiaceae). – Am. J. Plant Sci. 3: 12–32. https://doi.org/10.4236/ajps.2012.31002
  3. Androsova V.I., Tarasova V.N., Gorshkov V.V. 2018. Diversity of lichens and allied fungi on Norway spruce (Picea abies) in the middle boreal forests of Republic of Karelia (Russia). – Folia Cryptog. Eston. 55: 133–149. https://doi.org/10.12697/fce.2018.55.14
  4. Aragón G., Martínez I. 2003. Bacidia iberica, a new lichen from Spain, and its relationship to Bacidia rubella. – Bryologist 106(1): 143–146. https://doi.org/10.1639/0007-2745(2003)106[0143:BIANLF]2.0.CO;2
  5. Aragón G., Martínez I., de la Cruz M., Hurtado P. 2025. High Host Preferences in Epiphytic Lichens Across Diverse Phorophyte Species in the Mediterranean Region. – J. Fungi. 11(2): 104. https://doi.org/10.3390/jof11020104
  6. Arcadia L. 2024. The lichens and lichenicolous fungi of Greece. Online draft version 05 November 2024. https://www.lichensofgreece.com (дата обращения: 25.12.2024)
  7. Arup U., Åkelius E. 2009. A taxonomic revision of Caloplaca herbidella and C. furfuracea. – Lichenologist 41(5): 465–480. https://doi.org/10.1017/S0024282909008780
  8. Arup U., Ekman S., Lindblom L., Mattsson J.-E. 1993. High performance thin layer chromatography (HPTLC), an improved technique for screening lichen substances. – Lichenologist 25(1): 61–71. https://doi.org/10.1006/lich.1993.1018
  9. [Atlas…] Атлас “Государственный природный заповедник “Утриш”. Научные труды. Т. 2. 2013. Анапа. 88 с.
  10. Barkman J.J. 1958. Phytosociology and ecology of cryptoga- mic epiphytes. Van Gorcum, Assen. 628 p.
  11. Benítez A., Aragón G., González Y., Prieto M. 2018. Functional traits of epiphytic lichens in response to forest disturbance and as predictors of total richness and diversity. – Ecological Indicators. 86: 18–26. https://doi.org/10.1016/j.ecolind.2017.12.021
  12. Benítez Á., Aragón G., Prieto M. 2019. Lichen diversity on tree trunks in tropical dry forests is highly influenced by host tree traits. – Biodivers. Conserv. 28(11): 2909–2929. https://doi.org/10.1007/s10531-019-01805-9
  13. Brackel W., Döbbeler P. 2020. An addition to the knowledge of lichenicolous fungi of Greece with a key to the liche- nicolous fungi on Collema s. l. – Folia Cryptog. Eston. 57: 147–152. https://doi.org/10.12697/fce.2020.57.13
  14. [Byazrov] Бязров Л.Г. 2002. Лишайники в экологическом мониторинге. М. 336 с.
  15. Caruso A., Thor G. 2007. Importance of different tree fraction for epiphytic lichen diversity on Picea abies and Popu- lus tremula in mature managed boreonemoral Swedish forests. – Scand. J. For. Res. 22(3): 219–230. https://doi.org/10.1080/02827580701346031
  16. Christensen S.N. 2020. Lichens of Pinus sylvestris stands in Makedonia and Thraki, Northern Greece. – Herzogia. 33(1): 75–89. https://doi.org/10.13158/heia.33.1.2020.75
  17. Christensen S.N. 2022. Contribution to the knowledge of the lichenized mycota of the East Aegean island Kos, Dodekanisos island group, Greece. – Herzogia. 35(1): 41–60. https://doi.org/10.13158/heia.35.1.2022.41
  18. Conti M.E., Cecchetti G. 2001. Biological monitoring: lichens as bioindicators of air pollution assessment – a review. – Environ. Pollut. 114(3): 471–492. https://doi.org/10.1016/S0269-7491(00)00224-4
  19. Coppins B., Kondratyuk S.Ya., Khodosovtsev A.Ye., Wolseley P., Zelenko S.D. 2001. New for Crimea and Ukraine Species of the lichens. – Ukr. Botan. Journ. 58(6): 716–722.
  20. Darmostuk V. 2019. Current distribution of Phacothecium varium (Tul.) Trevis. in Ukraine. – In: Biology: from a mo- lecule up to the biosphere. Proceedings of the 14th International young scientists’ conference. Kharkiv. P. 191–192.
