Revisiting extinction debt through the lens of multitrophic networks and meta‐ecosystems

Blanchard, Grégoire; Munoz, François

doi:10.1111/oik.09435

Cited by 6 publications

(1 citation statement)

References 186 publications

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“…Linking the identity and quantity of interaction partners across three to four trophic levels using individual‐based interactions of cavity‐nesting bees and wasps allows the analysis of interaction network indexes and feeding links across all trophic levels or in multiple connected bipartite interactions. Multitrophic interactions can be viewed from multiple angles and may be analysed in various ways, as summarised by Abdala‐Roberts et al (2019), Kawatsu et al (2021), or García‐Callejas et al (2018), for example, for predicting extinction debt (Blanchard & Munoz 2023). Data on directly observed interactions across trophic levels may also allow for an in‐depth description of the dependence of higher trophic levels on all levels below.…”

Section: Discussionmentioning

confidence: 99%

DNA barcoding resolves quantitative multi‐trophic interaction networks and reveals pest species in trap nests

Fornoff,

Halla,

Geiger

et al. 2023

Insect Conserv Diversity

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Insects, as one of the most species‐rich taxa with enormous taxonomic, behavioural and functional diversity, are in decline. Bees and wasps are especially crucial for ecosystems as pollinators or to control populations of other insects. To understand population drivers, comprehensive knowledge about top‐down and bottom‐up interactions, including all interaction partners, is needed. Nests of trap‐nesting bees and wasps include multi‐trophic interactions between bees, wasps, their food resources and natural enemies, simultaneously, however, up to today, all trophic interactions are not yet included in trap nest research because of challenges to identify the food used by nesting bees and wasps. Here, we reconstructed quantitative three‐ and four‐trophic interaction networks of species in three apoid wasp families using DNA barcoding. The obtained tripartite and quadripartite networks encompassed natural enemy‐wasp‐spider and natural enemy‐wasp‐herbivore‐plant interactions. Moreover, we identified so far undescribed Hymenoptera‐prey interactions, including prey species known as agricultural and forest pests. More extensive research on bee and wasp multitrophic interaction networks will provide valuable insights to better understand responses to environmental and biodiversity change, to investigate ecological theory and to reveal so far unknown feeding links.

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Section: Discussionmentioning

confidence: 99%

DNA barcoding resolves quantitative multi‐trophic interaction networks and reveals pest species in trap nests

Fornoff,

Halla,

Geiger

et al. 2023

Insect Conserv Diversity

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Connectivity mediates the spatial ecological impacts of a glyphosate-based herbicide in experimental metaecosystems

Negrín Dastis,

McGuinness,

Tadiri

et al. 2024

Oecologia

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Metacommunity ecology has shown that connectivity is important for the persistence of a species locally and across connected ecosystems, however we do not know if ecological effects in freshwater ecosystems exposed to biocides leaking from agriculture depend on metaecosystem connectivity. We experimentally replicated metaecosystems in the laboratory using gradostats as a model system. We tested the effects of connectivity, in terms of node distance from the pollutant-source, flow rate, and a glyphosate-based herbicide, on phytoplankton productivity, diversity and stability. Gradostats were composed of interconnected equally spaced nodes where resources and phytoplankton move directionally along a gradient of increasing distance from the source of the polluting herbicide. We hypothesised that ecological effects would be stronger in the node situated closer to the point of herbicide input, but that flow would suppress phytoplankton populations in distant nodes. Overall, RoundUp impacted phytoplankton productivity and stability by reducing algal biomass and abundances. This occurred especially in the node closest to the diluted herbicide point-source and under high flow, where species abundances were heavily suppressed by the effects of the rapidly flowing herbicide. At low flow on the other hand, distant nodes where buffered from the effects of the slow-moving herbicide. No differences in beta and gamma diversity among replicate metaecosystems was found; however, a significant loss of alpha diversity in all metaecosystems occurred through time until the end of the experiment. Together, these results point to the importance of considering aquatic connectivity in management plans for monitoring and mitigating unintended ecological consequences of agrochemical runoff. Supplementary Information The online version contains supplementary material available at 10.1007/s00442-024-05601-3.

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Interaction network structure explains species’ temporal persistence in empirical plant–pollinator communities

Domínguez-Garcia,

Molina,

Godoy

et al. 2024

Nat Ecol Evol

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Revisiting extinction debt through the lens of multitrophic networks and meta‐ecosystems

Cited by 6 publications

References 186 publications

DNA barcoding resolves quantitative multi‐trophic interaction networks and reveals pest species in trap nests

DNA barcoding resolves quantitative multi‐trophic interaction networks and reveals pest species in trap nests

Connectivity mediates the spatial ecological impacts of a glyphosate-based herbicide in experimental metaecosystems

Interaction network structure explains species’ temporal persistence in empirical plant–pollinator communities

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