Maximum Likelihood Inference of Geographic Range Evolution by Dispersal, Local Extinction, and Cladogenesis

doi:10.1080/10635150701883881

Systematic Biology 2008 57(1):4-14; doi:10.1080/10635150701883881

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Maximum Likelihood Inference of Geographic Range Evolution by Dispersal, Local Extinction, and Cladogenesis

Richard H. Ree¹ and Stephen A. Smith²

¹ Department of Botany, Field Museum of Natural History 1400 South Lake Shore Drive, Chicago, Illinois 60605, USA; E-mail: rree{at}fieldmuseum.org
² Department of Ecology and Evolutionary Biology, Yale University New Haven, Connecticut 06520, USA

Edited by Allan Baker

Abstract

In historical biogeography, model-based inference methods forreconstructing the evolution of geographic ranges on phylogenetictrees are poorly developed relative to the diversity of analogousmethods available for inferring character evolution. We attemptto rectify this deficiency by constructing a dispersal-extinction-cladogenesis(DEC) model for geographic range evolution that specifies instantaneoustransition rates between discrete states (ranges) along phylogeneticbranches and apply it to estimating likelihoods of ancestralstates (range inheritance scenarios) at cladogenesis events.Unlike an earlier version of this approach, the present modelallows for an analytical solution to probabilities of rangetransitions as a function of time, enabling free parametersin the model, rates of dispersal, and local extinction to beestimated by maximum likelihood. Simulation results indicatethat accurate parameter estimates may be difficult to obtainin practice but also show that ancestral range inheritance scenariosnevertheless can be correctly recovered with high success ifrates of range evolution are low relative to the rate of cladogenesis.We apply the DEC model to a previously published, exemplarycase study of island biogeography involving Hawaiian endemicangiosperms in Psychotria (Rubiaceae), showing how the DEC modelcan be iteratively refined from inspecting inferences of rangeevolution and also how geological constraints involving timesof island origin may be imposed on the likelihood function.The DEC model is sufficiently similar to character models thatit might serve as a gateway through which many existing comparativemethods for characters could be imported into the realm of historicalbiogeography; moreover, it might also inspire the conceptualexpansion of character models toward inclusion of evolutionarychange as directly coincident, either as cause or consequence,with cladogenesis events. The DEC model is thus an incrementaladvance that highlights considerable potential in the nascentfield of model-based historical biogeographic inference.

Keywords: Ancestral state reconstruction; dispersal; extinction; Hawai'i; historical biogeography; Psychotria; speciation; vicariance

Received April 19, 2007; Revised June 5, 2007; Accepted August 29, 2007
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