  21. Degtjarenko P., Matos P., Marmor L., Branquinho C., Randlane T. 2018. Functional traits of epiphytic lichens respond to alkaline dust pollution. – Fungal Ecol. 36: 81–88. https://doi.org/10.1016/j.funeco.2018.08.006
  22. Diederich P., Lawrey J.D., Ertz D. 2018. The 2018 classification and checklist of lichenicolous fungi, with 2000 non-lichenized, obligately lichenicolous taxa. – Bryologist 121(3): 340–425. https://doi.org/10.1639/0007-2745-121.3.340
  23. Ellis C.J. 2012. Lichen epiphyte diversity: A species, community and trait-based review. – Perspect. Plant Ecol. Evol. Syst. 14(2): 131–152. https://doi.org/10.1016/j.ppees.2011.10.001
  24. Ellis C.J., Coppins B.J. 2019. Five decades of decline for old-growth indicator lichens in Scotland. – Edinb. J. Bot. 76(3): 319–331. https://doi.org/10.1017/S0960428619000088
  25. Halıcı M.G., Kocakaya M., Sweeney K., Fankhauser J.D., Schmitt I. 2010. Pertusaria paramerae (Pertusariales, Ascomycota), a species with variable secondary chemistry, and a new lichen record for Turkey. – Nova Hedwig. 91(1-2): 223–230. https://doi.org/10.1127/0029-5035/2010/0091-0223
  26. Hauck M., Bruyn U.D., Leuschner C. 2013. Dramatic diversity losses in epiphytic lichens in temperate broad-leaved forests during the last 150 years. – Biol. Conserv. 157: 136–145. http://dx.doi.org/10.1016/j.biocon.2012.06.015
  27. Hofmeister J., Hošek J., Malíček J., Palice Z., Syrovátková L., Steinová J., Černajová I. 2016. Large beech (Fagus sylva- tica) trees as ‘lifeboats’ for lichen diversity in central Euro- pean forests. – Biodivers. Conserv. 25(6): 1073–1090. https://doi.org/10.1007/s10531-016-1106-x
  28. Holien H. 1997. The lichen flora on Picea abies in a subo- ceanic spruce forest area in Central Norway with emphasis on the relationship to site and stand parameters. – Nord. J. Bot. 17(1): 55–76. https://doi.org/10.1111/j.1756-1051.1997.tb00290.x
  29. Hurtado P., Aragón R.G., Martínez I., Mayrhofer H., Prie- to M. 2023. The epiphytic lichens on Fagus sylvatica in beech forests of Europe: Towards an open and dynamic checklist. – Mediterr. Bot. 44: e84299. https://doi.org/10.5209/mbot.84299
  30. [Ismailov] Исмаилов А.Б. 2023. Эпифитная лихенобиота бука (Fagus orientalis) Предгорного Дагестана. – Нов. сист. низш. раст. 57(2): L15–L27. https://doi.org/10.31111/nsnr/2023.57.2.L15
  31. James P.W., Hawksworth D.L., Rose F. 1977. Lichen communities in the British Isles: a preliminary conspectus. – In: Lichen Ecology. London. P. 295–413.
  32. [Khodosovtsev] Ходосовцев О.Є. 2003. Анотований список лишайників Карадазького природного заповідника. – Вісті Біосферного заповідника “Асканія-Нова”. 5: 31–43 (In Ukrain.).
  33. [Khodosovtsev, Redchenko] Ходосовцев О.Є., Редченко О.О. 2002. Анотований список лишайників заповідника “Мис Март’ян”. – Укр. ботан. журн. 59(1): 64–71 (In Ukrain.).
  34. Kondratyuk S.Ya., Andrianova T.V., Tychonenko Yu.Ya. 1999. Study of Mycobiota Diversity of Ukraine. Kiev. 112 p.
  35. [Krasnaya…] Красная книга Российской Федерации. Растения и грибы. 2024. М. 944 с.
  36. Kukwa M., Ossowska E.A. 2021. New localities of two rare Ochrolechia species: O. azorica and O. dalmatica. – Herzogia. 34(2): 382–386. https://doi.org/10.13158/heia.34.2.2021.382
  37. Kuusinen M. 1994. Epiphytic lichen flora and diversity on Populus tremula in old-growth and managed forests of southern and middle boreal Finland. – Ann. Bot. Fenn. 31(4): 245–260.
