The diversity of microfungi in peatlands originated from the White Sea

Literature Cited

• AndersenRGrassetLThormannMNRochefortLFrancezA-J. 2010. Changes in microbial community structure and function following Sphagnum peatland restoration. Soil Biol Biochem 42:291–301, doi:10.1016/j.soilbio.2009.11.006
   Web of Science ®Google Scholar
• BissetJ. 1982. Notes on Tolypocladium and related genera. Can J Bot 61:1311–1329, doi:10.1139/b83-139
   Google Scholar
• BubnovaEN. 2005. Izmenenia komplexov pochvoobitaushih gribov pri perehode ot zonalnih pochv k morskim ekotopam (na primere poberezhia Kandalakshskogo zaliva Belogo moray) [doctoral dissertation]. Moscow State University. 141 p. [ In Russian]
   Google Scholar
• CzeczugaB. 1993. Studies of aquatic fungi XXVIII. The presence of predatory fungi in the waters of northeastern Poland. Acta Mycol 28:211–217.
   Google Scholar
• FilippovaNVThormannMN. 2014. Lager fungi of ombrotrophic bogs in west Siberia. Mires Peat 14:1–22.
   Google Scholar
• GilbertDMitchellEAD. 2006. Microbial diversity in Sphagnum peatlands. In: MartiniIPMartinez CortizasAChesworthW, eds. Peatlands: evolution and records of environmental and climate changes. Developments in earth surface processes. Elsevier Science.
   Google Scholar
• GolovchenkoAVSemenovaTAPolyakovaAVInishevaLI. 2002. The structure of the micromycete complexes of oligotrophic peat deposits in the southern taiga subzone of west Siberia. Microbiology 71:575–581, doi:10.1023/A:1020514904709
   Google Scholar
• Grum-GrzhimayloOABilanenkoEN. 2009. Microfungal communities of bogs of the northwest and central Russia: extreme inhabitations. Asian Mycological Congress 2009 and 11th International Marine and Freshwater Mycology Symposium. Taichung, Taiwan, 15–19 Nov 2009. Taichung, Taiwan. p 146–147.
   Google Scholar
• HodgeKTKrasnoffSBHumberRA. 1996. Tolypocladium inflatum is the anamorph of Cordyceps subsessilis. Mycologia 88:715–719.
   Web of Science ®Google Scholar
• JonesEBGSakayarojJSuetrongSSomrithipolSPangKL. 2009. Classification of marine Ascomycota, anamorphic taxa and Basidiomycota. Fungal Divers. 187 p.
   Google Scholar
• KachalkinAVChernovIYuSemyonovaTAGolovchenkoAV. 2005. Characteristic of the taxonomy structure hyphomycetes and yeast communities in peat soils of different genesis. Mat. IV nauch. konf. Bolota i Biosphera. Tomsk, Russian. p 208–216.[ In Russian]
   Google Scholar
• KarakousisATanLEllisDAlexiouHWormaldPJ. 2006. An assessment of the efficiency of fungal DNA extraction methods for maximizing the detection of medically important fungi using PCR. J Microbiol Methods 65:38–48, doi:10.1016/j.mimet.2005.06.008
   PubMed Web of Science ®Google Scholar
• KeränenSKalpioS. Aapa mires. The world of plants. http://julkaisut.metsa.fi/julkaisut/pdf/luo/aapa_mires_plants.pdf
   Google Scholar
• KochkinaGAIvanushkinaNEAkimovVNGilichinskiiDAOzerskayaSM. 2007. Halo- and psychrotolerant Geomyces fungi from arctic cryopegs and marine deposits. Microbiology 76:31–38, doi:10.1134/S0026261707010055
   Web of Science ®Google Scholar
• LaitinenJRehellSHuttunenA. 2005. Vegetation-related hydrotopographic and hydrologic classification for aapa mires (Hirvisio, Finland). Ann Bot Fennici 42:107–121.
