Niches versus neutrality: uncovering the drivers of diversity in a species-rich community.
TL;DR: This work provides the first empirical evidence that a niche-neutral model can explain niche space occupancy pattern in a natural species-rich community and suggests this class of model may be a useful hypothesis for the generation and maintenance of species diversity in other size-structured communities.
Abstract: Ecological models suggest that high diversity can be generated by purely niche-based, purely neutral or by a mixture of niche-based and neutral ecological processes. Here, we compare the degree to which four contrasting hypotheses for coexistence, ranging from niche-based to neutral, explain species richness along a body mass niche axis. We derive predictions from these hypotheses and confront them with species body-mass patterns in a highly sampled marine phytoplankton community. We find that these patterns are consistent only with a mechanism that combines niche and neutral processes, such as the emergent neutrality mechanism. In this work, we provide the first empirical evidence that a niche-neutral model can explain niche space occupancy pattern in a natural species-rich community. We suggest this class of model may be a useful hypothesis for the generation and maintenance of species diversity in other size-structured communities.
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TL;DR: A framework for disentangling the relative importance of deterministic and stochastic processes in generating site-to-site variation in species composition along ecological gradients and among biogeographic regions that differ in the size of the regional species pool is developed.
Abstract: Deterministic theories in community ecology suggest that local, niche-based processes, such as environmental filtering, biotic interactions and interspecific trade-offs largely determine patterns of species diversity and composition. In contrast, more stochastic theories emphasize the importance of chance colonization, random extinction and ecological drift. The schisms between deterministic and stochastic perspectives, which date back to the earliest days of ecology, continue to fuel contemporary debates (e.g. niches versus neutrality). As illustrated by the pioneering studies of Robert H. MacArthur and co-workers, resolution to these debates requires consideration of how the importance of local processes changes across scales. Here, we develop a framework for disentangling the relative importance of deterministic and stochastic processes in generating site-to-site variation in species composition (β-diversity) along ecological gradients (disturbance, productivity and biotic interactions) and among biogeographic regions that differ in the size of the regional species pool. We illustrate how to discern the importance of deterministic processes using null-model approaches that explicitly account for local and regional factors that inherently create stochastic turnover. By embracing processes across scales, we can build a more synthetic framework for understanding how niches structure patterns of biodiversity in the face of stochastic processes that emerge from local and biogeographic factors.
1,116 citations
TL;DR: This work redefined the traditional concept of assembly rules in a more general framework where the co‐occurrence of species is a product of chance, historical patterns of speciation and migration, dispersal, abiotic environmental factors, and biotic interactions, with none of these processes being mutually exclusive.
Abstract: Understanding how communities of living organisms assemble has been a central question in ecology since the early days of the discipline. Disentangling the different processes involved in community assembly is not only interesting in itself but also crucial for an understanding of how communities will behave under future environmental scenarios. The traditional concept of assembly rules reflects the notion that species do not co-occur randomly but are restricted in their co-occurrence by interspecific competition. This concept can be redefined in a more general framework where the co-occurrence of species is a product of chance, historical patterns of speciation and migration, dispersal, abiotic environmental factors, and biotic interactions, with none of these processes being mutually exclusive. Here we present a survey and meta-analyses of 59 papers that compare observed patterns in plant communities with null models simulating random patterns of species assembly. According to the type of data under study and the different methods that are applied to detect community assembly, we distinguish four main types of approach in the published literature: species co-occurrence, niche limitation, guild proportionality and limiting similarity. Results from our meta-analyses suggest that non-random co-occurrence of plant species is not a widespread phenomenon. However, whether this finding reflects the individualistic nature of plant communities or is caused by methodological shortcomings associated with the studies considered cannot be discerned from the available metadata. We advocate that more thorough surveys be conducted using a set of standardized methods to test for the existence of assembly rules in data sets spanning larger biological and geographical scales than have been considered until now. We underpin this general advice with guidelines that should be considered in future assembly rules research. This will enable us to draw more accurate and general conclusions about the non-random aspect of assembly in plant communities.
719 citations
TL;DR: This work introduces 12 different forms of functional rarity along gradients of species scarcity and trait distinctiveness and highlights the potential key role offunctional rarity in the long-term and large-scale maintenance of ecosystem processes.