  38. Lavrinenko I.A., Lavrinenko O.V. 1999. Relict spruce forest “islands” in the Bolshezemelskaya tundra – control sites for long-term climatic monitoring. Chemosphere – Glo- bal Change Science. 1 (4): 389402. https://doi.org/10.1016/S1465-9972(99)00031-8
  39. [Lavrinenko, Lavrinenko] Лавриненко О.В., Лавриненко И.А. 2003. Островные ельники восточно-европейских тундр. – Бот. журн. 88(8): 59–77.
  40. Llop E., Gómez-Bolea A. 1999. Bacidia parathalassica (Bacidiaceae, Lecanorales), a new Mediterranean corticolous lichen. – Mycotaxon 72: 79–89.
  41. Llop E., Ekman S., Hladun N.L. 2007. Bacidia thyrrenica (Ramalinaceae, lichenized Ascomycota), a new species from the Mediterranean region, and a comparison of European members of the Bacidia rubella group. – Nova Hedwigia 85(3-4): 445–455. https://doi.org/10.1127/0029-5035/2007/0085-0445
  42. Malíček J., Palice Z., Acton A., Berger F., Bouda F., Sanderson N., Vondrák J. 2018. Uholka primeval forest in the Ukrainian Carpathians – a keynote area for diversity of forest lichens in Europe. – Herzogia. 31(1): 140–171. https://doi.org/10.13158/099.031.0110
  43. Marmor L., Tõrra T., Saag L., Leppik E., Randlane T. 2013. Lichens on Picea abies and Pinus sylvestris. – Lichenologist. 45(1): 51–63. http://doi.org/10.1017/S0024282912000564
  44. Mikhailova I.N. 2007. Populations of epiphytic lichens under stress conditions: survival strategies. – Lichenologist. 39(1): 83–89. https://doi.org/10.1017/S0024282907006305
  45. Miller J.E.D., Villella J., Stone D., Hardman A. 2020. Using lichen communities as indicators of forest stand age and conservation value. – For. Ecol. Manage. 475: 118436. https://doi.org/10.1016/j.foreco.2020.118436
  46. Nimis P.L. 2024. ITALIC – The Information System on Italian Lichens. Version 8.0. University of Trieste, Dept. of Biology. https://italic.units.it/index.php (дата обращения: 01.12.2024)
  47. [Otte] Отте Ф. 2005. Заметки о лихенофлоре российского побережья Черного моря. – Нов. сист. низш. раст. 39: 248–253.
  48. Rosabal D., Burgaz A.R., Reyes O.J. 2013. Substrate preferences and phorophyte specificity of corticolous lichens on five tree species of the montane rainforest of Gran Piedra, Santiago de Cuba. – Bryologist. 116(2): 113–121. https://doi.org/10.1639/0007-2745-116.2.113
  49. Seregin A.P., Suslova E.G. 2007. Contribution to the vascular plant flora of the Utrish area, a relic sub-Mediterranean ecosystem of the Russian Black Sea Coast. – Willdenowia. 37(2): 451–463. https://doi.org/10.3372/wi.37.37207
  50. Stepanchikova I., Kukwa M., Kuznetsova E., Motiejūnaitė J., Himelbrant D. 2010. New records of lichens and allied fungi from the Leningrad Region, Russia. – Folia Cryptog. Eston. 47: 77–84.
  51. Svoboda D., Peksa O., Veselá J. 2011. Analysis of the species composition of epiphytic lichens in Central European oak forests. – Preslia. 83(1): 129–144.
  52. Tarasova V.N., Obabko R.P., Himelbrant D.E., Boychuk M.A., Stepanchikova I.S., Borovichev E.A. 2017. Diversity and distribution of epiphytic lichens and bryophytes on aspen (Populus tremula) in the middle boreal forests of Republic of Karelia (Russia). – Folia Cryptog. Eston. 54: 125–141. https://doi.org/10.12697/fce.2017.54.16
  53. [Urbanavichene] Урбанавичене И.Н. 2001. Экология эпифитных лишайников, произрастующих на Abies sibirica в Южном Прибайкалье. – Бот. журн. 86(9): 80–90.
