Network topology mediates freshwater fish metacommunity response to loss of connectivity

Lee, Finnbar; Simon, Kevin S.; Perry, George L.

doi:10.1002/ecs2.4286

Cited by 5 publications

(1 citation statement)

References 66 publications

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“…We require novel approaches to examine dynamics and functioning of ecosystems along longitudinal environmental gradients integrating meta‐ecosystem, meta‐community and river network concepts (Doretto et al, 2020 and references therein), as flow connectivity across longitudinal and lateral (aquatic–terrestrial linkage) dimensions aligns well with meta‐ecosystem and meta‐community perspectives (Humphries et al, 2014). Network topology is crucial to understand response of meta‐community to changing connectivity by altering dispersal patterns (Carraro & Altermatt, 2022; Lee et al, 2022), but also changing connectivity regimes impact on species richness as local species richness is mediated by spatial loss of connectivity (Lee et al, 2022). As already pointed out, food web structure and energy mobilisation routes may respond to biodiversity patterns along the river continuum (Figure 2).…”

Section: Thinking Outside the Main Stem River: Meta‐ecosystem Meta‐co...mentioning

confidence: 99%

Fresh perspectives on the River Continuum Concept require trophic ecology approaches focussed on food web structure and energy mobilisation routes

Sánchez‐Hernández

2023

Journal of Animal Ecology

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Stream‐dwelling communities are expected to show a gradual replacement of the dominant feeding types following the type of resources found along the river continuum. Yet, the underlying longitudinal gradients in food web structure and energy flow‐paths remain poorly understood. Here, I synthesise novel research on the River Continuum Concept (RCC) and identify promising areas for future research linked to longitudinal changes in food‐chain length and energy mobilisation routes. For example, feeding links and connectance should reach maximum values in mid‐order rivers and then decrease to river mouths following uncovered longitudinal diversity patterns. Regarding energy mobilisation routes, a gradual replacement in the food web fuelling between allochthonous (leaf litter) and autochthonous (periphyton) resources should be expected. Beyond longitudinal changes in primary basal resource to consumer paths, other allochthonous (e.g. riparian arthropod inputs) and autochthonous (e.g. fish prey) inputs subsidising higher level consumers may show longitudinal changes, that is, terrestrial invertebrates decreasing but piscivory increasing downstream. However, the role of these inputs, that can alter predator niche variation and have indirect community‐based effects, on both food web structure and energy flow‐paths along the river continuum is not clear yet. Incorporating energy mobilisation and food web structure into RCC principles is necessary for a broad understanding of ecosystem functioning and trophic diversity in riverine systems, driving the emergence of novel insights. How function and structure of riverine food webs adapt to longitudinal changes in physical and biological environments represent a challenge for next generation of stream ecologists.

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Section: Thinking Outside the Main Stem River: Meta‐ecosystem Meta‐co...mentioning

confidence: 99%

Fresh perspectives on the River Continuum Concept require trophic ecology approaches focussed on food web structure and energy mobilisation routes

Sánchez‐Hernández

2023

Journal of Animal Ecology

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Impacts of stream drying depend on stream network size and location of drying

Malish,

Gao,

Allen

et al. 2024

Ecological Applications

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Stream drying is increasing globally, with widespread impacts on stream ecosystems. Here, we investigated how the impacts of drying on stream ecosystem connectivity might depend on stream network size and the location of drying within the stream network. Using 11 stream networks from across the United States, we simulated drying scenarios in which we varied the location and spatial extent of drying. We found that the rate of connectivity loss varied with stream network size, such that larger stream networks lost connectivity more rapidly than smaller stream networks. We also found that the rate of connectivity loss varied with the location of drying. When drying occurred in the mainstem, even small amounts of drying resulted in rapid losses in ecosystem connectivity. When drying occurred in headwater reaches, small amounts of drying had little impact on connectivity. Beyond a certain threshold, however, connectivity declined rapidly with further increases in drying. Given the increasing stream drying worldwide, our findings underscore the need for managers to be particularly vigilant about fragmentation when managing at large spatial scales and when stream drying occurs in mainstem reaches.

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Nature-based solutions for urban biodiversity: Spatial targeting of retrofits can multiply ecological connectivity benefits

Croeser,

Bekessy,

Garrard

et al. 2024

Landscape and Urban Planning

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Network topology mediates freshwater fish metacommunity response to loss of connectivity

Cited by 5 publications

References 66 publications

Fresh perspectives on the River Continuum Concept require trophic ecology approaches focussed on food web structure and energy mobilisation routes

Fresh perspectives on the River Continuum Concept require trophic ecology approaches focussed on food web structure and energy mobilisation routes

Impacts of stream drying depend on stream network size and location of drying

Nature-based solutions for urban biodiversity: Spatial targeting of retrofits can multiply ecological connectivity benefits

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