Abstract
BackgroundDuring the growth of complex multicellular organisms, chronological age, size and morphology change together in a hierarchical and coordinated pattern. Among extinct species, the growth ofTyrannosaurus rexhas received repeated attention through quantitative analyses of relative maturity and chronological age. Its growth series shows an extreme transformation from shallow skulls in juveniles to deep skulls in adults along with a reduction in tooth count, and its growth curve shows thatT. rexhad a high growth rate in contrast to its closest relatives. However, separately, these sets of data provide an incomplete picture of the congruence between age, size, and relative maturity in this exemplar species. The goal of this work is to analyze these data sets together using cladistic analysis to produce a single hypothesis of growth that includes all of the relevant data.MethodsThe three axes of growth were analyzed together using cladistic analysis, based on a data set of 1,850 morphological characters and 44 specimens. The analysis was run in TNT v.1.5 under a New Technology search followed by a Traditional search. Correlation tests were run in IBM SPSS Statistics v. 24.0.0.0.ResultsAn initial analysis that included all of the specimens recovered 50 multiple most parsimonious ontograms a series of analyses identified 13 wildcard specimens. An analysis run without the wildcard specimens recovered a single most parsimonious tree (i.e., ontogram) of 3,053 steps. The ontogram is composed of 21 growth stages, and all but the first and third are supported by unambiguously optimized synontomorphies.T. rexontogeny can be divided into five discrete growth categories that are diagnosed by chronological age, morphology, and, in part, size (uninformative among adults). The topology shows that the transition from shallow to deep skull shape occurred between 13 and 15 years of age, and the size of the immediate relatives ofT. rexwas exceeded between its 15th and 18th years. Although size and maturity are congruent among juveniles and subadults, congruence is not seen among adults; for example, one of the least mature adults (RSM 2523.8) is also the largest and most massive example of the species. The extreme number of changes at the transition between juveniles and subadults shows that the ontogeny ofT. rexexhibits secondary metamorphosis, analogous to the abrupt ontogenetic changes that are seen at sexual maturity among teleosts. These results provide a point of comparison for testing the congruence between maturity and chronological age, size, and mass, as well as integrating previous work on functional morphology into a rigorous ontogenetic framework. Comparison of the growth series ofT. rexwith those of outgroup taxa clarifies the ontogenetic trends that were inherited from the common ancestor of Archosauriformes.
Highlights
Tyrannosaurus rex is an outlier in terms of its gigantic absolute size (Persons, Currie & Erickson, 2019; Snively et al, 2019) and extremely high bite force (Bates & Falkingham, 2012, 2018; Cost et al, 2019; Gignac & Erickson, 2017; Henderson, 2002), which is clear evidence that ontogeny in this species was carried far beyond the limits seen in its immediate relatives (Carr, 1999; Erickson et al, 2004)
The ontogram is composed of 21 growth stages, including the group of most mature specimens, and all but the first and third are supported by unambiguously optimized synontomorphies (Data S4)
The comparison showed that it is different from the others in that the rostral margin of the bone falls short of the adults, which was used by Carpenter (1990) to argue the specimen represents a new taxon; based on the results found here, this difference almost certainly arises from the fact its teeth are not as enlarged in adults and the internal sinuses are not expanded, changes that greatly reshape the bone in adults
Summary
Tyrannosaurus rex is an outlier in terms of its gigantic absolute size (Persons, Currie & Erickson, 2019; Snively et al, 2019) and extremely high bite force (Bates & Falkingham, 2012, 2018; Cost et al, 2019; Gignac & Erickson, 2017; Henderson, 2002), which is clear evidence that ontogeny in this species was carried far beyond the limits seen in its immediate relatives (Carr, 1999; Erickson et al, 2004). Its growth series shows an extreme transformation from shallow skulls in juveniles to deep skulls in adults along with a reduction in tooth count, and its growth curve shows that T. rex had a high growth rate in contrast to its closest relatives Separately, these sets of data provide an incomplete picture of the congruence between age, size, and relative maturity in this exemplar species. The extreme number of changes at the transition between juveniles and subadults shows that the ontogeny of T. rex exhibits secondary metamorphosis, analogous to the abrupt ontogenetic changes that are seen at sexual maturity among teleosts These results provide a point of comparison for testing the congruence between maturity and chronological age, size, and mass, as well as integrating previous work on functional morphology into a rigorous ontogenetic framework.
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