Moving beyond presence and absence when examining changes in species distributions

Ashcroft, Michael B.; King, Diana H.; Raymond, Ben; Turnbull, Johanna D.; Wasley, Jane; Robinson, Sharon A.

doi:10.1111/gcb.13628

Cited by 31 publications

(34 citation statements)

References 52 publications

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“…Quantifying shifts in species range boundaries is an important priority for species redistribution science (Bonebrake et al., ), yet difficulty identifying ranges edges from observational data make distinguishing shifts problematic (Ashcroft et al., ). For example, range boundaries determined directly from occurrence data are sensitive to sampling intensity (Brown et al., ), and variation in sampling effort through time can lead to incorrectly inferring range edge shifts (Bates et al., ; Hassall & Thompson, ).…”

Section: Discussionmentioning

confidence: 99%

“…Mapped indices of habitat suitability have previously been used to identify species core habitats (Hill, Tobin, Reside, Pepperell, & Bridge, ), but are rarely used to identify shifts in the range boundaries of marine species (but see Robinson, Gledhill, et al., ). Combining spatial predictions of species’ probability of occurrence from SDMs with sampling effort information has recently proved useful for identifying range boundaries for terrestrial species based on minimum relative abundance values (Ashcroft et al., ). When sampling effort is unknown, independent species occurrence data may be compared with spatial predictions from SDMs to define range boundaries or habitat edges in terms of a threshold probability of occurrence or a minimum habitat suitability value (Champion, Hobday, Zhang, Pecl, & Tracey, ).…”

Section: Introductionmentioning

confidence: 99%

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Rapid shifts in distribution and high‐latitude persistence of oceanographic habitat revealed using citizen science data from a climate change hotspot

Champion

Hobday

Tracey

et al. 2018

Global Change Biology

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The environmental effects of climate change are predicted to cause distribution shifts in many marine taxa, yet data are often difficult to collect. Quantifying and monitoring species' suitable environmental habitats is a pragmatic approach for assessing changes in species distributions but is underdeveloped for quantifying climate change induced range shifts in marine systems. Specifically, habitat predictions present opportunities for quantifying spatiotemporal distribution changes while accounting for sources of natural climate variation. Here we demonstrate the utility of a marine-based habitat model parameterized using citizen science data and remotely sensed environmental covariates for quantifying shifts in oceanographic habitat suitability over 22 years for a coastal-pelagic fish species in a climate change hotspot. Our analyses account for the effects of natural intra- and interannual climate variability to reveal rapid poleward shifts in core (94.4 km/decade) and poleward edge (108.8 km/decade) oceanographic habitats. Temporal persistence of suitable oceanographic habitat at high latitudes also increased by approximately 3 months over the study period. Our approach demonstrates how marine citizen science data can be used to quantify range shifts, but necessitates shifting focus from species distributions directly, to the distribution of species' environmental habitat preferences.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Rapid shifts in distribution and high‐latitude persistence of oceanographic habitat revealed using citizen science data from a climate change hotspot

Champion

Hobday

Tracey

et al. 2018

Global Change Biology

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“…This measure provides an estimate of variation explained between abundance and suitability. Lastly, previous studies have suggested that abundance–suitability relationships may be difficult to detect if variance in abundance estimates is too low (Ashcroft et al, ). That is, low variance and background noise in population abundance estimation could lead to type II errors.…”

Section: Methodsmentioning

confidence: 99%

Habitat suitability estimated by niche models is largely unrelated to species abundance

