Abstract
Studies comparing phenotypic variation with neutral genetic variation in modern humans have shown that genetic drift is a main factor of evolutionary diversification among populations. The genetic population history of our closest living relatives, the chimpanzees and bonobos, is now equally well documented, but phenotypic variation among these taxa remains relatively unexplored, and phenotype-genotype correlations are not yet documented. Also, while the adult phenotype is typically used as a reference, it remains to be investigated how phenotype-genotye correlations change during development. Here we address these questions by analyzing phenotypic evolutionary and developmental diversification in the species and subspecies of the genus Pan. Our analyses focus on the morphology of the femoral diaphysis, which represents a functionally constrained element of the locomotor system. Results show that during infancy phenotypic distances between taxa are largely congruent with non-coding (neutral) genotypic distances. Later during ontogeny, however, phenotypic distances deviate from genotypic distances, mainly as an effect of heterochronic shifts between taxon-specific developmental programs. Early phenotypic differences between Pan taxa are thus likely brought about by genetic drift while late differences reflect taxon-specific adaptations.
Highlights
The ready accessibility of population-wide genotypic and phenotypic data from humans and our closest relatives, the great apes, has spurred a large number of studies investigating the relationship between patterns of genotypic and phenotypic evolution
A steadily growing number of studies indicates that variation of cranial morphology among modern human populations, and between modern humans and fossil hominins largely reflects the effects of genetic drift, while only a small proportion of variation can be attributed to selection [1,2,3,4,5,6,7,8,9,10]
Volumetric data of the femora of N = 146 Pan specimens were acquired with computed tomography (CT)
Summary
The ready accessibility of population-wide genotypic and phenotypic data from humans and our closest relatives, the great apes, has spurred a large number of studies investigating the relationship between patterns of genotypic and phenotypic evolution. Fossil hominin aDNA permits insights into earlier phases of human population and evolutionary history at an unprecedented level of detail [11,12,13,14,15]. These analyses are limited, by the ‘‘aDNA preservation horizon’’, which is currently around 50,000 years BP for fossil hominin nDNA, and around 400,000 years BP for mtDNA from temperate zones [16]. These Pan taxa have been the subject of detailed anatomical [24,25,26,27,28], morphological [29,30,31,32,33], phylogeographic [17,19,23,34], and behavioral [32,35,36,37,38,39,40] studies
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