Plant specialisation may limit climate‐induced vegetation change to within topographic and edaphic niches on a sub‐Antarctic island

Extreme changes in temperature, rainfall and wind regimes have been correlated with plant species range expansion upslope on sub‐Antarctic islands. Ongoing climatic changes are expected to continue driving changes in species distributions globally, but niche specialisations may limit the capacity fo...

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Bibliographic Details
Published in:Functional ecology 2022-10, Vol.36 (10), p.2636-2648
Main Authors: Cramer, Michael D., Hedding, David W., Greve, Michelle, Midgley, Guy F., Ripley, Brad S.
Format: Article
Language:English
Subjects:
Air temperature
Climate change
Climate models
Copper
Correlation analysis
Ecological niches
Flowers & plants
Geographical distribution
Manganese
Marion Island
niche specificity
Niches
Nutrients
Plant species
Plants
Plants (botany)
Rainfall
Range extension
range shift
Regression analysis
Soil depth
Soil nutrients
Soil properties
Soil temperature
Soils
Specialization
Species
species distribution models
Substrates
Topography
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Summary:Extreme changes in temperature, rainfall and wind regimes have been correlated with plant species range expansion upslope on sub‐Antarctic islands. Ongoing climatic changes are expected to continue driving changes in species distributions globally, but niche specialisations may limit the capacity for range shifts. We hypothesised that non‐climatic characteristics of ecological niches of vascular plant species could limit climate induced range shifts. We determined the altitudinal ranges of vascular plant species (n = 13) on sub‐Antarctic Marion Island and measured air temperature, topographic, foliar and soil properties along transects on geologically distinct substrates. Climatic and non‐climatic associations were determined using multiple linear regression and boosted regression tree (BRT) analyses. The degree of niche specialisation was determined using outlying mean index analysis within the range of species on the island. Several species (7 of 13) exhibited niche‐specialisation. Correlation analysis revealed that edaphic properties including soil depth, loss on ignition, the principal component of most soil nutrients (Mg, Cl, K, Ca, Cu, Zn, P, S), Si, Mn and clay dominated the BRT prediction of overall plant cover. Although air temperature was correlated with plant cover in linear models, model simplification dropped temperature in both BRT and linear models. As a consequence, multiple determinants, including temperature, climate, topography and soils control the distribution of vascular plant species on this sub‐Antarctic island. Edaphic and topographic factors is likely to limit range‐shifts of specialised vascular plant species and could limit their survival when climate change drives them beyond the extent of their particular ecological niches. Resilience of such species is likely poorly predicted by distribution models that depend heavily on climate rather than less labile non‐climatic factors. Read the free Plain Language Summary for this article on the Journal blog. Read the free Plain Language Summary for this article on the Journal blog.
ISSN:0269-8463
1365-2435
DOI:10.1111/1365-2435.14123