Phenotypic plasticity in plants: evolution, adaptation and its relevance in a changing climate. Plants are highly responsive to the conditions under which they grow, but the combination of conditions they experience will be altered by climate change. This research into plant responses to novel environments posed by climate change will assess whether we can breed for more responsive crops or predict native plant tolerance of climate change.
Integrating ecoimmunology and population ecology to understand how tropical reptiles deal with novel challenges. Using tropical reptiles as a study system, the project will investigate the extent to which human-induced stressors, such as climate change and invasive species, affect stress levels and immunocompetence of wild animals.
The physiology of biome shifts and macroevolutionary change: how did Australian skinks colonise the arid zone so successfully? This project will examine two of Australia's most diverse lizard lineages, Lerista and Ctenotus, and will identify the physiological and morphological traits that enabled them to adaptively radiate within the arid zone. It will highlight those traits likely to be adaptive for environments predicted to become widespread under climate change.
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
Discovery Early Career Researcher Award - Grant ID: DE120100352
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Understanding the origin and maintenance of megadiverse plant communities. South-western Australia hosts some of the most biologically diverse plant communities on Earth, and these occur on the most ancient, nutrient-impoverished soils. By studying coastal dunes of increasing age, this project will determine how megadiverse plant communities originate during long-term ecosystem development, and how they are maintained.
Maintenance of high plant diversity in phosphorus-impoverished ecosystems. This project aims to determine the role of soil-inhabiting pathogens and symbiotic fungi in the maintenance of plant diversity in Australia’s hyperdiverse shrublands. These are among the world’s most species-rich systems, yet occur on extremely poor soils. This project tests the hypothesis that plants that are best adapted to acquire phosphorus in these extremely infertile soils are most susceptible to soil pathogens. Thi ....Maintenance of high plant diversity in phosphorus-impoverished ecosystems. This project aims to determine the role of soil-inhabiting pathogens and symbiotic fungi in the maintenance of plant diversity in Australia’s hyperdiverse shrublands. These are among the world’s most species-rich systems, yet occur on extremely poor soils. This project tests the hypothesis that plants that are best adapted to acquire phosphorus in these extremely infertile soils are most susceptible to soil pathogens. This trade-off would equalise differences in competitive abilities among plant species and promote high plant diversity. The project will help elucidate how pathogens and symbiotic fungi together drive plant diversity in a globally significant biodiversity hotspot in Australia, with relevance to other biodiverse regions.Read moreRead less
The role of leaf veins in vascular plant evolution. Leaves are continuously irrigated by a system of internal plumbing that defines their maximum photosynthetic output, and angiosperms are the most productive plants on earth largely by virtue of a uniquely efficient system of leaf plumbing. This project will identify how such an important modification of leaf water transport came to evolve.
The energetic basis to seed longevity and storage. The energetic basis to seed longevity and storage. This project aims to quantify patterns of metabolic rate in Australian native seeds to research seed ecology, dormancy, germination, longevity and persistence in natural and artificial seed banks. The project aims to optimise and refine current respirometry technology for use with native seeds, understand the allometric relationship and patterns with seed diversity, and apply this knowledge to b ....The energetic basis to seed longevity and storage. The energetic basis to seed longevity and storage. This project aims to quantify patterns of metabolic rate in Australian native seeds to research seed ecology, dormancy, germination, longevity and persistence in natural and artificial seed banks. The project aims to optimise and refine current respirometry technology for use with native seeds, understand the allometric relationship and patterns with seed diversity, and apply this knowledge to benefit restoration and conservation seed banks. By interpreting the energetics of seeds in a phylogenetic context, this project will develop an experimental protocol to predict the physiology and longevity, and test the viability of seeds in storage. Anticipated outcomes are improved efficiency of seed bank storage, conservation and restoration efforts.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100900
Funder
Australian Research Council
Funding Amount
$426,718.00
Summary
When and where are temperate reef communities vulnerable to ocean warming? This project will test in the laboratory and the field, when and where ocean warming will exceed the thermal limits of marine species and why certain species show greater sensitivity to warming temperatures than others. This project expects to generate robust estimates about how temperature sensitivity varies between populations across species’ ranges and identify the ecological implications for habitat loss in areas wher ....When and where are temperate reef communities vulnerable to ocean warming? This project will test in the laboratory and the field, when and where ocean warming will exceed the thermal limits of marine species and why certain species show greater sensitivity to warming temperatures than others. This project expects to generate robust estimates about how temperature sensitivity varies between populations across species’ ranges and identify the ecological implications for habitat loss in areas where thermal limits differ between key species. Expected outcomes include an enhanced capacity to detect when and where vulnerability hotspots will emerge that could jeopardise the immense social, ecological, and economic value of Australia’s temperate reefs, next to which 70% of Australians live, along 8,000 km of coastline.Read moreRead less
Facilitation of high leaf phosphorus-use efficiency by nitrate restraint. This project aims to determine the link between high phosphorus use efficiency and nitrogen metabolism in the Fabaceae, Myrtaceae and Proteaceace, the three families of plants that co-dominate the flora on the extremely phosphorus-impoverished soils of south-western Australia, a Global Biodiversity Hotspot. It is expected that the extremely high phosphorus use efficiency in these plants is inextricably linked to a low capa ....Facilitation of high leaf phosphorus-use efficiency by nitrate restraint. This project aims to determine the link between high phosphorus use efficiency and nitrogen metabolism in the Fabaceae, Myrtaceae and Proteaceace, the three families of plants that co-dominate the flora on the extremely phosphorus-impoverished soils of south-western Australia, a Global Biodiversity Hotspot. It is expected that the extremely high phosphorus use efficiency in these plants is inextricably linked to a low capacity for nitrogen uptake. An anticipated outcome is new insight into how these plants achieve highly efficient phosphorus and nitrogen use, providing new understanding into the functioning of plants in an exceptionally biodiverse ecosystem and into traits that may lead to to crops with higher fertilizer use efficiency.Read moreRead less