Marginal Calluna heathlands are more resistant to climate change, but not under high nitrogen loads

Research output: Contribution to journalResearch articleContributedpeer-review

Contributors

  • Maren Meyer-Grünefeldt - (Author)
  • Kristina Belz - , Leuphana University of Lüneburg (Author)
  • Leonor Calvo - , University of Leon (Author)
  • Elena Marcos - , University of Leon (Author)
  • Goddert von Oheimb - , Chair of Biodiversity and Nature Conservation (Author)
  • Werner Härdtle - , Leuphana University of Lüneburg (Author)

Abstract

The dominant plant species of European heathlands Calluna vulgaris is considered vulnerable to drought and enhanced nitrogen (N) loads. However, impacts may vary across the distribution range of Calluna heathlands. We tested the hypothesis that Calluna of southern and eastern marginal populations (MP) are more resistant to drought events than plants of central populations (CP), and that this is mainly due to trait differences such as biomass allocation patterns. Furthermore, we hypothesised that N fertilisation can offset differences in drought susceptibility between CP and MP. We conducted a full-factorial 2-year greenhouse experiment with Calluna plants of CP and MP and quantified growth responses in terms of biomass production, allocation and tissue δ13C signatures. Biomass production, shoot–root ratios and tissue δ13C values of 1-year-old plants were higher for CP than for MP, indicating a higher drought susceptibility of CP. These trait differences were not observed for 2-year-old plants. N fertilisation increased shoot–root ratios of 1- and 2-year-old plants and across populations due to a stimulation of the aboveground biomass allocation. As a consequence, population-related differences in drought susceptibility were offset for N-fertilised plants. We concluded that Calluna plants originating from different populations developed adaptive traits to local climates, which determined their drought sensitivity. However, the higher drought resistance of MP can be attenuated by an N-induced increase in shoot–root ratios. This suggests that analyses on plant growth responses to global change should include multi-factor approaches with a focus on different populations throughout a species’ distribution range.

Details

Original languageEnglish
Pages (from-to)111 - 122
JournalPlant Ecology
Volume217
Publication statusPublished - 2016
Peer-reviewedYes

External IDs

ORCID /0000-0001-7408-425X/work/148144191

Keywords