Responses of reptiles to fluctuating thermal environments: behaviour or biochemistry? I propose a conceptual shift in the way thermal physiology of reptiles is interpreted, questioning the predominant role of behaviour in reptilian thermoregulation. I will test the hypothesis that changes in cellular biochemistry are an important mechanism by which reptiles respond to environmental fluctuations. I will determine the relationship between metabolic enzyme activity and performance functions, and ....Responses of reptiles to fluctuating thermal environments: behaviour or biochemistry? I propose a conceptual shift in the way thermal physiology of reptiles is interpreted, questioning the predominant role of behaviour in reptilian thermoregulation. I will test the hypothesis that changes in cellular biochemistry are an important mechanism by which reptiles respond to environmental fluctuations. I will determine the relationship between metabolic enzyme activity and performance functions, and the results may call for a re-assessment of current concepts such as the notion that reptiles must achieve "preferred" body temperatures to maintain performance.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775666
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
Flora and Fauna Research Facility. Our ability to make informed decisions regarding conservation and management of unique Australian ecosytems depends greatly on our understanding of the organisms inhabiting them. Researchers at the University of Wollongong are addressing this need through a wide range of studies including the: effects of climate change on plants, biology of invasive species, possible causes for declining frog populations, role of the immune system in aging and natural selection ....Flora and Fauna Research Facility. Our ability to make informed decisions regarding conservation and management of unique Australian ecosytems depends greatly on our understanding of the organisms inhabiting them. Researchers at the University of Wollongong are addressing this need through a wide range of studies including the: effects of climate change on plants, biology of invasive species, possible causes for declining frog populations, role of the immune system in aging and natural selection, effects of maternal hormones on offspring, effects of pesticides on native vertebrates, and impacts of bushfires on ecosystems. The infrastructure requested will enable research in these and other important areas.Read moreRead less
Of birds and bees: membrane lipids and the determination of maximum lifespan. The underlying mechanisms that determine why different animals have different maximum lifespans are unknown. Why do queen bees live for years but the genetically-identical workers bees live for only weeks? Similarly, to understand why birds live much longer than similar-sized mammals will give immense insight into the processes that cause ageing. Understanding the aging process in animals will have significant implicat ....Of birds and bees: membrane lipids and the determination of maximum lifespan. The underlying mechanisms that determine why different animals have different maximum lifespans are unknown. Why do queen bees live for years but the genetically-identical workers bees live for only weeks? Similarly, to understand why birds live much longer than similar-sized mammals will give immense insight into the processes that cause ageing. Understanding the aging process in animals will have significant implications for human health as the biggest risk factor for most diseases is age. Such understanding will help to cope with the worldwide problems of an aging population.Read moreRead less
Design of the cardiovascular system of living and fossil vertebrates. This project aims to understand how the heart and blood vessels evolved in mammals, birds, reptiles and fish to achieve efficiency. The heart is the most important organ for life. The project will study the structure and function of vertebrate animals’ hollow and spongy hearts to show how energetics shaped their evolution. It will measure arterial holes in bone to gauge brain and bone metabolism, which opens up a new way to me ....Design of the cardiovascular system of living and fossil vertebrates. This project aims to understand how the heart and blood vessels evolved in mammals, birds, reptiles and fish to achieve efficiency. The heart is the most important organ for life. The project will study the structure and function of vertebrate animals’ hollow and spongy hearts to show how energetics shaped their evolution. It will measure arterial holes in bone to gauge brain and bone metabolism, which opens up a new way to measure metabolism in extinct animals directly from fossils, rather than by inference from living relatives. The expected outcome is to correlate cardiovascular design and metabolic rates of organs.Read moreRead less
