A New Approach to Evaluate and Reduce Uncertainty of Model-Based Biodiversity Projections for Conservation Policy Formulation

Myers, Bonnie J. E.; Weiskopf, Sarah R.; Shiklomanov, Alexey; Ferrier, Simon; Weng, Ensheng; Casey, Kimberly A.; Harfoot, Mike; Jackson, Stephen T.; Leidner, Allison K.; Lenton, Timothy M.; Luikart, Gordon; Matsuda, Hiroyuki; Pettorelli, Nathalie; Rosa, Isabel M.D.; Ruane, Alex C.; Senay, Gabriel B.; Serbin, Shawn P.; Tittensor, Derek P.; Beard, T. Douglas

doi:10.1093/biosci/biab094

Cited by 9 publications

(3 citation statements)

References 54 publications

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“…However, to effectively support decision making, it is crucial to understand and quantify how uncertainty resulting from decisions made during the modeling process (Myers et al, 2021) impact genomic offset-based forecasts. Although uncertainty in modeling decisions cannot ultimately be eliminated, careful sensitivity analysis of which components have the greatest influence on the predictions together with examination of spatial patterns of uncertainty can help with management decisions (Hagerman et al, 2010;Langford et al, 2011;Ramalho et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Assessing uncertainty in genomic offset forecasts from landscape genomic models (and implications for restoration and assisted migration)

et al. 2023

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IntroductionEcological genomic models are increasingly used to guide climate-conscious restoration and conservation practices in the light of accelerating environmental change. Genomic offsets that quantify the disruption of existing genotype–environment associations under environmental change are a promising model-based tool to inform such measures. With recent advances, potential applications of genomic offset predictions include but are not restricted to: (1) assessing in situ climate risks, (2) mapping future habitat suitability while accounting for local adaptations, or (3) selecting donor populations and recipient areas that maximize genomic diversity and minimize maladaptation to future environments in assisted migration planning. As for any model-based approach, it is crucial to understand how arbitrary decisions made during the modeling process affect predictions and induce uncertainty.MethodsHere, we present a sensitivity analysis of how various modeling components influence forecasts of genomic offset-based metrics, using red spruce (Picea rubens), a cool-temperate tree species endemic to eastern North America, as a case study. We assess the effects of genomic marker set, climatic predictor set, climate change scenario, and “not-to-exceed” offset threshold and evaluate how uncertainty in predictions varies across space.ResultsClimate change scenario induced by far the largest uncertainty to our forecasts; however, the choice of predictor set was also important in regions of the Southern and Central Appalachians that are of high relevance for conservation and restoration efforts. While much effort is often expended in identifying candidate loci, we found that genomic marker set was of minor importance. The choice of a maximum offset threshold to limit transfers between potential donor and recipient locations in assisted migration programs has mostly affected the magnitude rather than geographic variation in our predictions.DiscussionOverall, our model forecasts suggest high climate change risks across the entire distributional range of red spruce and strongly underscore the potential for assisted migration to help ameliorate these risks. In that regard, populations in the Southern and Central Appalachians as well as along the US and Canadian east coast seem the best candidates for both in situ conservation and relocation.

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Section: Introductionmentioning

confidence: 99%

Assessing uncertainty in genomic offset forecasts from landscape genomic models (and implications for restoration and assisted migration)

et al. 2023

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“…Conservation activities have been undertaken in many places around the world aiming to reduce the current rate of extinction (Leclère et al, 2020;Mokany et al, 2020). Spatial mapping of plant biodiversity helps with a better understanding of the distribution and temporal trends of plant species richness, facilitating effective policy making in environmental conservation and restoration (Stevenson et al, 2021;Myers et al, 2021;De Palma et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Plant species richness prediction from DESIS hyperspectral data: A comparison study on feature extraction procedures and regression models

Guo¹,

Mokany²,

Ong³

et al. 2023

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The diversity of terrestrial vascular plants plays a key role in maintaining the stability and productivity of ecosystems. Monitoring species compositional diversity across large spatial scales is challenging and time consuming. Airborne hyperspectral imaging has shown promise for measuring plant diversity remotely, but to operationalise these efforts over large regions we need to advance satellite-based alternatives. The advanced spectral and spatial specification of the recently launched DESIS (the DLR Earth Sensing Imaging Spectrometer) instrument provides a unique opportunity to test the potential for monitoring plant species diversity with spaceborne hyperspectral data. This study provides a quantitative assessment on the ability of DESIS hyperspectral data for predicting plant species richness in two different habitat types in southeast Australia. Spectral features were first extracted from the DESIS spectra, then regressed against on-ground estimates of plant species richness, with a two-fold cross validation scheme to assess the predictive performance. We tested and compared the effectiveness of Principal Component Analysis (PCA), Canonical Correlation Analysis (CCA), and Partial Least Squares analysis (PLS) for feature extraction, and Kernel Ridge Regression (KRR), Gaussian Process Regression (GPR), and Random Forest Regression (RFR) for species richness prediction. The best prediction results were r = 0.76 and RMSE = 5.89 for the Southern Tablelands region, and r = 0.68 and RMSE = 5.95 for the Snowy Mountains region. Relative importance analysis for the DESIS spectral bands showed

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“…global information products and indicators for assessing biodiversity change, are designed to set unifying standards for monitoring and modelling important biodiversity parameters. Species populations EBVs (Jetz et al ., 2019) describe the abundance and occurrence of species across space and time, providing a conceptual nexus and methodological framework for guiding data collection, integration, and modelling to deliver the predictions needed for invasion research, policy, and management (McGeoch & Jetz, 2019; Myers et al ., 2021). EBVs are used to overcome data gaps and biases, and deliver predictions of species' spatial dynamics at appropriate resolutions, and consequently are strongly aligned with the needs of proactive IAS management and invasion forecasting (Battini et al ., 2019).…”

Section: Introductionmentioning

confidence: 99%

A framework to integrate innovations in invasion science for proactive management

et al. 2022

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Invasive alien species (IAS) are a rising threat to biodiversity, national security, and regional economies, with impacts in the hundreds of billions of U.S. dollars annually. Proactive or predictive approaches guided by scientific knowledge are essential to keeping pace with growing impacts of invasions under climate change. Although the rapid development of diverse technologies and approaches has produced tools with the potential to greatly accelerate invasion research and management, innovation has far outpaced implementation and coordination. Technological and methodological syntheses are urgently needed to close the growing implementation gap and facilitate interdisciplinary collaboration and synergy among evolving disciplines. A broad review is necessary to demonstrate the utility and relevance of work in diverse fields to generate actionable science for the ongoing invasion crisis. Here, we review such advances in relevant fields including remote sensing, epidemiology, big data analytics, environmental DNA (eDNA) sampling, genomics, and others, and present a generalized framework for distilling existing and emerging data into products for proactive IAS research and management. This integrated workflow provides a pathway for scientists and practitioners in diverse disciplines to contribute to applied invasion biology in a coordinated, synergistic, and scalable manner.

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A New Approach to Evaluate and Reduce Uncertainty of Model-Based Biodiversity Projections for Conservation Policy Formulation

Cited by 9 publications

References 54 publications

Assessing uncertainty in genomic offset forecasts from landscape genomic models (and implications for restoration and assisted migration)

Assessing uncertainty in genomic offset forecasts from landscape genomic models (and implications for restoration and assisted migration)

Plant species richness prediction from DESIS hyperspectral data: A comparison study on feature extraction procedures and regression models

A framework to integrate innovations in invasion science for proactive management

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