Functional traits and environmental characteristics drive the degree of competitive intransitivity in European saltmarsh plant communities

Ulrich, Werner; Kubota, Yasuhiro; Piernik, Agnieszka; Gotelli, Nicholas J.

doi:10.1111/1365-2745.12958

Cited by 28 publications

(45 citation statements)

References 65 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…() suggest strong links between intransitive competition and the evolution of greater functional trait divergences in a given clade, which is supported by the empirical, bivariate relationships found by Ulrich et al. () in saltmarsh plant communities. Soliveres et al.…”

Section: Beyond Species Coexistence: What Are the Consequences Of Intsupporting

confidence: 54%

“…Most metrics of intransitivity consider competitive exclusion as a binary process: a species either wins or loses in competition. However, two of the studies in this special feature (Gallien, Landi, Hui, & Richardson, ; Ulrich, Kubota, Piernik, & Gotelli, ) show the need to consider more continuous measurements of competition (see also Gallien, Zimmermann, Levine, & Adler, ). If we take a more continuous view, there are almost endless possibilities for how a simple three‐species (A, B, C) competition network can organize, ranging from pure (or “strong”) hierarchy (A ≫ B ≫ C, A ≫ C) to strong intransitivity (A ≫ B ≫ C ≫ A) and everything in between (e.g.…”

Section: A Short Story Of a Difficult Task: How Can We Measure Intranmentioning

confidence: 99%

See 1 more Smart Citation

Everything you always wanted to know about intransitive competition but were afraid to ask

Soliveres

Allan

2018

Journal of Ecology

View full text Add to dashboard Cite

Over 40 years after the introduction of the concept into ecology, intransitive (i.e. non‐hierarchical) competition remains overlooked by ecological theory, despite theoretical work showing it could be a major driver of species coexistence. This special feature presents six studies, including models, reviews, experimental studies and large‐scale observational studies. Collectively, these studies help to (i) link intransitive competition with short‐ and long‐term coexistence and with other ecological patterns, (ii) evaluate the conditions under which intransitivity is more common and (iii) determine how best to quantify the degree of intransitivity. The studies in this special feature show the generality of intransitive competition in nature, explore interactions between intransitivity and other coexistence mechanisms, and illustrate the effect of environmental conditions (drought, shade, fertility) on intransitivity and coexistence. They also show which metrics best quantify intransitivity and highlight the importance of adopting a more continuous view of competition as varying from strongly transitive to strongly intransitive. The studies also examine relationships between intransitivity and functional diversity and explore the evolution of intransitivity over time. Synthesis. The studies presented here advance the field by integrating intransitive competition into species coexistence and general ecological theory. We also highlight important research gaps that will hopefully inspire the next generation of studies in this topic.

show abstract

Section: Beyond Species Coexistence: What Are the Consequences Of Intsupporting

confidence: 54%

Section: A Short Story Of a Difficult Task: How Can We Measure Intranmentioning

confidence: 99%

Everything you always wanted to know about intransitive competition but were afraid to ask

Soliveres

Allan

2018

Journal of Ecology

View full text Add to dashboard Cite

show abstract

“…If functional traits of species do affect their likelihood of engaging in intransitive competition then we might expect changes in intransitivity to also feed‐back to affect trait distributions. Previous studies have shown an increase in functional trait diversity under intransitive competition (Maynard, Bradford, et al., ; Ulrich et al., ), but these changes are not always expected (Gallien, ). Our results suggest that, if intransitive competition is driven by reciprocal competitive advantages (as seems to be the cases for fungi, mosses and bacteria), then it should strongly relate to functionally diverse communities.…”

Section: Discussionmentioning

confidence: 95%

“…C uptake vs. aggressiveness; see also Maynard, Crowther, et al., ). Assuming that functional traits were not only related only to competitive ranks, but also to the different ways by which different species compete for resources (Kraft et al., ; Kunstler et al., ; see also Ulrich et al., , Supplementary Material ), this could explain the positive effects of trait variation in the intransitivity level of triplets of fungi, mosses or bacteria (Figure ) even when the variance in competitive ranks had a negative effect. However, when competing species are too different in their ranks (i.e.…”

Section: Discussionmentioning

confidence: 99%

“…This limitation is particularly important when pairwise competition experiments are conducted without replication (such as in our vascular plants and fungi). To address this issue, we calculated a new metric ( Inest ) based on the “nestedness” of the matrix, which allows us to use all the information from the RYs (see figure S2b in Ulrich et al., ). By using the RYs directly, we downweight competitive reversals that arise from small competitive advantages in our estimation of intransitivity (e.g.…”

Section: Methodsmentioning

confidence: 99%

See 1 more Smart Citation

Intransitive competition is common across five major taxonomic groups and is driven by productivity, competitive rank and functional traits

et al. 2018

View full text Add to dashboard Cite

Competition can be fully hierarchical or intransitive, and this degree of hierarchy is driven by multiple factors, including environmental conditions, the functional traits of the species involved or the topology of competition networks. Studies simultaneously analysing these drivers of competition hierarchy are rare. Additionally, organisms compete either directly or via interference competition for resources or space, within a local neighbourhood or across the habitat. Therefore, the drivers of competition could change accordingly and depend on the taxa studied. We performed the first multi‐taxon study on pairwise competition across major taxonomic groups, including experiments with vascular plants, mosses, saprobic fungi, aquatic protists and soil bacteria. We evaluated how general is competition intransitivity from the pairwise competition matrix including all species and also for each possible three‐species combination (triplets). We then examined which species were likely to engage in competitive loops and the effects of environmental conditions, competitive rank and functional traits on intransitive competition. We found some degree of competition intransitivity in all taxa studied, with 38% to 5% of triplets being intransitive. Variance in competitive rank between species and more fertile conditions strongly reduced intransitivity, with triplets composed of species differing widely in their competitive ranks much less likely to be intransitive. Including functional traits of the species involved more than doubled the variation explained compared to models including competitive rank only. Both trait means and variance within triplets affected the odds of them being intransitive. However, the traits responsible and the direction of trait effects varied widely between taxa, suggesting that traits can have a wide variety of effects on competition. Synthesis. We evaluated the drivers of competition across multiple taxa and showed that productivity and competitive rank are fundamental drivers of intransitivity. We also showed that not only the functional traits of each species, but also those of the accompanying species, determine competition intransitivity. Intransitive competition is common across multiple taxa but can dampen under fertile conditions or for those species with large variance in their competitive abilities. This provides a first step towards predicting the prevalence of intransitive competition in natural communities.

show abstract

Soil resource availability is much more important than soil resource heterogeneity in determining the species diversity and abundance of karst plant communities

Yuan

et al. 2021

Ecology and Evolution

View full text Add to dashboard Cite

show abstract

Functional traits and environmental characteristics drive the degree of competitive intransitivity in European saltmarsh plant communities

Cited by 28 publications

References 65 publications

Everything you always wanted to know about intransitive competition but were afraid to ask

Everything you always wanted to know about intransitive competition but were afraid to ask

Intransitive competition is common across five major taxonomic groups and is driven by productivity, competitive rank and functional traits

Soil resource availability is much more important than soil resource heterogeneity in determining the species diversity and abundance of karst plant communities

Contact Info

Product

Resources

About