Bryophyte species differ widely in their growth and N 2 -fixation responses to temperature

Bryophytes are abundant in tundra ecosystems, where they affect carbon and nitrogen cycling through primary production and associations with N-2-fixing bacteria. Bryophyte responses to climate warming are inconclusive, likely because species-specific responses are poorly understood. Here we investig...

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Bibliographic Details
Published in:Arctic Science
Main Authors: Rzepczynska, Agnieszka Marta, Michelsen, Anders, Olsen, Maya Anne Nissen, Lett, Signe
Format: Article in Journal/Newspaper
Language:English
Published: 2022
Subjects:
acetylene reduction assay
delta C-13
delta N-15
mosses
nitrogen cycling
subarctic tundra ecosystems
CARBON-ISOTOPE DISCRIMINATION
BIOLOGICAL NITROGEN-FIXATION
EXPERIMENTAL WARMING ALTERS
N-15 NATURAL-ABUNDANCE
SUB-ARCTIC BRYOPHYTE
ATMOSPHERIC NITROGEN
COMMUNITY COMPOSITION
LITTER DECOMPOSITION
DINITROGEN FIXATION
SEASONAL-VARIATION
Arctic
Climate change
Subarctic
Tundra
Online Access:https://curis.ku.dk/portal/da/publications/bryophyte-species-differ-widely-in-their-growth-and-n2fixation-responses-to-temperature(d75361f0-3272-40b3-99a0-a71976bfa7ed).html
https://doi.org/10.1139/AS-2021-0053
https://curis.ku.dk/ws/files/332115929/as_2021_0053.pdf
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Summary:Bryophytes are abundant in tundra ecosystems, where they affect carbon and nitrogen cycling through primary production and associations with N-2-fixing bacteria. Bryophyte responses to climate warming are inconclusive, likely because species-specific responses are poorly understood. Here we investigated how warming affects the growth and nitrogenase activity of 10 tundra bryophyte species in two tundra landscapes. Collected bryophyte samples were grown in temperature-controlled growth chambers for 12 weeks at five temperatures from 3 to 18 degrees C. We measured growth, N concentration, delta N-15, and delta C-13 after 3 months and nitrogenase activity after 5 and 12 weeks. Bryophyte growth and associated nitrogenase activity generally increased with temperature, but species differed in their optima. Bryophyte N concentration and delta N-15 indicated that, for some species, increased N-2-fixation could not compensate for growth-induced N limitation. High landscape coverage and large positive warming effects on feather mosses and Sphagnum species highlight their competitive advantages, confirm earlier field observations, and contribute to the mechanistic understanding of differential bryophyte growth in response to warming. We suggest that indirect effects of climate change, such as surface drying and shrub expansion, are likely main threats to slow-growing bryophytes across the Arctic, with consequences for biodiversity and C balance.

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