Abstract
AbstractEstimating speciation and extinction rates is essential for understanding past and present biodiversity, but is challenging given the incompleteness of the rock and fossil records. Interest in this topic has led to a divergent suite of independent methods—paleontological estimates based on sampled stratigraphic ranges and phylogenetic estimates based on the observed branching times in a given phylogeny of living species. The fossilized birth–death (FBD) process is a model that explicitly recognizes that the branching events in a phylogenetic tree and sampled fossils were generated by the same underlying diversification process. A crucial advantage of this model is that it incorporates the possibility that some species may never be sampled. Here, we present an FBD model that estimates tree-wide diversification rates from stratigraphic range data when the underlying phylogeny of the fossil taxa may be unknown. The model can be applied when only occurrence data for taxonomically identified fossils are available, but still accounts for the incomplete phylogenetic structure of the data. We tested this new model using simulations and focused on how inferences are impacted by incomplete fossil recovery. We compared our approach with a phylogenetic model that does not incorporate incomplete species sampling and to three fossil-based alternatives for estimating diversification rates, including the widely implemented boundary-crosser and three-timer methods. The results of our simulations demonstrate that estimates under the FBD model are robust and more accurate than the alternative methods, particularly when fossil data are sparse, as the FBD model incorporates incomplete species sampling explicitly.
Highlights
Speciation and extinction rates are fundamental parameters in macroevolutionary models and integral to hypothesis testing in evolutionary biology
Methods have been introduced that enable using phylogenies of extant taxa calibrated to time to estimate diversification rates (Nee et al 1994; Gernhard 2008; Stadler 2009; Morlon et al 2011), this approach has been widely criticized for omitting and contradicting evidence provided by the fossil record (Rabosky 2010; Quental and Marshall 2010; Marshall 2017)
We demonstrate the importance of explicitly accounting for incomplete species sampling and show the benefits of incorporating singletons—including extant samples— which is possible under the mechanistic fossilized birth–death (FBD) phylogenetic framework
Summary
Speciation and extinction rates are fundamental parameters in macroevolutionary models and integral to hypothesis testing in evolutionary biology. Paleontological approaches to estimating speciation and extinction (together, diversification) rates use stratigraphic range data, the interval between the first and last appearance of a taxon in the fossil record (Raup 1975; Foote 2000; Alroy 2008, 2014). A small proportion of past diversity is preserved in the rock record and recovered by paleontologists, and the fossil-sampling process is heterogenous over time, across space, and among lineages (Raup 1972; Foote and Sepkoski 1999; Smith and McGowan 2007; Holland 2016).
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