# Population Genomics Reveals Small‐Scale Metapopulation Structure of Two Strictly Aquatic Keystone Species in a Recently Restored Urban River System (Emscher, Germany)

**Authors:** Martina Weiss, Marie V. Brasseur, Armin W. Lorenz, Florian Leese

PMC · DOI: 10.1002/ece3.71214 · Ecology and Evolution · 2025-04-24

## TL;DR

This study uses genetic markers to assess the population structure of two aquatic species in a restored urban river, showing how ecological restoration affects connectivity and species dynamics.

## Contribution

The study demonstrates the use of genetic tools to evaluate ecological restoration success and detect cryptic species in urban river systems.

## Key findings

- Strong metapopulation structure was found in both species, influenced by catchment affiliation, wastewater, and in-stream barriers.
- Mito-nuclear discordance was observed, with nuclear data indicating that diverging mitochondrial lineages of G. pulex represent a single species.
- Eco-evolutionary factors like priority effects and adaptation were found to influence population structure beyond physical barriers.

## Abstract

Urbanization and the resulting modifications of freshwater ecosystems can play an important role in shaping metapopulation structure and dynamics of aquatic organisms. Ecological restoration aims at improving river ecosystems by reducing or removing anthropogenic stressors and habitat fragmentation, facilitating natural dispersal among population patches. However, the success of such ecological restoration measures is not guaranteed, and for many of the functionally important but smaller organisms, improved connectivity is difficult to assess. Here, genetic markers can help in assessing small‐scale connectivity and in identifying persisting gene flow barriers. In this study used high‐resolution genetic markers to study the metapopulation structure of two ecologically important amphipod species, 
Gammarus pulex
 and Gammarus fossarum, in the heavily urbanized Emscher catchment in Germany. This catchment was strongly degraded and polluted for over a century but has been restored over the past two decades. For both strictly aquatic species, we analyzed mitochondrial cytochrome c oxidase I (COI) gene sequences as well as nuclear genome‐wide single nucleotide polymorphism (SNP) data. We detected strong metapopulation structure within both species, which was mainly driven by catchment affiliation, wastewater, large in‐stream barriers, and recent recolonization of restored stream sections. However, population structure was not fully explained by these factors, indicating that eco‐evolutionary factors such as priority effects, adaptation, or biotic interactions play a role in shaping the population structure. Furthermore, our data show a strong mito‐nuclear discordance for both species with regard to detailed population structure and also the presence of possible cryptic species for 
G. pulex
. Here, nuclear data indicate that the diverging mitochondrial lineages of 
G. pulex
 (Gp‐C and Gp‐E) represent only one species in this region. Our study shows how genetic markers can support the assessment of population connectivity and thus evaluate the success of ecological restoration.

The study used high‐resolution genetic markers to analyze the metapopulation structure of two aquatic amphipod species, Gammarus pulex and Gammarus fossarum, in an urban river catchment (Emscher, Germany). Strong metapopulation structure was identified, primarily influenced by catchment affiliation, wastewater, in‐stream barriers, and recolonization, with eco‐evolutionary factors also playing a role. Mito‐nuclear discordance was observed, with nuclear data suggesting that the strongly diverging mitochondrial lineages of G. pulex represent a single species in the region. The study demonstrates the power of genetic tools in evaluating restoration success and connectivity.

## Linked entities

- **Genes:** COX1 (cytochrome c oxidase subunit I) [NCBI Gene 4512]
- **Species:** Gammarus pulex (taxon 52641), Gammarus fossarum (taxon 52638), Mus musculus (taxon 10090)

## Full-text entities

- **Species:** Gammarus fossarum (species) [taxon 52638], Gammarus pulex (species) [taxon 52641]

## Full text

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## Figures

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## References

85 references — full list in the complete paper: https://tomesphere.com/paper/PMC12022002/full.md

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Source: https://tomesphere.com/paper/PMC12022002