   Web of Science ®Google Scholar
• LaitinenJRehellSHuttunenATahvanainenTHeikkilaRLindholmT. 2007. Mire systems in Finland—special view to aapa mires and their water-flow pattern. Suoseura Fin Peatland Soc Suo 58:1–26.
   Google Scholar
• LamTNCGoettelMSSoaresGGJr 1988. Host records for the entomopathogenic hyphomycete Tolypocladium cylindrosporum. Florida Entomol 71:86–89, doi:10.2307/3494898
   Web of Science ®Google Scholar
• LimpensJGranathGGunnarssonUAertsRBayleySBragazzaLBubierJButtlerABergLJLFrancezA-JGerdolRGrosvernierPHeijmansMMPDHoosbeekMRHotesSIlometsMLeithIMitchellEADMooreTNilssonMBNordbakkenJ-FRochefortLRydinHSheppardLJThormannMWiedermannMMWilliamsBLXuB. 2011. Climatic modifiers of the response to nitrogen deposition in peat-forming Sphagnum mosses: a meta analysis. New Phytol 191:496–507, doi:10.1111/j.1469-8137.2011.03680.x
   Google Scholar
• McIlvaineTC. 1921. A buffer solution for colorimetric comparison. J Biol Chem 49:183–186.
   Google Scholar
• NilssonMRülckerC. 1992. Seasonal variation of active fungal mycelium in an oligotrophic Sphagnum mire, northern Sweden. Soil Biol Biochem 24:795–804, doi:10.1016/0038-0717(92)90255-V
   Google Scholar
• OluninaES. 2008. Bolota poluostrova Kindo I ostrova Velikiy (Kandalakshskiy zaliv Belogo moray): frola, sovremennaya rastitelnost, stroenie torfyanoy zalezhi I istoria formirovaniya. Mat. XI nauch. konf., posvyashennoy 70-letiu Belomorskoy biologicheskoy stancii imeni N.A. Pertsova. Moscow: Grif i K. p 207–212. [ In Russian]
   Google Scholar
• PankratovTABelovaSEDedyshSN. 2005. Evaluation of the phylogenetic diversity of prokaryotic microorganisms in Sphagnum peat bogs by means of fluorescence in situ hybridization (FISH). Microbiology 74:722–728, doi:10.1016/0038-0717(92)90255-V
   Web of Science ®Google Scholar
• PantiulinANKrasnonvaED. 2011. Otdelyaushiesya vodoemi Belogo moray: noviy objekt dlya mezhdisciplinarnih issledovaniy. Mat. XIX Mezhdunarodnoy nauch. konf. (shkoli) po morskoy geologii Geologia morey I okeanov. Moscow. p 241–245. [ In Russian]
   Google Scholar
• PivkinMV. 2010. Vtorichnie morskie gribi Yaponskogo I Okhotskogo morey [doctoral dissertation]. Moscow State University. 407 p. [ In Russian]
   Google Scholar
• RiceAVTsunedaACurrahRS. 2006. In vitro decomposition of Sphagnum by some microfungi resembles white rot of wood. FEMS Microbiol Ecol 56:372–382, doi:10.1111/j.1574-6941.2006.00071.x
   PubMed Web of Science ®Google Scholar
• RomanenkoFA. 2012. Poslelednikovoe podnyatiye Karelskogo berega Belogo moray po dannim radiouglerodnogo i diatomovogo analisa ozerno-bolotnih otlozheniy poluostrova Kindo. Russia: Dokladi Academii Nauk. 442:544–548. [ In Russian]
   Google Scholar
• SchulzeEDProkuschkinAArnethAKnorreNVaganovEA. 2002. Net ecosystem productivity and peat accumulation in a Siberian Aapa mire. Tellus A 54:531–536.
