The evolutionary potential of fragmented and declining populations. This project aims to integrate adaptive genomic and epigenomic information from wild, captive and reintroduced populations to identify evolutionary potential across different life-histories and levels of habitat fragmentation. The project will capitalise on knowledge and genomic resources for Australian freshwater fishes, including a natural experiment of evolution. It is expected that the project will address fundamental and ap ....The evolutionary potential of fragmented and declining populations. This project aims to integrate adaptive genomic and epigenomic information from wild, captive and reintroduced populations to identify evolutionary potential across different life-histories and levels of habitat fragmentation. The project will capitalise on knowledge and genomic resources for Australian freshwater fishes, including a natural experiment of evolution. It is expected that the project will address fundamental and applied questions about the adaptive capacity of populations in their natural environment. The outcomes of the project will help evaluate and improve local and ecosystem-level initiatives towards the sustainable management of aquatic biodiversity impacted by human activities. The project will also inform on management of water resources in the Murray-Darling Basin.Read moreRead less
Comparative Evolutionary Genomics of Australian Rainbowfishes. This project aims to use an evolutionarily young and ecologically important fish clade to understand adaptive resilience and to test predictions derived from the 'climatic variability hypothesis' for the major climatic regions of mainland Australia. Correlative surveys along landscapes and mechanistic experimental studies will be integrated to implement a comparative evolutionary genomics framework capable of assessing the genetic ba ....Comparative Evolutionary Genomics of Australian Rainbowfishes. This project aims to use an evolutionarily young and ecologically important fish clade to understand adaptive resilience and to test predictions derived from the 'climatic variability hypothesis' for the major climatic regions of mainland Australia. Correlative surveys along landscapes and mechanistic experimental studies will be integrated to implement a comparative evolutionary genomics framework capable of assessing the genetic basis of adaptation and the evolutionary resilience of populations and lineages. This is expected to clarify climatic and geographic correlates of adaptation across a vast area of Australia and to disentangle responses to environmental change in an emerging model system for adaptation research.Read moreRead less
Primary producers; morphological flexibility under environmental constraints. Climate change impacts on phytoplankton that uptake nutrients for incorporation into food webs including marine mammals and fish. This project will study the morphological flexibility of diatoms to reveal principles underlying nutrient uptake under different climatic scenarios.