Patterns of relative species abundance in rainforests and coral reefs

Volkov, Igor; Banavar, Jayanth R.; Hubbell, Stephen P.; Maritan, Amos

doi:10.1038/nature06197

Cited by 266 publications

(346 citation statements)

References 20 publications

(7 reference statements)

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“…We use the formulation of Volkov et al (13), which is essentially equivalent to Hubbell's original zero-sum model (1,32). The dynamics of the species abundance distribution, P(N, t), are described by a master equation (1,13,33,34). Births and deaths are modeled as density-independent processes, so that births of individuals occur at a constant per capita rate, b, and deaths at a rate, d, such that b < d. Speciation is modeled as an immigration process at rate ν from the pool of all possible species:…”

Section: Ecologymentioning

confidence: 99%

An integrative framework for stochastic, size-structured community assembly

O’Dwyer

Lake

Ostling

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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We present a theoretical framework to describe stochastic, sizestructured community assembly, and use this framework to make community-level ecological predictions. Our model can be thought of as adding biological realism to Neutral Biodiversity Theory by incorporating size variation and growth dynamics, and allowing demographic rates to depend on the sizes of individuals. We find that the species abundance distribution (SAD) is insensitive to the details of the size structure in our model, demonstrating that the SAD is a poor indicator of size-dependent processes. We also derive the species biomass distribution (SBD) and find that the form of the SBD depends on the underlying size structure. This leads to a prescription for testing multiple, intertwined ecological predictions of the model, and provides evidence that alternatives to the traditional SAD are more closely tied to certain ecological processes. Finally, we describe how our framework may be extended to make predictions for more general types of community structure. ignited an ideological debate in community ecology, challenging the viewpoint that deterministic forces play the dominant role in shaping patterns of biodiversity (2-9). NBT proposes that community-level patterns are primarily determined by the effects of demographic stochasticity, and that a detailed knowledge of the traits of and interactions between individuals comprising the community is irrelevant. It has been argued that the predictions of NBT are uninformative of process (10-12), and it has been demonstrated that the assumptions underpinning NBT are often manifestly violated: in the tropical forests where the theory has found striking success (1,13,14), there is a huge variation in demographic rates of individuals (15,16). Although there has been much debate (6,17,18) about the importance of neutral, stochastic processes, one common principle has emerged (17-20): the need for a unified, theoretical framework both to quantify the effects of demographic stochasticity relative to other forces, and to generate a broader range of predictions more closely tied to process.In this article, we integrate the effects of demographic stochasticity with ontogenetic variation in the size of individuals (21), and allow the demographic rates of individuals to explicitly depend on their size. We assume that this variation in demographic rates depends on size alone, and is not linked to species identity, an approach that is closely related to the philosophy of allometric scaling theory (8,(22)(23)(24): individuals of a given size play by the same rules, regardless of species identity. Given the strong evidence that demographic rates in nature are correlated with size (8, 16), this synthesis of size variation with demographic stochasticity may be thought of as adding a crucial extra layer of biological realism to NBT.From these ingredients we derive a functional differential equation to describe ecological communities, and use its analytical solution to answer three key questions. First, are our predict...

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Section: Ecologymentioning

confidence: 99%

An integrative framework for stochastic, size-structured community assembly

O’Dwyer

Lake

Ostling

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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“…The characterization of biodiversity similarity among different LCs of the river network is carried out within a stochastic ecological framework (25)(26)(27)(28)(29) that allows us to formulate an analytically tractable model. We focus mainly on the study of a random variable, J(d), the relative fraction of common species between 2 LCs at distance d ϭ 0, 1, 2, … in link units.…”

