The respiratory gas exchange of sea turtle nests (Chelonia, Caretta)

Abstract

Sea turtles lay about 100 leathery-shelled eggs in a 25 cm diameter chamber carefully excavated about 50 cm deep in a nesting beach, where the eggs exchange gases (at approximately 28 C) during their 60-day incubation period. The sand surrounding the spherical nest chamber restricts the diffusion of gases into and out of the nest so that as embryonic development progresses, P O 2 decreases and P CO 2 increases in the gas inside the nest. P O 2 falls to 80–100 torr and P CO 2 rises to 40–60 torr inside 100-egg manmade Chelonia and Caretta nests. The change in gas tensions in the nest during development is very similar to that seen in the air cell of the chicken egg. Gas tensions inside the turtle nest and in the sand surrounding the nest can be described by a radial steady-state diffusion model. The rate of diffusion of gases in the sand is 30–50% of the rate found in the nest and 6–12% of the rate found in an equal volume of air. The sand surrounding the turtle nest appears to determine the gas exchange of the eggs in the nest and is functionally analogous to the shell surrounding the chicken embryo. The female sea turtle may construct her nest so as to maximize its gas exchange and minimize gas partial pressure gradients inside the nest.