Abstract
Sea turtle embryos at high-density nesting beaches experience relative high rates of early stage embryo death. One hypothesis to explain this high mortality rate is that there is an increased probability that newly constructed nests are located close to maturing clutches whose metabolising embryos cause low oxygen levels, high carbon dioxide levels, and high temperatures. Although these altered environmental conditions are well tolerated by mature embryos, early stage embryos, i.e. embryos in eggs that have only been incubating for less than a week, may not be as tolerant leading to an increase in their mortality. To test this hypothesis, we incubated newly laid sea turtle eggs over a range of temperatures in different combinations of oxygen and carbon dioxide concentrations and assessed embryo development and death rates. We found that gas mixtures of decreased oxygen and increased carbon dioxide, similar to those found in natural sea turtle nests containing mature embryos, slowed embryonic development but did not influence the mortality rate of early stage embryos. We found incubation temperature had no effect on early embryo mortality but growth rate at 27°C and 34°C was slower than at 30°C and 33°C. Our findings indicate that low oxygen and high carbon dioxide partial pressures are not the cause of the high early stage embryo mortality observed at high-density sea turtle nesting beaches, but there is evidence suggesting high incubation temperatures, particularly above 34°C are harmful. Any management strategies that can increase the spacing between nests or other strategies such as shading or irrigation that reduce sand temperature are likely to increase hatching success at high-density nesting beaches.
Highlights
The oxygen limitation hypothesis predicts that decreased oxygen availability in the environment and / or limitations in internal oxygen transport can limit aerobic metabolic processes at the intracellular level and limit cellular metabolism [1]
Through a set of controlled incubation experiments, we investigate if incubation conditions that vary significantly from optimal with respect to oxygen and carbon dioxide, elevated temperatures or a combination of these factors increase the frequency of early embryo mortality in sea turtle embryos
For loggerhead eggs that formed a white-patch, with the exception of one embryo incubated at 27 ̊C in 14% O2, 7% CO2, which died at development stage 9, there was no embryo mortality between the 36 h to 7 day period of gas exposure across all treatments (Table 1)
Summary
The oxygen limitation hypothesis predicts that decreased oxygen availability in the environment and / or limitations in internal oxygen transport can limit aerobic metabolic processes at the intracellular level and limit cellular metabolism [1]. During the early stages of incubation, sea turtle embryos experience oxygen and carbon dioxide partial pressures close to those of the atmosphere above the sand [7, 8] and temperatures in the range 28–30 ̊C and these are considered to be optimal conditions for embryonic development. Through a set of controlled incubation experiments, we investigate if incubation conditions that vary significantly from optimal with respect to oxygen and carbon dioxide, elevated temperatures or a combination of these factors increase the frequency of early embryo mortality in sea turtle embryos
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