Your search keyword '"Castilla, Antonio R."' showing total 3 results

1. Integrating genomic data and simulations to evaluate alternative species distribution models and improve predictions of glacial refugia and future responses to climate change.

Author

Naughtin, Sarah R., Castilla, Antonio R., Smith, Adam B., Strand, Allan E., Dawson, Andria, Hoban, Sean, Abhainn, Everett Andrew, Romero‐Severson, Jeanne, and Robinson, John D.

Subjects

*SPECIES distribution, *LAST Glacial Maximum, *ATMOSPHERIC models, *CURRENT distribution, *PREDICTION models, *CLIMATE change

Abstract

Climate change poses a threat to biodiversity, and it is unclear whether species can adapt to or tolerate new conditions, or migrate to areas with suitable habitats. Reconstructions of range shifts that occurred in response to environmental changes since the last glacial maximum (LGM) from species distribution models (SDMs) can provide useful data to inform conservation efforts. However, different SDM algorithms and climate reconstructions often produce contrasting patterns, and validation methods typically focus on accuracy in recreating current distributions, limiting their relevance for assessing predictions to the past or future. We modeled historically suitable habitat for the threatened North American tree green ash Fraxinus pennsylvanica using 24 SDMs built using two climate models, three calibration regions, and four modeling algorithms. We evaluated the SDMs using contemporary data with spatial block cross‐validation and compared the relative support for alternative models using a novel integrative method based on coupled demographic‐genetic simulations. We simulated genomic datasets using habitat suitability of each of the 24 SDMs in a spatially‐explicit model. Approximate Bayesian computation (ABC) was then used to evaluate the support for alternative SDMs through comparisons to an empirical population genomic dataset. Models had very similar performance when assessed with contemporary occurrences using spatial cross‐validation, but ABC model selection analyses consistently supported SDMs based on the CCSM climate model, an intermediate calibration extent, and the generalized linear modeling algorithm. Finally, we projected the future range of green ash under four climate change scenarios. Future projections using the SDMs selected via ABC suggest only minor shifts in suitable habitat for this species, while some of those that were rejected predicted dramatic changes. Our results highlight the different inferences that may result from the application of alternative distribution modeling algorithms and provide a novel approach for selecting among a set of competing SDMs with independent data. [ABSTRACT FROM AUTHOR]

Published

2024

2. Variation and plasticity in life-history traits and fitness of wild Arabidopsis thaliana populations are not related to their genotypic and ecological diversity.

Author

de la Mata, Raul, Mollá-Morales, Almudena, Méndez-Vigo, Belén, Torres-Pérez, Rafael, Oliveros, Juan Carlos, Gómez, Rocío, Marcer, Arnald, Castilla, Antonio R., Nordborg, Magnus, Alonso-Blanco, Carlos, and Picó, F. Xavier

Published

2024

3. Integrative demographic modelling reduces uncertainty in estimated rates of species' historical range shifts.

Author

Castilla, Antonio R., Brown, Alissa, Hoban, Sean, Abhainn, Everett Andrew, Robinson, John D., Romero‐Severson, Jeanne, Smith, Adam B., Strand, Allan E., Tipton, John R., and Dawson, Andria

Subjects

*FOSSIL pollen, *SPECIES distribution, *DATA integration, *SPECIES, *POLLEN

Abstract

Aim: Biogeographers have used three primary data types to examine shifts in tree ranges in response to past climate change: fossil pollen, genetic data and contemporary occurrences. Although recent efforts have explored formal integration of these types of data, we have limited understanding of how integration affects estimates of range shift rates and their uncertainty. We compared estimates of biotic velocity (i.e. rate of species' range shifts) using each data type independently to estimates obtained using integrated models. Location: Eastern North America. Taxon: Fraxinus pennsylvanica Marshall (green ash). Methods: Using fossil pollen, genomic data and modern occurrence data, we estimated biotic velocities directly from 24 species distribution models (SDMs) and 200 pollen surfaces created with a novel Bayesian spatio‐temporal model. We compared biotic velocity from these analyses to estimates based on coupled demographic‐coalescent simulations and Approximate Bayesian Computation that combined fossil pollen and SDMs with population genomic data collected across the F. pennsylvanica range. Results: Patterns and magnitude of biotic velocity over time varied by the method used to estimate past range dynamics. Estimates based on fossil pollen yielded the highest rates of range movement. Overall, integrating genetic data with other data types in our simulation‐based framework reduced apparent uncertainty in biotic velocity estimates and resulted in greater similarity in estimates between SDM‐ and pollen‐integrated analyses. Main Conclusions: By reducing uncertainty in our assessments of range shifts, integration of data types improves our understanding of the past distribution of species. Based on these results, we propose further steps to reach the integration of these three lines of biogeographical evidence into a unified analytical framework. [ABSTRACT FROM AUTHOR]

Published

2024