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.
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.
How does your garden grow? Scaling functional traits to whole-plant growth. Understanding how the traits of leaves and stems influence plant growth is important because plant growth drives emergent ecosystem properties such as rates of water use and carbon and nitrogen cycling. The project will build a new understanding of trait-growth relationships, focusing on species from four Australian forest types.
Dining with Dasyurids: Using Nutritional Geometry to Improve Diets for Captive Breeding Programs. Captive breeding programs are an important part of conservation and reintroduction plans for endangered Northern quolls and Tasmanian devils. This project aims to initiate new collaboration between the Charles Perkins Centre and Taronga Conservation Society to improve diets for captive breeding of marsupial carnivores using the framework of nutritional geometry. Specifically, the project aims to: qu ....Dining with Dasyurids: Using Nutritional Geometry to Improve Diets for Captive Breeding Programs. Captive breeding programs are an important part of conservation and reintroduction plans for endangered Northern quolls and Tasmanian devils. This project aims to initiate new collaboration between the Charles Perkins Centre and Taronga Conservation Society to improve diets for captive breeding of marsupial carnivores using the framework of nutritional geometry. Specifically, the project aims to: quantify the macronutrient (carbohydrate, lipid and protein) targets and regulatory behaviour of marsupial carnivores; test explanations for why animals are prone to excess weight gain in captivity; and quantify changes in nutrient targets with reproduction. These results aims to be applied by Taronga to improve captive-diets for marsupial carnivore breeding programs.Read moreRead less
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.
Australian and global plant diversity from first principles. This project aims to explain the composition of vegetation in Australia and worldwide using ecological and evolutionary first principles. Researchers have studied how climate shapes vegetation for centuries, but still lack a basic quantitative theory predicting what types of plants should be found where and why. Combining first principles models, statistics and large Australian data synthesis, this project will determine whether vegeta ....Australian and global plant diversity from first principles. This project aims to explain the composition of vegetation in Australia and worldwide using ecological and evolutionary first principles. Researchers have studied how climate shapes vegetation for centuries, but still lack a basic quantitative theory predicting what types of plants should be found where and why. Combining first principles models, statistics and large Australian data synthesis, this project will determine whether vegetation structure and diversity is predictable and thus improve predictive models. Predicting the long term effects of evolutionary adaptation and humans on ecosystems could enable the management of terrestrial carbon and underpin effective ecosystem management and restoration.Read moreRead less
Optimal photosynthetic traits on ecological time-scales. This project aims to understand how soils and climate shape plant ecological strategies for nutrient and water use in photosynthesis. Terrestrial biosphere models (including ecosystem, land surface and vegetation models) are based on a biochemical model for photosynthesis that accurately represents processes on physiological time-scales but lacks the ecological-evolutionary perspective needed to understand species’ adaptations along geogra ....Optimal photosynthetic traits on ecological time-scales. This project aims to understand how soils and climate shape plant ecological strategies for nutrient and water use in photosynthesis. Terrestrial biosphere models (including ecosystem, land surface and vegetation models) are based on a biochemical model for photosynthesis that accurately represents processes on physiological time-scales but lacks the ecological-evolutionary perspective needed to understand species’ adaptations along geographic gradients of soils and climate. This project will integrate theory based on microeconomic and optimality principles with empirical analysis of local- and global-scale trait datasets. This knowledge is intended to form the core of a ‘next-generation’ global vegetation model. This will allow government agencies to discover the likely effects of future climate and carbon dioxide changes on Australian vegetation structure, function and composition, forest productivity, and biodiversity.Read moreRead less