Spatiotemporal shifts in distribution of a recolonizing black bear population

McFadden-Hiller, Jamie E.; Belant, Jerrold L.

doi:10.1002/ecs2.2375

Cited by 7 publications

(9 citation statements)

References 70 publications

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“…Another potential problem from not differentiating between sexes is over‐ or underestimation of smaller scale presence–environment relationships. Previous species distribution models developed in Missouri from citizen reported black bear sightings found a strong positive effect of roads and negligible effect of forested areas (McFadden‐Hiller & Belant, ), which contrasts with our results. Missouri bear sightings are likely male‐biased due to males moving larger distances (Gantchoff et al, ) and more likely to occur in human‐modified areas (this study).…”

Section: Discussioncontrasting

confidence: 99%

Conservation implications of sex‐specific landscape suitability for a large generalist carnivore

Gantchoff

Conlee

Belant

2019

Diversity and Distributions

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Aim: Terrestrial mammal distribution models typically do not differentiate between sexes when making spatial predictions, which could have important conservation implications. As male carnivores are usually more risk tolerant and travel longer distances, male potential range should be larger and include more human-modified areas than female range. To evaluate if differences between females and males could influence their conservation planning, we quantified sex-specific suitable range for a recolonizing population of American black bears (Ursus americanus). Location:We applied this method in Missouri, USA. Methods:We collected telemetry data from 57 females and 43 male bears from 2010 to 2018. We used three machine-learning methods (generalized boosted regression, random forest and maximum entropy) to develop sex-specific distribution models, which were combined into a weighted average ensemble model and converted into a binary (presence/absence) model using an optimized threshold. We used 80% of individuals for each sex as training data, and 20% as evaluation data. Results:All models had high predictive performance; the greatest uncertainty in model predictions corresponded with the periphery of the distributions, whereas there was high agreement in the core distribution. Male suitable range was 66% larger than female range, and males were predicted to occur in more human-modified areas and more likely to be present in developed land and agriculture.Main conclusions: Distribution models based on data from both sexes, or that is male-biased, could overestimate the female (i.e., reproductive) range and potentially misrepresent the biologically relevant species distribution. This bias can potentially lead to misguided decisions and suboptimal use of resources. By improving models when sex-specific data are available, we can better focus resources in areas where there is reproductive potential, leading to more accurate assessments of species' conservation status and better identifying areas vital for species persistence. K E Y W O R D Scarnivore, habitat suitability, mammal, range, sex-specific, spatial ecology, species distribution model, ursid | 1489 GANTCHOFF eT Al.

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Section: Discussioncontrasting

confidence: 99%

Conservation implications of sex‐specific landscape suitability for a large generalist carnivore

Gantchoff

Conlee

Belant

2019

Diversity and Distributions

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“…This sampling bias is a result of suitability being overestimated in areas near roads (due to greater “sampling” intensity; McFadden‐Hiller & Belant, 2018; Warton et al, 2013). Similarly, a previous study modeled bear range distribution and expansion in this area also using public reports (1991–2015), but even after implementing different spatial correction methods, a consistent positive relationship with roads remained (McFadden‐Hiller & Belant, 2018). Other alternatives to account for sampling bias include incorporating road biases as a covariate in models (Warton et al, 2013) or aggregating records at coarser scales (Elith et al, 2011; Fourcade et al, 2014).…”

Section: Discussionmentioning

confidence: 99%

“…To test whether the simple step of excluding road covariates can increase the similarity between opportunistic data‐based models and professional data‐based models, each of the three report‐based data sets (unfiltered, filtered, and verified) and the telemetry data set were modeled twice, once including the two road covariates (distance to major and minor roads) and once without. Our modeling approach and bias correction methods were informed in part by a previous study in this area, which modeled black bear range using older public reports (1991–2015) and evaluated several methods to mitigate sampling bias (e.g., spatial filtering, restricting background locations, and road exclusion; McFadden‐Hiller & Belant, 2018).…”

Section: Methodsmentioning

confidence: 99%

“…We present a unique approach that compares mapping results from telemetry data and public reports for a large carnivore, American black bear ( Ursus americanus ) in Missouri (USA). Our objective was to investigate whether distribution models developed using opportunistic public‐gathered data are congruent with those developed using professional (i.e., GPS telemetry) data, while evaluating two strategies to remove common biases in opportunistic data and improve the similarity with the professional model: data filtering and covariate removal (McFadden‐Hiller & Belant, 2018; Steen et al, 2019). We assume results from the telemetry models to better approximate the “true” black bear distribution, as the locations are largely free from human‐derived observation biases.…”

