Generation and application of river network analogues for use in ecology and evolution

Carraro, Luca; Bertuzzo, Enrico; Fronhofer, Emanuel A.; Furrer, Reinhard; Gounand, Isabelle; Rinaldo, Andrea; Altermatt, Florian

doi:10.1101/2020.02.17.948851

Cited by 23 publications

(49 citation statements)

References 80 publications

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“…Application of our model on more complex landscapes, or more highly dimensional habitats such as are experienced by terrestrial, wind‐dispersed organisms (2D) or marine species (3D), would provide valuable insight into the interaction of the effects of currents and system complexity on dispersal strategies, genetic variability (Morrissey and De Kerckhove 2009, Paz‐Vinas et al 2015) and community structure (Fagan 2002, Tonkin et al 2014). Running dispersal evolution models within suites of simulated artificial river networks (Carraro et al 2020) would provide an effective means for generating predictions on how different river characteristics are likely to exert different selective forces. Introducing temporal variability in current strength would allow us to investigate the resilience of populations to occasional disturbances (Bonte et al 2012, Travis et al 2012) such as storm surges, flooding events or local patch extinction due to pollution events.…”

Section: Discussionmentioning

confidence: 99%

Dispersal evolution in currents: spatial sorting promotes philopatry in upstream patches

et al. 2020

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Substantial literature is devoted to understanding dispersal evolution, but we lack theory on how dispersal evolves when populations inhabit currents. Such theory is required for understanding connectivity in freshwater and marine environments; moreover, many animals, fungi and plants rely on wind‐based dispersal, but the effects of currents on dispersal evolution in these organisms is unknown. We develop an individual‐based model for evolution of dispersal probability along a linear environment with a unidirectional current. Even a slight current substantially reduces overall emigration probability compared to no current. Under stronger currents, emigration can be drastically reduced, especially in the upstream patches. When introducing rare long‐distance dispersal that is not subject to the current, higher emigration probabilities evolve and the spatial variability in emigration propensity along the stream is reduced. Our results provide an alternative solution to the long debated ‘drift paradox' concerning the loss of individuals from upstream populations due to advective forces. A combination of natural selection and spatial sorting generates and maintains downstream gradients in dispersal propensity, where individuals from upstream populations tend to be substantially more philopatric. This is likely to have major implications for ecological and genetic connectivity that will impact effective management strategies for populations inhabiting currents.

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Section: Discussionmentioning

confidence: 99%

Dispersal evolution in currents: spatial sorting promotes philopatry in upstream patches

et al. 2020

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“…The virtual river network used in the following simulations is an Optimal Channel Network (OCN) built via the R‐package OCNet (Carraro, Altermatt, et al, 2020; Carraro, Bertuzzo, et al, 2020). OCNs are idealized constructs that reproduce the topological and scaling features of real river networks and are therefore suitable for simulation studies on various ecological and ecohydrological issues (Rinaldo et al., 2014; Rodriguez‐Iturbe et al., 1992).…”

Section: Methodsmentioning

confidence: 99%

“…Representation of the optimal channel network used in this study, spanning a square of side 20 km. The aggregation of the OCN at the AG level (see Carraro, Bertuzzo, et al, 2020) identifies 200 nodes, which are here displayed at the downstream end of the corresponding river reaches. Red indicates nodes whose drainage area is lower than the median drainage area across the 200 nodes (referred to in the text as upstream nodes); black identifies nodes with drainage area higher than the median (downstream nodes)…”

Section: Methodsmentioning

confidence: 99%

“…A threshold area of 461 pixels (

A_{T} = 461 \cdot 0 . 05^{2} = 1.15 {km}^{2}

) is used to distinguish the fraction of lattice pixels that effectively constitute the river network. At this so‐called RN (river network) aggregation level, the network is constituted by 4,468 nodes (each corresponding to a 50‐m pixel with drainage area ≥ A T ; see Carraro, Bertuzzo, et al (2020) for details on aggregation levels of an OCN). Subsequently, such network is further coarsened into the AG (aggregated) level, where nodes represent sources and confluences of the network at the RN level, while edges follow the drainage directions previously identified.…”

