Comparing evolutionary rates between trees, clades and traits

Revell, Liam J.; González‐Valenzuela, Laura E.; Alfonso, Alejandro; Castellanos‐García, Luisa A.; Guarnizo, Carlos E.; Crawford, Andrew J.

doi:10.1111/2041-210x.12977

Cited by 27 publications

(18 citation statements)

References 53 publications

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“…We also used the function "ratebytree" from the R package "phytools" (Revell, 2012) to evaluate whether there are differences in the rate of CTmax and CTmin evolution. This function allows the comparison of phenotypic evolution of continuous traits between trees under different models of evolution: "random walk" (Brownian motion, BM) and the adaptive models Ornstein-Uhlenbeck (OU) and early burst (EB) (Revell et al, 2018). We first fitted the three different models of evolution to each physiological trait (CTmax and CTmin) using the "fitContinuous" function from the R package geiger (Harmon, Weir, Brock, Glor, & Challenger, 2008).…”

Section: Statistical Analysesmentioning

confidence: 99%

Elevational and microclimatic drivers of thermal tolerance in Andean Pristimantis frogs

Pintanel

Tejedo

Ron

et al. 2019

Journal of Biogeography

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Aim We analysed elevational and microclimatic drivers of thermal tolerance diversity in a tropical mountain frog clade to test three macrophysiological predictions: less spatial variation in upper than lower thermal limits (Bretts’ heat‐invariant hypothesis); narrower thermal tolerance ranges in habitats with less variation in temperature (Janzen's climatic variability hypothesis); and higher level of heat impacts at lower elevations. Location Forest and open habitats through a 4,230‐m elevational gradient across the tropical Andes of Ecuador. Method We examined variability in critical thermal limits (CTmax and CTmin) and thermal breadth (TB; CTmax–CTmin) in 21 species of Pristimantis frogs. Additionally, we monitored maximum and minimum temperatures at the local scale (tmax, tmin) and estimated vulnerability to acute thermal stress from heat (CTmax–tmax) and cold (tmin–CTmin), by partitioning thermal diversity into elevational and microclimatic variation. Results Our results were consistent with Brett's hypothesis: elevation promotes more variation in CTmin and tmin than in CTmax and tmax. Frogs inhabiting thermally variable open habitats have higher CTmax and tmax and greater TBs than species restricted to forest habitats, which show less climatic overlap across the elevational gradient (Janzen's hypothesis). Vulnerability to heat stress was higher in open than forest habitats and did not vary with elevation. Main conclusions We suggest a mechanistic explanation of thermal tolerance diversity in elevational gradients by including microclimatic thermal variation. We propose that the unfeasibility to buffer minimum temperatures locally may explain the rapid increase in cold tolerance (lower CTmin) with elevation. In contrast, the relative invariability in heat tolerance (CTmax) with elevation may revolve around the organisms’ habitat selection of open‐ and canopy‐buffered habitats. Secondly, on the basis of microclimatic estimates, lowland and upland species may be equally vulnerable to temperature increase, which is contrary to the pattern inferred from regional interpolated climate estimators.

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Section: Statistical Analysesmentioning

confidence: 99%

Elevational and microclimatic drivers of thermal tolerance in Andean Pristimantis frogs

Pintanel

Tejedo

Ron

et al. 2019

Journal of Biogeography

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“…These advantages with thinner roots could increase the plant's efficiency to absorb water and nutrients (Chen et al ., ), and shape the different responses of biomass to warming between gymnosperms and angiosperms. However, in general, the divergence age could not predict the magnitude of the phylogenetic components well (Tables S3, S4), indicating that the evolutionary rate might vary among different clades (Revell et al ., ).…”

Section: Discussionmentioning

confidence: 97%

“…These methods relied on the underlying evolutionary models such as Brownian motion and Ornstein-Uhlenbeck models. However, as the evolutionary processes might be more complicated than the model assumption (Castiglione et al, 2018;Revell et al, 2018), these methods could underestimate the contribution of phylogenetic effects (Cadotte et al, 2017). For that reason, we applied a purely data-driven variance partitioning approach, the phylogenetic eigenvector regression (PVR; Diniz-Filho et al, 1998;Desdevises et al, 2003), to partition the total variance in biomass responses.…”

Section: Partitioning the Total Variancementioning

confidence: 99%

Plant evolutionary history mainly explains the variance in biomass responses to climate warming at a global scale

Shao

Yuan

et al. 2019

New Phytologist

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Summary Evolutionary history shapes the interspecific relatedness and intraspecific variation, which has a profound influence on plant functional traits and productivity. However, it is far from clear how the phylogenetic relatedness among species and intraspecific variation could contribute to the observed variance in plant biomass responses to climate warming. We compiled a dataset with 284 species from warming experiments to explore the relative importance of phylogenetic, intraspecific, experimental and ecological factors to warming effects on plant biomass, using phylogenetic eigenvector regression and variance decomposition. Our results showed that phylogenetic relatedness could account for about half the total variance in biomass responses to warming, which were correlated with leaf economic traits at the family level but not at species level. The intraspecific variation contributed to approximately one‐third of the variance, whereas the experimental design and ecological characteristics only explained 7–17%. These results suggest that intrinsic factors (evolutionary history) play more important roles than extrinsic factors (experimental treatment and environment) in determining the responses of plant biomass to warming at the global scale. This highlights the urgent need for land surface models to include evolutionary aspects in predicting ecosystem functions under climate change.

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“…To deal with this problem, the BBMV package calculates the likelihood of the FPK model over multiple clades by multiplying the likelihoods in all clades. This procedure is similar to one that was recently published for the BM model (Revell et al 2018). Functions exist to fit 1) a model in which all clades share the same macroevolutionary landscape and the same rate of evolution, 2) a model in which all clades share the same macroevolutionary landscape but have different rates of evolution, or 3) a model in which both the macroevolutionary landscape and the rate of evolution can vary between clades.…”

Section: Fitting the Fpk Model To Multiple Clades At Oncementioning

confidence: 99%

BBMV: an R package for the estimation of macroevolutionary landscapes

Boucher

2018

Ecography

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The distribution of traits along phylogenies bears signatures of how ecological and evolutionary processes have interacted to influence phenotypic evolution, which can be deciphered using macroevolutionary models. BBMV implements a model for the evolution of continuous characters on phylogenies that generalizes existing ones, like Brownian motion and the Ornstein-Uhlenbeck model. In this model quantitative characters evolve under both random diffusion and a deterministic force that can be of any possible shape and strength. The model can be used to infer evolutionary scenarios that remained inaccessible so far, like directional trends, disruptive selection, and even bounded evolution. With this new tool at hand, researchers will be able to test complex hypothesis-driven scenarios regarding trait evolution, but they will also have the possibility to estimate the shape of the adaptive landscapes in which traits evolved. Ultimately, this will provide a way to infer how ecological processes have influenced phenotypic evolution over long timescales. The BBMV package is implemented in the R statistical language and is freely available on the CRAN repository . All source code can also be found on < https://github.com/fcboucher/BBMV >, along with a detailed tutorial.

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Comparing evolutionary rates between trees, clades and traits

Cited by 27 publications

References 53 publications

Elevational and microclimatic drivers of thermal tolerance in Andean Pristimantis frogs

Elevational and microclimatic drivers of thermal tolerance in Andean Pristimantis frogs

Plant evolutionary history mainly explains the variance in biomass responses to climate warming at a global scale

BBMV: an R package for the estimation of macroevolutionary landscapes

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