Short- and long-term plant and microbial uptake of 15N-labelled urea in a mesic tundra heath, West Greenland

Terrestrial animals are key elements in the cycling of elements in the Arctic where nutrient availability is low. Waste production by herbivores, in particular urine deposition, has a crucial role for nitrogen (N) recycling, still, it remains largely unexplored. Also, experimental evidence is biased...

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Bibliographic Details
Published in:Polar Biology
Main Authors: Barthelemy, Hélène, Nobel, Liv Alexa, Stark, Sari, Väisänen, Maria, Olofsson, Johan, Michelsen, Anders
Format: Article in Journal/Newspaper
Language:English
Published: Umeå universitet, Institutionen för ekologi, miljö och geovetenskap 2024
Subjects:
15N labelling
Arctic tundra
Ecosystem N retention
Microbial N immobilization
Plant nitrogen uptake
Urine
Ecology
Ekologi
Arctic
Greenland
Polar Biology
Tundra
Online Access:http://urn.kb.se/resolve?urn=urn:nbn:se:umu:diva-216900
https://doi.org/10.1007/s00300-023-03209-6
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Summary:Terrestrial animals are key elements in the cycling of elements in the Arctic where nutrient availability is low. Waste production by herbivores, in particular urine deposition, has a crucial role for nitrogen (N) recycling, still, it remains largely unexplored. Also, experimental evidence is biased toward short-term studies and Arctic regions under high herbivore pressure. In this study, we aimed to examine the fate of N derived from urine in a nutrient poor tundra heath in West Greenland, with historical low level of herbivory. We performed a pulse labelling with 15N-urea over the plant canopy and explored ecosystem N partition and retention in the short-term (2 weeks and 1 year) and longer-term (5 years). We found that all vascular plants, irrespective of their traits, could rapidly take up N-urea, but mosses and lichens were even more efficient. Total 15N enrichment was severely reduced for all plants 5 years after tracer addition, with the exception of cryptogams, indicating that non-vascular plants constituted a long-term sink of 15N-urea. The 15N recovery was also high in the litter suggesting high N immobilization in this layer, potentially delaying the nutrients from urine entering the soil compartment. Long-term 15N recovery in soil microbial biomass was minimal, but as much as 30% of added 15N remained in the non-microbial fraction after 5 years. Our results demonstrate that tundra plants that have evolved under low herbivory pressure are well adapted to quickly take advantage of labile urea, with urine having only a transient effect on soil nutrient availability. Published online: 12 November 2023

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