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.
Origins of a biodiversity hotspot flora: diversification of the Australian Proteaceae. Why does Australia's only biodiversity hotspot, with nearly 3000 endemic plant species, occur in an area with poor soils and low rainfall? This project will analyse DNA sequences from over 1000 plant species of the Australian Proteaceae, many found only in this hotspot, to help us understand the evolutionary and ecological origins of this iconic flora.
Evolution of Australia's globally unique hotspot of floral diversity. Australia has a globally recognised biodiversity hotspot, the southwest of Western Australia, but this unique eucalypt-dominated flora is threatened. This project will gain new insights into the evolutionary processes that generate and maintain such diversity, their vulnerability; and how the iconic eucalypts came to dominate the Australian landscape.
New approaches to understanding the forces driving convergent evolution. This project aims to address the evolutionary biology question of what drives convergent evolution of morphological phenotypes. Leveraging previous research on the phylogenetics of Australian reptiles and amphibians, the project will apply new methodological and analytical tools for quantifying and evaluating morphological diversity in a phylogenetic context. The project expects to test the influence of climate, habitat and ....New approaches to understanding the forces driving convergent evolution. This project aims to address the evolutionary biology question of what drives convergent evolution of morphological phenotypes. Leveraging previous research on the phylogenetics of Australian reptiles and amphibians, the project will apply new methodological and analytical tools for quantifying and evaluating morphological diversity in a phylogenetic context. The project expects to test the influence of climate, habitat and evolutionary history on driving convergent morphological evolution across multiple independent animal groups. The project will address fundamental theories on convergent evolution and will improve public awareness of Australia’s unique animals and their history.Read moreRead less
Phenotypic diversity dynamics at a continental scale. This project aims to build on previous research on the phylogenetics of Australian vertebrate animals to apply sophisticated new methodological and analytical tools for modelling species diversification. Australia is famous for the great diversity and uniqueness of its plants and animals, due in part to 40 million years of relative isolation. The project plans to test the influence of historical climate and habitat shifts on morphological evo ....Phenotypic diversity dynamics at a continental scale. This project aims to build on previous research on the phylogenetics of Australian vertebrate animals to apply sophisticated new methodological and analytical tools for modelling species diversification. Australia is famous for the great diversity and uniqueness of its plants and animals, due in part to 40 million years of relative isolation. The project plans to test the influence of historical climate and habitat shifts on morphological evolution and assembly of the Australian biota. This project could showcase Australia as the best place in the World to rigorously test hypotheses concerning rates of biological diversification at a continental scale.Read moreRead less
Biological diversification across Australia in space and time. This project aims to address fundamental questions about the diversification of Australian species and to have practical and impactful outcomes. It will leverage previous ARC funded research on the phylogenomics of Australian reptiles and amphibians and apply sophisticated analytical tools for quantifying and evaluating biological diversity in multiple dimensions and in a phylogenetic context. The expected outcomes include a publicly ....Biological diversification across Australia in space and time. This project aims to address fundamental questions about the diversification of Australian species and to have practical and impactful outcomes. It will leverage previous ARC funded research on the phylogenomics of Australian reptiles and amphibians and apply sophisticated analytical tools for quantifying and evaluating biological diversity in multiple dimensions and in a phylogenetic context. The expected outcomes include a publicly accessible comprehensive database that will be integrated with the Atlas of Living Australia and rigorous testing of a series of hypotheses concerning how old and recent Australian groups evolved in response to biotic invasions and climate change. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100491
Funder
Australian Research Council
Funding Amount
$418,386.00
Summary
Linking genomic changes to the generation of biodiversity. This project aims to provide a suite of theories, methods and software to enhance our understanding on how the generation of variation at molecular level is linked to the generation of species richness at lineage level. This new approach tests various ways that molecular changes are manifested as patterns of diversification, as revealed by genomic data analysed at the lineage level in phylogenetic studies. Expected outcomes of this proje ....Linking genomic changes to the generation of biodiversity. This project aims to provide a suite of theories, methods and software to enhance our understanding on how the generation of variation at molecular level is linked to the generation of species richness at lineage level. This new approach tests various ways that molecular changes are manifested as patterns of diversification, as revealed by genomic data analysed at the lineage level in phylogenetic studies. Expected outcomes of this project add to a growing body of evolutionary theory and provide practical phylogenetic tools for future analyses. These should benefit Australia by improving our understanding on the formation of Australia’s biodiversity hotspots.Read moreRead less
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.
Australian Laureate Fellowships - Grant ID: FL100100183
Funder
Australian Research Council
Funding Amount
$2,168,370.00
Summary
Biological adaptation under natural and anthropogenic conditions. This project covers all four national priority areas. Nature abounds with conflicts between what is good for the individual or a larger entity (a population, a society, or a species). Researching them will explain why populations adapt or fail to adapt to novel conditions (e.g., climate change) and predict when interventions are beneficial. Similar rules govern the spread of invasive species. Even health problems, e.g., new virule ....Biological adaptation under natural and anthropogenic conditions. This project covers all four national priority areas. Nature abounds with conflicts between what is good for the individual or a larger entity (a population, a society, or a species). Researching them will explain why populations adapt or fail to adapt to novel conditions (e.g., climate change) and predict when interventions are beneficial. Similar rules govern the spread of invasive species. Even health problems, e.g., new virulent strains of human, animal or plant diseases, require such evolutionary thinking. Cutting-edge mathematical tools also prepare Australians for an era in the near future where genomic data are so cheap to acquire that training in complex mathematical and logical analysis becomes a factor limiting scientific progress.Read moreRead less
Growing up to be supersonic: bat echolocation origins and mechanics. This project aims to address the unresolved evolutionary origins of bat echolocation. Using a unique combination of development, evolution and novel engineering testing, this project expects to generate new insights into how features of the skull have evolved to allow bats to use their senses to interact with the environment. Expected outcomes include the identification of skull features that are unique to echolocating bats and ....Growing up to be supersonic: bat echolocation origins and mechanics. This project aims to address the unresolved evolutionary origins of bat echolocation. Using a unique combination of development, evolution and novel engineering testing, this project expects to generate new insights into how features of the skull have evolved to allow bats to use their senses to interact with the environment. Expected outcomes include the identification of skull features that are unique to echolocating bats and tests of how these relate to the frequency and detection range of sounds produced. Benefits include improved conservation planning for urban and rural bat populations, and potential commercial advances through engineering applications that mimic the biological process of echolocation. Read moreRead less