Signatures of Microevolutionary Processes in Phylogenetic Patterns

Costa, Carolina Lemes Nascimento; Lemos-Costa, Paula; Marquitti, Flavia M D; Fernandes, Lucas D.; Ramos, Marlon; Schneider, David M.; Martins, Ayana B.; Aguiar, Marcus A. M. de

doi:10.1093/sysbio/syy049

Cited by 20 publications

(51 citation statements)

References 81 publications

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“…Our three main results are 1) the branch lengths distribution is independent of the geographic structure (α‐values change marginally according to the number of demes), 2) the trees become more balanced as the number of demes increases (the normalized Sackin index decreases with higher number of demes), displaying one large clade per deme and 3) in the long term the differences between the differing geographic configurations vanish and the balance of trees reach the value expected by the Yule model (or the Equal Rate Markov process). In opposition to the expectations based on augment of geographic complexity, points 1) and 2) show that increasing the number of demes (this work) is different from the complexity of the sympatry–parapatry dualism (as discussed in Costa et al ).…”

Section: Discussioncontrasting

confidence: 73%

“…Here we use the IBM of speciation proposed in Costa et al (), which in turn is a modified version of the model by de Aguiar et al (). We included this brief explanation about the model to make the present study easier to understand on its own.…”

Section: Methodsmentioning

confidence: 99%

“…We identify species as groups of individuals reproductively isolated from all others by the genetic threshold on mating defined by parameter G . Notice that not all members of the group have to be able to mate with each other, but could maintain an indirect gene flow through an intermediary individual (de Aguiar et al , Costa et al ). No other conditions but the genetic are imposed on the members of a species.…”

Section: Methodsmentioning

confidence: 99%

“…As a result, individuals that are far apart tend to be genetically different, forming species in spatial clusters of genetically similar individuals (de Aguiar et al 2009, Baptestini et al 2013a. Previous results using the same modelling framework (Costa et al 2019) have shown that the mating range significantly affects the branching tempo: larger mating ranges (when individuals use the same geographic region, corresponding to sympatry) lead to an increase in the rate of speciation throughout the radiation process. These results also indicate that tree imbalance, as measured by the normalized Sackin index, increases linearly with species richness as a result of parapatry (i.e.…”

Section: Introductionmentioning

confidence: 99%

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Allopatry increases the balance of phylogenetic trees during radiation under neutral speciation

2020

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The shape of a phylogenetic tree is defined by the sequence of speciation events, represented by its branching points, and extinctions, represented by branch interruptions. In a neutral scenario of parapatry and isolation by distance, species tend to branch off the original population one after the other, leading to highly unbalanced trees. In this case the degree of imbalance, measured by the normalized Sackin index, grows linearly with species richness. Here we claim that moderate values of imbalance for trees with large number of species can occur if the geographic distribution involves more than one deme (allopatry) and speciation is parapatric within demes. The combined values of balance (normalized Sackin index) and species richness provide an estimate of how many demes were involved in the process if it happened in such neutral scenario. We also show that the spatial division in demes moderately slows down the diversification process, portraying a neutral mechanism for structuring the branch length distribution of phylogenetic trees.

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Section: Discussioncontrasting

confidence: 73%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Allopatry increases the balance of phylogenetic trees during radiation under neutral speciation

2020

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“…Other individual‐level models for macroevolution do exist, and show a great deal of promise in elucidating patterns (Costa et al . ; Gavrilets et al . ; Aguiar et al .…”

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confidence: 99%

REvoSim: Organism‐level simulation of macro and microevolution

2019

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Macroevolutionary processes dictate the generation and loss of biodiversity. Understanding them is a key challenge when interrogating the earth–life system in deep time. Model‐based approaches can reveal important macroevolutionary patterns and generate hypotheses on the underlying processes. Here we present and document a novel model called REvoSim (Rapid Evolutionary Simulator) coupled with a software implementation of this model. The latter is available here as both source code (C++/Qt, GNU General Public License) and as distributables for a variety of operating systems. REvoSim is an individual‐based model with a strong focus on computational efficiency. It can simulate populations of 105–107 digital organisms over geological timescales on a typical desktop computer, and incorporates spatial and temporal environmental variation, recombinant reproduction, mutation and dispersal. Whilst microevolutionary processes drive the model, macroevolutionary phenomena such as speciation and extinction emerge. We present results and analysis of the model focusing on validation, and note a number potential applications. REvoSim can serve as a multipurpose platform for studying both macro and microevolution, and bridges this divide. It will be continually developed by the authors to expand its capabilities and hence its utility.

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Linking population‐level and microevolutionary processes to understand speciation dynamics at the macroevolutionary scale

Alencar

Quental

2021

Ecology and Evolution

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Although speciation dynamics have been described for several taxonomic groups in distinct geographic regions, most macroevolutionary studies still lack a detailed mechanistic view on how or why speciation rates change. To help partially fill this gap, we suggest that the interaction between the time taken by a species to geographically expand and the time populations take to evolve reproductive isolation should be considered when we are trying to understand macroevolutionary patterns. We introduce a simple conceptual index to guide our discussion on how demographic and microevolutionary processes might produce speciation dynamics at macroevolutionary scales. Our framework is developed under different scenarios: when speciation is mediated by geographical or resource‐partitioning opportunities, and when diversity is limited or not. We also discuss how organismal intrinsic properties and different overall geographical settings can influence the tempo and mode of speciation. We argue that specific conditions observed at the microscale might produce a pulse in speciation rates even without a pulse in either climate or physical barriers. We also propose a hypothesis to reconcile the apparent inconsistency between speciation measured at the microscale and macroscale, and emphasize that diversification rates are better seen as an emergent property. We hope to bring the reader's attention to interesting mechanisms to be further studied, to motivate the development of new theoretical models that connect microevolution and macroevolution, and to inspire new empirical and methodological approaches to more adequately investigate speciation dynamics either using neontological or paleontological data.

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Signatures of Microevolutionary Processes in Phylogenetic Patterns

Cited by 20 publications

References 81 publications

Allopatry increases the balance of phylogenetic trees during radiation under neutral speciation

Allopatry increases the balance of phylogenetic trees during radiation under neutral speciation

REvoSim: Organism‐level simulation of macro and microevolution

Linking population‐level and microevolutionary processes to understand speciation dynamics at the macroevolutionary scale

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