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Eggshell structure in Apteryx: Form, Function, and Adaptation
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  • David Vieco-Galvez,
  • Isabel Castro,
  • Patrick Morel,
  • Wei Chua,
  • Michael Loh
David Vieco-Galvez
Massey University College of Sciences

Corresponding Author:[email protected]

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Isabel Castro
Massey University College of Sciences
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Patrick Morel
Massey University College of Sciences
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Wei Chua
Massey University College of Sciences
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Michael Loh
Fonterra Research and Development Centre
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The structure of Apteryx’s eggshell has generated much debate over the decades because it does not fit well with most allometric predictions. Apteryx eggshells are unusually thin and have been reported to be 60% less porous than expected. It has been suggested that these adaptations are compensations for a very long incubation period. Most studies so far have been carried out in what has been reported as Apteryx australis, and using infertile eggs or eggs laid in captivity. However, A. australis once comprised all kiwi with brown plumage, now separated into three distinct species: Brown Kiwi (A.mantelli), Rowi (A.rowi), and Tokoeka (A.australis). These three species use different habitats and live at different latitudes and altitudes. In addition, captive eggs are much smaller than wild laid eggs. These confounding factors make necessary to revise the assumptions made for Apteryx in the past. In this study, we analysed the physical characteristics of the Apteryx eggshells making a comparison between the three species of brown coloured kiwi and for some of the analysis we included some specimens of Roroa (A. haastii, Great Spotted Kiwi). We found that shell characteristics are different between the different species studied. The pore area of Apteryx eggshells was higher than previously suggested, and the water vapour conductance was much closer to what is expected for an egg that size. We found several new features such as triangular mineral particles composing the cuticle, only reported for a cretaceous Theropod, and the presence of plugs and caps on the eggshell pores. We suggest that the characteristics of the eggshells of the different species relate to the mating system of each species in addition to environmental variables, particularly pluviosity. We also suggest that the erosion of the cuticle during incubation is an adaptation to a long incubation period in a burrow.
11 Sep 2020Submitted to Ecology and Evolution
15 Sep 2020Submission Checks Completed
15 Sep 2020Assigned to Editor
24 Sep 2020Reviewer(s) Assigned
02 Nov 2020Review(s) Completed, Editorial Evaluation Pending
04 Nov 2020Editorial Decision: Revise Minor
08 Jan 20211st Revision Received
11 Jan 2021Review(s) Completed, Editorial Evaluation Pending
11 Jan 2021Submission Checks Completed
11 Jan 2021Assigned to Editor
15 Jan 2021Editorial Decision: Accept