The study, published in Global Change Biology, demonstrates that the mechanisms involved in restoring offspring sex ratios across generations are switched on during early development of the parents and do not simply occur as a result of adults being exposed to higher temperatures.
"Understanding the ability of species to respond and cope with rising environmental temperature is key to predicting the biological consequences of global warming," said lead author and UTS Chancellor's Postdoctoral Research Fellow Dr Jennifer Donelson.
The ability to compensate for the sex bias caused by rising temperatures is an important trait that could help constrain the impacts of ocean warming on reef fish populations and other species. However the research also suggests that when developmental temperature is too hot there is a limit to this "transgenerational plasticity."
"The research findings are significant because global warming poses a threat to species with temperature-dependent sex determination (TSD), such as reptiles and fish, potentially skewing the sex-ratio of offspring and, consequently, breeding individuals in a population," Dr Donelson said.
"It's well known that gender bias away from the optimal sex ratio of juveniles, that is roughly equal numbers of males and females, can have significant consequences for population success.
"A reduction in the proportion of females in the population could be especially damaging because population growth rate is often constrained by female fertility."
The researchers showed that even relatively small increases in developmental temperatures, just 1.5 degrees Celsius above average summer temperatures, can reduce the proportion of female offspring by more than 30 per cent. However the female sex ratio of offspring was restored when parental fish were reared at this temperature for their entire life and for two generations.
"However, only partial improvement in the sex ratio occurred at 3.0 degrees Celsius above average conditions, even after two generations, suggesting a limitation to transgenerational plasticity when the developmental temperature is too hot," Dr Donelson said.
"Previous research has focused on the changes to the timing of breeding and mothers behaviourally altering the location of their nest to compensate for warming. The novelty of our study was using a multigenerational (three generations) rearing design to ask questions about non-genetic and non-behavioural parental effects to sex determination," Dr Donelson added.
Read more at Science Daily
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