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Introduction to sabinaNSDM

6 de October de 2024

Introduction to sabinaNSDM: A new R package to improve species distribution models based on spatially nested hierarchical models

Teresa Goicolea, Alejandra Zarzo

Species Distribution Models (SDMs) are essential tools for scientists and conservationists to predict where species are likely to be found, where they have existed in the past, and where they may appear in the future. With pressing issues like climate change and biodiversity loss, generating accurate predictions is more important than ever to identify key areas for conservation actions. However, SDMs often face accuracy issues, especially due to niche truncation and environmental extrapolation problems.

This is where the new R package sabinaNSDM comes in. Designed by our research team SABINA, this package uses a new approach to building SDMs, known as spatially nested hierarchical models (N-SDMs). By combining large-scale global patterns with finer regional features, sabinaNSDM allows for more accurate predictions of species distributions. This makes the new package a powerful resource for conservation planning and ecological research.

The problem with traditional SDMs

Standard SDMs present a set of limitations. Most models fall into one of two categories: regional or global.

Regional models focus on specific areas, such as a country or a region. While they can offer detailed information about local conditions, they lack the broader environmental perspective that shapes a species’ distribution. This leads to what is known as niche truncation, where models do not consider the full range of conditions a species experiences across its distribution (i.e., its ecological niche). These spatially restricted models also suffer from a higher proportion of non-analogous conditions, leading to issues when projecting to other areas (e.g., predicting the spread of invasive species) or time periods (e.g., forecasting the impact of climate change on species distribution).
On the other hand, global models cover an entire species’ range but often rely on coarse and low-resolution data. They also typically rely only on bioclimatic variables, as other environmental factors are unavailable at such a large scale, and the species data are often imprecise. As a result, they lack the fine details needed for accurate localized predictions.

The solution: Nested Species Distribution Models (N-SDMs)

Spatially nested hierarchical SDMs (N-SDMs) address these issues by combining the broad perspective of global models with the fine detail of regional models to get the best of both worlds. Global models provide an overview, capturing a species’ full ecological niche across its range, and take into account factors like climate at a coarse resolution. Regional models then focus on finer details, such as land use or microhabitat conditions, and more precise species distribution data, which are usually available for smaller areas, such as at the national level. These fine details are critical for making accurate and high-resolution predictions.

Figure. Advantages (in green) and limitations (in red) of traditional species distribution models (both global and regional scales), compared to the benefits of combining them into a Spatially Nested Species Distribution Model (N-SDM).

Key features of the sabinaNSDM package

sabinaNSDM is designed to make the N-SDM approach more accessible to researchers and conservationists. Here are some of its key features:

Generate N-SDMs: The package combines global and regional models.
Different nesting strategies: Users can choose between two methods for combining models: the covariate approach, which uses the output of the global model as input for the regional model, or the multiple approach, which averages the global and regional predictions.
Consensus models: sabinaNSDM uses consensus models, a technique that combines multiple statistical algorithms to increase prediction reliability and accuracy.
Comprehensive workflow: The package is a tool that integrates (a) background data generation; (b) preparation and spatial filtering of species occurrences (and absences, if available); (c) environmental covariate selection; and (d) N-SDM calibration, evaluation, and projection.
Proven effectiveness: In an applied study on 77 tree and shrub species in the Iberian Peninsula, sabinaNSDM outperformed traditional SDMs, providing more accurate predictions of these species’ distributions.
Open-source and user-friendly: sabinaNSDM is freely available on GitHub, and we are working to make it available on CRAN. The package is designed to be user-friendly, making it accessible to ecologists and conservationists with varying levels of programming experience.

Real-world impact
The ability to accurately model species distributions has real-world consequences, and the improved modeling capabilities of sabinaNSDM can play a crucial role in guiding conservation efforts more effectively. For example, the package can predict how climate change may alter species distributions, guide restoration programs to identify areas with the greatest potential to protect biodiversity, or anticipate the spread of invasive species. One of our key applications has been creating a geoportal that shows the predicted distribution of 200 woody plant species in Spain under current conditions and four future climate scenarios. The geoportal offers practical applications, such as generating lists of shrubs and trees with the highest suitability for specific locations. This can help inform restoration efforts by identifying species most likely to thrive both now and in the future. sabinaNSDM has already demonstrated its potential in our work, and we are excited to see how other researchers and conservationists use it in their projects.

