Convergence, Consilience, and the Evolution of Temperate Deciduous Forests

Edwards, Erika J.; Chatelet, David S.; Chen, Bo Chang; Ong, Jin Yao; Tagane, Shuichiro; Kanemitsu, Hironobu; Tagawa, Koichi; Teramoto, Kentaro; Park, Brian; Chung, Kuo-Fang; Hu, Jer Ming; Yahara, Tetsukazu; Donoghue, Michael J.

doi:10.1086/692627

Cited by 51 publications

(56 citation statements)

References 82 publications

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“…Specifically, our analyses are consistent with the view that the first viburnums had more-or-less entire (smooth) or irregularly toothed leaf margins, and that shifts into colder climates in multiple lineages were accompanied by the evolution of regularly toothed and/or lobed leaves (Schmerler et al, 2012;Edwards et al, 2016). Likewise, our findings support multiple shifts from the evergreen habit to the deciduous habit associated with adaptation to climates with prolonged winter freezing (Edwards et al, 2017). We note that there have also been reversals in both characters; for example, evergreen leaves with entire margins evolved in the cloud forests of the Neotropics.…”

Section: Ancestral Biomes and Biome Shifts Previous Analyses Have Resupporting

confidence: 86%

“…Instead, it appears that there were multiple transitions from warm temperate into cold temperate forests. The earliest of these shifts, perhaps in the Late Eocene, occurred in two clades (Opulus and Pseudotinus) that today occupy the coldest climates of any Viburnum species (Edwards et al, 2017; forests. It appears that the Porphyrotinus clade occupied warm temperate forests when it entered North America, and it is possible that the occupation of this biome (with limited distribution in North America today) preceded both the shift into cold temperate forests to the north and cloud forests to the south.…”

Section: By the Late Paleocene Or The Early Eocene We See Evidence Fomentioning

confidence: 99%

“…Species were assigned affinities to one or more of four mesic forest biome classes, following Edwards et al (2017): tropical/subtropical (T), warm temperate (i.e., lucidophyllous) (W), cold temperate (Co), and/or cloud forest (Cl). Tropical forests experience limited seasonality (i.e., temperature and precipitation remain relatively stable and high throughout the year).…”

Section: Introductionmentioning

confidence: 99%

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Joint phylogenetic estimation of geographic movements and biome shifts during the global diversification ofViburnum

Landis

Eaton

Clement

et al. 2019

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AbstractPhylogeny, fossils, biogeography, and biome occupancy provide evidence that reflects the singular evolutionary history of a clade. Despite the connections that bind them together, these lines of evidence are most often studied separately, by first inferring a fossil-dated molecular phylogeny, then mapping on ancestral ranges and biomes inferred from extant species. Here we jointly model the evolution of biogeographic ranges, biome affinities, and molecular sequences, incorporating fossils to estimate a dated phylogeny for all of the 163 extant species of the woody plant clade Viburnum (Adoxaceae) that we currently recognize. Our analyses indicate that while the major Viburnum lineages evolved in the Eocene, the majority of extant species originated since the Miocene. Viburnum radiated first in Asia, in warm, broad-leaved evergreen (lucidophyllous) forests. Within Asia we infer several early shifts into more tropical forests, and multiple shifts into forests that experience prolonged freezing. From Asia we infer two early movements into the New World. These two lineages probably first occupied warm temperate forests and adapted later to spreading cold climates. One of these lineages (Porphyrotinus) occupied cloud forests and moved south through the mountains of the Neotropics. Several other movements into North America took place more recently, facilitated by prior adaptations to freezing in the Old World. We also infer four disjunctions between Asia and Europe: the Tinus lineage is the oldest and probably occupied warm forests when it spread, while the other three were more recent and in cold-adapted lineages. These results variously contradict published accounts, especially the view that Viburnum radiated initially in cold forests and, accordingly, maintained vessel elements with scalariform perforations. We explored how the location and biome assignments of fossils affected our inference of ancestral areas and biome states. Our results are sensitive to, but not entirely dependent upon, the inclusion of fossil biome data. We argue that it will be critical to take advantage of all available lines of evidence to decipher events in the distant past, and the joint estimation approach developed here provides cautious hope even when fossil evidence is limited.

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Section: Ancestral Biomes and Biome Shifts Previous Analyses Have Resupporting

confidence: 86%

Section: By the Late Paleocene Or The Early Eocene We See Evidence Fomentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Joint phylogenetic estimation of geographic movements and biome shifts during the global diversification ofViburnum

Landis

Eaton

Clement

et al. 2019

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“…It was important that we gather data from as many different, independent sources as feasible rather than simply slicing up previously constructed "megaphylogenies" (66) for two reasons. First, very large trees are necessarily constructed using only the few genes that are widely available for many taxa; there is thus likely to be substantial uncertainty in both topology and divergence times (66)(67)(68) . Second, we wanted to minimize the correlation of error across datasets.…”

