Organic acids produced by mycorrhizal Pinus sylvestris exposed to elevated aluminium and heavy metal concentrations

ULLA AHONEN-JONNARTH; PATRICK A. W. VAN HEES; ULLA S. LUNDSTRÖM; ROGER D. FINLAY

doi:10.1046/j.1469-8137.2000.00653.x

Abstract

A cultivation method was developed to enable exposure of ectomycorrhizal plants with intact extramatrical mycelium to solutions containing different concentrations of aluminium or heavy metals. Pinus sylvestris seedlings colonized by Suillus variegatus (two isolates), Rhizopogon roseolus or Paxillus involutus (two isolates) were used. Seedlings were transferred to Petri dishes containing glass beads and exposed to elevated concentrations of Al, Cd, Cu, or Ni in two ways: immediately following transfer; and after allowing mycorrhizal seedlings to develop an extraradical mycelium that colonized the interface between the upper surface of the beads and the metal- containing solution. Production of organic acids in mycorrhizal and non-mycorrhizal systems was measured by withdrawing samples from the solution and analyzing by HPLC. In most experiments, levels of oxalic acid were significantly higher in mycorrhizal treatments than in non-mycorrhizal controls. The measured levels of organic acids were variable, but the results obtained suggest that production of oxalic acid is stimulated by exposure to elevated Al in mycorrhizal seedlings colonized by S. variegatus and R. roseolus. Elevated Al concentrations also increased oxalic acid production by non-mycorrhizal seedlings significantly in two of four Al experiments performed, but the measured concentrations were significantly lower than in corresponding mycorrhizal treatments in both cases. Malonic acid was found in the culture solution of non-mycorrhizal and P. involutus- colonized seedlings, but only trace amounts were found in S. variegatus or R. roseolus-infected seedlings. Citric, shikimic, lactic, acetic, propionic, fumaric, formic, iso-butyric and butyric acid were found in variable concentrations. Production of oxalic acid by seedlings colonized by S. variegatus BL or P. involutus was not stimulated by exposure to 0.44 μM Cd or 17 μM Ni. Exposure to 0.157 mM Cu in two separate experiments using P. involutus 87.017 and two strains of S. variegatus (BL and I59) appeared to stimulate production of oxalic acid irrespective of mycorrhizal status or species.

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Van Tichelen, Katia K. Colpaert, Jan V. and Vangronsveld, Jaco 2001. Ectomycorrhizal protection of Pinus sylvestris against copper toxicity. New Phytologist, Vol. 150, Issue. 1, p. 203.

Landeweert, Renske Hoffland, Ellis Finlay, Roger D. Kuyper, Thom W. and van Breemen, Nico 2001. Linking plants to rocks: ectomycorrhizal fungi mobilize nutrients from minerals. Trends in Ecology & Evolution, Vol. 16, Issue. 5, p. 248.

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.

Bomberg, Malin Jurgens, German Saano, Aimo Sen, Robin and Timonen, Sari 2003. Nested PCR detection of Archaea in defined compartments of pine mycorrhizospheres developed in boreal forest humus microcosms. FEMS Microbiology Ecology, Vol. 43, Issue. 2, p. 163.

Mahmood, Shahid 2003. Colonisation of spruce roots by two interacting ectomycorrhizal fungi in wood ash amended substrates. FEMS Microbiology Letters, Vol. 221, Issue. 1, p. 81.

Meharg, Andrew A. 2003. The mechanistic basis of interactions between mycorrhizal associations and toxic metal cations. Mycological Research, Vol. 107, Issue. 11, p. 1253.

Van Hees, P. A. W. Godbold, D. L. Jentschke, G. and Jones, D. L. 2003. Impact of ectomycorrhizas on the concentration and biodegradation of simple organic acids in a forest soil. European Journal of Soil Science, Vol. 54, Issue. 4, p. 697.

Rosling, Anna Lindahl, BjÃ¶rn D. Taylor, Andy F.S. and Finlay, Roger D. 2004. Mycelial growth and substrate acidification of ectomycorrhizal fungi in response to different minerals. FEMS Microbiology Ecology, Vol. 47, Issue. 1, p. 31.

Jacob, Christophe Courbot, Mikaël Martin, Francis Brun, Annick and Chalot, Michel 2004. Transcriptomic responses to cadmium in the ectomycorrhizal fungus Paxillus involutus. FEBS Letters, Vol. 576, Issue. 3, p. 423.

Xinmin, Wang Yanlin, Hou and Xiaolei, Jie 2004. Citric and Oxalic Acids Effect on Pb and Zn Uptake by Maize and Winter Wheat. Chinese Journal of Population Resources and Environment, Vol. 2, Issue. 4, p. 37.

Holmstr�m, Sara J.M. Lundstr�m, Ulla S. Finlay, Roger D. and van Hees, Patrick A.W. 2004. Siderophores in forest soil solution. Biogeochemistry, Vol. 71, Issue. 2, p. 247.

Rosling, Anna Lindahl, Björn D. and Finlay, Roger D. 2004. Carbon allocation to ectomycorrhizal roots and mycelium colonising different mineral substrates. New Phytologist, Vol. 162, Issue. 3, p. 795.

Fomina, M. Alexander, I. J. Hillier, S. and Gadd, G. M. 2004. Zinc Phosphate and Pyromorphite Solubilization by Soil Plant-Symbiotic Fungi. Geomicrobiology Journal, Vol. 21, Issue. 5, p. 351.

Asiegbu, Frederick O. Abu, Selim Stenlid, Jan and Johansson, Martin 2004. Sequence polymorphism and molecular characterization of laccase genes of the conifer pathogen Heterobasidion annosum. Mycological Research, Vol. 108, Issue. 2, p. 136.

Wallander, H�kan Fossum, Anna Rosengren, Ulrika and Jones, Helen 2005. Ectomycorrhizal fungal biomass in roots and uptake of P from apatite by Pinus sylvestris seedlings growing in forest soil with and without wood ash amendment. Mycorrhiza, Vol. 15, Issue. 2, p. 143.

Tahara, Ko Norisada, Mariko Tange, Takeshi Yagi, Hisayoshi and Kojima, Katsumi 2005. Ectomycorrhizal Association Enhances Al Tolerance by Inducing Citrate Secretion inPinus densiflora. Soil Science and Plant Nutrition, Vol. 51, Issue. 3, p. 397.

Aravind, P. and Prasad, M.N.V. 2005. Cadmium-induced toxicity reversal by zinc in Ceratophyllum demersum L. (a free floating aquatic macrophyte) together with exogenous supplements of amino- and organic acids. Chemosphere, Vol. 61, Issue. 11, p. 1720.

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Organic acids produced by mycorrhizal Pinus sylvestris exposed to elevated aluminium and heavy metal concentrations

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Organic acids produced by mycorrhizal Pinus sylvestris exposed to elevated aluminium and heavy metal concentrations

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