   Google Scholar
• ShaporenkoSIKorenevaGAPantyulinANPertsovaNM. 2005. Characteristics of the ecosystems of water bodies separating from Kandalaksha Bay of the White Sea. Water Resources 32:469–483, doi:10.1007/s11268-005-0060-x
   Google Scholar
• ShilovaOS. 2011. Golotsenovie diatomei bolot Karelskogo poluostrova i Severo-Vostochnoy Karelii. Moscow: MAKS Press. 177 p. [ In Russian]
   Google Scholar
• ThormannMN. 2006a. Diversity and function of fungi in peatlands: a carbon cycling perspective. Can J Soil Sci 86:281–293, doi:10.4141/S05-082
   Web of Science ®Google Scholar
• ThormannMN. 2006b. The role of fungi in boreal peatlands. Ecol Stud 188:101–123.
   Google Scholar
• ThormannMNBayleySECurrahRS. 2001a. The microbial wildcard in peatland carbon storage: implications for global warming. Inf Rep NOR-X 383:25–28.
   Google Scholar
• ThormannMNCurrahRSBayleySE. 1999. The mycorrhizal status of the dominant vegetation along a peatland gradient in southern boreal Alberta, Canada. Wetlands 19:438–450, doi:10.1007/978-3-540-31913-9_6
   Web of Science ®Google Scholar
• ThormannMNCurrahRSBayleySE. 2001b. Microfungi isolated from Sphagnum fuscum from a southern boreal bog in Alberta, Canada. Bryologist 104:548–559, doi:10.1639/0007-2745(2001)104[0548:MIFSFF]2.0.CO;2
   Web of Science ®Google Scholar
• ThormannMNCurrahRSBayleySE. 2002. The relative ability of fungi from Sphagnum fuscum to decompose selected carbon substrates. Can J Microbiol 48:204–211, doi:10.1139/w02-010
   PubMed Web of Science ®Google Scholar
• ThormannMNCurrahRSBayleySE. 2003. Succession of microfungal assemblages in decomposing peatland plants. Plant Soil 250:323–333, doi:10.1023/A:1022845604385
   Web of Science ®Google Scholar
• ThormannMNRiceAV. 2007. Fungi from peatlands. Fungal Divers 24:241–299.
   Web of Science ®Google Scholar
• ThormannMNRiceAVBeilmanDW. 2007. Yeasts in peatlands: a review of richness and roles in peat decomposition. Wetlands 27:761–773, doi:10.1672/0277-5212(2007)27[761:YIPARO]2.0.CO;2
   Web of Science ®Google Scholar
• TsunedaAThormannMNCurrahRS. 2001. Modes of cell-wall degradation of Sphagnum fuscum by Acremonium cf. curvulum and Oidiodendron maius. Can J Bot 79:93–100.
   Google Scholar
• UndientEMüllerK. 1985. Colonization of Sphagnum cells by Lyophillum palustre. Can J Bot 63:757–761.
   Google Scholar
• VilgalysRGonzalezD. 1990. Organization of ribosomal DNA in the basidiomycete Thanatephorus praticola. Curr Genet 18:277–280, doi:10.1007/BF00318394
   Web of Science ®Google Scholar
• WangZBinderMSchochCLJohnstonPRSpataforaJWHibbettDS. 2006. Evolution of helotialen fungi (Leotiomycetes, Pezizomycotina): a nuclear rDNA phylogeny. Mol Phylogenet Evol 41:295–312, doi:10.1016/j.ympev.2006.05.031
   PubMed Web of Science ®Google Scholar
• WhiteTJBrunsTLeeSTaylorJW. 1990. Amplification and direct sequencing of fungal ribosomal RNA genes for phylogenetics. In: InnisMAGelfandDHSninskyJJWhiteTJ, eds. PCR protocols: a guide to methods and applications. New York: Academic Press. p 315–322.
   Google Scholar
• YurkovskayaTK. 2004. Raised bogs on the north east of Europe. Annali di Botanika nuova serie IV:19–28.
   Google Scholar
• ZakJCWilligMR. 2004. Fungal biodiversity patterns. In: MuellerGMBillsGFFosterMS, eds. Biodiversity of fungi: inventory and monitoring methods. Burlington, Massachusetts: Elsevier Academic Press. p 59–75.
   Google Scholar