An island view of endemic rarity—Environmental drivers and consequences for nature conservation
Date
2017Abstract
Aim: Rarity—an important measure for conservation biogeography—can vary over
many orders of magnitude. However, it is unclear which regional-scale
abiotic conditions
drive processes affecting rarity of endemic species on islands. To support conservation
efforts, we (1) assess the main abiotic drivers of endemic rarity, (2) determine
how well existing protected areas (PAs) coincide with hotspots of endemic rarity and
(3) introduce and evaluate a new hypervolume-based
rarity estimator.
Location: La Palma (Canary Islands).
Methods: We recorded all present endemic vascular plant species in 1,212 plots covering
the entire island. We calculated endemic rarity (corrected range-rarity
richness
for endemics) using a rarity estimation approach based on kernel density estimations
(hypervolume approach). We performed a sensitivity analysis based on multiple linear
regressions and relative importance estimations of environmental drivers to estimate
the performance of the hypervolume-based
rarity estimation compared to standard
methods (occurrence frequency, convex hulls, alpha hulls).
Results: Climate variables (mean annual temperature, climatic rarity, precipitation variability)
best explained archipelago endemic (AE) and single-island
endemic (SIE) rarity.
Existing PAs covered the majority of AE and SIE rarity, especially national and natural
parks as well as the Natura 2000 sites. In our study system, hypervolumes performed
better than standard measures of range size.
Main conclusion: Both AE and SIE rarity on La Palma show a clear spatial pattern, with
hotspots of endemic rarity found at high elevations and in rare climates, presumably
owing to geographical and climatic constraints and possibly anthropogenic pressure
(e.g., land use, introduced herbivores, fire). Areas of high rarity estimates coincide with
the distribution and extent of PAs on La Palma, especially since the recent addition of
the Natura 2000 sites. The hypervolume approach is a promising tool to estimate species
range sizes, and can be applied on all scales where point/plot data are available.