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Mycological Progress

, Volume 11, Issue 1, pp 131–147 | Cite as

Obba and Sebipora, new polypore genera related to Cinereomyces and Gelatoporia (Polyporales, Basidiomycota)

  • Otto Miettinen
  • Mario Rajchenberg
Original Article

Abstract

Cinereomyces clade is a newly proposed monophyletic group of polypores containing currently four genera and five species, including two promising biopulping fungi, Ceriporiopsis rivulosa and C. subvermispora. The Cinereomyces clade is well-delimited in nrDNA-based phylogenetic analysis, but its position in Polyporales remains unclear. Its closest relative may be found in the core polyporoid clade. Only a few morphological characters are common for all the species in the clade, e.g. CB– and CRB+ hyphae, white fruiting bodies, presence of oil, and middle-sized spores. Culturally, the species are unified by producing simple-septate generative hyhpae in the margin, which produce simple-clamped hyphae backwards. The genus Gelatoporia is the correct place for Ceriporiopsis subvermispora. Two new genera are described in the group: Obba to incorporate C. rivulosa and a new austral species, Obba valdiviana, known from southern Argentina and recorded here also from Tasmania, and Sebipora to accommodate a new species from tropical Asia, S. aquosa. ITS sequences imply that Eurasian Gelatoporia subvermispora may belong to a different species from the North American one. G. subvermispora is recorded as new to Indonesia.

Keywords

Ceriporiopsis rivulosa Ceriporiopsis subvermispora Diplomitoporus lindbladii Taxonomy Biopulping 

Notes

Acknowledgements

We express our gratitude to Arbinis Arbain, Syamsurdi, Rusdji Tamin, Hernawati, and Nurainas (Padang), and Pertti Uotila (H) for providing generous assistance to work in Indonesia. Genevieve Gates (Hobart) provided us with valuable specimens. Tuomo Niemelä (Helsinki) revised the manuscript, and Teuvo Ahti (Helsinki) revised the Latin. Tuuli Timonen and Pirkko Harju (Helsinki) identified some host tree species from wood attached to fungal specimens. We thank Pekka Maijala (Helsinki) for his ideas and support for this work, and Annele Hatakka (Helsinki) for providing lab facilities. Ellen Larsson, Elisabet Sjökvist (Göteborg) and Petri Oinonen (Stockholm) did most of the DNA work. The Ella and Georg Ehrnrooth Foundation provided financial support. MR is a researcher for the National Research Council of Argentina (CONICET).

