Project Details
Description
How does our rapidly changing climate impact thermosensitive species, and what capacity
do they have to cope with these changes? For many ectothermic species, temperatures
experienced during development can trigger changes that impact the individual for the rest
of its life, which ultimately influences population-scale processes.
One such species is the emerging model organism Pogona vitticeps, the central bearded
dragon. It is one of the only species known to undergo sex reversal during development
from exposure to extreme temperatures. Under high temperatures, genetically male
individuals reverse their sex and instead develop as females. These individuals are
reproductively viable, and occur across the species’ range (1, 2).
We know that sex reversed P. vitticeps females behave differently to their normal male
and female counterparts (3), but we do not understand the molecular and structural neural
underpinnings of this behavioral difference. This behavioural study (3) was also limited
in its scope, so there is still much to learn about the interplay between temperature,
development, and behaviour, and its fitness consequences, in this species. To explore this,
we will use a unique combination of genetic sequencing, brain morphological analyses, and
behavioral assays to understand how incubation temperature shapes traits that influence an
individual during its entire post-hatching life.
As global temperatures continue to rise, the need to understand the effects of temperature
stress on environmentally sensitive species is crucial. Australia has the world’s highest
reptile diversity (~1,100 species), and as an ectothermic lineage, all species can be
impacted by a rapidly changing climate, but it is unclear whether these species can respond quickly enough to the current pace of climate change (4–7).
do they have to cope with these changes? For many ectothermic species, temperatures
experienced during development can trigger changes that impact the individual for the rest
of its life, which ultimately influences population-scale processes.
One such species is the emerging model organism Pogona vitticeps, the central bearded
dragon. It is one of the only species known to undergo sex reversal during development
from exposure to extreme temperatures. Under high temperatures, genetically male
individuals reverse their sex and instead develop as females. These individuals are
reproductively viable, and occur across the species’ range (1, 2).
We know that sex reversed P. vitticeps females behave differently to their normal male
and female counterparts (3), but we do not understand the molecular and structural neural
underpinnings of this behavioral difference. This behavioural study (3) was also limited
in its scope, so there is still much to learn about the interplay between temperature,
development, and behaviour, and its fitness consequences, in this species. To explore this,
we will use a unique combination of genetic sequencing, brain morphological analyses, and
behavioral assays to understand how incubation temperature shapes traits that influence an
individual during its entire post-hatching life.
As global temperatures continue to rise, the need to understand the effects of temperature
stress on environmentally sensitive species is crucial. Australia has the world’s highest
reptile diversity (~1,100 species), and as an ectothermic lineage, all species can be
impacted by a rapidly changing climate, but it is unclear whether these species can respond quickly enough to the current pace of climate change (4–7).
| Short title | Lizard responses to global warming |
|---|---|
| Acronym | (Uni of Canberra led) |
| Status | Active |
| Effective start/end date | 1/07/24 → 30/06/27 |