Continuity of ectomycorrhizal fungi in self-regenerating boreal Pinus sylvestris forests studied by comparing mycobiont diversity on seedlings and mature trees

L. JONSSON; A. DAHLBERG; M-C. NILSSON; O. KÅRÉN; O. ZACKRISSON

doi:10.1046/j.1469-8137.1999.00383.x

Abstract

Seedlings and old trees of Scots pine in self-regenerating, old, virgin boreal forest in northern Sweden were compared in terms of the species composition of their associated ectomycorrhizal (EM) fungi. The natural regeneration of seedlings was mimicked by annual seeding for 10 yr (1986–1995) in intact field vegetation at three sites. In 1995, all seedlings were harvested, and 171 were examined for mycorrhizas. Twenty-five soil cores were taken in order to study the mycorrhizas on the established trees. Most short roots were mycorrhizal. Using mycorrhizal morphology and restriction fragment length polymorphisms (RFLP) analysis, we were able to distinguish 43 ectomycorrhizal taxa. Fourteen of these taxa were identified using a sporocarp and mycelial culture based internal transcribed spacer (ITS)-RFLP reference database, and another three were identified by mycorrhizal morphology. Cenococcum geophilum, Piloderma croceum and Suillus variegatus were present on the seedlings, irrespective of age, as well as on the old trees. At one forest, 23 ectomycorrhizal taxa were found as mycorrhizas, of which 10 occurred on both seedlings and old trees. These 10 species accounted for 92 and 73% of the mycorrhizas on the seedlings and old trees, respectively. A 3-yr survey of ectomycorrhizal sporocarps at the same site revealed 62 EM taxa. The degree of similarity between the composition of EM species reflected by sporocarps and by mycorrhizas, was low. Ectomycorrhizal species present in our ITS-RFLP database constituted 7.5–19% of the mycorrhizas on seedlings and old trees, whereas they constituted 80–95% of the total production of epigeous sporocarps. The unidentified taxa comprised 70–87% of the mycorrhizas. Our findings support the view that the species composition of mycorrhizas colonizing naturally regenerated seedlings in forests is similar to that of mycorrhizas colonizing surrounding trees. We suggest that the concept of the mycelial network be expanded in order to embrace both the significance of interconnections between different trees as well as the continuity or perpetuation of EM fungal communities.

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Kõljalg, U. Dahlberg, A. Taylor, A. F. S. Larsson, E. Hallenberg, N. Stenlid, J. Larsson, K.‐H. Fransson, P. M. Kårén, O. and Jonsson, L. 2000. Diversity and abundance of resupinate thelephoroid fungi as ectomycorrhizal symbionts in Swedish boreal forests. Molecular Ecology, Vol. 9, Issue. 12, p. 1985.

Grogan, P. Baar, J. and Bruns, T.D. 2000. Below‐ground ectomycorrhizal community structure in a recently burned bishop pine forest. Journal of Ecology, Vol. 88, Issue. 6, p. 1051.

Heinonsalo, Jussi Jørgensen, Kirsten S Haahtela, Kielo and Sen, Robin 2000. Effects ofPinus sylvestrisroot growth and mycorrhizosphere development on bacterial carbon source utilization and hydrocarbon oxidation in forest and petroleum-contaminated soils. Canadian Journal of Microbiology, Vol. 46, Issue. 5, p. 451.

van der Heijden, EW Vries, FW de and Kuyper, Th. W 2000. Mycorrhizal associations of Salix repens L. communities in succession of dune ecosystems. I. Above-ground and below-ground views of ectomycorrhizal fungi in relation to soil chemistry. Canadian Journal of Botany, Vol. 77, Issue. 12, p. 1821.

Dahlberg, Anders 2001. Community ecology of ectomycorrhizal fungi: an advancing interdisciplinary field. New Phytologist, Vol. 150, Issue. 3, p. 555.

Dahlberg, Anders Schimmel, Johnny Taylor, Andy F.S. and Johannesson, Hanna 2001. Post-fire legacy of ectomycorrhizal fungal communities in the Swedish boreal forest in relation to fire severity and logging intensity. Biological Conservation, Vol. 100, Issue. 2, p. 151.