Start using sabinaNSDM

If you are interested in trying sabinaNSDM, you can download the package and explore its features in our GitHub repository. For a deeper dive into how it works, check out our article published in Methods in Ecology and Evolution. We have also included supplementary material and tutorials to help you get started with single or multi-species models. If you are interested in learning more about sabinaNSDM or have any questions, feel free to get in touch.

Course: Practical and Theoretical Approach to Ecological Modeling

6 de October de 2024

We invite you to the course “Practical and Theoretical Approach to Ecological Modeling” organized by the Spanish Botanical Society:

Course Instructor: Rubén G. Mateo, Department of Biology, Autonomous University of Madrid

Research Group: SABINA https://geosabina.com

Course Summary:

In a constantly changing world, understanding and predicting species distribution patterns is essential for biodiversity conservation and natural resource management. This course will provide participants with a comprehensive understanding of the methods and techniques used in ecological modeling. Participants will learn how to generate and apply species distribution models effectively in various research contexts.

Course Syllabus: View PDF.

Requirements:

The course is aimed at researchers and students interested in ecological modeling. Prior knowledge of geographic information systems (GIS), R programming, and statistics is required. It is recommended to have a personal computer with the necessary software and a good internet connection.

Dates and Schedule:

June 10 to 17, 2024

Live online sessions: June 10, 11, 12, 13, 14, and 17, from 9:30 AM to 1:30 PM (CET)

Total course hours: 50 hours

Evaluation:

Attendance at online sessions and presentation of a practical case by each student.

Additional Information:

The course will be taught in Spanish, live and online. A certificate of completion will be issued to participants who successfully complete the course.

Prices:

Standard fee: €270

Student fee: €200

Standard fee for SEBOT members: €200

Student fee for SEBOT members: €150

Pre-registration: https://forms.gle/ApmJfkKAZHrCqkw78

Mapping the Most Suitable Areas for Ecosystem Restoration After a Megafire

6 de October de 2024

In 2022, wildfires devastated around 310,000 hectares of land in Spain, an area five times the size of the city of Madrid. This figure triples the amount of land burned in 2021, and given the ongoing climate crisis, the risk of wildfires is expected to increase in the coming years.

Faced with this situation, decision-makers and forest managers are confronted with an urgent challenge. There is a growing consensus on the need to conserve forests and promote the creation of resilient ecological zones as part of the solution.

Over the past three decades, scientific advances have enabled the development of ecological niche models. These provide maps that identify areas potentially suitable for certain species by statistically correlating known locations of species presence with various variables, including climate and soil type, among others.

Rubén G. Mateo, botanist and academic at the Autonomous University of Madrid (UAM), has worked on calibrating these models at various scales to provide useful information for managing areas devastated by megafires.

“Ecological niche models (ENMs) aim to recreate the relationships between species and their environments, allowing us to identify unexplored areas where these species could potentially exist. While these models are used in various fields of research, such as conservation plans and studies of exotic species, they had not yet been tested for the restoration of areas impacted by megafires,” explains the researcher.

Along with his team and in collaboration with researchers from the Technical University of Madrid (UPM) and the Forest Science Institute (ICIFOR-INIA, CSIC), Mateo has produced precise maps indicating the current and future suitability of certain areas for tree species affected by fires that occurred nearly two decades ago, in 2005. For this, they have considered both the current state of regeneration and projections of a 4.5°C increase in global average temperature by the end of this century.

The climate crisis presents an increasingly variable and dynamic scenario. Changes in rainfall patterns, hailstorms, more intense but less frequent precipitation events, and prolonged droughts are increasing the vulnerability of our forests to megafires. This requires equally dynamic solutions.

“We propose that post-fire restoration plans take into account the effects of climate change on forest regeneration. The use of ENMs can be an effective support tool for forest managers, providing more dynamic restoration plans,” concludes Rubén Mateo.

The findings of this research will be included in the doctoral thesis of Cristina Carrillo (ICIFOR, UPM), who is also researching the effects of burned wood management on the vulnerability of forests to future megafires.

Reference: Carrillo-García, C., Girola-Iglesias, L., Guijarro, M., Hernando, C., Madrigal, J., G. Mateo, R. 2022. Ecological niche models applied to post-megafire vegetation restoration in the context of climate change Science of The Total Environment

doi: 10.1016/j.scitotenv.2022.158858

ForesteCCo. Project

6 de October de 2024

On May 1st, we launched a new project: ForesteCCo. Through this project, funded by the Biodiversity Foundation, a web viewer for forest species adapted to future climate conditions will be developed, among other activities.

