# Unlocking the Depths: Use of a Trait‐Based Approach to Reveal the Diversity of Foraging Strategies in a Deep‐Pelagic Fish Community

**Authors:** Liz Loutrage, Anik Brind'Amour, Benoit Simon‐Bouhet, Rachel Dubourg, Célina Chantre, Jérôme Spitz

PMC · DOI: 10.1002/ece3.71891 · 2025-07-28

## TL;DR

This study explores how deep-pelagic fish communities adapt to environmental gradients by analyzing foraging strategies across different depths.

## Contribution

The paper introduces a trait-based approach to reveal the diversity of foraging strategies in deep-pelagic fish communities.

## Key findings

- Epipelagic species show trait convergence adapted for prey-tracking strategies.
- Bathypelagic species exhibit high functional richness and unique trait combinations.
- Functional rarity at depth suggests irreplaceable ecosystem functions.

## Abstract

Community trait structure is shaped by environmental filtering and limiting similarity, balancing abiotic selection and competitive divergence. In the context of environmental change and anthropogenic pressures, increasing our understanding of the relative importance of these mechanisms is essential for predicting future changes in biodiversity. The deep‐pelagic ecosystem is characterised by pronounced environmental gradients, particularly in light and food availability. The mechanisms by which fish have adapted to these gradients remain poorly understood. To better understand community trait structure, we measured 26 traits related to foraging function in 42 epi‐ to bathypelagic fish species sampled between 20 and 2000 m depth at night in the Bay of Biscay. We first tested whether limiting similarity or environmental filtering dominates trait structure along the depth gradient by calculating the standardised effect size of four functional diversity indices. Differences in morphological trait values along the depth gradient were then examined using the community weight mean. Species in the epipelagic layer exhibited significant trait convergence, while species in the bathypelagic layer exhibited high functional trait diversity. High locomotor capacity may have been selected in the epipelagic layer, where light and food resources are higher, which could explain the pressure to possess traits adapted for a prey‐tracking strategy. In the bathypelagic layer, species may have to limit the competitive pressure for the food‐scarce conditions by displaying a higher diversity of feeding strategies. The increase in functional space at depth was supported by a few species with a unique combination of traits that may reflect an ambush hunting strategy. The relatively stable environmental conditions at depth may have favoured high functional diversity and rarity. These results raise concerns about the vulnerability of this community to future climate change and potential exploitation, as rare species may provide irreplaceable functions in ecosystems.

The deep‐pelagic fish community showed differences in functional strategies along the depth gradient. Epipelagic species exhibited significant trait convergence with traits adapted to the prey‐tracking strategy, while bathypelagic species exhibited significantly higher functional richness values than expected at random. High functional rarity was observed at depth, with species exhibiting a unique combination of traits that may represent irreplaceable functions within the ecosystem.

## Full-text entities

- **Chemicals:** carbon (MESH:D002244)
- **Species:** Scomberesox saurus (Atlantic saury, species) [taxon 129061], Melanostomias bartonbeani (scaleless black dragonfish, species) [taxon 882842], Anoplogaster cornuta (common fangtooth, species) [taxon 88656], Myctophum punctatum (spotted lanternfish, species) [taxon 114866], Cubiceps gracilis (driftfish, species) [taxon 473306], Eurypharynx pelecanoides (pelican eel, species) [taxon 55117], Notoscopelus elongatus kroyeri (lancet fish, subspecies) [taxon 125806], Stomias boa (scaly dragonfis, species) [taxon 472766], Chauliodus sloani (Sloane's viperfish, species) [taxon 68509], Argyropelecus olfersii (species) [taxon 473298], Argyropelecus hemigymnus (half-naked hatchetfish, species) [taxon 68504], Malacosteus niger (stoplight loosejaw, species) [taxon 76143], Platytroctidae (tubeshoulders, family) [taxon 170200], Serrivomer beanii (Bean's sawtoothed eel, species) [taxon 182440], Derichthys serpentinus (deepwater neck eel, species) [taxon 391192], Homo sapiens (human, species) [taxon 9606]

## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12304439/full.md

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Source: https://tomesphere.com/paper/PMC12304439