Abstract: Rarity has been a central topic for conservation and evolutionary biologists aiming to determine the species characteristics that cause extinction risk. More recently, beyond the rarity of species, the rarity of functions or functional traits, called functional rarity, has gained momentum in helping to understand the impact of biodiversity decline on ecosystem functioning. However, a conceptual framework for defining and quantifying functional rarity is still lacking. We introduce 12 different forms of functional rarity along gradients of species scarcity and trait distinctiveness. We then highlight the potential key role of functional rarity in the long-term and large-scale maintenance of ecosystem processes, as well as the necessary linkage between functional and evolutionary rarity.
233 citations
TL;DR: The results demonstrate that at high fertility dominant species differ in resource use strategy, but as soil fertility declines over the long-term, dominant species increasingly converge on a resource-retentive strategy, which suggests that differentiation in resourceUse strategy is required for co-existence at highertility but not in low fertility ecosystems.
Abstract: 1. Functional trait diversity can reveal mechanisms of species co-existence in plant communities. Few studies have tested whether functional diversity for foliar traits related to resource use strategy increases or decreases with declining soil phosphorus (P) in forest communities.
2. We quantified tree basal area and four foliar functional traits (i.e. nitrogen (N), phosphorus (P), thickness and tissue density) for all woody species along the c. 120 kyr Franz Josef soil chronosequence in cool temperate rainforest, where strong shifts occur in light and soil nutrient availability (i.e. total soil P declines from 805 to 100 mg g–1). We combined the abundance and trait data in functional diversity indices to quantify trait convergence and divergence, in an effort to determine whether mechanisms of co-existence change with soil fertility.
3. Relationships between species trait means and total soil N and P were examined using multiple regression, with and without weighting of species abundances. We used Rao’s quadratic entropy to quantify functional diversity at the plot scale, then compared this with random expectation, using a null model that randomizes abundances across species within plots. Taxonomic diversity was measured using Simpson’s Diversity. Relationships between functional and taxonomic diversity and total soil P were examined using jackknife linear regression.
4. Leaf N and P declined and leaf thickness and density increased monotonically with declining total soil P along the sequence; these relationships were unaffected by abundance-weighting of species in the analyses. Inclusion of total soil N did not improve predictions of trait means. All measures of diversity calculated from presence/absence data were unrelated to total soil N and P. There was no evidence for a relationship between Rao values using quantitative abundances and total soil P. However, there was a strongly positive relationship between Rao, expressed relative to random expectation, and total soil P, indicating trait convergence of dominant species as soil P declined.
5. Synthesis: Our results demonstrate that at high fertility dominant species differ in resource use strategy, but as soil fertility declines over the long-term, dominant species increasingly converge on a resource-retentive strategy. This suggests that differentiation in resource use strategy is required for co-existence at high fertility but not in low fertility ecosystems.
200 citations
TL;DR: These results suggest that plant population and community dynamics in grassland communities should increase with increasing biomass and decrease with distur-bance ingrassland communities, and emphasize that contrasting community assembly processes mayoccurfordifferentnicheaxes, even withinasinglecommunity.
