Complex relationships between species niches and environmental heterogeneity affect species co-occurrence patterns in modelled and real communities

Bar‐Massada, Avi

doi:10.1098/rspb.2015.0927

Cited by 52 publications

(56 citation statements)

References 45 publications

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“…To that end, pairs of taxa were identified as potentially interacting if they were found more or less frequently together than expected by random chance. Given that every local environment is initially identical, cooccurrence patterns are not linked to initial abiotic conditions and "habitat-filtering," a common problem for studies done in situ (32). Overall, we observed a larger number of interactions in the anaerobic samples than in the aerobic samples (Table 1 and Fig.…”

Section: Discussionmentioning

confidence: 57%

Environmental Selection, Dispersal, and Organism Interactions Shape Community Assembly in High-Throughput Enrichment Culturing

Justice

Sczesnak

Hazen

et al. 2017

Appl Environ Microbiol

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A central goal of microbial ecology is to identify and quantify the forces that lead to observed population distributions and dynamics. However, these forces, which include environmental selection, dispersal, and organism interactions, are often difficult to assess in natural environments. Here, we present a method that links microbial community structures with selective and stochastic forces through highly replicated subsampling and enrichment of a single environmental inoculum. Specifically, groundwater from a well-studied natural aquifer was serially diluted and inoculated into nearly 1,000 aerobic and anaerobic nitrate-reducing cultures, and the final community structures were evaluated with 16S rRNA gene amplicon sequencing. We analyzed the frequency and abundance of individual operational taxonomic units (OTUs) to understand how probabilistic immigration, relative fitness differences, environmental factors, and organismal interactions contributed to divergent distributions of community structures. We further used a most probable number (MPN) method to estimate the natural condition-dependent cultivable abundance of each of the nearly 400 OTU cultivated in our study and infer the relative fitness of each. Additionally, we infer condition-specific organism interactions and discuss how this high-replicate culturing approach is essential in dissecting the interplay between overlapping ecological forces and taxon-specific attributes that underpin microbial community assembly.IMPORTANCE Through highly replicated culturing, in which inocula are subsampled from a single environmental sample, we empirically determine how selective forces, interspecific interactions, relative fitness, and probabilistic dispersal shape bacterial communities. These methods offer a novel approach to untangle not only interspecific interactions but also taxon-specific fitness differences that manifest across different cultivation conditions and lead to the selection and enrichment of specific organisms. Additionally, we provide a method for estimating the number of cultivable units of each OTU in the original sample through the MPN approach.KEYWORDS 16S RNA, community assembly, enrichment culturing, microbial ecology M icrobial communities are central players in Earth's biogeochemical cycles (1), human health (2), biotechnological processes, such as wastewater treatment (3), and the production of foods (4). Underpinning the structure, function, and evolution of all these communities are the ecological forces of dispersal, drift, selection, and speciation (5, 6). Even on short timescales, in which one can ignore evolutionary mechanisms of diversification, drift, selection, and dispersal interact to turn over populations of organisms in both predictable and unpredictable ways. Unpredictable changes in community structure are rooted in random dispersal and drift, while predictable changes are caused by

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Section: Discussionmentioning

confidence: 57%

Environmental Selection, Dispersal, and Organism Interactions Shape Community Assembly in High-Throughput Enrichment Culturing

Justice

Sczesnak

Hazen

et al. 2017

Appl Environ Microbiol

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“…This study is unique as it explicitly examined several confounding factors that are often ignored (Bar‐Massada ), but may substantially bias the results of co‐occurrence analyses. For example, species co‐occurrence analyses typically conflate species interactions with environmental filtering, making separating the two difficult.…”

Section: Discussionmentioning

confidence: 97%

“…Previous studies have shown that non‐random species co‐occurrence patterns might emerge simply due to the degree of similarity in species’ niches, the amount of cohesion in their geographic distributions, and the environmental heterogeneity of the regions they inhabit (Connor, Collins & Simberloff ; Bar‐Massada ; Royan et al . ).…”

Section: Methodsmentioning

confidence: 99%

“…). For example, increasing levels of niche overlap between tree species leads to more aggregated co‐occurrence patterns, while increased environmental heterogeneity leads to more segregated patterns (Bar‐Massada ). Co‐occurrence analyses should account for these confounding factors if one attempts to gain insight about relationships between co‐occurrence patterns and biotic interactions.…”