Section: Modeling Spatial Biodiversity Similaritymentioning

confidence: 99%

Predicting spatial similarity of freshwater fish biodiversity

Azaele

Muneepeerakul²,

Maritan

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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A major issue in modern ecology is to understand how ecological complexity at broad scales is regulated by mechanisms operating at the organismic level. What specific underlying processes are essential for a macroecological pattern to emerge? Here, we analyze the analytical predictions of a general model suitable for describing the spatial biodiversity similarity in river ecosystems, and benchmark them against the empirical occurrence data of freshwater fish species collected in the Mississippi-Missouri river system. Encapsulating immigration, emigration, and stochastic noise, and without resorting to species abundance data, the model is able to reproduce the observed probability distribution of the Jaccard similarity index at any given distance. In addition to providing an excellent agreement with the empirical data, this approach accounts for heterogeneities of different subbasins, suggesting a strong dependence of biodiversity similarity on their respective climates. Strikingly, the model can also predict the actual probability distribution of the Jaccard similarity index for any distance when considering just a relatively small sample. The proposed framework supports the notion that simplified macroecological models are capable of predicting fundamental patterns-a theme at the heart of modern community ecology. macroecology ͉ river networks ͉ Jaccard index ͉ average annual runoff production ͉ Mississippi-Missouri basin T he fundamental mechanisms that underlie emergent biodiversity patterns are the fabric of the large canvas of ecological complexity (1-5), whose functioning across spatial and temporal scales is still challenging modern ecologists (6, 7).River ecosystems, like tropical forests, constitute an invaluable source of species diversity whose study can shed light on these puzzling issues (8), and whose insights will in turn resonate in the conservation biology of freshwater fauna suffering extinction rates comparable to the species decline in tropical rainforests (9). Riverine ecology has recognized the importance of geomorphology for biodiversity (10): on the one hand, ecologists have investigated the role of branches (11-13) and riparian zones (14) as primary habitats as well as the importance of tributaries (15) in sculpting species diversity (16, 17); on the other hand, theoretical studies have looked into possible implications of dendritic networks (18) on population persistence (19), species richness, and spatial turnover (20). Recent advances have also pointed out that simplifying neutral assumptions can reproduce important macroecological patterns in such dendritic structures (21).Indeed, despite the fact that biodiversity similarity among habitat patches is crucial to dispersal, speciation, and adaptation to climate diversity at large scales (22) and can also be related to species richness (23, 24), it is not well understood yet. Here, we develop an analytical model suggesting that essential features of biodiversity similarity in river ecosystems may be captured by using only the occurrence...

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“…In particular, neutral models [16][17][18] constitute an interesting entry into metacommunity dynamics: they assume ecological equivalence of species [6] and attribute a major role to the balance between demographic stochasticity and dispersal. Importantly, these models yield accurate quantitative descriptions of community structure [19]. An outstanding example is the fit of a neutral model to the rank-abundance diagram of tropical trees in Barro Colorado Island [20].…”

Section: Introductionmentioning

confidence: 99%

The evolution of the competition–dispersal trade-off affects α- and β-diversity in a heterogeneous metacommunity

et al. 2016

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Difference in dispersal ability is a key driver of species coexistence in metacommunities. However, the available frameworks for interpreting species diversity patterns in natura often overlook trade-offs and evolutionary constraints associated with dispersal. Here, we build a metacommunity model accounting for dispersal evolution and a competition-dispersal trade-off. Depending on the distribution of carrying capacities among communities, species dispersal values are distributed either around a single strategy (evolutionarily stable strategy, ESS), or around distinct strategies (evolutionary branching, EB). We show that limited dispersal generates spatial aggregation of dispersal traits in ESS and EB scenarios, and that the competition-dispersal trade-off strengthens the pattern in the EB scenario. Importantly, individuals in larger (respectively (resp.) smaller) communities tend to harbour lower (resp. higher) dispersal, especially under the EB scenario. We explore how dispersal evolution affects species diversity patterns by comparing those from our model to the predictions of a neutral metacommunity model. The most marked difference is detected under EB, with distinctive values of both aand b-diversity (e.g. the dissimilarity in species composition between small and large communities was significantly larger than neutral predictions). We conclude that, from an empirical perspective, jointly assessing community carrying capacity with species dispersal strategies should improve our understanding of diversity patterns in metacommunities.

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Patterns of relative species abundance in rainforests and coral reefs

Cited by 266 publications

References 20 publications

An integrative framework for stochastic, size-structured community assembly

An integrative framework for stochastic, size-structured community assembly

Predicting spatial similarity of freshwater fish biodiversity

The evolution of the competition–dispersal trade-off affects α- and β-diversity in a heterogeneous metacommunity

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