References

  1. Akhtar M, Attridge MC, Blanchette RA, Myers GC, Wall MB, Sykes MS, Koning JW Jr, Burgess RR, Wegner TH, Kirk TK (1992) The white-rot fungus Ceriporiopsis subvermispora saves electrical energy and improves strength properties during biomechanical pulping of wood. In: Kuwahara M, Shimada M (eds) Biotechnology in pulp and paper industry. UNi, Tokyo, pp 3–8Google Scholar
  2. Akhtar M, Scott GM, Swaney RE, Shipley DF (2000) Biomechanical pulping: a mill-scale evaluation. Resour Conserv Recycl 28:241–252CrossRefGoogle Scholar
  3. Amirta R, Tanabe T, Watanabe T, Honda Y, Kuwahara M, Watanabe T (2006) Methane fermentation of Japanese cedar wood pretreated with a white rot fungus, Ceriporiopsis subvermispora. J Biotech 123:71–77CrossRefGoogle Scholar
  4. Atik C, Imamoglu S, Bermek H (2006) Impact of xylanase pre-treatment on peroxide bleaching stage of biokraft pulp. Int Biodeter Biodegr 58:22–26CrossRefGoogle Scholar
  5. Bernicchia A (2005) Polyporaceae s.l. Edizione Candusso, AlassioGoogle Scholar
  6. Binder M, Hibbett DS, Larsson KH, Larsson E, Langer E, Langer G (2005) The phylogenetic distribution of resupinate forms across the major clades of homobasidiomycetes. Syst Biodivers 3:113–157CrossRefGoogle Scholar
  7. Boidin J (1971) Nuclear behaviour in the mycelium and the evolution of the Basidiomycetes. In: Petersen RH (ed) Evolution in the higher Basidiomycetes. University of Tennessee Press, Knoxville, pp 129–148Google Scholar
  8. Corner EJH (1992) Additional resupinate non-xanthochroic polypores from Brazil and Malesia. Nova Hedwigia 55:119–152Google Scholar
  9. Dai YC (1998) Changbai wood-rotting fungi 9. Three new species and other species in Rigidoporus, Skeletocutis and Wolfiporia (Basidiomycota, Aphyllophorales). Ann Bot Fenn 35:143–154Google Scholar
  10. Dai YC, Wang Z, Binder M, Hibbett DS (2006) Phylogeny and a new species of Sparassis (Polyporales, Basidiomycota): evidence from mitochondrial atp6, nuclear rDNA and rpb2 genes. Mycologia 98:584–592PubMedCrossRefGoogle Scholar
  11. David A (1971) Caractères myceliens de Rigidoporus rivulosus (Berk. et Curt.) comb. nov., espèce nouvelle pour l'Europe. Bull Soc Mycol Fr 87:415–419Google Scholar
  12. David A (1972) Comportement nucléaire des représentants du genre Gloeoporus Mont.: G. conchoides Mont., G. dichrous (Fr.) Bres. et G. pannocinctus (Rom.) J. Erikss. récolté pour la première fois en France. Bull Soc Mycol Fr 88:209–213Google Scholar
  13. David A (1982) Étude monographique du genre Skeletocutis (Polyporaceae). Naturaliste Can 109:235–272Google Scholar
  14. David A, Déquatre B (1984) Deux “ultraespecies”: Antrodia malicola (Berk. & Curt.) Donk et A. ramentacea (Berk. & Br.) Donk (Basidiomycetes, Aphyllophorales). Cryptogam Mycol 5:293–300Google Scholar
  15. David A, Déquatre B (1985) Antrodia albidoides (Polyporaceae) nouvelle ultraspecies meridionale. Mycol Helv 6:357–369Google Scholar
  16. Fackler K, Gradinger C, Schmutzer M, Tavzes C, Burgert I, Schwanninger M, Hinterstoisser B, Watanabe T, Messner K (2007) Biomodification of wood with selective white-rot fungi. Food Technol Biotechnol 45:269–276Google Scholar
  17. Galkin A, Vares T, Kalsi M, Hatakka A (1998) Production of organic acids by different white-rot fungi as detected using capillary zone electrophoresis.Biotechnol Tech 12:267–271Google Scholar