Section: Introductionmentioning

confidence: 99%

“…However, these analyses are confounded by several factors that can lead to non‐random co‐occurrence patterns even in the absence of interspecific interactions. These factors include similarities between species’ environmental preferences (Bar‐Massada ; Royan et al . ), environmental heterogeneity (Heino & Grönroos ; Bar‐Massada ) and differences in geographic ranges (Connor, Collins & Simberloff ; Pollock et al .…”

Section: Introductionmentioning

confidence: 99%

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Non‐stationarity in the co‐occurrence patterns of species across environmental gradients

Bar‐Massada

Belmaker

2017

Journal of Ecology

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Summary Quantifying the role of biotic interactions in driving community assembly often relies on analysing species co‐occurrence patterns, where segregated patterns are taken to indicate antagonistic interactions such as competition. It is unknown, however, if co‐occurrence patterns are stationary across environmental gradients, as it is possible that the strength of biotic interactions that drive these patterns also depends on the environment. In this study, we aim to understand how patterns of co‐occurrence change when species move from their environmental range centre towards their range periphery while isolating the potential signal of biotic interactions from confounding factors. We used two separate statistical approaches (null models and joint species distribution models) to quantify pairwise co‐occurrence patterns for tree species sampled in 9382 plots distributed across the conterminous US. We also analysed co‐occurrence patterns that emerged from a simple meta‐community model. We then assessed how patterns of species segregation and aggregation change in relation to habitat suitability while accounting for multiple factors known to confound co‐occurrence analyses. We found strong non‐stationarity in co‐occurrences, with patterns shifting from segregated at the environmental range centre towards aggregated at range margins for the majority of tree species. Patterns were in full agreement between model simulations and both empirical analyses. Model simulations suggest that this pattern is at least partly driven by variation in the relative abundances of non‐focal species even when no direct biological interactions are present. Synthesis. Patterns of tree species co‐occurrence vary across environmental gradients, with increased segregation when environmental conditions are optimal and increased aggregation when the environment is less suitable. This pattern may originate from a trade‐off between the abundance of the focal species pair, which decreases towards the environmental range margin, and the increasing abundance of non‐focal species to which the environment is more suitable. The strong dependence of co‐occurrence patterns on environmental conditions might limit the predictive ability of joint species distribution models, which couple species co‐occurrences and their environmental responses, because co‐occurrence patterns and environmental responses are confounded.

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Sharing space between native and invasive small mammals: Study of commensal communities in Senegal

Granjon,

Artige,

Bâ

et al. 2023

Ecology and Evolution

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Urbanization processes are taking place at a very high rate, especially in Africa. At the same time, a number of small mammal species, be they native or invasive, take advantage of human‐induced habitat modifications. They represent commensal communities of organisms that cause a number of inconveniences to humans, including potential reservoirs of zoonotic diseases. We studied via live trapping and habitat characterization such commensal small mammal communities in small villages to large cities of Senegal, to try to understand how the species share this particular space. Seven major species were recorded, with exotic invasive house mice (Mus musculus) and black rats (Rattus rattus) dominating in numbers. The shrew Crocidura olivieri appeared as the main and more widespread native species, while native rodent species (Mastomys natalensis, M. erythroleucus, Arvicanthis niloticus and Praomys daltoni) were less abundant and/or more localized. Habitat preferences, compared between species in terms of room types and characteristics, showed differences among house mice, black rats and M. natalensis especially. Niche (habitat component) breadth and overlap were measured. Among invasive species, the house mouse showed a larger niche breadth than the black rat, and overall, all species displayed high overlap values. Co‐occurrence patterns were studied at the global and local scales. The latter show cases of aggregation (between the black rat and native species, for instance) and of segregation (as between the house mouse and the black rat in Tambacounda, or between the black rat and M. natalensis in Kédougou). While updating information on commensal small mammal distribution in Senegal, a country submitted to a dynamic process of invasion by the black rat and the house mouse, we bring original information on how species occupy and share the commensal space, and make predictions on the evolution of these communities in a period of ever‐accelerating global changes.

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Complex relationships between species niches and environmental heterogeneity affect species co-occurrence patterns in modelled and real communities

Cited by 52 publications

References 45 publications

Environmental Selection, Dispersal, and Organism Interactions Shape Community Assembly in High-Throughput Enrichment Culturing

Environmental Selection, Dispersal, and Organism Interactions Shape Community Assembly in High-Throughput Enrichment Culturing

Non‐stationarity in the co‐occurrence patterns of species across environmental gradients

Sharing space between native and invasive small mammals: Study of commensal communities in Senegal

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