Abstract
Macroevolutionary theory predicts high rates of evolution should occur early in a clade's history as species exploit ecological opportunity. Evidence from the fossil record has shown a high prevalence of early bursts in morphological evolution, but recent work has provided little evidence for early high rates in the evolution of extant clades. Here, I test the prevalence of early bursts in extant data using phylogenetic comparative methods. Existing models are extended to allow a shift from a background Brownian motion (BM) process to an early burst process within subclades of phylogenies, rather than an early burst being applied to an entire phylogenetic tree. This nested early burst model is compared to other modes of evolution that can occur within subclades, such as evolution with a constraint (Ornstein‐Uhlenbeck model) and nested BM rate shift models. These relaxed models are validated using simulations and then are applied to body size evolution of three major clades of amniotes (mammals, squamates and aves) at different levels of taxonomic organization (order, family). Applying these unconstrained models greatly increases the support for early bursts within nested subclades, and so early bursts are the most common model of evolution when only one shift is analysed. However, the relative fit of early burst models is worse than models that allow for multiple shifts of the BM or OU process. No single‐shift or homogenous model is superior to models of multiple shifts in BM or OU evolution, but the patterns shown by these multirate models are generally congruent with patterns expected from early bursts.
Highlights
The adaptive radiation of morphological traits is a key part of macroevolutionary theory
I apply the two models of nested early bursts: the nested EB model in which the early burst process inherits the basal Brownian motion (BM) rate; and the nested EB rate model that is similar to the nested EB model except a scalar allows for a higher rate of evolution within the nested clade compared to the ancestral rate of BM evolution
The increased support for nested early bursts is only seen when comparing the relative fit of homogenous or single-shift models. This increased support for early bursts is not seen when compared to models of rate heterogeneity that allow for multiple shifts in a BM or OU process (Table 2)
Summary
The adaptive radiation of morphological traits is a key part of macroevolutionary theory. A clade’s early history is characterized by movement into new areas of morphospace, usually in response to ecological opportunity (Simpson, 1944; Schluter, 2000; Losos, 2010). This definition is distinct from early high rates of speciation: adaptive radiations are defined by the rapid acquisition of diverse morphological traits within closely related clades (Givnish, 2015). Patterns of morphological evolution are more widely recognized in the fossil record where the theory of early bursts was first formulated (Foote, 1994; Wagner, 1997; Hughes et al, 2013)
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