Trait–environment relationships remain strong despite 50 years of trait compositional change in temperate forests

Amatangelo, Kathryn L.; Johnson, Susan; Rogers, David A.; Waller, Donald M.

doi:10.1890/13-0757.1

Cited by 44 publications

(60 citation statements)

References 83 publications

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“…However, at all spatial scales (10 × 10 m, 20 × 20 m, and 50 × 50 m), perhaps unexpectedly, we found that species with a large seed mass preferred the resource-rich part of the plot, while small-seeded species were distributed in the nutrient-limited part of the plot. A similar report also showed that large seed mass associated with nutrient-rich environments 41 . In summary, variation in the soil resource availability at these scales shapes the distribution of functional traits in a tropical forest.…”

Section: Discussionmentioning

confidence: 61%

Environmental filtering structures tree functional traits combination and lineages across space in tropical tree assemblages

Asefa

Cao

Zhang

et al. 2017

Sci Rep

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Environmental filtering consistently shapes the functional and phylogenetic structure of species across space within diverse forests. However, poor descriptions of community functional and lineage distributions across space hamper the accurate understanding of coexistence mechanisms. We combined environmental variables and geographic space to explore how traits and lineages are filtered by environmental factors using extended RLQ and fourth-corner analyses across different spatial scales. The dispersion patterns of traits and lineages were also examined in a 20-ha tropical rainforest dynamics plot in southwest China. We found that environmental filtering was detected across all spatial scales except the largest scale (100 × 100 m). Generally, the associations between functional traits and environmental variables were more or less consistent across spatial scales. Species with high resource acquisition-related traits were associated with the resource-rich part of the plot across the different spatial scales, whereas resource-conserving functional traits were distributed in limited-resource environments. Furthermore, we found phylogenetic and functional clustering at all spatial scales. Similar functional strategies were also detected among distantly related species, suggesting that phylogenetic distance is not necessarily a proxy for functional distance. In summary, environmental filtering considerably structured the trait and lineage assemblages in this species-rich tropical rainforest.

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Section: Discussionmentioning

confidence: 61%

Environmental filtering structures tree functional traits combination and lineages across space in tropical tree assemblages

Asefa

Cao

Zhang

et al. 2017

Sci Rep

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“…We determined the dispersal mode of our 26 most common quadrat species by referring to a plant traits database compiled from literature and field specimens (Amatangelo et al . ). The sapling (0·6 cm ≤ DBH <10 cm) and tree tallies were converted to plot‐level averages for hardwood and conifer sapling and overstory basal area (BA, m 2 ha −1 ).…”

Section: Methodsmentioning

confidence: 97%

Deer‐mediated changes in environment compound the direct impacts of herbivory on understorey plant communities

et al. 2017

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Summary In forests of eastern North America, white‐tailed deer (Odocoileus virginianus) can directly affect, via herbivory, the presence, abundance and reproductive success of many plant species. In addition, deer indirectly influence understorey communities by altering environmental conditions. To examine how deer indirectly influence understorey plants via environmental modification, we sampled vegetation and environmental variables in‐ and outside deer exclosures (10–20 years old) located in temperate forests in northern Wisconsin and the Upper Peninsula of Michigan, USA. We assessed how excluding deer affected understorey community composition and structure, the soil and light environment, and relationships between direct and indirect effects, using non‐metric multidimensional scaling (NMDS), mixed linear models and nonparametric multiplicative regression (NPMR). Excluding deer altered sapling communities and several aspects of the understorey environment. Excluding deer from plots with lower overstory basal area increased sapling abundance, decreasing the amount of light available to groundlayer plants. Exclusion also reduced soil compaction and the thickness of the soil E horizon. The composition of understorey communities covaried in apparent response to the environmental factors affected by exclusion. In several common species and groups, E horizon thickness, compaction, openness, and/or total (sapling and overstory) basal area were significant predictors of plant frequency. Complementary analyses revealed that deer exclusion also altered the frequency distributions of several species and groups across environmental space. Synthesis. Deer alter many facets of the understorey environment, such as light availability, soil compaction and thickness of the soil E horizon, which, in turn, appear to mediate variation in plant communities. Those environmental modifications likely compound direct impacts of herbivory as drivers of understorey community change. Our results provide evidence that deer effects on the environment have important implications for forest composition. Thus, we suggest a re‐examination of the common assumption that understorey community shifts stem primarily from tissue removal.

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“…Life history traits and range characteristics served to predict extinction risk due to climate change in some regions (Pearson et al ., ), but these responses are complex and rarely generalize to predict range shifts across a broad range of taxa (Angert et al ., ). In studies resurveying multiple species across many sites, species’ traits can help to disentangle diverse drivers of ecological change (Leach & Givnish, ; Damschen et al ., ; Crimmins et al ., ; Soudzilovskaia et al ., ; Amatangelo et al ., ; Savage & Vellend, ). It is thus reasonable to suppose that traits might help explain the complex responses of individual species to climate change.…”

Section: Introductionmentioning

confidence: 99%

Tracking lags in historical plant species’ shifts in relation to regional climate change

Ash

Givnish

Waller

2016

Global Change Biology

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Can species shift their distributions fast enough to track changes in climate? We used abundance data from the 1950s and the 2000s in Wisconsin to measure shifts in the distribution and abundance of 78 forest-understory plant species over the last half-century and compare these shifts to changes in climate. We estimated temporal shifts in the geographic distribution of each species using vectors to connect abundance-weighted centroids from the 1950s and 2000s. These shifts in distribution reflect colonization, extirpation, and changes in abundance within sites, separately quantified here. We then applied climate analog analyses to compute vectors representing the climate change that each species experienced. Species shifted mostly to the northwest (mean: 49 ± 29 km) primarily reflecting processes of colonization and changes in local abundance. Analog climates for these species shifted even further to the northwest, however, exceeding species' shifts by an average of 90 ± 40 km. Most species thus failed to match recent rates of climate change. These lags decline in species that have colonized more sites and those with broader site occupancy, larger seed mass, and higher habitat fidelity. Thus, species' traits appear to affect their responses to climate change, but relationships are weak. As climate change accelerates, these lags will likely increase, potentially threatening the persistence of species lacking the capacity to disperse to new sites or locally adapt. However, species with greater lags have not yet declined more in abundance. The extent of these threats will likely depend on how other drivers of ecological change and interactions among species affect their responses to climate change.

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Trait–environment relationships remain strong despite 50 years of trait compositional change in temperate forests

Cited by 44 publications

References 83 publications

Environmental filtering structures tree functional traits combination and lineages across space in tropical tree assemblages

Environmental filtering structures tree functional traits combination and lineages across space in tropical tree assemblages

Deer‐mediated changes in environment compound the direct impacts of herbivory on understorey plant communities

Tracking lags in historical plant species’ shifts in relation to regional climate change

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