Graph embedding and transfer learning can help predict potential species interaction networks despite data limitations

Tanya Strydom; Salomé Bouskila; Francis Banville; Ceres Barros; Dominique Caron; Maxwell J. Farrell; Marie‐Josée Fortin; Benjamin Mercier; Laura J. Pollock; Rogini Runghen; Giulio V. Dalla Riva; Timothée Poisot

doi:10.1111/2041-210X.14228

Methods in Ecology and Evolution (Dec 2023)

Graph embedding and transfer learning can help predict potential species interaction networks despite data limitations

Tanya Strydom,
Salomé Bouskila,
Francis Banville,
Ceres Barros,
Dominique Caron,
Maxwell J. Farrell,
Marie‐Josée Fortin,
Benjamin Mercier,
Laura J. Pollock,
Rogini Runghen,
Giulio V. Dalla Riva,
Timothée Poisot

Affiliations

Tanya Strydom: Département de Sciences Biologiques Université de Montréal Montréal Quebec Canada
Salomé Bouskila: Département de Sciences Biologiques Université de Montréal Montréal Quebec Canada
Francis Banville: Département de Sciences Biologiques Université de Montréal Montréal Quebec Canada
Ceres Barros: Department of Forest Resources Management University of British Columbia Vancouver British Columbia Canada
Dominique Caron: Quebec Centre for Biodiversity Science Montréal Quebec Canada
Maxwell J. Farrell: Department of Ecology & Evolutionary Biology University of Toronto Toronto Ontario Canada
Marie‐Josée Fortin: Department of Ecology & Evolutionary Biology University of Toronto Toronto Ontario Canada
Benjamin Mercier: Quebec Centre for Biodiversity Science Montréal Quebec Canada
Laura J. Pollock: Quebec Centre for Biodiversity Science Montréal Quebec Canada
Rogini Runghen: Centre for Integrative Ecology, School of Biological Sciences University of Canterbury Canterbury New Zealand
Giulio V. Dalla Riva: School of Mathematics and Statistics University of Canterbury Canterbury New Zealand
Timothée Poisot: Département de Sciences Biologiques Université de Montréal Montréal Quebec Canada

DOI: https://doi.org/10.1111/2041-210X.14228
Journal volume & issue: Vol. 14, no. 12
pp. 2917 – 2930

Abstract

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Abstract Metawebs (networks of potential interactions within a species pool) are a powerful abstraction to understand how large‐scale species interaction networks are structured. Because metawebs are typically expressed at large spatial and taxonomic scales, assembling them is a tedious and costly process; predictive methods can help circumvent the limitations in data deficiencies, by providing a first approximation of metawebs. One way to improve our ability to predict metawebs is to maximize available information by using graph embeddings, as opposed to an exhaustive list of species interactions. Graph embedding is an emerging field in machine learning that holds great potential for ecological problems. Here, we outline how the challenges associated with inferring metawebs line‐up with the advantages of graph embeddings; followed by a discussion as to how the choice of the species pool has consequences on the reconstructed network, specifically as to the role of human‐made (or arbitrarily assigned) boundaries and how these may influence ecological hypotheses.

Published in Methods in Ecology and Evolution

ISSN: 2041-210X (Online)
Publisher: Wiley
Country of publisher: United Kingdom
LCC subjects: Science: Biology (General): Ecology; Science: Biology (General): Evolution
Website: https://besjournals.onlinelibrary.wiley.com/journal/2041210X

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