Community structure determines the predictability of population collapse

Baruah, Gaurav; Özgül, Arpat; Clements, Christopher F.

doi:10.1101/2022.03.07.483267

Cited by 3 publications

(5 citation statements)

References 58 publications

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“…For example, whereas the linearized dynamics can be used to compute a recovery rate under equilibrium (Arnoldi et al ., 2018, Medeiros et al ., 2021, Strogatz, 2018), we show that they can be used to derive the time-varying expected sensitivity of different species to perturbations under non-equilibrium dynamics. Similarly to previous studies, our results confirm the utility of tracking variances and covariances of perturbed abundances to anticipate changes in ecological communities (Baruah et al ., 2022, Chen et al ., 2019, Dakos, 2018). In addition, we use the leading eigenvector, which has been previously employed to decompose community responses into species responses to perturbations under equilibrium dynamics (Dakos, 2018, Ghadami et al ., 2020, Patterson et al ., 2021, Weinans et al ., 2019).…”

Section: Discussionsupporting

confidence: 90%

Ranking species based on sensitivity to perturbations under non-equilibrium community dynamics

Medeiros

Allesina

Dakos

et al. 2022

Preprint

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Managing ecological communities requires fast detection of species that are sensitive to perturbations. Yet, the focus on recovery to equilibrium has prevented us from assessing species responses to perturbations when abundances fluctuate over time. Here, we introduce two data-driven approaches (expected sensitivity and eigenvector rankings) based on the time-varying Jacobian matrix to rank species over time according to their sensitivity to perturbations on abundances. Using several population dynamics models, we demonstrate that we can infer these rankings from time-series data to predict the order of species sensitivities. We find that the most sensitive species are not always the ones with the most rapidly changing or lowest abundance, which are typical criteria used to monitor populations. Finally, using two empirical time series, we show that sensitive species tend to be harder to forecast. Our results suggest that incorporating information on species interactions can improve how we manage communities out of equilibrium.

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Section: Discussionsupporting

confidence: 90%

Ranking species based on sensitivity to perturbations under non-equilibrium community dynamics

Medeiros

Allesina

Dakos

et al. 2022

Preprint

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“…When an ecological network collapses both at the local as well as at the spatial scale, signals of global meta-network instability could also be manifested in species in an ecological community. It is relatively unknown, however, which species could exhibit signals of instability, but see Dakos (2017) , Baruah et al (2022) or Patterson et al (2021). Indeed, the species that exhibited strong increases in standard deviation as networks collapsed, were the ones which had on average a larger number of interactions (Fig.…”

Section: Discussionmentioning

confidence: 99%

“…Studies have indicated that in addition to monitoring dynamics of species abundance, phenotypic traits should be monitored as well. Including information from phenotypic dynamics such as body size could improve forecasts of biodiversity collapse (Clements and Ozgul 2016), although such an accurate forecast of biodiversity collapse is dependent on the type of environmental perturbation and the type of interactions prevalent in the community (Baruah et al 2019(Baruah et al , 2022. When changes in the environment impact communities both locally and spatially alike, ecological networks could abruptly collapse.…”

Section: Discussionmentioning

confidence: 99%

“…However, such signals and their efficacy have been questioned recently both in numerical simulations studies (Hastings and Wysham 2010; Clements et al 2015; Baruah et al 2020) and experimental studies (Wilkinson et al 2018; Baruah et al 2021). Their application on multi-species communities (Dakos and Bascompte 2014; Dakos 2017; Patterson et al 2021; Baruah et al 2022), particularly in the context of a spatial structure has been lacking. Here, I evaluated how the efficacy of commonly used statistical signals measured at the species level (autocorrelation at first-lag, standard deviation), community level (patch variability, spatial variability) and at the metacommunity level (temporal regional variability) in relation to network topology and spatial scale of interactions.…”

Section: Discussionmentioning

confidence: 99%

“…However, there are statistical tools that been developed to forecast such impending transitions which are commonly known as “early warning signals.” Commonly used signals are temporal autocorrelation and variance that could derived using a sliding window approach (see [Dakos et al (2012a) for details) from state based temporal data such as abundance or biomass. However, the utility of such signals are dependent on a host of factors that includes sampling requirements (Arkilanian et al 2020), data quality (Clements et al 2015), eco-evolutionary factors (Baruah et al 2020, 2021) and type of species interactions (Dakos 2017; Patterson et al 2021; Baruah et al 2022). One important challenge is to test the utility of such signals in a multispecies context embedded within a spatial scale of species interactions.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Abrupt transitions and its indicators in mutualistic meta-networks: effects of network topology, size of metacommunities and species dispersal

Baruah

2022

Preprint

Self Cite

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Gradual changes in the environment could cause dynamical ecological networks to abruptly shift from one state to an alternative state. When this happens ecosystem functions and services provided by ecological networks get disrupted. We, however, know very little about how the topology of such interaction networks can play a role in the transitions of ecological networks at a spatial scale. In the event of such unwanted transitions, little is known how statistical metrics used to inform such impending transitions, measured at the species-level or at the community-level could relate to network architecture and the scale of spatial interactions. Here, using fifty-six empirical plantpollinator networks in a spatial setting, I evaluated the impact of network topology and spatial scale of species interactions on abrupt transitions, and on statistical metrics used as predictors to forecast such abrupt transitions. Using generalized Lotka-Volttera equations in a meta-network framework, I show that species dispersal rate and the size of the metacommunity can impact when an abrupt transition can occur. In addition, forecasting such unwanted abrupt transitions of meta-networks using statistical metrics of instability was also consequently dependent on the topology of the network, species dispersal rate, and the size of the metacommunity. The results indicated that the plantpollinator meta-networks that could exhibit stronger statistical signals before collapse than others were dependent on their network architecture and on the spatial scale of species interactions.

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Transitions and its indicators in mutualistic meta-networks: effects of network topology, size of metacommunities and species dispersal

Baruah

2023

Evol Ecol

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Gradual changes in the environment could cause dynamical ecological networks to suddenly shift from one state to an alternative state. When this happens ecosystem functions and services provided by ecological networks get disrupted. We, however, know very little about how the topology of such interaction networks can play a role in the transition of ecological networks when spatial interactions come into play. In the event of such unwanted transitions, little is known about how statistical metrics used to inform such impending transitions, measured at the species-level or at the community-level could relate to network architecture and the size of the metacommunity. Here, using hundred and one empirical plant-pollinator networks in a spatial setting, I evaluated the impact of network topology and spatial scale of species interactions on transitions, and on statistical metrics used as predictors to forecast such transitions. Using generalized Lotka-Volterra equations in a meta-network framework, I show that species dispersal rate and the size of the metacommunity can impact when a transition can occur. In addition, forecasting such unwanted transitions of meta-networks using statistical metrics of instability was also consequently dependent on the topology of the network, species dispersal rate, and the size of the metacommunity. The results indicated that the plant-pollinator meta-networks that could exhibit stronger statistical signals before collapse than others were dependent on their network architecture and on the spatial scale of species interactions.

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Community structure determines the predictability of population collapse

Cited by 3 publications

References 58 publications

Ranking species based on sensitivity to perturbations under non-equilibrium community dynamics

Ranking species based on sensitivity to perturbations under non-equilibrium community dynamics

Abrupt transitions and its indicators in mutualistic meta-networks: effects of network topology, size of metacommunities and species dispersal

Transitions and its indicators in mutualistic meta-networks: effects of network topology, size of metacommunities and species dispersal

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