A framework for evaluating the influence of climate, dispersal limitation, and biotic interactions using fossil pollen associations across the late Quaternary

Blois, Jessica L.; Gotelli, Nicholas J.; Behrensmeyer, Anna K.; Faith, J. Tyler; Lyons, S. Kathleen; Williams, John W.; Amatangelo, Kathryn L.; Bercovici, Antoine; Du, Andrew; Eronen, Jussi T.; Graves, Gary R.; Jud, Nathan A.; Labandeira, Conrad C.; Looy, Cindy V.; McGill, Brian J.; Patterson, David B.; Potts, Richard; Riddle, Brett R.; Terry, Robert M.; Tóth, Anikó B.; Villaseñor, Amelia; Wing, Scott L.

doi:10.1111/ecog.00779

Cited by 75 publications

(149 citation statements)

References 62 publications

(94 reference statements)

Supporting

Mentioning

141

Contrasting

Unclassified

Order By: Relevance

“…The first 'Classic framework' has been recently proposed and applied to examine taxon associations through time for late Quaternary fossil pollen assemblages at relatively large spatial extent and small spatial grain (Blois et al 2014). The first 'Classic framework' has been recently proposed and applied to examine taxon associations through time for late Quaternary fossil pollen assemblages at relatively large spatial extent and small spatial grain (Blois et al 2014).…”

Section: Discussionmentioning

confidence: 99%

“…Diamond (1975) proposed that species coexistence is regulated by 'community assembly rules' based primarily on species interactions, and inferred these rules from the pattern of species co-occurrence in replicated island assemblages. Since then, the search for community assembly rules has dominated community ecology (Gotelli and Graves 1996, Ovaskainen et al 2010, Boulangeat et al 2012, HilleRisLambers et al 2012, Blois et al 2014), and null model analysis has become a standard tool to search for patterns that may reflect processes of community assembly (Gotelli and Ulrich 2012). Since then, the search for community assembly rules has dominated community ecology (Gotelli and Graves 1996, Ovaskainen et al 2010, Boulangeat et al 2012, HilleRisLambers et al 2012, Blois et al 2014), and null model analysis has become a standard tool to search for patterns that may reflect processes of community assembly (Gotelli and Ulrich 2012).…”

Section: Introductionmentioning

confidence: 99%

“…1a, b left box), the pattern of spatial overlap in pairwise occurrences (Fig. 1d left box), (Blois et al 2014 Is the environment at different types of sites significant? 1d left box), (Blois et al 2014 Is the environment at different types of sites significant?…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Disentangling biotic interactions, environmental filters, and dispersal limitation as drivers of species co‐occurrence

et al. 2017

Self Cite

View full text Add to dashboard Cite

A key focus in ecology is to search for community assembly rules. Here we compare two community modelling frameworks that integrate a combination of environmental and spatial data to identify positive and negative species associations from presenceabsence matrices, and incorporate an additional comparison using joint species distribution models (JSDM).The frameworks use a dichotomous logic tree that distinguishes dispersal limitation, environmental requirements, and interspecific interactions as causes of segregated or aggregated species pairs. The first framework is based on a classical null model analysis complemented by tests of spatial arrangement and environmental characteristics of the sites occupied by the members of each species pair (Classic framework). The second framework, (SDM framework) implemented here for the first time, builds on the application of environmentally-constrained null models (or JSDMs) to partial out the influence of the environment, and includes an analysis of the geographical configuration of species ranges to account for dispersal effects.We applied these approaches to examine plot-level species co-occurrence in plant communities sampled along a wide elevation gradient in the Swiss Alps. According to the frameworks, the majority of species pairs were randomly associated, and most of the non-random positive and negative species associations could be attributed to environmental filtering and/or dispersal limitation. These patterns were partly detected also with JSDM. Biotic interactions were detected more frequently in the SDM framework, and by JSDM, than in the Classic framework. All approaches detected species aggregation more often than segregation, perhaps reflecting the important role of facilitation in stressful high-elevation environments.Differences between the frameworks may reflect the explicit incorporation of elevational segregation in the SDM framework and the sensitivity of JSDM to the environmental data. Nevertheless, all methods have the potential to reveal general patterns of species co-occurrence for different taxa, spatial scales, and environmental conditions.

