Extant and extinct Xenarthran skull morphological analysis: evolutionary and functional inferences

Xenarthra are an eutherian mammal clade and little is known about their cranial morphological evolution. This thesis has initiated studies related to this topic and, based on quantitative genetics, morphometrics and systematics, aimed to: 1) empirically assess if the phenotypic variance and covariance matrices (P-matrix) of several genera can be used as surrogates for their respective additive genetic variance and covariance matrices (G-matrix), since G-matrices for Xenarthra are not available, and also if P-matrices can be used in macroevolutionary studies; 2) test whether the skull morphological diversification within the group occurred only through genetic drift; and 3) understand how the relationship between the traits (modules) and overall magnitude of integration may influence cranial morphological evolution. Besides these objectives focused on the evolution of the group, it was also within the scope of this thesis to infer the feeding habits of late Pleistocene/early Holocene fossil taxa to better understand the ecology of some fossil groups. The database used consist of linear measurements of approximately 1150 adult specimens, representing 12 of the 14 extant genera and seven of the several extinct genera of Xenarthra. The data gathered were used to estimate variance/covariance and correlation P-matrices for every genus. These matrices were compared between pairs of genera to evaluate the matrices\' structural similarities. Based on these matrices, within and between population variances were obtained and it was tested whether morphological diversification was in accordance to the theoretical expectation of diversification under genetic drift alone. The same matrices were compared to theoretical matrices expressing modularity hypotheses. These theoretical matrices represent the relationship among traits in reference to the shared development and/or function of different skull\'s anatomical regions (modules). For every correlation P-matrix the overall magnitude of integration was calculated. Moreover, the extinct groups\' diet was inferred through discriminant function analysis relying on the relationship between form and function of extant animals. Results indicate that P-matrices from several genera were structurally similar. This suggests that P-matrices can be used as surrogates of their G-matrices and in the macroevolutionary context. Results refuted the null hypothesis of cranial morphological diversification occurring only due to genetic drift, at least in more inclusive levels of Xenarthran phylogeny. Consequently, natural selection probably acted on this diversification process. The results also suggested that the Xenarthran skull is organized in modules, and the most conspicuous modules are in the face region. A large variation in the overall magnitude of integration among genera was detected. The variation in the modular pattern, but especially in the overall magnitude of integration, allows genera to differ in their potential capacity to respond aligned with selective pressures. Finally, morphofunctional analyses indicate a high diversity of feeding habits among extinct Xenarthra (AU)