Specifically, at the Climate Research Foundation, in addition to coordinating the project, we will develop local future climate scenarios, species distribution models (SDM), a habitat fragmentation analysis, a web viewer, and we will contribute to the development of a guide for climate change adaptation and resilience of green infrastructure.

The International Foundation for Ecosystem Restoration (FIRE) will propose a national-scale connectivity plan and will participate in the development of the guide for climate change adaptation and resilience of green infrastructure, as well as in the definition of the web viewer functionalities.

At the Autonomous University of Madrid, researchers from the SABINA group will contribute to the development of species distribution models (SDM) and the definition of the web viewer functionalities.

INIA will be involved in the collection and analysis of information for the formation of genetic groups of species, habitat fragmentation and connectivity analysis of the Green Infrastructure Network, and the definition of the viewer’s functionalities.

Hierarchical Ecological Models: An Effective Tool for Climate Management

6 de October de 2024

The stability of ecological communities and the conservation of biodiversity, both in Spain and globally, are increasingly threatened by the intense impacts of climate change. Researchers at the Global Biodiversity and Change Research Center at UAM and other institutions are working on the development of hierarchical ecological models, which allow for the measurement of biodiversity vulnerability and, thus, the design of appropriate forest management and restoration strategies.

Viewer of a Hierarchical Ecological Model applied to a specific area in Spain, combining data at different scales

Forests are cornerstones of the European bioeconomy and contribute decisively to mitigating climate change. Their trees, along with the living organisms they coexist with, feed on carbon from the air, storing it in wood, plant matter, and beneath the soil. Without forests and trees, much of that carbon would remain in the atmosphere as carbon dioxide (CO2), a greenhouse gas whose reduction is a critical part of one of humanity’s most pressing challenges: the climate crisis.

The Iberian Peninsula is home to about 50% of Europe’s species of plants and vertebrates. It hosts nearly 6,500 species of vascular plants and one of the highest species diversification rates in the world. However, recent assessments predict an intensification of climate change effects on biodiversity in the region, particularly in Mediterranean climate areas.

Protecting and preserving biodiversity in forest ecosystems is a crucial and urgent challenge in this scenario. Regional forest management and restoration programs require robust information on the composition and spatial patterns of plant species, as well as monitoring conflicts between forest biodiversity conservation and other opposing human interests. This is where ecological models come into play.

Rubén G. Mateo, a botanist and researcher at the Global Biodiversity and Change Research Center at UAM (CIBC-UAM), works on the Connect2restore project, “Towards a national restoration plan considering connectivity and vulnerability to climate change,” which is developing innovative tools for restoring Spanish forests. “We believe these tools can support efficient ecological restoration through optimized and realistic biodiversity forecasting, applied to different scenarios of connectivity and future climate change. This would allow for the development of novel, dynamic restoration plans in the context of climate change, as opposed to the more static restoration plans currently in place,” the researcher says.

The models being developed by the research team gain further strength when used alongside other sources of information, such as field observations, expert criteria, or remote sensing. For this reason, NGOs, foundations, scientific societies, and regional administrations are involved in this project, contributing their concerns and suggestions regarding the necessary requirements for the efficient implementation of these models. At the same time, they incorporate the knowledge provided by these models early on for decision-making.

“We are convinced of the value of building connections and alliances with the public sector, academia, civil society, and other stakeholders. Our project is enriched by their input, helping to create management solutions that are increasingly tailored to current ecosystems, which can then be useful for designing more effective conservation and ecological restoration strategies,” Rubén affirms.

The project’s results will be available on a map server on the website of the SABINA research group (SpatiAl ecology, BiodIversity conservation, and New modelling Approaches), led by Rubén, where any user can download models and gather information about which species are most recommended for use in a local restoration plan in a specific region, considering the dynamic and challenging context of climate change.

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Project Reference:

Connect2restore (TED2021-129589B-I00) is a project funded by the Ministry of Science and Innovation (State Research Agency) and by “European Union NextGenerationEU/PRTR”

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Academic Institutions Participating in this Research:

Autonomous University of Madrid (Rubén G. Mateo, Juan Carlos Moreno, Francisco Lara, Manolo Macía, Juan Antonio Calleja, Teresa Goicolea)

University of Castilla-La Mancha (Virgilio Gómez-Rubio)

University of Córdoba (Manuel de la Estrella)

University of Lausanne (Antoine Guisan, Antoine Adde, Olivier Broenniman)

Polytechnic University of Madrid (Juan Ignacio García Viñas, Aitor Gastón, Pepa Aroca)

University of Valencia (Ricardo Garilleti)

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News Author: Joaquín Acevedo