Resolving how five million years of dramatic climatic changes shaped Australia's unique fauna. Australia’s biota is a product of its unique heritage, tectonic history and most especially its climate. Over the past five million years it has been beset by a series of intense climatic shifts driven by a combination of global and regional factors. This project will be the first to track faunal responses to environmental changes across this critical interval. It will establish the dynamics of the ori ....Resolving how five million years of dramatic climatic changes shaped Australia's unique fauna. Australia’s biota is a product of its unique heritage, tectonic history and most especially its climate. Over the past five million years it has been beset by a series of intense climatic shifts driven by a combination of global and regional factors. This project will be the first to track faunal responses to environmental changes across this critical interval. It will establish the dynamics of the origin of the modern southern vertebrate fauna, analysing changes in diversity, diet and community structure. By exploring associations between phases of faunal turnover and key climatic transitions, it will bring a Southern Hemisphere perspective to evolutionary models of Cenozoic faunal change largely generated to date from Northern Hemisphere data.Read moreRead less
Illuminating the evolutionary history of Australia’s most iconic animals. This project aims to pinpoint the nature and timing of key steps in macropod history and to test how these link with major climatic and biotic changes. Macropods (kangaroos and relatives) are widely considered the marsupial equivalents to hoofed mammals on other continents, but we have a weaker understanding of how their evolution was shaped by environmental change. This project will combine palaeontology, anatomy and gene ....Illuminating the evolutionary history of Australia’s most iconic animals. This project aims to pinpoint the nature and timing of key steps in macropod history and to test how these link with major climatic and biotic changes. Macropods (kangaroos and relatives) are widely considered the marsupial equivalents to hoofed mammals on other continents, but we have a weaker understanding of how their evolution was shaped by environmental change. This project will combine palaeontology, anatomy and genetics to address questions such as how and why ancestral macropods descended from the trees and evolved bipedal hopping, and the upper size limits of the kangaroo “body plan”. This should improve our understanding of the long-term effects of climate change on marsupials, and provide a test of key placental-based evolutionary models.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150100542
Funder
Australian Research Council
Funding Amount
$355,000.00
Summary
Understanding adaptation of plants along environmental clines. This project aims to address a key debate on the relative roles of dispersal and selection on adaptation, testing how life history traits determine the magnitude of adaptation. Since dispersal should override selection, this project endeavours to show that plants that strongly disperse will display weaker signals of adaptation but a higher capacity to adapt. The project aims to test these predictions with ecological genomics and func ....Understanding adaptation of plants along environmental clines. This project aims to address a key debate on the relative roles of dispersal and selection on adaptation, testing how life history traits determine the magnitude of adaptation. Since dispersal should override selection, this project endeavours to show that plants that strongly disperse will display weaker signals of adaptation but a higher capacity to adapt. The project aims to test these predictions with ecological genomics and functional genetics at a multi-species scale across climate gradients in South Australia, using a novel design that separates dispersal (isolation-by-distance) from selection (isolation-by-ecology). This understanding will provide improved conservation planning that seeks to restore resilience to biological communities that are under increasing environmental pressures.Read moreRead less
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: DE190101069
Funder
Australian Research Council
Funding Amount
$390,000.00
Summary
Adaptation and diversification of the first peoples of Sahul. This project aims to further advance work on the genetic history of Indigenous Australians and Papuans that has revealed that Aboriginal Australians have inhabited a variety of diverse and challenging environments for approximately 50,000 years. Using novel techniques for extraction of human DNA from soil and the use of cutting-edge graph-based methods, hundreds of Indigenous Australian and Papuan genomes will be analysed. This projec ....Adaptation and diversification of the first peoples of Sahul. This project aims to further advance work on the genetic history of Indigenous Australians and Papuans that has revealed that Aboriginal Australians have inhabited a variety of diverse and challenging environments for approximately 50,000 years. Using novel techniques for extraction of human DNA from soil and the use of cutting-edge graph-based methods, hundreds of Indigenous Australian and Papuan genomes will be analysed. This project expects to generate new knowledge by filling in the gaps in the Australian genetic record via ancient human DNA from sediments. Expected outcomes from this project are producing a detailed picture of genomic adaptation in Indigenous Australians and Papuans and creating a comprehensive genetic history of the First Peoples of Sahul.Read moreRead less