  54. [Urbanavichene, Urbanavichus] Урбанавичене И.Н., Урбанавичюс Г.П. 2024. Дополнение к лихенофлоре России IV. Bactrospora patellarioides и заметки по российским видам рода Bactrospora (Arthoniales, Ascomycota). – Нов. сист. низш. раст. 58(2): L81–L89. https://doi.org/10.31111/nsnr/2024.58.2.L81
  55. [Urbanavichene, Urbanavichus] Урбанавичене И.Н., Урбанавичюс Г.П. 1999. Лишайники на Populus suaveolens (Salicaceae) в Южном Прибайкалье. – Бот. журн. 84(1): 30–44.
  56. [Urbanavichus, Urbanavichene] Урбанавичюс Г.П., Урбанавичене И.Н. 2015. Материалы к лихенофлоре заповедника “Утриш”. – Turczaninowia. 18(2): 86–95. https://doi.org/10.14258/turczaninowia.18.2.9
  57. Urbanavichus G., Urbanavichene I. 2017a. New and noteworthy records of lichen-forming and lichenicolous fungi from Abrau Peninsula (NW Caucasus, Russia). – Flora Mediterr. 27: 175–184. https://doi.org/10.7320/FlMedit27.175
  58. [Urbanavichus, Urbanavichene] Урбанавичюс Г.П., Урбанавичене И.Н. 2017b. Tylophoron hibernicum (Arthoniaceae, lichenized Ascomycota) – первое указание рода и вида для России. – Turczaninowia. 20(4): 82–86. https://doi.org/10.14258/turczaninowia.20.4.10
  59. [Urbanavichus, Urbanavichene] Урбанавичюс Г.П., Урбанавичене И.Н. 2019. Эпифитные лишайники и нелихенизированные грибы ели на крайнем северном пределе ее распространения (Мурманская область). – Бот. журн. 104(2): 191–205. https://doi.org/10.1134/S0006813619030098
  60. [Urbanavichus, Urbanavichene] Урбанавичюс Г.П., Урбанавичене И.Н. 2022. Ядро заповедника “Кологривский лес” (Россия) – горячая точка биоразнообразия лишайников южной тайги в Восточной Европе. – Nat. Conserv. Res. 7(3): 46–63. https://dx.doi.org/10.24189/ncr.2022.029
  61. [Urbanavichus, Urbanavichene] Урбанавичюс Г.П., Урбанавичене И.Н. 2024. Diromma dirinellum и Ocellomma picconianum (Roccellaceae, Ascomycota) в лихенофлоре России. – Turczaninowia. 27(2): 52–59. https://doi.org/10.14258/turczaninowia.27.2.7
  62. [Urbanavichus et al.] Урбанавичюс Г.П., Урбанавичене И.Н., Симакова У.В., Москаленко В.Н. 2022. Stauro- lemma omphalarioides (Pannariaceae, Ascomycota) – новый для лихенофлоры России вид и род с полуострова Абрау (Северо-Западный Кавказ). – Turczaninowia. 25(3): 115–120. https://doi.org/10.14258/turczaninowia.25.3.11
  63. Valadbigi T., Sipman H.J.M. 2010. New records of lichens and lichenicolous fungi from Iran and their biogeographical significance. – Mycotaxon 113: 191–194.
  64. Vondrák J., Malíček J., Palice Z., Bouda F., Berger F., Sanderson N., Acton A., Pouska V., Kish R. 2018. Exploiting hot-spots; effective determination of lichen diversity in a Carpathian virgin forest. – PLoS ONE 13(9): e0203540. https://doi.org/10.1371/journal.pone.0203540
  65. Vondrák J., Urbanavichus G., Palice Z., Malíček J., Urbana- vichene I., Kubásek J., Ellis C. 2019. The epiphytic lichen biota of Caucasian virgin forests: a comparator for Euro- pean conservation. – Biodivers. Conserv. 28(12): 3257–3276. https://doi.org/10.1007/s10531-019-01818-4
  66. Vondrák J., Frolov I., Košnar J., Arup U., Veselská T., Halıcı G., Malíček J., Søchting U. 2020. Substrate switches, phenotypic innovations and allopatric speciation formed taxonomic diversity within the lichen genus Blastenia. – J. Syst. Evol. 58(3): 295–330. https://doi.org/10.1111/jse.12503
  67. Westberg M., Moberg R., Myrdal M., Nordin A., Ekman S. 2021. Santesson’s Checklist of Fennoscandian Lichen-Forming and Lichenicolous Fungi. Uppsala. 933 p.