Section: Curation Of Phylogenetic Datasetsmentioning

confidence: 99%

Macroevolutionary diversification rates show time-dependency

Diaz

Harmon

Sugawara

et al. 2018

Preprint

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For centuries, biologists have been captivated by the vast disparity in species richnessbetween different groups of organisms. Variation in diversity is widely attributed to differences between groups in how fast they speciate or go extinct. Such macroevolutionary rates have been estimated for thousands of groups and have been correlated with an incredible variety of organismal traits. Here we analyze a large collection of phylogenetic trees and fossil time series and describe a hidden generality amongst these seemingly idiosyncratic results: speciation and extinction rates follow a scaling law where both depend on the age of the group in which they are measured, with the fastest rates in the youngest clades. Using a series of simulations and sensitivity analyses, we demonstrate that the time-dependency is unlikely to be a result of simple statistical artifacts. As such, this time-scaling is likely a genuine feature of the Tree of Life --hinting that the dynamics of biodiversity over deep time may be driven, in part, by surprisingly simple and general principles.Significance Statement Some branches of the Tree of Life are incredibly diverse, while others are represented by only a few living species. Ultimately, this difference reflects the balance of the formation and the extinction of species. Countless explanations have been proposed for why the rates of these two processes vary between lineages including aspects of the organisms themselves and the environments they live in. Here we reveal that a substantial amount of variation in these rates is associated with a simple factor --time. Younger groups appear to accumulate diversity at much faster rates than older groups. This time-scaling of macroevolutionary rates suggests that there may be hidden generalities governing the diversification of life on Earth.Though once controversial, it is now widely accepted that both the traits of organisms and the environments in which they live can influence the pace of evolution of life on Earth (1-3) . In particular, there is tremendous variation between groups of organisms in the rate at which species form and go extinct. This variation is reflected both in the wildly uneven diversity of clades in the fossil record and in the imbalanced shape of the tree of life (2)(3)(4)(5) . Our estimates of speciation and extinction rates vary by orders of magnitude when comparing different clades, locations, or time intervals.In turn, researchers have suggested a tremendous array of mechanisms that may have accelerated or slowed the accumulation of biodiversity. These mechanisms include aspects of organisms, such as colour polymorphism (6) , body size (7) , and many others; the environment, including geographic region (8,9) , temperature (10) , and the interactions between the two (11) . Taken as a whole, this growing body of work implicates a wide variety of factors that influence speciation and/or extinction rates and suggests that the growth of the Tree of Life has been largely idiosyncratic.Despite the rapid growth of research on v...

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“…Four of these fossils are older samples (48 to 33 Ma) from paleofloral 161 communities that we previously judged to be warm temperate or subtropical (Landis et al 162 2019). For our analyses in this study, we defined three mesic forest biomes based on 163 annual temperatures and rainfall patterns (Edwards et al 2017 forests, which include paratropical, lucidophyllous, and cloud forests, vary seasonally in 166 temperature and precipitation, but do not experience prolonged freezing temperatures 167 during the coldest months. Cold temperate forests also experience seasonal temperatures 168 and precipitation, but average minimum temperatures drop below freezing in at least one 169 of the coldest months.…”

Section: Introduction 38mentioning

confidence: 99%

Modeling phylogenetic biome shifts on a planet with a past

Landis

Edwards

Donoghue

2019

Preprint

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The spatial distribution of biomes has changed considerably over deep time, so the geographical opportunity for an evolutionary lineage to shift into a new biome may depend on how the availability and connectivity of biomes has varied temporally. To better understand how lineages shift between biomes in space and time, we developed a phylogenetic biome shift model in which each lineage shifts between biomes and disperses between regions at rates that depend on the lineage’s biome affinity and location relative to the spatiotemporal distribution of biomes at any given time. To study the behavior of the biome shift model in an empirical setting, we developed a literature-based representation of paleobiome structure for three mesic forest biomes, six regions, and eight time strata, ranging from the Late Cretaceous (100 Ma) through the present. We then fitted the model to a time-calibrated phylogeny of 119 Viburnum species to compare how the results responded to various realistic or unrealistic assumptions about paleobiome structure.Ancestral biome estimates that account for paleobiome dynamics reconstructed a warm temperate (or tropical) origin of Viburnum, which is consistent with previous fossil-based estimates of ancestral biomes. Imposing unrealistic paleobiome distributions led to ancestral biome estimates that eliminated support for tropical origins, and instead inflated support for cold temperate ancestry throughout the warmer Paleocene and Eocene. The biome shift model we describe is applicable to the study of evolutionary systems beyond Viburnum, and the core mechanisms of our model are extensible to the design of richer phylogenetic models of historical biogeography and/or lineage diversification. We conclude that biome shift models that account for dynamic geographical opportunities are important for inferring ancestral biomes that are compatible with our understanding of Earth history.

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Convergence, Consilience, and the Evolution of Temperate Deciduous Forests

Cited by 51 publications

References 82 publications

Joint phylogenetic estimation of geographic movements and biome shifts during the global diversification ofViburnum

Joint phylogenetic estimation of geographic movements and biome shifts during the global diversification ofViburnum

Macroevolutionary diversification rates show time-dependency

Modeling phylogenetic biome shifts on a planet with a past

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