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Changes in the microbial community in a forest soil amended with aluminium in situ

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Abstract

Considerable knowledge exists about the effect of aluminium (Al) on root vitality, but whether elevated levels of Al affect soil microorganisms is largely unknown. We thus compared soils from Al-treated and control plots of a field experiment with respect to microbial and chemical parameters, as well as root growth and vitality. The field experiment was established in a 50-year-old Norway spruce (Picea abies L.) stand where no Al or low concentrations of Al had been added every 7–10 days during the growth season for 7 years. Analysis of soil solutions collected using zero tension lysimeters and porous suction cups showed that Al treatment lead to increased concentrations of Al, Ca and Mg and lower pH and [Ca + Mg + K/Al] molar ratio. Corresponding soil analyses showed that soil pH remained unaffected (pH 3.8), that exchangeable Al increased, while exchangeable Ca and Mg decreased due to the Al treatment. Root in-growth into cores placed in the upper 20 cm of the soil during three growth seasons was not affected by Al additions, neither was nutrient concentration or mortality of these roots. The biomass of some taxonomic groups of soil microorganisms, analyzed using specific membrane components (phospholipid fatty acids; PLFAs), was clearly affected by the imposed Al treatment, both in the organic soil horizon and in the underlying mineral soil. Microbial community structure in both horizons was also clearly modified by the Al treatment. Shifts in PLFA trans/cis ratios indicative of short term physiological stress were not observed. Yet, aluminium stress was indicated both by changes in community structure and in ratios of single PLFAs for treated/untreated plots. Thus, soil microorganisms were more sensitive indicators of subtle chemical changes in soil than chemical composition and vitality of roots.

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  1. Erik J. Joner

    Present address: Laboratoire Pierre Süe, CEA – CNRS, Centre de Saclay, bât. 637, F-91191, Gif sur Yvette, France

Authors and Affiliations

  1. Skogforsk, Norwegian Forest Research Institute, Høgskoleveien. 8, N-1432, Ås, Norway

    Erik J. Joner, Toril D. Eldhuset & Holger Lange

  2. Department of Chemistry, Biotechnology and Food Sciences, Agricultural University of Norway, P.O. Box 5003, N-1432, Ås, Norway

    Åsa Frostegård

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  1. Erik J. Joner
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Correspondence to Erik J. Joner.

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Joner, E.J., Eldhuset, T.D., Lange, H. et al. Changes in the microbial community in a forest soil amended with aluminium in situ . Plant Soil 275, 295–304 (2005). https://doi.org/10.1007/s11104-005-2287-3

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