  68. Adams D.B., Risser P.G. 1971. The effect of host specificity on the interspecific associations of bark lichens. – Bryologist. 74(4): 451–457. https://doi.org/10.2307/3241304
  69. Al-Saghir M.G., Porter D.M. 2012. Taxonomic Revision of the Genus Pistacia L. (Anacardiaceae). – Am. J. Plant Sci. 3: 12–32. https://doi.org/10.4236/ajps.2012.31002
  70. Androsova V.I., Tarasova V.N., Gorshkov V.V. 2018. Diversity of lichens and allied fungi on Norway spruce (Picea abies) in the middle boreal forests of Republic of Karelia (Russia). – Folia Cryptog. Eston. 55: 133–149. https://doi.org/10.12697/fce.2018.55.14
  71. Aragón G., Martínez I. 2003. Bacidia iberica, a new lichen from Spain, and its relationship to Bacidia rubella. – Bryologist 106(1): 143–146. https://doi.org/10.1639/0007-2745(2003)106[0143:BIANLF]2.0.CO;2
  72. Aragón G., Martínez I., de la Cruz M., Hurtado P. 2025. High Host Preferences in Epiphytic Lichens Across Diverse Phorophyte Species in the Mediterranean Region. – J. Fungi. 11(2): 104. https://doi.org/10.3390/jof11020104
  73. Arcadia L. 2024. The lichens and lichenicolous fungi of Greece. Online draft version 05 November 2024. https://www.lichensofgreece.com (accessed 25 December 2024)
  74. Arup U., Åkelius E. 2009. A taxonomic revision of Caloplaca herbidella and C. furfuracea. – Lichenologist 41(5): 465–480. https://doi.org/10.1017/S0024282909008780
  75. Arup U., Ekman S., Lindblom L., Mattsson J.-E. 1993. High performance thin layer chromatography (HPTLC), an improved technique for screening lichen substances. – Lichenologist 25(1): 61–71. https://doi.org/10.1006/lich.1993.1018
  76. Atlas “Gosudarstvennyy prirodnyy zapovednik Utrish”. Nauchnye trudy. Tom 2 [Atlas “Utrish State Nature Reserve”. Scientific works. Vol. 2]. 2013. Anapa. 88 p. (In Russ.).
  77. Barkman J.J. 1958. Phytosociology and ecology of cryptogamic epiphytes. Van Gorcum, Assen. 628 p.
  78. Benítez A., Aragón G., González Y., Prieto M. 2018. Functional traits of epiphytic lichens in response to forest disturbance and as predictors of total richness and diversity. – Ecological Indicators. 86: 18–26. https://doi.org/10.1016/j.ecolind.2017.12.021
  79. Benítez Á., Aragón G., Prieto M. 2019. Lichen diversity on tree trunks in tropical dry forests is highly influenced by host tree traits. – Biodivers. Conserv. 28(11): 2909–2929. https://doi.org/10.1007/s10531-019-01805-9
  80. Brackel W., Döbbeler P. 2020. An addition to the knowledge of lichenicolous fungi of Greece with a key to the liche- nicolous fungi on Collema s. l. – Folia Cryptog. Eston. 57: 147–152. https://doi.org/10.12697/fce.2020.57.13
  81. Byazrov L.G. 2002. Lishayniki v ekologicheskom monitoringe [Lichens in ecological monitoring]. Moscow. 336 p. (In Russ.).
  82. Caruso A., Thor G. 2007. Importance of different tree fraction for epiphytic lichen diversity on Picea abies and Popu- lus tremula in mature managed boreonemoral Swedish fo- rests. – Scand. J. For. Res. 22(3): 219–230. https://doi.org/10.1080/02827580701346031
  83. Christensen S.N. 2020. Lichens of Pinus sylvestris stands in Makedonia and Thraki, Northern Greece. – Herzogia. 33(1): 75–89. https://doi.org/10.13158/heia.33.1.2020.75
  84. Christensen S.N. 2022. Contribution to the knowledge of the lichenized mycota of the East Aegean Island Kos, Dodekanisos island group, Greece. – Herzogia. 35(1): 41–60. https://doi.org/10.13158/heia.35.1.2022.41
  85. Conti M.E., Cecchetti G. 2001. Biological monitoring: lichens as bioindicators of air pollution assessment – a review. – Environ. Pollut. 114(3): 471–492. https://doi.org/10.1016/S0269-7491(00)00224-4
  86. Coppins B., Kondratyuk S.Ya., Khodosovtsev A.Ye., Wolseley P., Zelenko S.D. 2001. New for Crimea and Ukraine Species of the lichens. – Ukr. Botan. Journ. 58(6): 716–722.