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Disentangling biotic interactions, environmental filters, and dispersal limitation as drivers of species co‐occurrence

et al. 2017

Self Cite

View full text Add to dashboard Cite

show abstract

“…Such modern-day corroborations are stimulating novel analyses of living populations in light of geologic history, finding, for example, that present-day endemism is most strongly correlated with the velocity of postglacial climate change rather than with a threshold temperature or particular direction of change (86) and that populations along the margin of a species' range still exhibit low genetic diversity, a legacy of Quaternary expansion (87). Young fossil records alone show (i) just how pervasive changes in species' distributions are likely to become, constituting both local losses and additions, (ii) that novel groupings are most likely to emerge near the edges rather than centers of biogeographic provinces or ranges (88,89), (iii) that species most able to cross former boundaries and those showing strongest population declines are not random draws from their parent community (79,90), and (iv) that species associations suggesting biotic interactions are rare and inconstant (91).…”

Section: Proxy Evidence Of (Paleo)environmentalmentioning

confidence: 99%

Biology in the Anthropocene: Challenges and insights from young fossil records

Kidwell

2015

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

117

View full text Add to dashboard Cite

With overwhelming evidence of change in habitats, biologists today must assume that few, if any, study areas are natural and that biological variability is superimposed on trends rather than stationary means. Paleobiological data from the youngest sedimentary record, including death assemblages actively accumulating on modern land surfaces and seabeds, provide unique information on the status of present-day species, communities, and biomes over the last few decades to millennia and on their responses to natural and anthropogenic environmental change. Key advances have established the accuracy and resolving power of paleobiological information derived from naturally preserved remains and of proxy evidence for environmental conditions and sample age so that fossil data can both implicate and exonerate human stressors as the drivers of biotic change and permit the effects of multiple stressors to be disentangled. Legacy effects from Industrial and even pre-Industrial anthropogenic extirpations, introductions, (de)nutrification, and habitat conversion commonly emerge as the primary factors underlying the present-day status of populations and communities; within the last 2 million years, climate change has rarely been sufficient to drive major extinction pulses absent other human pressures, which are now manifold. Young fossil records also provide rigorous access to the baseline composition and dynamics of modern-day biota under pre-Industrial conditions, where insights include the millennial-scale persistence of community structures, the dominant role of physical environmental conditions rather than biotic interactions in determining community composition and disassembly, and the existence of naturally alternating states.biodiversity | ecology | conservation | paleobiology | paleoecology

show abstract

“…However, these authors used indirect evidence within the community assembly framework that assumes that overdispersion of phylogenetic and functional traits is a consequence of competitive interactions (Darwin’s competition-relatedness hypothesis, reviewed in Allan et al 2013, Götzenberger et al 2012) [85–86]. However, Cahill et al (2008) [87] found little evidence for this assertion and it is now well known that overdispersion (spatial segregation) might stem from different processes, particularly from filter effects within heterogeneous landscapes [88] and even from dispersal limited neutral community assembly [89]. Here we used a direct way to assess whether any set of competitive strength relationships between species is able to predict observed abundance distributions.…”

Section: Discussionmentioning

confidence: 99%

Contrasting Patterns of Species Richness and Functional Diversity in Bird Communities of East African Cloud Forest Fragments

et al. 2016

View full text Add to dashboard Cite

Rapid fragmentation and degradation of large undisturbed habitats constitute major threats to biodiversity. Several studies have shown that populations in small and highly isolated habitat patches are prone to strong environmental and demographic stochasticity and increased risk of extinction. Based on community assembly theory, we predict recent rapid forest fragmentation to cause a decline in species and functional guild richness of forest birds combined with a high species turnover among habitat patches, and well defined dominance structures, if competition is the major driver of community assembly. To test these predictions, we analysed species co-occurrence, nestedness, and competitive strength to infer effects of interspecific competition, habitat structure, and species′ traits on the assembly of bird species communities from 12 cloud forest fragments in southern Kenya. Our results do not point to a single ecological driver of variation in species composition. Interspecific competition does not appear to be a major driver of species segregation in small forest patches, while its relative importance appears to be higher in larger ones, which may be indicative for a generic shift from competition-dominated to colonisation-driven community structure with decreasing fragment size. Functional trait diversity was independent of fragment size after controlling for species richness. As fragmentation effects vary among feeding guilds and habitat generalists, in particular, tend to decline in low quality forest patches, we plead for taking species ecology fully into account when predicting tropical community responses to habitat change.

show abstract

A framework for evaluating the influence of climate, dispersal limitation, and biotic interactions using fossil pollen associations across the late Quaternary

Cited by 75 publications

References 62 publications

Disentangling biotic interactions, environmental filters, and dispersal limitation as drivers of species co‐occurrence

Disentangling biotic interactions, environmental filters, and dispersal limitation as drivers of species co‐occurrence

Biology in the Anthropocene: Challenges and insights from young fossil records

Contrasting Patterns of Species Richness and Functional Diversity in Bird Communities of East African Cloud Forest Fragments

Contact Info

Product

Resources

About