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Predicting missing links in food webs using stacked models and species traits

 
cris.virtual.department#PLACEHOLDER_PARENT_METADATA_VALUE#
cris.virtual.orcid#PLACEHOLDER_PARENT_METADATA_VALUE#
cris.virtualsource.department643c3540-f094-4667-b0d7-7816633f5c95
cris.virtualsource.orcid643c3540-f094-4667-b0d7-7816633f5c95
dc.contributor.authorVan Kleunen, Lucy
dc.contributor.authorDee, Laura E.
dc.contributor.authorWootton, Kate L.
dc.contributor.authorMassol, Francois
dc.contributor.authorClauset, Aaron
dc.date.accessioned2026-07-08T09:27:22Z
dc.date.available2026-07-08T09:27:22Z
dc.date.createdwos2026-03-19
dc.date.issued2026
dc.description.abstractNetworks are a powerful way to represent the complexity of large ecological systems. However, most ecological networks, such as food webs, contain only partial lists of species interactions. Computational methods for inferring missing links can facilitate field work and investigations of ecological processes. Here, we describe a stacked generalization approach to predict missing links in food webs that accounts for ecological assumptions including link direction. Tests of this method on synthetic food webs show that it can learn to optimally combine structural and trait-based predictions. On a global database of 290 food webs, the method often achieves near-perfect performance, performs better when it can exploit both species traits and network structure, and is principally driven by a subset of ecologically-interpretable predictors. Furthermore, we find that link predictability varies with ecosystem and network characteristics. These results show broad applicability of stacked generalization for predicting and understanding ecological interactions.
dc.description.wosFundingTextThe authors thank the Brose lab for help with the empirical data, A. Ghasemian for helpful conversations about stacking models for link prediction, and B. Singh, D.B. Larremore and E. Bradley for helpful discussions and feedback. This work was supported in part by the National Science Foundation Division of Ocean Sciences (NSF OCE 2049360), the Eppley Foundation for Research, and the Chateaubriand Fellowship of the Office for Science & Technology of the Embassy of France in the United States. The stacking model code used here is adapted for use in directed, attributed, hierarchical networks from Ghasemian et al. (2020). The authors acknowledge the BioFrontiers Computing Core at the University of Colorado Boulder for providing High Performance Computing resources supported by BioFrontiers IT.
dc.identifier.doi10.1038/s41467-026-68769-7
dc.identifier.eissn2041-1723
dc.identifier.issn2041-1723
dc.identifier.pmidMEDLINE:41633976
dc.identifier.urihttps://imec-publications.be/handle/20.500.12860/59768
dc.language.isoeng
dc.provenance.editstepusergreet.vanhoof@imec.be
dc.publisherNATURE PORTFOLIO
dc.source.beginpage2298
dc.source.issue1
dc.source.journalNATURE COMMUNICATIONS
dc.source.numberofpages15
dc.source.volume17
dc.subject.keywordsSIZE
dc.subject.keywordsPARASITES
dc.subject.keywordsRESOURCE
dc.title

Predicting missing links in food webs using stacked models and species traits

dc.typeJournal article
dspace.entity.typePublication
imec.internal.crawledAt2026-04-07
imec.internal.sourcecrawler
imec.internal.wosCreatedAt2026-04-07
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