Section: Introductionmentioning

confidence: 99%

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The effectiveness of opportunistic public reports versus professional data to estimate large carnivore distribution

2022

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Species distribution models are key to spatially explicit conservation and management plans. Modeling distributions using data collected by the public has become increasingly popular; however, it is vital to evaluate their advantages and limitations. We investigated whether distribution models developed using opportunistic data (public reports) are congruent with those developed using professional data, while evaluating two strategies to remove spatial biases: data filtering and covariate removal. We compared GPS telemetry data (598 locations, 2010-2018) with public reports (1384 locations, 2016-2019) of American black bears (Ursus americanus) in Missouri (USA). Reports were subdivided into unfiltered reports, filtered reports (more reliable), and verified reports (confirmed by state agency staff). Each data set was modeled twice, with and without road covariates. Each distribution model was an ensemble of three machine-learning methods. Models using filtered or verified reports and excluding road covariates were most similar to the telemetry model, both in spatial extent and spatial suitability patterns.However, the report-derived distributions included several times more agriculture and developed land. The inclusion of roads resulted in spurious patterns and consistently reduced the predicted distribution area by ~10%.Elevation and vegetation productivity were consistently selected as the most important variables, regardless of data source and covariates included in models, but the report-derived distributions included more agriculture and developed lands. Filtering data for reliability and removing covariates related to spatial biases resulted in models suitable to estimate broad black bear distribution, though differences remained that could represent different segments of the bear population (e.g., dispersing vs. established). Verification was not essential to develop suitable models if reports are filtered for reliability, important for areas that lack professionally collected data to model species distributions.

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“…Reintroduced species could expand outside the protected areas where they were introduced (Smeraldo et al., 2017), requiring rangers and decision‐makers to engage with local communities to generate awareness and support (Karamanlidis et al., 2016). Natural and unnatural barriers, such as topographic changes or roads, could inhibit a reintroduced species' expansion (Engler et al., 2012; McFadden‐Hiller & Belant, 2018). Furthermore, mapping a species' potential range requires understanding and proper handling of predictive model limitations, for example, how much extrapolation to allow into new regions (Elith et al., 2010) or a model's inability to account for environmental conditions that are non‐existent in a species' current range but become important as the species expands its range (Leroux et al., 2017; Swinnen et al., 2017).…”

Section: Introductionmentioning

confidence: 99%

Integrated SDM database: Enhancing the relevance and utility of species distribution models in conservation management

Frans

Augé²,

Fyfe³

et al. 2021

Methods Ecol Evol

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1. Species' ranges are changing at accelerating rates. Species distribution models (SDMs) are powerful tools that help rangers and decision-makers prepare for reintroductions, range shifts, reductions and/or expansions by predicting habitat suitability across landscapes. Yet, range-expanding or -shifting species in particular face other challenges that traditional SDM procedures cannot quantify, due to large differences between a species' currently occupied range and potential future range. The realism of SDMs is thus lost and not as useful for conservation management in practice. Here, we address these challenges with an extended assessment of habitat suitability through an integrated SDM database (iSDMdb).2. The iSDMdb is a spatial database of predicted sites in a species' prediction range, derived from SDM results, and is a single spatial feature that contains additional, user-friendly data fields that synthesise and summarise SDM predictions and uncertainty, human impacts, restoration features, novel preferences in novel spaces and management priorities. To illustrate its utility, we used the endangered New Zealand sea lion Phocarctos hookeri. We consulted with wildlife rangers, decisionmakers and sea lion experts to supplement SDM predictions with additional, more realistic and applicable information for management.3. Almost half the data fields included in this database resulted from engaging with these end-users during our study. The SDM found 395 predicted sites. However, the iSDMdb's additional assessments showed that the actual suitability of most sites (90%) was questionable due to human impacts. >50% of sites contained unnatural barriers (fences, grazing grasslands), and 75% of sites had roads located within the species' range of inland movement. Just 5% of the predicted sites were mostly (>80%) protected.4. Integrating SDM results with supplemental assessments provides a way to address SDM limitations, especially for range-expanding or -shifting species. SDM products for conservation applications have been critiqued for lacking transparency and interpretation support, and ineffectively communicating uncertainty.This is an open access article under the terms of the Creat ive Commo ns Attri bution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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Spatiotemporal shifts in distribution of a recolonizing black bear population

Cited by 7 publications

References 70 publications

Conservation implications of sex‐specific landscape suitability for a large generalist carnivore

Conservation implications of sex‐specific landscape suitability for a large generalist carnivore

The effectiveness of opportunistic public reports versus professional data to estimate large carnivore distribution

Integrated SDM database: Enhancing the relevance and utility of species distribution models in conservation management

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