  18. Gardes M, Bruns TD (1993) ITS primers with enhanced specificity for basidiomycetes—application to the identification of mycorrhizae and rusts. Mol Ecol 2:113–118PubMedCrossRefGoogle Scholar
  19. Gilbertson RL, Ryvarden L (1986) North American polypores 1. Abortiporus to Lindtneria. Fungiflora, OsloGoogle Scholar
  20. Harreither W, Sygmund C, Dünhofen E, Vicuña R, Haltrich D, Ludwig R (2007) Cellobiose dehydrogenase from the ligninolytic basidiomycete Ceriporiopsis subvermispora. Appl Env Microbiol 75:2750–2757CrossRefGoogle Scholar
  21. Hakala TK, Lundell T, Galkin S, Maijala P, Kalkkinen N, Hatakka A (2005) Manganese peroxidases, laccases and oxalic acid from the selective white-rot fungus Physisporinus rivulosus grown on spruce wood chips. Enz Microb Technol 36:461–468CrossRefGoogle Scholar
  22. Hallenberg N (1984) Compatibility between species of Corticiaceae s.l. (Basidiomycetes) from Europe and North America. Mycotaxon 21:335–388Google Scholar
  23. Hattori T (2001a) Type studies of the polypores described by E. J. H. Corner from Asia and West Pacific Areas II. Species described in Gloeophyllum, Heteroporus, Microporellus, Oxyporus, Paratrichaptum, and Rigidoporus. Mycoscience 42:19–28CrossRefGoogle Scholar
  24. Hattori T (2001b) Type studies of the polypores described by E. J. H. Corner from Asia and West Pacific Areas 3. Species described in Trichaptum, Albatrellus, Boletopsis, Diacanthodes, Elmerina, Fomitopsis and Gloeoporus. Mycoscience 42:423–431CrossRefGoogle Scholar
  25. Hattori T (2002) Type studies of the polypores described by E.J.H. Corner from Asia and West Pacific Areas 4. Species described in Tyromyces (1). Mycoscience 43:307–315CrossRefGoogle Scholar
  26. Hattori T (2003a) Type studies of the polypores described by E.J.H. Corner from Asia and West Pacific Areas 5. Species described in Tyromyces (2). Mycoscience 44:265–276CrossRefGoogle Scholar
  27. Hattori T (2003b) Type studies of the polypores described by E.J.H. Corner from Asia and West Pacific Areas 6. Species described in Tyromyces (3), Cristelloporia, Grifola, Hapalopilus, Heterobasidion, Ischnoderma, Loweporus, and Stecchericium. Mycoscience 44:453–463CrossRefGoogle Scholar
  28. Hibbett DS, Binder M, Bischoff JF, Blackwell M, Cannon PF, Eriksson OE, Huhndorf S, James T, Kirk PM, Lücking R, Lumbsch T, Lutzoni F, Matheny PB, Mclaughlin DJ, Powell MJ, Redhead S, Schoch CL, Spatafora JW, Stalpers JA, Vilgalys R, Aime MC, Aptroot A, Bauer R, Begerow D, Benny GL, Castlebury LA, Crous PW, Dai YC, Gams W, Geiser DM, Griffith GW, Gueidan C, Hawksworth DL, Hestmark G, Hosaka K, Humber RA, Hyde K, Ironside JE, Kõljalg U, Kurtzman CP, Larsson KH, Lichtwardt R, Longcore J, Miądlikowska J, Miller A, Moncalvo JM, Mozley-Standridge S, Oberwinkler F, Parmasto E, Reeb V, Rogers JD, Roux C, Ryvarden L, Sampaio JP, Schüßler A, Sugiyama J, Thorn RG, Tibell L, Untereiner WA, Walker C, Wang Z, Weir A, Weiß M, White MM, Winka K, Yao YJ, Zhang N (2007) A higher-level phylogenetic classification of the Fungi. Mycol Res 111:509–247PubMedCrossRefGoogle Scholar
  29. Hopple JS Jr, Vilgalys R (1999) Phylogenetic relationships in the mushroom genus Coprinus and dark-spored allies based on sequence data from the nuclear gene coding for the large ribosomal subunit RNA:divergent domains, outgroups, and monophyly. Mol Phylogenet Evol 13:1–19PubMedCrossRefGoogle Scholar
  30. Jülich W (1974) Notes on the cyanophily of spores, with discussion of the genus Leucogyrophana (Corticiaceae). Persoonia 8:51–58Google Scholar
