Abstract
Glacial relicts, especially those with very narrow habitat requirements, are particularly affected by global warming. We considered Papaver occidentale, a glacial relict endemic to the Western Prealps, belonging to the alpine poppy complex (P. alpinum aggr.), as a model taxon to study the actual status and potential future distribution of species restricted to particular microrefugia. For this study, all known localities were visited, each population was georeferenced and the number of individuals was estimated. Species Distribution Modelling (SDM) was used to evaluate the present and future potential distribution range and habitat suitability, taking into account the specificity of its habitat (calcareous screes). According to our study, there are globally 19 natural populations of P. occidentale, and a total of about 30,000 individuals. The taxon is a highly specialized alpine plant growing in the majority of natural sites between 1900 and 2100 m a.s.l. on north-facing screes. Predictions for the end of the 21st century indicate that a suitable area will significantly decrease (0–30% remaining). Under the most severe climatic scenarios (RCP 8.5), the species risks complete extinction. The long-term in situ conservation of P. occidentale, and all other taxa of the P. alpinum complex, is unlikely to be achieved without slowing global climate change. More generally, our fine-scale study shows that local environmental buffering of large-scale climate change in high-mountain flora may be very limited in specialised taxa of patchy environments such as screes.
Highlights
Understanding how species respond to climate change is a major challenge of conservation biology [1]
P. occidentale belongs to the alpine poppy complex Papaver alpinum s.l., which is distributed in small isolated regions all across the Alps and neighbouring mountain ranges [24,30,31]
The present study aims at answering the following questions: (1) What is the present global distribution of Papaver occidentale? (2) What are the population sizes in different regions across its distribution area? (3) What are the ecological preferences of the species? we aimed at applying Species Distribution Modelling (SDM) based on the collected occurrence data, to (4)
Summary
Understanding how species respond to climate change is a major challenge of conservation biology [1] This is especially the case for high mountain plants, and glacial relicts inhabiting European Alps [2,3,4]. P. occidentale belongs to the alpine poppy complex Papaver alpinum s.l., which is distributed in small isolated regions all across the Alps and neighbouring mountain ranges [24,30,31]. Distribution Modelling (SDM) combines species’ current natural occurrence data and environmental variables to estimate the geographic range of suitable habitats in the past, present, and future [40,41,42,43] It has been widely applied in conservation biology to predict potential shifts in geographic ranges in response to climate changes, e.g., [44].
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