The geography of metapopulation synchrony in dendritic river networks

Dendritic habitats, such as river ecosystems, promote the persistence of species by favouring spatial asynchronous dynamics among branches. Yet, our understanding of how network topology influences metapopulation synchrony in these ecosystems remains limited. Here, we introduce the concept of fluvia...

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Bibliographic Details
Published in:Ecology letters 2021-04, Vol.24 (4), p.791-801
Main Authors: Larsen, Stefano, Comte, Lise, Filipa Filipe, Ana, Fortin, Marie‐Josée, Jacquet, Claire, Ryser, Remo, Tedesco, Pablo A., Brose, Ulrich, Erős, Tibor, Giam, Xingli, Irving, Katie, Ruhi, Albert, Sharma, Sapna, Olden, Julian D., Heino, Mikko
Format: Article
Language:English
Subjects:
Animals
Aquatic ecosystems
Complexity
Decay rate
Ecosystem
Environmental Sciences
Euclidean geometry
Europe
Fish
Fish populations
Fish time‐series
fluvial variography
Geography
Letter
Letters
Metapopulations
Network topologies
network topology
Population Dynamics
Populations
River networks
Rivers
spatial patterns
spatial synchrony
Topology
Water flow
Watersheds
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Summary:Dendritic habitats, such as river ecosystems, promote the persistence of species by favouring spatial asynchronous dynamics among branches. Yet, our understanding of how network topology influences metapopulation synchrony in these ecosystems remains limited. Here, we introduce the concept of fluvial synchrogram to formulate and test expectations regarding the geography of metapopulation synchrony across watersheds. By combining theoretical simulations and an extensive fish population time‐series dataset across Europe, we provide evidence that fish metapopulations can be buffered against synchronous dynamics as a direct consequence of network connectivity and branching complexity. Synchrony was higher between populations connected by direct water flow and decayed faster with distance over the Euclidean than the watercourse dimension. Likewise, synchrony decayed faster with distance in headwater than mainstem populations of the same basin. As network topology and flow directionality generate fundamental spatial patterns of synchrony in fish metapopulations, empirical synchrograms can aid knowledge advancement and inform conservation strategies in complex habitats. Synchrony between spatially separated populations influences species persistence and ecosystem stability. We provide theoretical and empirical evidence that in dendritic habitats, such as river ecosystems, network topology and flow directionality generate fundamental spatial patterns in fish metapopulation synchrony. We articulate an empirical geography of synchrony within river basins that allow predicting synchrony patterns even if population time‐series data are not available.
ISSN:1461-023X
1461-0248
DOI:10.1111/ele.13699