Generalism drives abundance: A computational causal discovery approach

Generalism drives abundance: A computational causal discovery approach

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A ubiquitous pattern in ecological systems is that more abundant species tend to be more generalist; that is, they interact with more species or can occur in wider range of habitats.However, there is no consensus on whether generalism drives abundance read more (a selection process) or abundance drives generalism (a drift process).As it is difficult to conduct direct experiments to solve this chicken-and-egg dilemma, previous studies have used a causal discovery method based on formal logic and have found that abundance drives generalism.Here, we refine this method by correcting its bias regarding skewed distributions, and employ two other independent causal discovery methods based on nonparametric regression and on information theory, respectively.

Contrary to previous work, all three independent methods strongly indicate that generalism drives abundance when applied to datasets on plant-hummingbird communities and reef fishes.Furthermore, we find that selection processes are more important than drift processes in structuring multispecies systems when the environment is variable.Our results showcase the power of the computational causal discovery approach to aid ecological research.Author summary Ever since Aristotle, the chicken-or-egg causality dilemma has baffled researchers.

Such causality dilemmas are abundant in ecological research, where causal directions are often assumed but not tested.An archetypal example is whether being a generalist causes a species to be more abundant, or whether being more abundant causes a species to be generalists.Without doubt, the gold standard to establish causal directions is controlled experiments.However, controlled experiments that can disentangle the direction of causality in this case are challenging because it involves controlling biotic or abiotic niche breadth.

These challenges create an opportunity for computational tools to detect the most likely causal direction.Here, by adapting a set of recently developed canine spectra kc 3 intranasal single dose computational methods, we provide strong evidence that generalism drives abundance, overturning the previously established direction.We hope our work raises awareness of the potential for computational discovery methods to address long-standing questions in ecology, especially increasingly large datasets become available.