Shoot biomass, δ13C, nitrogen and chlorophyll responses of two arctic dwarf shrubs to in situ shading, nutrient application and warming simulating climatic change

Anders Michelsen; Sven Jonasson; Darren Sleep; Mats Havström; Terry V Callaghan

doi:10.1007/BF00328785

Shoot biomass, δ¹³C, nitrogen and chlorophyll responses of two arctic dwarf shrubs to in situ shading, nutrient application and warming simulating climatic change

Oecologia. 1996 Jan;105(1):1-12. doi: 10.1007/BF00328785.

Authors

Anders Michelsen¹, Sven Jonasson², Darren Sleep¹, Mats Havström³, Terry V Callaghan⁴

Affiliations

¹ Institute of Terrestrial Ecology, Merlewood Research Station, LA11 6JU, Grange-over-Sands, Cumbria, UK.
² Department of Plant Ecology, University of Copenhagen, Øster Farimagsgade 2 D, DK-1353, Copenhagen K, Denmark.
³ Institute of Botany, University of Göteborg, Carl Skottsbergs Gata 22, S-413 19, Göteborg, Sweden.
⁴ Sheffield Centre for Arctic Ecology, University of Sheffield, P.O. Box 601, S10 2UQ, Sheffield, UK.

PMID: 28307116
DOI: 10.1007/BF00328785

Abstract

As climatic change might induce ecophysiological changes in plants which affect their long-term performance, we investigated responses in above-ground biomass, δ¹³C, nitrogen and chlorophyll of two evergreen arctic dwarf shrubs, Cassiope tetragona and Empetrum hermaphroditum, to 5 (biomass, N) or 6 years of shading, nutrient application and air/soil warming at a dwarf shrub dominated tree-line heath (450 m a.s.l) and a high altitude fellfield (1100 m a.s.l.) in Swedish Lapland. Warming enhanced the green biomass (equivalent to the last 3-4 years of leaf production) and the ratio of green to brown biomass of C. tetragona at the fellfield, and diluted the shoot N concentration. Fertilizer application led to higher shoot N concentration and larger green-to-brown biomass ratio at both sites, and fertilizer application and warming generally had an additive effect on the green biomass. We conclude that both warming and increased soil nutrient availability stimulated the growth of C. tetragona at the fellfield whereas at the heath there was a clear increase in production only if enhanced temperature was combined with nutrient application. Across treatments C. tetragona at the fellfield had 0.6‰ higher δ¹³C and 1.4 mg g^-1 more leaf N, and the soil organic matter δ¹³C was 1.0‰ higher at the fellfield than at the heath. However, an increase in shoot N concentration with altitude does not necessarily lead to higher δ¹³C as no differences in δ¹³C were observed when leaf N of the two dwarf shrubs was increased by fertilizer application c. tetragona in non-warmed plots had higher δ¹³C values than those from warmed plots at the same altitude, which provides the first in situ experimental validation of the theory that temperature partly is responsible for altitudinal trends in plant carbon isotope discrimination. Increased biomass and chlorophyll concentration of C. tetragona in warmed plots points to increased assimilation, at least at the fellfield. As the δ¹³C-based and, therefore, time-integrated estimate of the ratio of CO₂ concentration in the leaf intercellular spaces to that in the atmosphere (C _i/C _a) also increased, warming probably enhanced the stomatal conductance relatively more than the C assimilation, which may be harmful if climatic change leads to reduced soil moisture content and increased plant competition for water. At both sites C. tetragona and E. hermaphroditum responded to shade by increasing the concentration of shoot N and photosynthetic pigments whereas biomass production (and therefore also net photosynthesis) did not decline. Shade was accompanied by a 0.6-1.3‰ (E. hermaphroditum) or 1.2-2.2‰ (C. tetragona) decrease in δ¹³C. This could be due to enhanced stomatal conductance with shading, and perhaps to shade reducing the ericoid mycorrhizal uptake of soil organic C, a factor which has been overlooked as an influence on plant δ¹³C.

Keywords: Altitude; Carbon isotopes; Cassiope tetragona; Empetrum hermaphroditum; Global change.