  87. Darmostuk V. 2019. Current distribution of Phacothecium va- rium (Tul.) Trevis. in Ukraine. – In: Biology: from a molecule up to the biosphere. Proceedings of the 14th International young scientists’ conference. Kharkiv. P. 191–192.
  88. Degtjarenko P., Matos P., Marmor L., Branquinho C., Randlane T. 2018. Functional traits of epiphytic lichens respond to alkaline dust pollution. – Fungal Ecol. 36: 81–88. https://doi.org/10.1016/j.funeco.2018.08.006
  89. Diederich P., Lawrey J.D., Ertz D. 2018. The 2018 classification and checklist of lichenicolous fungi, with 2000 non-lichenized, obligately lichenicolous taxa. – Bryologist 121(3): 340–425. https://doi.org/10.1639/0007-2745-121.3.340
  90. Ellis C.J. 2012. Lichen epiphyte diversity: A species, community and trait-based review. – Perspect. Plant Ecol. Evol. Syst. 14(2): 131–152. https://doi.org/10.1016/j.ppees.2011.10.001
  91. Ellis C.J., Coppins B.J. 2019. Five decades of decline for old-growth indicator lichens in Scotland. – Edinb. J. Bot. 76(3): 319–331. https://doi.org/10.1017/S0960428619000088
  92. Halıcı M.G., Kocakaya M., Sweeney K., Fankhauser J.D., Schmitt I. 2010. Pertusaria paramerae (Pertusariales, Ascomycota), a species with variable secondary chemistry, and a new lichen record for Turkey. – Nova Hedwig. 91(1-2): 223–230. https://doi.org/10.1127/0029-5035/2010/0091-0223
  93. Hauck M., Bruyn U.D., Leuschner C. 2013. Dramatic diversity losses in epiphytic lichens in temperate broad-leaved forests during the last 150 years. – Biol. Conserv. 157: 136–145. http://dx.doi.org/10.1016/j.biocon.2012.06.015
  94. Hofmeister J., Hošek J., Malíček J., Palice Z., Syrovátková L., Steinová J., Černajová I. 2016. Large beech (Fagus sylvatica) trees as ‘lifeboats’ for lichen diversity in central Euro- pean forests. – Biodivers. Conserv. 25(6): 1073–1090. https://doi.org/10.1007/s10531-016-1106-x
  95. Holien H. 1997. The lichen flora on Picea abies in a suboceanic spruce forest area in Central Norway with emphasis on the relationship to site and stand parameters. – Nord. J. Bot. 17(1): 55–76. https://doi.org/10.1111/j.1756-1051.1997.tb00290.x
  96. Hurtado P., Aragón R.G., Martínez I., Mayrhofer H., Prieto M. 2023. The epiphytic lichens on Fagus sylvatica in beech forests of Europe: Towards an open and dynamic checklist. – Mediterr. Bot. 44: e84299. https://doi.org/10.5209/mbot.84299
  97. Ismailov A.B. 2023. Epiphytic lichens on Fagus orientalis in foothill Dagestan. – Novosti Sist. Nizsh. Rast. 57(2): L15–L27 (In Russ.). https://doi.org/10.31111/nsnr/2023.57.2.L15
  98. James P.W., Hawksworth D.L., Rose F. 1977. Lichen communities in the British Isles: a preliminary conspectus. – In: Lichen Ecology. London. P. 295–413.
  99. Khodosovtsev O.Ye. 2003. An annotated list of the lichen forming fungi of the Karadag natural reserve. – Visti Biosphernogo zapovednika “Askaniya-Nova”. 5: 31–43 (In Ukrain.).
  100. Khodosovtsev O.Ye., Redchenko O.O. 2002. An annota- ted list of the lichen forming fungi of the natural reserve “Mys Mart’yan”. – Ukr. Botan. Journ. 59(1): 64–71 (In Ukrain.).
  101. Kondratyuk S.Ya., Andrianova T.V., Tychonenko Yu.Ya. 1999. Study of Mycobiota Diversity of Ukraine. Kiev. 112 p.
  102. Krasnaya kniga Rossiyskoy Federatsii. Rasteniya i griby. 2024 [Red data book of the Russian Federation. Plants and fungi]. Moscow. 944 p. (In Russ.).