Tammi, Hanna Timonen, Sari and Sen, Robin 2001. Spatiotemporal colonization of Scots pine roots by introduced and indigenous ectomycorrhizal fungi in forest humus and nursery Sphagnum peat microcosms. Canadian Journal of Forest Research, Vol. 31, Issue. 5, p. 746.

Brunner, Ivano 2001. Ectomycorrhizas: their role in forest ecosystems under the impact of acidifying pollutants. Perspectives in Plant Ecology, Evolution and Systematics, Vol. 4, Issue. 1, p. 13.

Glen, Morag Tommerup, Inez C. Bougher, Neale L. and O'Brien, Philip A. 2001. Specificity, sensitivity and discrimination of primers for PCR-RFLP of larger basidiomycetes and their applicability to identification of ectomycorrhizal fungi in Eucalyptus forests and plantations. Mycological Research, Vol. 105, Issue. 2, p. 138.

Heinonsalo, Jussi JÃ¸rgensen, Kirsten S. and Sen, Robin 2001. Microcosm-based analyses of Scots pine seedling growth, ectomycorrhizal fungal community structure and bacterial carbon utilization profiles in boreal forest humus and underlying illuvial mineral horizons. FEMS Microbiology Ecology, Vol. 36, Issue. 1, p. 73.

Peter, Martina Ayer, François Egli, Simon and Honegger, Rosmarie 2001. Above- and below-ground community structure of ectomycorrhizal fungi in three Norway spruce (Picea abies) stands in Switzerland. Canadian Journal of Botany, Vol. 79, Issue. 10, p. 1134.

Horton, Thomas R. and Bruns, Thomas D. 2001. The molecular revolution in ectomycorrhizal ecology: peeking into the black‐box. Molecular Ecology, Vol. 10, Issue. 8, p. 1855.

Eaton, Gregory K. and Ayres, Matthew P. 2002. Plasticity and constraint in growth and protein mineralization of ectomycorrhizal fungi under simulated nitrogen deposition. Mycologia, Vol. 94, Issue. 6, p. 921.

Horton, Thomas R. 2002. Diversity and Integration in Mycorrhizas. p. 29.

Sakakibara, Stacey M. Jones, Melanie D. Gillespie, Michelle Hagerman, Shannon M. Forrest, Mary E. Simard, Suzanne W. and Durall, Daniel M. 2002. A comparison of ectomycorrhiza identification based on morphotyping and PCR-RFLP analysis. Mycological Research, Vol. 106, Issue. 8, p. 868.

Wiemken, Verena and Boller, Thomas 2002. Ectomycorrhiza: gene expression, metabolism and the wood-wide web. Current Opinion in Plant Biology, Vol. 5, Issue. 4, p. 355.

Mahmood, Shahid Finlay, Roger D Wallander, Håkan and Erland, Susanne 2002. Ectomycorrhizal colonisation of roots and ash granules in a spruce forest treated with granulated wood ash. Forest Ecology and Management, Vol. 160, Issue. 1-3, p. 65.

Kranabetter, J M and Friesen, J 2002. Ectomycorrhizal community structure on western hemlock (Tsuga heterophylla) seedlings transplanted from forests into openings. Canadian Journal of Botany, Vol. 80, Issue. 8, p. 861.

Jones, Melanie D Hagerman, Shannon M and Gillespie, M 2002. Ectomycorrhizal colonization and richness of previously colonized, containerized Picea engelmannii does not vary across clearcuts when planted in mechanically site-prepared mounds. Canadian Journal of Forest Research, Vol. 32, Issue. 8, p. 1425.

Markkola, A.M Ahonen-Jonnarth, U Roitto, M Strömmer, R and Hyvärinen, M 2002. Shift in ectomycorrhizal community composition in Scots pine (Pinus sylvestris L.) seedling roots as a response to nickel deposition and removal of lichen cover. Environmental Pollution, Vol. 120, Issue. 3, p. 797.

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Continuity of ectomycorrhizal fungi in self-regenerating boreal Pinus sylvestris forests studied by comparing mycobiont diversity on seedlings and mature trees

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Continuity of ectomycorrhizal fungi in self-regenerating boreal Pinus sylvestris forests studied by comparing mycobiont diversity on seedlings and mature trees

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