Faunal responses to past climatic and human impacts in eastern Australia. The Wellington Caves in central eastern New South Wales are Australia's most historically significant fossil locality and preserve one of the world's most complete records of vertebrate life spanning the past 4 million years. To date this unique archive has been vastly under-exploited as a source of information on how faunas respond to increased aridity and climatic variability, as well as human activities over the past 50 ....Faunal responses to past climatic and human impacts in eastern Australia. The Wellington Caves in central eastern New South Wales are Australia's most historically significant fossil locality and preserve one of the world's most complete records of vertebrate life spanning the past 4 million years. To date this unique archive has been vastly under-exploited as a source of information on how faunas respond to increased aridity and climatic variability, as well as human activities over the past 50 000 years. This project aims to elucidate how climate change drove the evolution of the modern fauna of eastern Australia by analysing changes in diversity, diet and community structure over time. It may also help break the 130-year climate-versus-humans deadlock over what drove the Pleistocene megafaunal extinctions.Read moreRead less
Using genetics to reconstruct the peopling and diversification of Sahul. A recent landmark study has revealed that people who first arrived on Sahul (the landmass connecting Australia with New Guinea) remained largely genetically isolated from subsequent migrations. However, there is still little known about the route(s) taken into Sahul, or how adaptation has shaped the enormous diversity now observed across Indigenous Australians and Papuans. This project aims to look at these issues by applyi ....Using genetics to reconstruct the peopling and diversification of Sahul. A recent landmark study has revealed that people who first arrived on Sahul (the landmass connecting Australia with New Guinea) remained largely genetically isolated from subsequent migrations. However, there is still little known about the route(s) taken into Sahul, or how adaptation has shaped the enormous diversity now observed across Indigenous Australians and Papuans. This project aims to look at these issues by applying phylogenetic and population genetic tools to the largest genetic dataset yet analysed from populations across Australia, New Guinea, and Island South East Asia. The outcomes of the project should reveal both the route(s) taken into Sahul and how adaptation has shaped the diversity now observed in descendants of the colonisation.Read moreRead less
How are visual gene pathways lost and restored during reptile evolution? This project aims to investigate how complex traits are lost during evolution, and once lost if they can be regained. The project will use the diverse visual systems of snakes and lizards to shed light on the process of gene loss in degenerative lineages, and discover the mechanisms that compensate for gene losses in taxa with secondarily evolved visual capabilities- providing a case of evolutionary re-innovation in complex ....How are visual gene pathways lost and restored during reptile evolution? This project aims to investigate how complex traits are lost during evolution, and once lost if they can be regained. The project will use the diverse visual systems of snakes and lizards to shed light on the process of gene loss in degenerative lineages, and discover the mechanisms that compensate for gene losses in taxa with secondarily evolved visual capabilities- providing a case of evolutionary re-innovation in complex traits.Read moreRead less
Fire, air, water and earth: Using fossils to discover the evolution of Australia’s open vegetation. How Australia came to be dominated by open, tough-leaved vegetation is an old but still highly controversial question, especially with recent developments in molecular biology that challenge paradigms established from the fossil record. The project will test this new molecular paradigm with innovative use of characteristics of fossil leaves to identify the timing and drivers of the evolution of Au ....Fire, air, water and earth: Using fossils to discover the evolution of Australia’s open vegetation. How Australia came to be dominated by open, tough-leaved vegetation is an old but still highly controversial question, especially with recent developments in molecular biology that challenge paradigms established from the fossil record. The project will test this new molecular paradigm with innovative use of characteristics of fossil leaves to identify the timing and drivers of the evolution of Australia’s open vegetation. The integration of new and rigorous evidence derived from living and fossil plants will provide the clearest evidence yet for the origins of Australian environments. This has ramifications for understanding plant responses to past and future climate changes.Read moreRead less
Harnessing genetic diversity for complex traits. Genetic diversity underpins crop improvement but has become increasingly narrow in our major crops. Strategies exist for mobilising simple traits (e.g. disease resistance) from wild accessions or landraces into cultivars, but there are no effective approaches for introducing complex traits, including stress tolerance or components of yield. Using barley as an important crop and a genetic model, the project aims to address this problem by applying ....Harnessing genetic diversity for complex traits. Genetic diversity underpins crop improvement but has become increasingly narrow in our major crops. Strategies exist for mobilising simple traits (e.g. disease resistance) from wild accessions or landraces into cultivars, but there are no effective approaches for introducing complex traits, including stress tolerance or components of yield. Using barley as an important crop and a genetic model, the project aims to address this problem by applying a novel approach; partial redomestication of wild accessions by introgressing genes required for modern farming, then evaluating the resulting partially adapted germplasm in hybrids with elite cultivars. The project expects to generate new and diverse germplasm pools for breeding.Read moreRead less