TY - JOUR
T1 - Avian egg shape
T2 - form, function, and evolution
AU - Stoddard, Mary Caswell
AU - Yong, Ee Hou
AU - Akkaynak, Derya
AU - Sheard, Catherine
AU - Tobias, Joseph A.
AU - Mahadevan, L.
N1 - MCS was supported by Princeton University, with additional support from the L’Oréal USA For Women in Science Fellowship, the L’Oréal-UNESCO International Rising Talents Fellowship, the Harvard Society of Fellows and the Milton Fund. EHY was supported by a Start-Up Grant No. M4081583 from Nanyang Technological University, Singapore. CS was supported by the Oxford Clarendon Fund and the US-UK Fulbright Commission. Collection of biometric, life-history and environmental data was supported by a Natural Environment Research Council grant (NE/I028068/1) to JAT. LM was supported by fellowships from the MacArthur Foundation and the Radcliffe Institute.
PY - 2017/6/23
Y1 - 2017/6/23
N2 - Avian egg shape is generally explained as an adaptation to life history, yet we currently lack a global synthesis of how egg-shape differences arise and evolve. Here, we apply morphometric, mechanistic, and macroevolutionary analyses to the egg shapes of 1400 bird species. We characterize egg-shape diversity in terms of two biologically relevant variables, asymmetry and ellipticity, allowing us to quantify the observed morphologies in a two-dimensional morphospace. We then propose a simple mechanical model that explains the observed egg-shape diversity based on geometric and material properties of the egg membrane. Finally, using phylogenetic models, we show that egg shape correlates with flight ability on broad taxonomic scales, suggesting that adaptations for flight may have been critical drivers of egg-shape variation in birds.
AB - Avian egg shape is generally explained as an adaptation to life history, yet we currently lack a global synthesis of how egg-shape differences arise and evolve. Here, we apply morphometric, mechanistic, and macroevolutionary analyses to the egg shapes of 1400 bird species. We characterize egg-shape diversity in terms of two biologically relevant variables, asymmetry and ellipticity, allowing us to quantify the observed morphologies in a two-dimensional morphospace. We then propose a simple mechanical model that explains the observed egg-shape diversity based on geometric and material properties of the egg membrane. Finally, using phylogenetic models, we show that egg shape correlates with flight ability on broad taxonomic scales, suggesting that adaptations for flight may have been critical drivers of egg-shape variation in birds.
U2 - 10.1126/science.aaj1945
DO - 10.1126/science.aaj1945
M3 - Article
SN - 0036-8075
VL - 356
SP - 1249
EP - 1254
JO - Science
JF - Science
IS - 6344
ER -