  31. Katoh K, Kuma K, Toh H, Miyata T (2005) MAFFT version 5: improvement in accuracy of multiple sequence alignment. Nucleic Acids Res 33:511–518PubMedCrossRefGoogle Scholar
  32. Katoh K, Toh H (2008) Improved accuracy of multiple ncRNA alignment by incorporating structural information into a MAFFT-based framework. BMC Bioinform 9:212CrossRefGoogle Scholar
  33. Kotiranta H (1985) Physisporinus rivulosus, an interesting polypore species. Karstenia 25:66–69Google Scholar
  34. Kotlaba F, Pouzar Z (1964) Preliminary results on the staining of spores and other structures of Homobasidiomycetes in Cotton Blue and its importance for taxonomy. Feddes Repertorium 69:131–142Google Scholar
  35. Larsson KH (2007) Re-thinking the classification of corticioid fungi. Mycol Res 111:1040–1063PubMedCrossRefGoogle Scholar
  36. Larsson KH, Larsson E, Kõljalg U (2004) High phylogenetic diversity among corticioid homobasidiomycetes. Mycol Res 108:983–1002PubMedCrossRefGoogle Scholar
  37. Lindner DL, Banik MT (2008) Molecular phylogeny of Laetiporus and other brown rot polypore genera in North America. Mycologia 100:417–430PubMedCrossRefGoogle Scholar
  38. Lowe JL (1966) Polyporaceae of North America. The genus Poria. State Univ Coll For Syracuse Univ Techn Publ 90:1–183Google Scholar
  39. Maijala P, Kleen M, Westin C, Poppius-Levlin K, Herranen K, Lehto JH, Reponen P, Mäentausta O, Mettälä A, Hatakka A (2008) Biomechanical pulping of softwood with enzymes and white-rot fungus Physisporinus rivulosus. Enz Microb Technol 43:169–177CrossRefGoogle Scholar
  40. Matheny PB, Wang Z, Binder M, Curtis JM, Lim YW, Nilsson RH, Hughes KW, Hofstetter V, Ammirati JF, Schoch CL, Langer E, Langer G, McLaughlin DJ, Wilson AW, Froslev T, Ge ZW, Kerrigan RW, Slot JC, Yang ZL, Baroni TJ, Fischer M, Hosaka K, Matsuura K, Seidl MT, Vauras J, Hibbett DS (2007) Contributions of rpb2 and tef1 to the phylogeny of mushrooms and allies (Basidiomycota, Fungi). Mol Phyl Evol 43:430–451CrossRefGoogle Scholar
  41. Melo I, Tellería MT (1992) Novidades para a micoflora portuguesa (Aphyllophorales, Basidiomycotina). Portug Acta Biol Sér B 16:11–50Google Scholar
  42. Miettinen O, Larsson KH (2010) Sidera, a new genus in Hymenochaetales with poroid and hydnoid species. Mycol Prog (in press, doi: 10.1007/s11557-010-0682-5)
  43. Miettinen O, Niemelä T, Spirin W (2006) Northern Antrodiella species:the identity of A. semisupina, and type studies of related taxa. Mycotaxon 96:211–239Google Scholar
  44. Müller J, Müller K, Quandt D (2008) PhyDE – Phylogenetic Data Editor, version 0.995. http://phyde.de
  45. Nakasone KK (1981) Cultural studies on Poria cinerascens, P. rivulosa and P. subvermispora (Aphyllophorales, Basidiomycotina). Mycotaxon 13:105–111Google Scholar
  46. Niemelä T (1985) On Fennoscandian polypores 9. Gelatoporia n.gen. and Tyromyces canadensis, plus notes on Skeletocutis and Antrodia. Karstenia 25:21–40Google Scholar
  47. Niemelä T (2005) Polypores, lignicolous fungi. Norrlinia 13:1–320 (in Finnish, with English summary)Google Scholar
  48. Nilsson RH, Veldre V, Hartmann M, Unterseher M, Amend A, Bergsten J, Kristiansson E, Ryberg M, Jumpponen A, Abarenkov K (2010) An open source software package for automated extraction of ITS1 and ITS2 from fungal ITS sequences for use in high-throughput community assays and molecular ecology. Fungal Ecol 3:284–287CrossRefGoogle Scholar