Abstract: Summary1. Understanding the processes by which species sort themselves into communities remains acentralpuzzleforattemptstomaintainbiodiversity.Itremainsunclearwhetheranysingleassemblyprocess is generally dominant or whether the influence of contrasting processes varies in a predict-able way relative to biotic and abiotic gradients. Abundance-weighted niche overlap betweenspeciesprovidesapowerfulmeansofcontrastingtwomajorassemblyprocesses–nichecomplemen-tarityandenvironmentalfiltering.2. We examined mean overlap for four vegetative functional traits, relative to that expected whenabundances were randomly allocated to species co-occurring in experimental plots in a wet mea-dow. This provided a test of whether any single assembly process prevailed for the meadow as awhole and across all traits. The effects of mowing, fertilization and dominant species removal, andassociated gradients of Simpson’s dominance and biomass on the niche overlap of plots, were alsoexamined.3. Nicheoverlapwashigherthanexpectedatrandomforthreeofthefourtraitsstudied(height,leafand stem dry matter content, leaf C:N ratio). However, niche overlap was lower than expected forspecificleafarea.4. Mowingwasthetreatmentwiththegreatesteffectonbothnicheoverlapandbiomass,withover-lap significantly lower in the absence of mowing for three of the traits, while biomass was lower inmown plots. For three of the traits there was evidence of a significant decrease in overlap withincreasing biomass, but notincreasing dominance. None of the significant mowing effects on over-lapremainedwhentheeffectofbiomasshadbeenremoved.5. Synthesis: Theseresultssuggestthattheimportanceofnichedifferencesbetweenspeciesinstruc-turing grassland communities should increase with increasing biomass and decrease with distur-bance in grassland communities. They also emphasize that contrasting community assemblyprocessesmayoccurfordifferentnicheaxes,evenwithinasinglecommunity.Key-words: coexistence, complementarity, fertilization, functional trait, meadow, mowing,null model, plant population and community dynamics, productivity, removalIntroduction
199 citations
References
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01 Jan 1934
TL;DR: For three-quarters of a century past more has been written about natural selection and the struggle for existence that underlies the selective process, than perhaps about any other single idea in the whole realm of Biology as discussed by the authors.
Abstract: For three-quarters of a century past more has been written about natural selection and the struggle for existence that underlies the selective process, than perhaps about any other single idea in the whole realm of Biology. We have seen natural selection laid on its Sterbebett, and subsequently revived again in the most recent times to a remarkable degree of vigor. There can be no doubt that the old idea has great survival value.
2,641 citations
TL;DR: Cellular carbon and nitrogen content and cell volume of nutritionally and morphologically diverse dinoflagellate species were measured to determine carbon to volume and nitrogen to volume relationships.
Abstract: Cellular carbon and nitrogen content and cell volume of nutritionally and morphologically diverse dinoflagellate species were measured to determine carbon to volume (C : vol) and nitrogen to volume (N : vol) relationships. Cellular C and N content ranged from 48 to 3.0 3 10 4 pgC cell 21 21 5
2,137 citations
TL;DR: Community ecology and ecosystem ecology seem to have existed in different worlds, and Levin (1989) suggests that the gulf between the two is the consequence of the different historical traditions in each.
Abstract: Community ecology and ecosystem ecology seem to have existed in different worlds. Levin (1989) suggests that the gulf between the two is the consequence of the different historical traditions in each. Community ecology, for example, emerged from basic studies, where generalized patterns were sought in the natural interactions among the biota. From the outset, the goal has been to deduce general and simple theory. On the other hand, many of the modelling approaches developed to understand ecosystem dynamics emerged from specific applied problems, where not only biotic but abiotic and human disturbances transformed ecosystem function. That tradition, therefore, is often more complete, but at the price of producing a collection of complex specific examples from which generalization is difficult.
1,426 citations
"Niches versus neutrality: uncoverin..." refers background in this paper
...A purely nichedriven model of coexistence is Holling’s textural model (Holling 1992) which also predicts aggregated species richness distributions although the underlying mechanism differs....
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01 Jan 1992
TL;DR: The role of marine organisms in primary production was discussed in this paper, where the importance of new production and the importance and measurement of New Production was discussed. But the role of Marine Organisms in Primary Production: Phytoplankton Size S.W. Lewis.
Abstract: Honorary Lecture: Towards Understanding the Roles of Phytoplankton in Biogeochemical Cycles R.W. Eppley. Factors Limiting Primary Productivity in the Sea: Light: The Nature and Measurement of Light Environment in the Ocean J.T.O. Kirk. Factors Limiting Primary Productivity in the Sea: Nutrients: Nutrient Limitation and Marine Photosynthesis J. Cullen, et al. Estimation of Global Ocean Production: Satellite Ocean Color Observations of Global Biogeochemical Cycles M.R. Lewis. The Role of Marine Organisms in Primary Production: Phytoplankton Size S.W. Chisholm. New Production and Biogeochemical Cycles: The Importance and Measurement of New Production T. Platt, et al. Loss Processes and Material Recycling: Respiration R.J. Geider. Phytoplankton in the Global Context: Biosphere, Atmosphere, Ocean Interactions J.A. Berry. 17 additional articles. Index.
1,044 citations