Physiological effects of extreme hot weather on animals’ metabolism, development, body size and cell lifespan. This project aims to determine the physiological effects of extreme hot weather on animals’ metabolism, development, body size and cell lifespan. Body size in animals is negatively related to latitude; individuals are relatively small in hot climates. The project will test the idea that the adverse effects of heat during development constrain body size. The project will draw on physiolo ....Physiological effects of extreme hot weather on animals’ metabolism, development, body size and cell lifespan. This project aims to determine the physiological effects of extreme hot weather on animals’ metabolism, development, body size and cell lifespan. Body size in animals is negatively related to latitude; individuals are relatively small in hot climates. The project will test the idea that the adverse effects of heat during development constrain body size. The project will draw on physiology, endocrinology, behaviour and cell biology and study birds across Australian climates and in a temperature-controlled laboratory. The outcomes of the project will provide insight into regional variation in species vulnerabilities to climate variation and inform biodiversity management.Read moreRead less
Living in a changing climate: the impacts of temperature during aestivation on burrowing frogs. Although arid zones of Australia are characterised by extremes of temperature, little is known about the thermal ecology of frogs inhabiting these regions. This project will determine the effects of temperature on the physiology of an arid-adapted frog and determine whether likely increases in global temperatures will impact its survival.
Hydroregulation – a missing piece of the climate change puzzle. There is a great need for process-explicit approaches to the puzzle of how organisms will respond to changes in temperature and rainfall. To achieve this for animals, behavioural buffering of both body temperature and water balance must be accounted for. Much is known about thermoregulation, but 'hydroregulation' stands out as a major missing piece of the climate change forecasting puzzle. This project will integrate new modelling m ....Hydroregulation – a missing piece of the climate change puzzle. There is a great need for process-explicit approaches to the puzzle of how organisms will respond to changes in temperature and rainfall. To achieve this for animals, behavioural buffering of both body temperature and water balance must be accounted for. Much is known about thermoregulation, but 'hydroregulation' stands out as a major missing piece of the climate change forecasting puzzle. This project will integrate new modelling methods and empirical approaches to understand the connections between thermoregulation, hydroregulation, activity and, ultimately, distribution and abundance. It will test the predictions against long-term activity observations of reptiles and invertebrates from the Australian arid zone.Read moreRead less
Silicon defences for plant protection. This project aims to study how silicon uptake in grasses affects plant susceptibility aboveground. Grasses contain more silicon than nearly any other plant, which they acquire entirely from the soil. Silicon increases plant resistance to herbivores, disease and drought, but up to 25 per cent of grass productivity is lost to root herbivores, a situation compounded by water stress. Silicon uptake is poorly understood, but root herbivory and changing rainfall ....Silicon defences for plant protection. This project aims to study how silicon uptake in grasses affects plant susceptibility aboveground. Grasses contain more silicon than nearly any other plant, which they acquire entirely from the soil. Silicon increases plant resistance to herbivores, disease and drought, but up to 25 per cent of grass productivity is lost to root herbivores, a situation compounded by water stress. Silicon uptake is poorly understood, but root herbivory and changing rainfall patterns can either impair uptake or induce the plant to take up more silicon. The goal of this project is to optimise silicon-based resistance in grasses and exploit this for plant protection from invasive pests and drought.Read moreRead less
Predicting invertebrate life cycles under variable climates. This project seeks to characterise and predict the responses of invertebrates to climate variability and climate change. Alterations to the developmental trajectory are a major way that organisms adapt their life cycles to climatic variability. Many invertebrates avoid extremes of heat, cold and dry by entering a quiescent or diapause state, often at the egg stage. This project plans to apply novel high-throughput methods for character ....Predicting invertebrate life cycles under variable climates. This project seeks to characterise and predict the responses of invertebrates to climate variability and climate change. Alterations to the developmental trajectory are a major way that organisms adapt their life cycles to climatic variability. Many invertebrates avoid extremes of heat, cold and dry by entering a quiescent or diapause state, often at the egg stage. This project plans to apply novel high-throughput methods for characterising developmental patterns in the eggs of invertebrates in conjunction with microclimate models and modern phylogenetic methods to understand and predict responses to climatic variability. The methods are expected to be transferable to other invertebrates and may lead to breakthroughs in pest management and conservation.Read moreRead less
Turning water into carbon: a synthesis of plant water-use efficiency from leaf to globe. The efficiency with which plants use water to gain carbon is a fundamental aspect of plant growth that has been frequently measured but is poorly understood. Using our new theory to draw together major datasets, the project will make a dramatic advance in our ability to understand and predict this key aspect of ecosystem function.