Restoring & future-proofing the biocultural values of endangered seagrasses. This project aims to develop best-practice methods for the biocultural restoration of the endangered seagrass Posidonia australis. This species is highly productive, supports fisheries and biodiversity, and plays a key role in mitigating climate change. This project will generate valuable new genetic information to guide restoration strategies including climate-adjusted genotypes. Working with Indigenous groups, we aim ....Restoring & future-proofing the biocultural values of endangered seagrasses. This project aims to develop best-practice methods for the biocultural restoration of the endangered seagrass Posidonia australis. This species is highly productive, supports fisheries and biodiversity, and plays a key role in mitigating climate change. This project will generate valuable new genetic information to guide restoration strategies including climate-adjusted genotypes. Working with Indigenous groups, we aim to document and restore cultural values associated with Posidonia. Working with industrial designers, we seek to develop cost-effective techniques to scale-up seagrass restoration. This research should provide significant environmental, economic, social and cultural benefits by improving seagrass restoration.Read moreRead less
Creating coolspots: eco-engineering heat-resistant intertidal communities. This project aims to identify structural characteristics of marine intertidal habitat patches, formed by seaweeds and shellfish, that protect associated species from thermal extremes. This project will generate new knowledge about how thermally sensitive intertidal species can persist in stressful environments. Expected outcomes of this project
include new approaches for building heat-tolerant ecological communities on co ....Creating coolspots: eco-engineering heat-resistant intertidal communities. This project aims to identify structural characteristics of marine intertidal habitat patches, formed by seaweeds and shellfish, that protect associated species from thermal extremes. This project will generate new knowledge about how thermally sensitive intertidal species can persist in stressful environments. Expected outcomes of this project
include new approaches for building heat-tolerant ecological communities on coastal infrastructure, and improved tools for predicting the response of intertidal seaweeds and animals to environmental change. The results of this project will benefit coastal management by identifying conservation and rehabilitation strategies that maximise the
resilience of coastal ecosystems to environmental change.Read moreRead less
Do root microbiomes control seagrass response to environmental stress? The project aims to determine the role root microbes play in controlling seagrass responses to environmental stress. By integrating marine and microbial ecology, environmental genomics and ecosystem function (e.g., biogeochemical cycling), this project is significant as it will create new knowledge of the processes that confer seagrass resilience to global environmental issues. An expected outcome is an increased understandin ....Do root microbiomes control seagrass response to environmental stress? The project aims to determine the role root microbes play in controlling seagrass responses to environmental stress. By integrating marine and microbial ecology, environmental genomics and ecosystem function (e.g., biogeochemical cycling), this project is significant as it will create new knowledge of the processes that confer seagrass resilience to global environmental issues. An expected outcome is an increased understanding of how microbes control seagrass health and an enhanced capacity to develop effective restoration strategies for Australia's valuable seagrass ecosystems. Benefits include improving the extensive environmental, economic, social/cultural services Australian communities derive from seagrass ecosystems.Read moreRead less
Improving the success of hybrid living shorelines for coastal protection. This project aims to improve the success of hybrid living shorelines that combine the restoration of mangroves and oysters with engineered structures to enhance restoration outcomes and coastal hazard resilience. It expects to generate new knowledge on the effectiveness of innovative coastal-manager-led solutions that have not yet been robustly evaluated. Expected outcomes of this project include delivery of the technical ....Improving the success of hybrid living shorelines for coastal protection. This project aims to improve the success of hybrid living shorelines that combine the restoration of mangroves and oysters with engineered structures to enhance restoration outcomes and coastal hazard resilience. It expects to generate new knowledge on the effectiveness of innovative coastal-manager-led solutions that have not yet been robustly evaluated. Expected outcomes of this project include delivery of the technical guidelines needed to practically design and implement nature-based coastal protection at scale. This should provide significant socio-economic and environmental benefits through improving Australia’s capacity to adapt to increased erosion and flood risk caused by climate change and coastal urbanisation.Read moreRead less
Population fluctuations: models, mechanisms and management. Changes in plant populations lead to extinctions and invasions in Australia and globally. The project will determine the drivers of plant population change and provide new tools to enable better population management.
Assessing fish connectivity across highly-modified seascapes. This project aims to quantify the effects of large-scale infrastructure on fish connectivity and populations by advancing our understanding of critical ecological processes within these modified coastal seascapes. The project expects to generate new knowledge in the area of fish seascape ecology and management using an innovative approach which considers all life history stages within a metapopulation modelling context. Expected outco ....Assessing fish connectivity across highly-modified seascapes. This project aims to quantify the effects of large-scale infrastructure on fish connectivity and populations by advancing our understanding of critical ecological processes within these modified coastal seascapes. The project expects to generate new knowledge in the area of fish seascape ecology and management using an innovative approach which considers all life history stages within a metapopulation modelling context. Expected outcomes of this project include the development of an integrated modelling approaches to better predict the effects of habitat modifications. This should provide significant benefits by allowing assessment of development and management actions before they take place, supporting long-term planning.Read moreRead less
Answering longstanding plant ecology questions with new technology: the effects of changes in leaf proteins with age. Total leaf nitrogen is important for major processes in ecosystems. It is used as a predictor for carbon fixation because photosynthesis proteins are a large fraction of leaf nitrogen. Yet leaf nitrogen may also be allocated to stress-response and defense-related proteins at the expense of photosynthesis proteins. Our working hypothesis might explain two important ecological patt ....Answering longstanding plant ecology questions with new technology: the effects of changes in leaf proteins with age. Total leaf nitrogen is important for major processes in ecosystems. It is used as a predictor for carbon fixation because photosynthesis proteins are a large fraction of leaf nitrogen. Yet leaf nitrogen may also be allocated to stress-response and defense-related proteins at the expense of photosynthesis proteins. Our working hypothesis might explain two important ecological patterns: the decline of photosynthetic nitrogen use efficiency with leaf age; and, low and variable nitrogen recovery levels from senescent leaves across species and habitats. New quantitative proteomics methods together with protein functional categorisation can answer these questions across dozens of Australian native plant species.Read moreRead less
Cane toads as a model system for demographic analysis and invasive-species control. How do impacts on juvenile stages within a population affect later ages? This project will exploit recently developed methods to control early life-history stages of cane toads to provide a better understanding of population ecology and develop more effective ways to control invasive cane toads.
Cane toads in southern Australia: invasion dynamics and options for control. This project aims to investigate the spread of cane toads through southern Australia, an invasion front that has attracted far less research than the same species’ expansion through tropical regions, even though toads severely impact native wildlife in both areas. This project expects to generate new knowledge to determine why the rate of toad invasion is so much slower in New South Wales than in the tropics, and how be ....Cane toads in southern Australia: invasion dynamics and options for control. This project aims to investigate the spread of cane toads through southern Australia, an invasion front that has attracted far less research than the same species’ expansion through tropical regions, even though toads severely impact native wildlife in both areas. This project expects to generate new knowledge to determine why the rate of toad invasion is so much slower in New South Wales than in the tropics, and how best to modify newly-developed approaches to toad control to the conditions in southern Australia. Expected outcomes include predicting future trajectories of expansion, and identifying optimal approaches to toad control and impact mitigation. This should provide significant benefits for biodiversity conservation.Read moreRead less
Ecology, impact and control of cane toads on the southern invasion front. The invasion of cane toads has killed many native animals in tropical Australia, but the toads’ southern (NSW) invasion front remains unstudied. This project will build on recent research to understand how toads affect southern biodiversity, and will develop new ways to reduce that impact.