  49. Nobles MK (1958) Cultural characters as a guide to the taxonomy and phylogeny of the Polyporaceae. Can J Bot 36:883–926CrossRefGoogle Scholar
  50. Nobles KM (1965) Identification of cultures of wood-inhabiting Hymenomycetes. Can J Bot 43:1097–1139CrossRefGoogle Scholar
  51. Penttilä R, Kotiranta H (1996) Short-term effects of prescribed burning on wood-rotting fungi. Silva Fenn 30:399–419Google Scholar
  52. Rajchenberg M (1995) Basidiomicetos xilofilos (Aphyllophorales) de los bosques andinopatagonicos, adiciones y correcciones IV. Bol Soc Argent Bot 30:153–161Google Scholar
  53. Robledo GL (2009) Hongos degradadores de la madera de las Yungas argentinas. Diversidad de Políporos (Aphyllophorales, Basidiomycota). Doctoral thesis, Universidad Nacional de CórdobaGoogle Scholar
  54. Robledo GL, Amalfi M, Castillo G, Rajchenberg M, Decock C (2009) Perenniporiella chaquenia sp. nov. and further notes on Perenniporiella and its relationships with Perenniporia (Poriales, Basidiomycota). Mycologia 101:657–673PubMedCrossRefGoogle Scholar
  55. Ronquist F, Huelsenbeck JP (2003) MrBayes 3: Bayesian phylogenetic inference under mixed models. Bioinformatics 19:1572–1574PubMedCrossRefGoogle Scholar
  56. Ryvarden L (1984) Type studies in the Polyporaceae 16. Species described by J.M. Berkeley, either alone or with other mycologists from 1856 to 1886. Mycotaxon 20:329–363Google Scholar
  57. Ryvarden L, Gilbertson RL (1994) European polypores. Part 2. MeripilusTyromyces. Fungiflora, OsloGoogle Scholar
  58. Sotome K, Hattori T, Ota Y, To-anun C, Salleh B, Kakishima M (2008) Phylogenetic relationships of Polyporus and morphologically allied genera. Mycologia 100:603–615PubMedCrossRefGoogle Scholar
  59. Spirin WA (2005) Notes on some rare polypores, found in Russia 2. Junghuhnia vitellina sp. nova, plus genera Cinereomyces and Skeletocutis. Karstenia 45:103–113Google Scholar
  60. Stalpers JA (1978) Identification of wood-inhabiting fungi in pure culture. Stud Mycol 16:1–248Google Scholar
  61. Tomšovský M, Menkis A, Vasaitis R (2010) Phylogenetic relationships in European Ceriporiopsis species inferred from nuclear and mitochondrial ribosomal DNA sequences. Fungal Biol 114:350–358PubMedCrossRefGoogle Scholar
  62. Tortić M (1976) Some experiences with the use of cresyl blue in the determination of polypores. Kew Bull 31:611–616CrossRefGoogle Scholar
  63. Wang, Z, Dai YC, Hibbett DS (2004) Phylogenetic relationships of Sparassis inferred from nuclear and mitochondrial ribosomal DNA and RNA polymerase sequences. Mycologia 96:1015–1029Google Scholar
  64. White TJ, Bruns T, Lee S, Taylor JW (1990) Amplification and direct sequencing of fungal ribosomal RNA genes for phylogenetics. In: Innis MA, Gelfand DH, Sinisky JJ, White TJ (eds) PCR protocols: a guide to method and application. Academic, San Diego, pp 315–322Google Scholar
  65. Wu SH, Nilsson HR, Chen CT, Yu SY, Hallenberg N (2010) The white-rotting genus Phanerochaete is polyphyletic and distributed throughout the phlebioid clade of the Polyporales (Basidiomycota). Fungal Divers 42:107–118CrossRefGoogle Scholar

Copyright information

© German Mycological Society and Springer 2011

Authors and Affiliations

  1. 1.Botanical MuseumUniversity of HelsinkiHelsinkiFinland
  2. 2.Centro de Investigación y Estensión Forestal Andino Patagónico (CIEFAP)ChubutArgentina

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