Abstract
Assessments of risk to biodiversity often rely on spatial distributions of species and ecosystems. Range-size metrics used extensively in these assessments, such as area of occupancy (AOO), are sensitive to measurement scale, prompting proposals to measure them at finer scales or at different scales based on the shape of the distribution or ecological characteristics of the biota. Despite its dominant role in red-list assessments for decades, appropriate spatial scales of AOO for predicting risks of species' extinction or ecosystem collapse remain untested and contentious. There are no quantitative evaluations of the scale-sensitivity of AOO as a predictor of risks, the relationship between optimal AOO scale and threat scale, or the effect of grid uncertainty. We used stochastic simulation models to explore risks to ecosystems and species with clustered, dispersed, and linear distribution patterns subject to regimes of threat events with different frequency and spatial extent. Area of occupancy was an accurate predictor of risk (0.81<|r|<0.98) and performed optimally when measured with grid cells 0.1-1.0 times the largest plausible area threatened by an event. Contrary to previous assertions, estimates of AOO at these relatively coarse scales were better predictors of risk than finer-scale estimates of AOO (e.g., when measurement cells are <1% of the area of the largest threat). The optimal scale depended on the spatial scales of threats more than the shape or size of biotic distributions. Although we found appreciable potential for grid-measurement errors, current IUCN guidelines for estimating AOO neutralize geometric uncertainty and incorporate effective scaling procedures for assessing risks posed by landscape-scale threats to species and ecosystems.
Highlights
As life on Earth erodes unabated, a reliable understanding of the risks to biodiversity becomes ever more imperative to inform effective conservation action
We used simulation models to explore the sensitivity of estimates of area of occupancy (AOO) to geometric uncertainty; the ability of AOO estimated at a given spatial scale to predict risks to biodiversity across a range of distribution types and threat regimes; how the predictive performance of AOO varies with the spatial scale at which it is estimated; and whether there is an optimal scale for estimating AOO that maximizes its predictive performance, taking into account the spatial properties of both biological distributions and threat regimes
The statistical distribution of AOO estimates differed depending on the pattern and extent of a biological distribution
Summary
As life on Earth erodes unabated, a reliable understanding of the risks to biodiversity becomes ever more imperative to inform effective conservation action. The International Union for Conservation of Nature (IUCN) Red List criteria for assessing risks to both species and ecosystems incorporate simple range-size metrics to identify what is most at risk. Despite the dominant role of range-size metrics in redlist assessments since the 1990s, the factors that influence their performance as predictors of risk to biodiversity have not been evaluated systematically. We empirically assessed the performance of area of occupancy (AOO), the most contentious of the standard range-size metrics for predicting risks to biodiversity (Simaika & Samways 2010; Cardoso et al 2011; Gigante et al 2016). Our analyses represent the first comprehensive assessment of scale-sensitivity in AOO as a predictor of risks to biodiversity
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