  103. Kukwa M., Ossowska E.A. 2021. New localities of two rare Ochrolechia species: O. azorica and O. dalmatica. – Herzogia. 34(2): 382–386. https://doi.org/10.13158/heia.34.2.2021.382
  104. Kuusinen M. 1994. Epiphytic lichen flora and diversity on Populus tremula in old-growth and managed forests of southern and middle boreal Finland. – Ann. Bot. Fenn. 31(4): 245–260.
  105. Lavrinenko I.A., Lavrinenko O.V. 1999. Relict spruce forest “islands” in the Bolshezemelskaya tundra – control sites for long-term climatic monitoring. Chemosphere – Glo- bal Change Science. 1(4): 389402. https://doi.org/10.1016/S1465-9972(99)00031-8
  106. [Lavrinenko, Lavrinenko] Lavrinenko O.V., Lavrinenko I.A. 2003. Spruce islands of the East European tundra – Bot. Zhurn. 88(8): 59–77 (In Russ.).
  107. Llop E., Gómez-Bolea A. 1999. Bacidia parathalassica (Bacidiaceae, Lecanorales), a new Mediterranean corticolous lichen. – Mycotaxon 72: 79–89.
  108. Llop E., Ekman S., Hladun N.L. 2007. Bacidia thyrrenica (Ramalinaceae, lichenized Ascomycota), a new species from the Mediterranean region, and a comparison of European members of the Bacidia rubella group. – Nova Hedwigia 85(3-4): 445–455. https://doi.org/10.1127/0029-5035/2007/0085-0445
  109. Malíček J., Palice Z., Acton A., Berger F., Bouda F., Sander- son N., Vondrák J. 2018. Uholka primeval forest in the Ukrainian Carpathians – a keynote area for diversity of fo- rest lichens in Europe. – Herzogia. 31(1): 140–171. https://doi.org/10.13158/099.031.0110
  110. Marmor L., Tõrra T., Saag L., Leppik E., Randlane T. 2013. Lichens on Picea abies and Pinus sylvestris. – Lichenologist. 45(1): 51–63. http://doi.org/10.1017/S0024282912000564
  111. Mikhailova I.N. 2007. Populations of epiphytic lichens under stress conditions: survival strategies. – Lichenologist. 39(1): 83–89. https://doi.org/10.1017/S0024282907006305
  112. Miller J.E.D., Villella J., Stone D., Hardman A. 2020. Using lichen communities as indicators of forest stand age and conservation value. – For. Ecol. Manage. 475: 118436. https://doi.org/10.1016/j.foreco.2020.118436
  113. Nimis P.L. 2024. ITALIC – The Information System on Ita- lian Lichens. Version 8.0. University of Trieste, Dept. of Biology. https://italic.units.it/index.php (accessed: 01 December 2024)
  114. Otte V. 2005. Notes on the lichen flora of the Black Sea coast of Russia. – Novosti Sist. Nizsh. Rast. 39: 248–253 (In Russ.).
  115. Rosabal D., Burgaz A.R., Reyes O.J. 2013. Substrate prefe- rences and phorophyte specificity of corticolous lichens on five tree species of the montane rainforest of Gran Piedra, Santiago de Cuba. – Bryologist. 116(2): 113–121. https://doi.org/10.1639/0007-2745-116.2.113
  116. Seregin A.P., Suslova E.G. 2007. Contribution to the vascular plant flora of the Utrish area, a relic sub-Mediterranean ecosystem of the Russian Black Sea Coast. – Willdenowia. 37(2): 451–463. https://doi.org/10.3372/wi.37.37207
  117. Stepanchikova I., Kukwa M., Kuznetsova E., Motiejūnaitė J., Himelbrant D. 2010. New records of lichens and allied fungi from the Leningrad Region, Russia. – Folia Cryptog. Eston. 47: 77–84.
  118. Svoboda D., Peksa O., Veselá J. 2011. Analysis of the species composition of epiphytic lichens in Central European oak forests. – Preslia. 83(1): 129–144.
  119. Tarasova V.N., Obabko R.P., Himelbrant D.E., Boychuk M.A., Stepanchikova I.S., Borovichev E.A. 2017. Diversity and distribution of epiphytic lichens and bryophytes on aspen (Populus tremula) in the middle boreal fo- rests of Republic of Karelia (Russia). – Folia Cryptog. Eston. 54: 125–141. https://doi.org/10.12697/fce.2017.54.16
  120. Urbanavichene I.N. 2001. Ecology of epiphytic lichens growing on Abies sibirica along the south of Baikal. – Bot. Zhurn. 86(9): 80–90 (In Russ.).
