Tree rings provide valuable insight into past environmental changes. This study aimed to evaluate perturbations in tree ring width (TRW) and δ15N alongside soil acidity and nutrient availability gradients caused by the contrasting legacy of air pollution (nitrogen [N] and sulphur [S] deposition) and tree species (European beech, Silver fir and Norway spruce). We found consistent declines of tree ring δ15N, which were temporarily unrelated to the changes in the TRW. The rate of δ15N change in tree rings was related to the contemporary foliar carbon (C) to phosphorus (P) ratio. This observation suggested that the long-term accumulation of 15N depleted N in tree rings, likely mediated by retained N from deposition, was restricted primarily to stands with currently higher P availability. The shifts observed in tree-ring δ15N and TRW suggest that acidic air pollution rather than changes in stand productivity determined alteration of N and C cycles. Stable N isotopes in tree rings provided helpful information on the trajectory of the N cycle over the last century with direct consequences for a better understanding of future interactions among N, P and C cycles in terrestrial ecosystems.

Czech Geological Survey Klárov 3 118 21 Prague Czech Republic; Global Change Research Institute of the Czech Academy of Sciences Bělidla 986 4a 603 00 Brno Czech Republic

Department of Ecosystem Biology Faculty of Science University of South Bohemia Branišovská 31 370 05 České Budějovice Czech Republic

Department of Forest Protection and Wildlife Management Faculty of Forestry and Wood Technology Mendel University in Brno 613 00 Brno Czech Republic

Global Change Research Institute of the Czech Academy of Sciences Bělidla 986 4a 603 00 Brno Czech Republic

Global Change Research Institute of the Czech Academy of Sciences Bělidla 986 4a 603 00 Brno Czech Republic; Department of Wood Science and Technology Faculty of Forestry and Wood Technology Mendel University in Brno 613 00 Brno Czech Republic

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