Section: Methodsmentioning

confidence: 99%

“…Here, we fill this gap by making use of computer simulations in order to assess different scenarios of eDNA release, transport, and detection. We test these scenarios based on the application of the hydrology‐based eDNA transport model of Carraro, Hartikainen, et al (2018) using synthetic analogues of river networks (so‐called Optimal Channel Networks, see Carraro, Bertuzzo, et al (2020) and Rinaldo, Rigon, Banavar, Maritan, and Rodriguez‐Iturbe (2014)). This allows testing realistic spatial scenarios in a generic setting that is not constrained to the particular shape of a real river network.…”

Section: Introductionmentioning

confidence: 99%

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How to design optimal eDNA sampling strategies for biomonitoring in river networks

2020

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The current biodiversity crisis calls for appropriate methods for assessing biodiversity. In this respect, environmental DNA (eDNA) holds great promise, especially for aquatic ecosystems. While initial eDNA studies assessed biodiversity at single sites, technology now allows analyzing samples from many points simultaneously. However, the selection of these sites has been mostly motivated on an ad‐hoc basis. To this end, hydrology‐based models might offer a unique guidance on where to sample eDNA to most effectively reconstruct spatial patterns of biodiversity. Here, we performed computer simulations to identify best‐practice criteria for the choice of positioning of eDNA sampling sites in river networks. To do so, we combined a hydrology‐based eDNA transport model with a virtual river network reproducing the scaling features of real rivers. In particular, we conducted simulations investigating scenarios of different number and location of eDNA sampling sites in a riverine network, different spatial taxon distributions, and different eDNA measurement errors. We found that, due to hydrological controls, non‐uniform patterns of eDNA concentration arise even if the taxon distribution is uniform and decay is neglected. Best practices for sampling site selection depend on the taxon's spatial distribution: when taxa are concentrated in some hotspots and only few sampling sites can be placed, it is better to preferentially locate them in the downstream part of the catchment; when taxa are more evenly distributed, and/or many sites can be placed, these should be preferentially located upstream. We also found that uncertainties in eDNA concentration estimates do not necessarily hamper model predictions. Knowledge of eDNA decay rates improves model predictions, highlighting the need for empirical estimates of these rates under relevant environmental conditions. Our simulations help define strategies for designing eDNA sampling campaigns in river networks and can guide the sampling effort of field ecologists and environmental authorities.

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Network topology mediates freshwater fish metacommunity response to loss of connectivity

2022

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Changes in connectivity regimes affect patterns of diversity and species richness. In riverine ecosystems, factors that vary through space and time, such as flow, the presence of barriers to movement, and network topology determine connectivity, and in turn shape patterns of diversity and richness.While the effects of network topology and changes in spatiotemporal connectivity regimes on patterns of species richness have been studied in isolation, they have not been studied simultaneously. We used a discrete-time logistic growth metacommunity model to analyze the role of spatial and temporal functional connectivity in determining patterns of local (patch level) species richness in freshwater fish metacommunities. Our modeling suggests that:(1) the effect of spatial loss of connectivity on local species richness is mediated by network topology and where richness is measured in the system and (2) increasing temporal autocorrelation in connectivity results in increasing temporal autocorrelation in patch occupancy. Spatial and temporal loss of connectivity is a ubiquitous issue for river ecosystems, making understanding and predicting its effects of fundamental importance to both improving theory and guiding river management. Our findings highlight the importance of network topology (and hence context dependency) in shaping metacommunity response to changing connectivity regimes.

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Generation and application of river network analogues for use in ecology and evolution

Cited by 23 publications

References 80 publications

Dispersal evolution in currents: spatial sorting promotes philopatry in upstream patches

Dispersal evolution in currents: spatial sorting promotes philopatry in upstream patches

How to design optimal eDNA sampling strategies for biomonitoring in river networks

Network topology mediates freshwater fish metacommunity response to loss of connectivity

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