  121. Urbanavichene I.N., Urbanavichus G.P. 2024. Addition to the lichen flora of Russia. IV. Bactrospora patellarioides and notes on the Russian species of the genus Bactrospora (Arthoniales, Ascomycota). – Novosti Sist. Nizsh. Rast. 58(2): L81–L89 (In Russ.). https://doi.org/10.31111/nsnr/2024.58.2.L81
  122. Urbanavichene I.N., Urbanavichus G.P. 1999. Lichens on Populus suaveolens (Salicaceae) in southern Baikal region. – Bot. Zhurn. 84(1): 30–44 (In Russ.).
  123. Urbanavichus G.P., Urbanavichene I.N. 2015. A contribution to the lichen flora of Utrish Nature Reserve. – Turczaninowia. 18(2): 86–95 (In Russ.). https://doi.org/10.14258/turczaninowia.18.2.9
  124. Urbanavichus G., Urbanavichene I. 2017a. New and noteworthy records of lichen-forming and lichenicolous fungi from Abrau Peninsula (NW Caucasus, Russia). – Flora Mediterr. 27: 175–184. https://doi.org/10.7320/FlMedit27.175
  125. Urbanavichus G.P., Urbanavichene I.N. 2017b. Tylophoron hibernicum (Arthoniaceae, lichenized Ascomycota) – the first record of the genus and species for Russia. – Turczaninowia. 20(4): 82–86 (In Russ.). https://doi.org/10.14258/turczaninowia.20.4.10
  126. Urbanavichus G.P., Urbanavichene I.N. 2019. Epiphytic lichens and non-lichenized fungi of spruce in the northernmost distribution limit (Murmansk Region)]. – Bot. Zhurn. 104(2): 191–205 (In Russ.). https://doi.org/10.1134/S0006813619030098
  127. Urbanavichus G.P., Urbanavichene I.N. 2022. The core of the Kologriv Forest State Nature Reserve (Russia) is a hotspot of lichen biodiversity in the southern taiga of Eastern Europe. – Nat. Conserv. Res. 7(3): 46–63 (In Russ.). https://dx.doi.org/10.24189/ncr.2022.029
  128. Urbanavichus G.P., Urbanavichene I.N. 2024. Diromma dirinellum and Ocellomma picconianum (Roccellaceae, Ascomycota) in the lichen flora of Russia. – Turczaninowia. 27(2): 52–59 (In Russ.). https://doi.org/10.14258/turczaninowia.27.2.7
  129. Urbanavichus G.P., Urbanavichene I.N., Simakova U.V., Moskalenko V.N. 2022. Staurolemma omphalarioides (Pannariaceae, Ascomycota), a new species and genus for the lichen flora of Russia from Abrau Peninsula (North-Western Caucasus). – Turczaninowia. 25(3): 115–120 (In Russ.). https://doi.org/10.14258/turczaninowia.25.3.11
  130. Valadbigi T., Sipman H.J.M. 2010. New records of lichens and lichenicolous fungi from Iran and their biogeographical significance. – Mycotaxon. 113: 191–194.
  131. Vondrák J., Malíček J., Palice Z., Bouda F., Berger F., Sander- son N., Acton A., Pouska V., Kish R. 2018. Exploiting hot-spots; effective determination of lichen diversity in a Carpathian virgin forest. – PLoS ONE. 13(9): e0203540. https://doi.org/10.1371/journal.pone.0203540
  132. Vondrák J., Urbanavichus G., Palice Z., Malíček J., Urbana- vichene I., Kubásek J., Ellis C. 2019. The epiphytic lichen biota of Caucasian virgin forests: a comparator for Euro- pean conservation. – Biodivers. Conserv. 28(12): 3257–3276. https://doi.org/10.1007/s10531-019-01818-4
  133. Vondrák J., Frolov I., Košnar J., Arup U., Veselská T., Halıcı G., Malíček J., Søchting U. 2020. Substrate switches, phenotypic innovations and allopatric speciation formed taxonomic diversity within the lichen genus Blastenia. – J. Syst. Evol. 58(3): 295–330. https://doi.org/10.1111/jse.12503
  134. Westberg M., Moberg R., Myrdal M., Nordin A., Ekman S. 2021. Santesson’s Checklist of Fennoscandian Lichen-Forming and Lichenicolous Fungi. Uppsala. 933 p.

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