Modelling ecological communities when composition is manipulated experimentally

Skwara, Abigail; Lemos-Costa, Paula; Miller, Zachary R.; Allesina, Stefano

doi:10.1111/2041-210x.14028

Cited by 5 publications

(9 citation statements)

References 45 publications

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“…This approach is grounded in a simple framework to infer interactions and predict biomasses from community “endpoints” — a framework that is gaining traction in the ecological literature (Xiao et al 2017; Fort 2018; Maynard, Miller, and Allesina 2020; Ansari et al 2021; Skwara et al 2023). One of the main advantages of this framework is that it makes predictions that are compatible with models of population dynamics: if we were to simulate communities using the fitted interaction strengths as parameters of the Generalized Lotka-Volterra model, we would find the same predicted abundances as equilibria of the dynamical system.…”

Section: Discussionmentioning

confidence: 99%

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Phylogeny structures species’ interactions in experimental ecological communities

Lemos-Costa,

Miller,

Allesina

2023

Preprint

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The advent of molecular phylogenetics provided a new perspective on the structure and function of ecological communities. In particular, the hypothesis that traits responsible for species' interactions are largely determined by shared evolutionary history has suggested the possibility of connecting the phylogeny of ecological communities to their functioning. However, statistical tests of this link have yielded mixed results. Here we propose a novel framework to test whether phylogeny influences the patterns of coexistence and abundance of species assemblages, and apply it to analyze data from large biodiversity-ecosystem functioning experiments. In our approach, phylogenetic trees are used to parameterize species' interactions, which in turn determine the abundance of species in a specified assemblage. We use a maximum likelihood-based approach to score models parameterized with a given phylogenetic tree. To test whether evolutionary history structures interactions, we fit and score ensembles of randomized trees, allowing us to determine if phylogenetic information helps to predict species' abundances. Moreover, we can determine the contribution of each branch of the tree to the likelihood, revealing particular clades in which interaction strengths are closely tied to phylogeny. We find strong evidence of phylogenetic signal across a range of published experiments and a variety of models. The flexibility of our framework permits incorporation of ecological information beyond phylogeny, such as functional groups or traits, and provides a principled way to test hypotheses about which factors shape the structure and function of ecological communities.

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Section: Discussionmentioning

confidence: 99%

“…Versions of this basic framework have been proposed numerous times in the ecological literature (Xiao et al 2017; Fort 2018; Maynard, Miller, and Allesina 2020; Ansari et al 2021), and here we closely follow the approach of Maynard et al . (Maynard, Miller, and Allesina 2020; Skwara et al 2023).…”

Section: Methodsmentioning

confidence: 99%

Phylogeny structures species’ interactions in experimental ecological communities

Lemos-Costa,

Miller,

Allesina

2023

Preprint

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“…If we can write down and parameterize a model that accurately represents interactions, but using only a limited amount of experimental data, we might be able to use such a model to predict outcomes beyond those experiments. A longstanding approach to modeling interactions has been to use pairwise interactions among species, with the strength of this pairwise dependence encoded in a community interaction matrix [16,17]. But there is a recent realization that microbial communities may be infused with higher-order interactions, where the influence of one species on another is dependent on the presence or absence of a third, fourth, or fifth species [18][19][20][21][22].…”

Section: Introductionmentioning

confidence: 99%

“…But there is a recent realization that microbial communities may be infused with higher-order interactions, where the influence of one species on another is dependent on the presence or absence of a third, fourth, or fifth species [18][19][20][21][22]. With the potential for such higher-order interactions, fitting mechanistic models could just bring us back to a similar combinatorial problem to the one we started with [17,18,23,24]. Finally, deep learning has been deployed to address this question [23,25], at the expense of making results and predictions challenging to interpret.…”

Section: Introductionmentioning

confidence: 99%

“…If we can write down and parameterize a model that accurately represents interactions, but using only a limited amount of experimental data, we might be able to use such a model to predict outcomes beyond those experiments. A longstanding approach to modeling interspecific interactions, inspired by Robert May's seminal work [16] on complex systems, has been to use pairwise interactions among species, with the strength of this pairwise dependence encoded in a community interaction matrix [17,18]. There is certainly no conceptual obstacle to pairwise interactions providing a potential description of microbial communities-theoretical work demonstrates that pairwise interactions can lead to diverse, realistic communities [19][20][21][22][23][24][25][26].…”

Section: Introductionmentioning

confidence: 99%

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Sparsity of higher-order landscape interactions enables learning and prediction for microbiomes

Arya

George

O’Dwyer

2023

Preprint

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Microbiome engineering offers the potential to leverage microbial communities to improve outcomes in human health, agriculture, and climate. To translate this potential into reality, it is crucial to reliably predict community composition and function. But a brute force approach to cataloguing community function is hindered by the combinatorial explosion in the number of ways we can combine microbial species. An alternative is to parametrize microbial community outcomes using simplified, mechanistic models, and then extrapolate these models beyond where we have sampled. But these approaches remain data-hungry, as well as requiring ana priorispecification of what kinds of mechanism are included and which are omitted. Here, we resolve both issues by introducing a new, mechanism-agnostic approach to predicting microbial community compositions using limited data. The critical step is the discovery of a sparse representation of the community landscape. We then leverage this sparsity to predict community compositions, drawing from techniques in compressive sensing. We validate this approach onin silicocommunity data, generated from a theoretical model. By sampling just ∼ 1% of all possible communities, we accurately predict community compositions out of sample. We then demonstrate the real-world application of our approach by applying it to four experimental datasets, and showing that we can recover interpretable, accurate predictions from highly limited data.

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