Dallas

Hastings

2018

Global Ecol Biogeogr

116

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Aim Data on species occurrences are far more common than data on species abundances. However, a central goal of large‐scale ecology is to understand the spatial distribution of abundance. It has been proposed that species distribution models trained on species occurrence records may capture variation in species abundance. Here, we gauge support for relationships between species abundance and predicted climatic suitability from species distribution models, and relate the slope of this relationship to species traits, evolutionary relationships and sampling completeness. Location USA. Time period 1658–2017. Major taxa studied Mammal and tree species. Methods, Results To explore the generality of abundance–suitability relationships, we trained species distribution models on species occurrence and species abundance data for 246 mammal species and 158 tree species, and related model‐predicted occurrence probabilities to population abundance predictions. Further, we related the resulting abundance–suitability relationship coefficients to species traits, geographic range sizes, evolutionary relationships and the number of occurrence records to investigate a potential trait or sampling basis for abundance–suitability relationship detectability. We found little evidence for consistent abundance–suitability relationships in mammal (truerfalse¯ = .045) or tree (truerfalse¯ = −.005) species, finding nearly as many negative and positive relationships. These relationships had little explanatory power, and coefficients were unrelated to species traits, range size or evolutionary relationships. Main conclusions Our findings suggest that species climatic suitability based on occurrence data may not be reflected in species abundances, suggesting a need to investigate nonclimatic sources of species abundance variation.

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“…This would be an important step forward to investigate macroecological patterns (McGill & Collins, ), such as species abundance distributions (McGill et al, ; Xiao, O'Dwyer, & White, ), biomass distribution (Hatton et al, ) or range size–abundance relationships (Gaston et al, ). Understanding the spatial patterns of abundance would allow conservation biologists to identify regions within species distributions where viability is low (Di Marco et al, ; Hilbers et al, ) and contribute to forecasting the responses of species to climate change, assuming space for time substitution as done in species distribution modelling (Ashcroft et al, ). Finally, estimates of species abundance over large geographical scales and for multiple species would permit description of the change in a number of biodiversity measures (e.g., heterogeneity indices, functional or phylogenetic diversity metrics weighted by species relative abundance) over time and space (Schipper et al, ).…”

Section: Introductionmentioning

confidence: 99%

Global drivers of population density in terrestrial vertebrates

Santini

Isaac

Maiorano

et al. 2018

Global Ecol Biogeogr

122

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Aim: Although the effects of life history traits on population density have been investigated widely, how spatial environmental variation influences population density for a large range of organisms and at a broad spatial scale is poorly known. Filling this knowledge gap is crucial for global species management and conservation planning and to understand the potential impact of environmental changes on multiple species. Location: Global.Time period: Present.Major taxa studied: Terrestrial amphibians, reptiles, birds and mammals.Methods: We collected population density estimates for a range of terrestrial vertebrates, including 364 estimates for amphibians, 850 for reptiles, 5,667 for birds and 7,651 for mammals. We contrasted the importance of life history traits and environmental predictors using mixed models and tested different hypotheses to explain the variation in population density for the four groups.We assessed the predictive accuracy of models through cross-validation and mapped the partial response of vertebrate population density to environmental variables globally.Results: Amphibians were more abundant in wet areas with high productivity levels, whereas reptiles showed relatively higher densities in arid areas with low productivity and stable temperatures.The density of birds and mammals was typically high in temperate wet areas with intermediate levels of productivity. The models showed good predictive abilities, with pseudo-R 2 ranging between 0.68 (birds) and 0.83 (reptiles).Main conclusions: Traits determine most of the variation in population density across species, whereas environmental conditions explain the intraspecific variation across populations. Species traits, resource availability and climatic stability have a different influence on the population density of the four groups. These models can be used to predict the average species population density over large areas and be used to explore macroecological patterns and inform conservation analyses.abundance, amphibians, birds, mammals, population density, reptiles | I NTR OD U CTI ONPopulation density is one of the key demographic parameters determining the dynamics of populations. Clearly, it also represents a crucial information for conservation planning as it is a direct proxy for extinction risk (Brown, Mehlman, & Stevens, 1995;Currie & Fritz, 1993;Sanderson, 2006). In a macroecological context, research has mostly focused on the biological predictors of average population density per 968 |

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Moving beyond presence and absence when examining changes in species distributions

Cited by 31 publications

References 52 publications

Rapid shifts in distribution and high‐latitude persistence of oceanographic habitat revealed using citizen science data from a climate change hotspot

Rapid shifts in distribution and high‐latitude persistence of oceanographic habitat revealed using citizen science data from a climate change hotspot

Habitat suitability estimated by niche models is largely unrelated to species abundance

Global drivers of population density in terrestrial vertebrates

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