Ecology and molecular characterization of dark septate fungi from roots, living stems, coarse and fine woody debris

Audrius MENKIS; Johan ALLMER; Rimvydas VASILIAUSKAS; Vaidotas LYGIS; Jan STENLID; Roger FINLAY

doi:10.1017/S0953756204000668

Abstract

The aim of the present work was to determine the identity and molecular relationships between 127 strains of dark septate (DS) fungi isolated from healthy root tips, decayed coarse roots, live healthy-looking stems, coarse (stumps, snags and logs) and fine (tree branches and tops) woody debris in temperate-boreal forests in Sweden and Lithuania. Sequence analysis of ITS rDNA was used to identify the fungi. In a neighbour-joining similarity tree, all sequences were grouped into five distinct clusters. Within each of these, ITS rDNA sequence variation consisted of 2–18 nucleotides, corresponding to 1–3% of their total length. The four least variable clusters were supported with high bootstrap values of 86–100%. Comparisons with the sequences in the GenBank database showed that all our strains had a 95–100% homology with identified Phialocephala species, and they were thus assigned to this genus. The representatives of two clusters were identified, as P. fortinii and P. dimorphospora. The representatives of three remaining clusters were defined as Phialocephala sp. 35, Phialocephala sp. 6 and Phialocephala sp. 18. Within each of these clusters, ITS rDNA sequence uniformity was higher than that observed within P. fortinii and P. dimorphospora. Consequently, their clusters were most discrete, supported with bootstrap values of 100%. Genetic variation in the five distinguished Phialocephala species and their possible ecological roles are discussed. Phialocephala sp. 6 was confined to healthy root tips of conifers. P. dimorphospora was only associated with dead woody tissue of P. abies. P. fortinii, Phialocephala sp. 18 and sp. 35 were isolated from both dead and living conifers and Betula pendula. In conclusion, the present study revealed the ability of fungi from the genus Phialocephala to colonise and persist in live and dead trees under strikingly different ecological conditions.

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Queloz, Valentin Grünig, Christoph R. Sieber, Thomas N. and Holdenrieder, Ottmar 2005. Monitoring the spatial and temporal dynamics of a community of the tree‐root endophyte Phialocephala fortinii s.l.. New Phytologist, Vol. 168, Issue. 3, p. 651.

Addy, H D Piercey, M M and Currah, R S 2005. Microfungal endophytes in roots. Canadian Journal of Botany, Vol. 83, Issue. 1, p. 1.

Kauserud, Håvard Lie, Marit Stensrud, Øyvind and Ohlson, Mikael 2005. Molecular characterization of airborne fungal spores in boreal forests of contrasting human disturbance. Mycologia, Vol. 97, Issue. 6, p. 1215.

Vasiliauskas, Rimvydas Lygis, Vaidotas Larsson, Karl-Henrik and Stenlid, Jan 2005. Airborne fungal colonisation of coarse woody debris in North Temperate Picea abies forest: impact of season and local spatial scale. Mycological Research, Vol. 109, Issue. 4, p. 487.

Trocha, L. K. Rudawska, M. Leski, T. and Dabert, M. 2006. Genetic Diversity of Naturally Established Ectomycorrhizal Fungi on Norway Spruce Seedlings under Nursery Conditions. Microbial Ecology, Vol. 52, Issue. 3, p. 418.

Menkis, A. Vasiliauskas, R. Taylor, A. F. S. Stenström, E. Stenlid, J. and Finlay, R. 2006. Fungi in decayed roots of conifer seedlings in forest nurseries, afforested clear‐cuts and abandoned farmland. Plant Pathology, Vol. 55, Issue. 1, p. 117.

Rice, Adrianne V. and Currah, Randolph S. 2006. Microbial Root Endophytes. Vol. 9, Issue. , p. 227.

AllmÃ©r, Johan Vasiliauskas, Rimvis Ihrmark, Katarina Stenlid, Jan and Dahlberg, Anders 2006. Wood-inhabiting fungal communities in woody debris of Norway spruce (Picea abies (L.) Karst.), as reflected by sporocarps, mycelial isolations and T-RFLP identification. FEMS Microbiology Ecology, Vol. 55, Issue. 1, p. 57.

Hamelin, Richard C. 2006. Molecular epidemiology of forest pathogens: from genes to landscape. Canadian Journal of Plant Pathology, Vol. 28, Issue. 2, p. 167.

Grünig, Christoph R. Duò, Angelo and Sieber, Thomas N. 2006. Population genetic analysis of Phialocephala fortinii s.l. and Acephala applanata in two undisturbed forests in Switzerland and evidence for new cryptic species. Fungal Genetics and Biology, Vol. 43, Issue. 6, p. 410.

Iwański, Michał and Rudawska, Maria 2007. Ectomycorrhizal colonization of naturally regenerating Pinus sylvestris L. seedlings growing in different micro-habitats in boreal forest. Mycorrhiza, Vol. 17, Issue. 5, p. 461.

Grünig, Christoph R. Brunner, Patrick C. Duò, Angelo and Sieber, Thomas N. 2007. Suitability of methods for species recognition in the Phialocephala fortinii–Acephala applanata species complex using DNA analysis. Fungal Genetics and Biology, Vol. 44, Issue. 8, p. 773.

Stenlid, Jan Penttilä, Reijo and Dahlberg, Anders 2008. Ecology of Saprotrophic Basidiomycetes. Vol. 28, Issue. , p. 239.

Grünig, Christoph R. Duò, Angelo Sieber, Thomas N. and Holdenrieder, Ottmar 2008. Assignment of species rank to six reproductively isolated cryptic species of thePhialocephala fortiniis.l.-Acephala applanataspecies complex. Mycologia, Vol. 100, Issue. 1, p. 47.

Peterson, R. Larry Wagg, Cameron and Pautler, Michael 2008. Associations between microfungal endophytes and roots: do structural features indicate function?. Botany, Vol. 86, Issue. 5, p. 445.

2008. Mycorrhizal Symbiosis. p. 637.

Grünig, Christoph R. Queloz, Valentin Sieber, Thomas N. and Holdenrieder, Ottmar 2008. Dark septate endophytes (DSE) of the Phialocephala fortinii s.l. – Acephala applanata species complex in tree roots: classification, population biology, and ecology. Botany, Vol. 86, Issue. 12, p. 1355.

Brenn, Nina Menkis, Audrius Grünig, Christoph R. Sieber, Thomas N. and Holdenrieder, Ottmar 2008. Community structure of Phialocephala fortinii s. lat. in European tree nurseries, and assessment of the potential of the seedlings as dissemination vehicles. Mycological Research, Vol. 112, Issue. 6, p. 650.

Münzenberger, Babette Bubner, Ben Wöllecke, Jens Sieber, Thomas N. Bauer, Robert Fladung, Matthias and Hüttl, Reinhard F. 2009. The ectomycorrhizal morphotype Pinirhiza sclerotia is formed by Acephala macrosclerotiorum sp. nov., a close relative of Phialocephala fortinii. Mycorrhiza, Vol. 19, Issue. 7, p. 481.

Grünig, Christoph R. Queloz, Valentin Duò, Angelo and Sieber, Thomas N. 2009. Phylogeny of Phaeomollisia piceae gen. sp. nov.: a dark, septate, conifer-needle endophyte and its relationships to Phialocephala and Acephala. Mycological Research, Vol. 113, Issue. 2, p. 207.

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Ecology and molecular characterization of dark septate fungi from roots, living stems, coarse and fine woody debris

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Ecology and molecular characterization of dark septate fungi from roots, living stems, coarse and fine woody debris

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