Unifying the mechanisms that drive spatial patterns in biological traits. The project aims to resolve the mechanisms that generate spatial variation in biological traits. This project expects to overcome several significant shortcomings of previous investigations by using mechanistic modelling, field-based ecophysiological studies, and macroecological analyses to develop a single, integrated approach to investigating geographic variation in size, colour, life history and reproduction. The expect ....Unifying the mechanisms that drive spatial patterns in biological traits. The project aims to resolve the mechanisms that generate spatial variation in biological traits. This project expects to overcome several significant shortcomings of previous investigations by using mechanistic modelling, field-based ecophysiological studies, and macroecological analyses to develop a single, integrated approach to investigating geographic variation in size, colour, life history and reproduction. The expected outcomes are a comprehensive empirical test of a unified mechanism for spatial trait variation, using a diverse terrestrial vertebrate lineage as a model system. The results of this study should provide a powerful framework for predicting future patterns of biological trait variation under anthropogenic climate change.Read moreRead less
Discovering nature's photonic devices to control light and heat. This project aims to discover how and why beetles and butterflies reflect near-infrared light. Reflection of near-infrared radiation may be critical to prevent overheating, yet its role in thermal protection remains largely unexplored. The project will integrate evolutionary biology, optical physics and biophysics to reveal the diversity, mechanism, function and evolution of near-infrared signatures. Expected outcomes include the d ....Discovering nature's photonic devices to control light and heat. This project aims to discover how and why beetles and butterflies reflect near-infrared light. Reflection of near-infrared radiation may be critical to prevent overheating, yet its role in thermal protection remains largely unexplored. The project will integrate evolutionary biology, optical physics and biophysics to reveal the diversity, mechanism, function and evolution of near-infrared signatures. Expected outcomes include the discovery of nature’s solutions to selection for both optical (camouflage, communication) and thermal functions. The project will have significant benefits such as creating opportunities to develop biomimetic and bioinspired materials to enhance energy efficiency, which will have significant economic and environmental benefits.Read moreRead less
Computing the climate-life history nexus for Australia's fauna. Life histories are the trajectories organisms follow as they develop, grow, reproduce and age; they are shaped by evolution and limited by the physical and biological environment. Recent breakthroughs by the CI allow the computation of life histories in any sequence of climatic environments, with demonstrated potential to gain new insights into the past, present and future responses of species to climate variability and change. This ....Computing the climate-life history nexus for Australia's fauna. Life histories are the trajectories organisms follow as they develop, grow, reproduce and age; they are shaped by evolution and limited by the physical and biological environment. Recent breakthroughs by the CI allow the computation of life histories in any sequence of climatic environments, with demonstrated potential to gain new insights into the past, present and future responses of species to climate variability and change. This project aims to apply the new methods to understand how species' life histories have adapted to Australia's unique physical conditions and predict how they will respond to future conditions. It will simultaneously lay the foundations for a long-term, open-access research program on species' climate responses.Read moreRead less
Unlocking telomere effects on life, death and fitness in a warming world. Few things in biology provoke such a strong desire for understanding as when adult death and fatal disease can be predicted early in life. A common factor linking early life stress, disease, ageing and time of death are telomeres, the protective regions at the end of each chromosome. This project aims to explicitly link telomere dynamics in free-living ectotherm populations with experimental approaches to advance our under ....Unlocking telomere effects on life, death and fitness in a warming world. Few things in biology provoke such a strong desire for understanding as when adult death and fatal disease can be predicted early in life. A common factor linking early life stress, disease, ageing and time of death are telomeres, the protective regions at the end of each chromosome. This project aims to explicitly link telomere dynamics in free-living ectotherm populations with experimental approaches to advance our understanding of parental and environmental effects on offspring telomeres and their effects later in life. This project will take advantage of one of the world’s longest datasets on ectotherm responses to climate to provide new knowledge of how telomeres affect fitness and the role that the environment plays.Read moreRead less
Are evolutionary refugia traps for endemic species? This project aims to determine whether species that have small geographic ranges and which live in historically stable refugia have evolved narrow climatic tolerances. The project will compare such species with more widespread, related species living in the same areas and combine field- and lab-based estimates of physiological tolerances with genomic estimates of population history and diversity. The expected outcome is to test the prediction f ....Are evolutionary refugia traps for endemic species? This project aims to determine whether species that have small geographic ranges and which live in historically stable refugia have evolved narrow climatic tolerances. The project will compare such species with more widespread, related species living in the same areas and combine field- and lab-based estimates of physiological tolerances with genomic estimates of population history and diversity. The expected outcome is to test the prediction from evolutionary theory that small-range, refugial species are intrinsically more sensitive to climatic change. The project expects to provide improved guidance for ecological management of biodiversity hotspots.Read moreRead less