Animals response to extreme climatic events. Climate change is causing extreme climatic events, such as floods and heat waves, to become more frequent. This project will investigate by which mechanism animals can adjust to extreme climatic events and whether the response is fast enough to avoid extinction, thereby providing urgently needed insights into the natural resilience of Australian fauna.
Generalised methods for testing extinction dynamics across geological, near and modern time scales. The record of extinctions over deep time is patchy and incomplete, yet we must use it to determine how major changes in past environments have shaped life on Earth today. The project will develop cutting-edge mathematical tools to determine the patterns of extinctions and speciation over geological time to help predict our uncertain environmental future.
Evolution in a changing environment. Climate change is having dramatic effects on wild animal populations. This project will investigate how and why these effects occur, and whether populations will be able to evolve to adapt to a changing environment.
Analysing the roles of cospeciation and host-shifting in the evolution of behaviour and ecology of thrips associated with Australian Acacia. The relationships and interactions between phytophagous thrips and their host Acacia species provide a system well suited to investigating mechanisms of macroevolution in the Australian arid-zone biota. In this project we will determine the relative importance of mechanisms such as cospeciation and host-shifting within this model system, and examine the in ....Analysing the roles of cospeciation and host-shifting in the evolution of behaviour and ecology of thrips associated with Australian Acacia. The relationships and interactions between phytophagous thrips and their host Acacia species provide a system well suited to investigating mechanisms of macroevolution in the Australian arid-zone biota. In this project we will determine the relative importance of mechanisms such as cospeciation and host-shifting within this model system, and examine the influence of these mechanisms on the evolution of both the insects and the host-plants. It is expected that the results of this study will provide insights into the evolution of arid-zone biodiversity in Australia and the nature of insect/host-plant interactions.Read moreRead less
Evolution in tooth and claw: exploring the relationship between the radiation of marsupial herbivores and late Cenozoic climate change. Establishing how animals responded to past environmental changes is essential for understanding the ecology of modern species and managing them in light of contemporary climatic trends. By applying several novel analytical methods this project will unravel the links between the radiation of Australian marsupials and key stages in climatic evolution.
Evolution at extremes: Macroevolutionary responses to harsh environments. The project seeks to investigate the capacity of iconic Australian plant groups (Eucalyptus, Acacia, Banksia, Grevillea, Hakea) to adapt to increases in extreme conditions. Australia presents many extreme conditions for plant survival, such as drought, heat, or salt-affected soils. Are some lineages better able to adapt and diversify in these conditions? This project aims to develop new methods to identify lineages most to ....Evolution at extremes: Macroevolutionary responses to harsh environments. The project seeks to investigate the capacity of iconic Australian plant groups (Eucalyptus, Acacia, Banksia, Grevillea, Hakea) to adapt to increases in extreme conditions. Australia presents many extreme conditions for plant survival, such as drought, heat, or salt-affected soils. Are some lineages better able to adapt and diversify in these conditions? This project aims to develop new methods to identify lineages most tolerant of extreme environments, detect enabling traits that contribute to stress resistance, and test whether plant assemblages in extreme environments are formed from colonisation by specialist tolerators, or by local species adapting. These methods may allow the prediction of species or communities best able to adapt to conditions expected under global environmental change.Read moreRead less
Peripheral isolates as hotbeds of adaptive diversity. This project uses cutting edge molecular technology and spatial analyses to predict the location of diversity relevant to managing the impact of climate change. Knowledge generated in this project will open the door to the informed use of genetic translocation in efforts to kerb expected biodiversity losses.
Discovery Early Career Researcher Award - Grant ID: DE180100624
Funder
Australian Research Council
Funding Amount
$365,058.00
Summary
The role of epigenetic modifications in tiger snake adaptation. This project aims to investigate mechanisms underlying animal adaptation to future environmental change by examining the molecular basis for phenotypic plasticity in snakes. This project will specifically examine variation in genetic/epigenetic profiles and compare against important fitness traits, such as variable head size, bite force and swallowing performance to identify relationships between molecular change and physiology. Suc ....The role of epigenetic modifications in tiger snake adaptation. This project aims to investigate mechanisms underlying animal adaptation to future environmental change by examining the molecular basis for phenotypic plasticity in snakes. This project will specifically examine variation in genetic/epigenetic profiles and compare against important fitness traits, such as variable head size, bite force and swallowing performance to identify relationships between molecular change and physiology. Such research is a critical first step in improving our knowledge of the mechanisms whereby animal populations may adapt to environmental change, allowing us to facilitate such processes or concentrate conservation effort where species are unable to adapt via epigenetic modification.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140100220
Funder
Australian Research Council
Funding Amount
$375,149.00
Summary
How do time, climate change and adaptation shape the assembly and evolution of a diverse continental biota? This project will use new statistical techniques for analysing patterns of biological diversification to test how time, environmental change and evolutionary adaptation shape the accumulation of biodiversity in a continental setting. A supermatrix of genetic and ecological data for Australia's most diverse terrestrial vertebrate group (lizards and snakes) will be compiled. This will allow ....How do time, climate change and adaptation shape the assembly and evolution of a diverse continental biota? This project will use new statistical techniques for analysing patterns of biological diversification to test how time, environmental change and evolutionary adaptation shape the accumulation of biodiversity in a continental setting. A supermatrix of genetic and ecological data for Australia's most diverse terrestrial vertebrate group (lizards and snakes) will be compiled. This will allow the testing of the macroevolutionary responses to key environmental changes through the Cainozoic (rapid climatic transgressions and aridification), the relationship between lineage age and species diversity and the effects of major ecological shifts on rates of speciation, extinction and morphological diversification.Read moreRead less
Multi-trait plasticity in response to a changing climate. This project aims to understand the effect of climate change on natural populations. Phenotypic plasticity (the ability to change phenotype with environment) determines natural populations’ immediate response to environmental change. However, studies of plasticity frequently rely on simplifying assumptions, and understanding the genomic and epigenomic mechanisms underlying plasticity is only just emerging. This project will combine a fine ....Multi-trait plasticity in response to a changing climate. This project aims to understand the effect of climate change on natural populations. Phenotypic plasticity (the ability to change phenotype with environment) determines natural populations’ immediate response to environmental change. However, studies of plasticity frequently rely on simplifying assumptions, and understanding the genomic and epigenomic mechanisms underlying plasticity is only just emerging. This project will combine a fine-scale temperature-manipulation experiment with genomic and multivariate statistical analyses of a native Australian alpine plant. The intended outcome is a comprehensive analysis of whether multi-trait phenotypic plasticity is adaptive; whether it can evolve; and the epigenomic mechanisms that drive it. The project will predict the likely effect of temperature change on alpine plants, and so generate information internationally relevant to the management of populations adapting to climate change and locally relevant to the conservation of Australian montane flora.Read moreRead less