Plasticity in placental vasculature and the evolution of viviparity in lizards. This cross-disciplinary research will provide thorough understanding of the reproductive physiology of animals with different forms of reproduction, information critical for conservation and management of Australia's biodiversity. Australia's unique reptiles provide the best animal system in the world for research in this area. Our research on maternal-embryonic interactions in this animal model has direct implicatio ....Plasticity in placental vasculature and the evolution of viviparity in lizards. This cross-disciplinary research will provide thorough understanding of the reproductive physiology of animals with different forms of reproduction, information critical for conservation and management of Australia's biodiversity. Australia's unique reptiles provide the best animal system in the world for research in this area. Our research on maternal-embryonic interactions in this animal model has direct implications for understanding some medical disorders, such as human angiogenic disorders. The research will strengthen ties internationally through research in South Africa, and provide training in combined biological and medical technologies. It will maintain Australia's long-term leadership in this area of research.Read moreRead less
The physiological mechanisms underlying animal group dynamics. The project aims to provide novel insights into how individual differences in muscle biomechanics and metabolism constrain group assemblages, and the extent to which these constraints can cause fission and fusion of populations in changing environments. This research is significant because most ecological and evolutionary processes and their management occur at the level of groups. The project expects to yield a theoretical model cal ....The physiological mechanisms underlying animal group dynamics. The project aims to provide novel insights into how individual differences in muscle biomechanics and metabolism constrain group assemblages, and the extent to which these constraints can cause fission and fusion of populations in changing environments. This research is significant because most ecological and evolutionary processes and their management occur at the level of groups. The project expects to yield a theoretical model calibrated against empirical data to predict group dynamics of natural populations in changing environments, and of human crowds as diseases and lifestyle change physiological capacities.Read moreRead less
Evolution of viviparity in reptiles: the fundamental role of junctional complexes. This project utilises unique Australian reptile fauna to understand global questions in fundamental biology. We will discover basic biological information on native species, which will be important in future conservation of Australian ecosystems and animals and ultimately in helping to maintain Australia's biodiversity. The project also provides training opportunities for graduate and undergraduate students in ....Evolution of viviparity in reptiles: the fundamental role of junctional complexes. This project utilises unique Australian reptile fauna to understand global questions in fundamental biology. We will discover basic biological information on native species, which will be important in future conservation of Australian ecosystems and animals and ultimately in helping to maintain Australia's biodiversity. The project also provides training opportunities for graduate and undergraduate students in several different research methods that are widely applicable in the more general Australian workforce. Because the research work is genuinely cross-disciplinary research, its findings are applicable to both biological and medically oriented technologies.Read moreRead less
The Role of Torpor in the Life of Arid Zone Mammals. Global warming is predicted to significantly affect our climate. The study will provide critical information about the thermal and energetic capabilities and requirements of native Australian mammals. As little is known about the functional adaptations of arid zone mammals in the wild, these results will be a significant advancement in knowledge about the biology of native Australian species. The data will allow us to predict whether and how p ....The Role of Torpor in the Life of Arid Zone Mammals. Global warming is predicted to significantly affect our climate. The study will provide critical information about the thermal and energetic capabilities and requirements of native Australian mammals. As little is known about the functional adaptations of arid zone mammals in the wild, these results will be a significant advancement in knowledge about the biology of native Australian species. The data will allow us to predict whether and how populations may be affected in the future and provide wildlife managers with an additional tool for making appropriate and sound decisions for the conservation of wildlife. Moreover, the project will enhance the scientific standing of Australia, improve international collaboration, and train students.Read moreRead less
Discovery Indigenous Researchers Development - Grant ID: DI100100158
Funder
Australian Research Council
Funding Amount
$199,988.00
Summary
Climate change research: Can Sydney rock oysters adapt to chronic multigenerational exposure to ocean acidification and temperature?
. Our goal is to understand how long term exposure to climate change will affect oysters in an effort to climate-proof the Australian oyster industry. Oyster farming is worth more than $1 billion a year in retail sales and employs thousands of Australians. The future of this industry is threatened by climate change, particularly its impact on the reproduction an ....Climate change research: Can Sydney rock oysters adapt to chronic multigenerational exposure to ocean acidification and temperature?
. Our goal is to understand how long term exposure to climate change will affect oysters in an effort to climate-proof the Australian oyster industry. Oyster farming is worth more than $1 billion a year in retail sales and employs thousands of Australians. The future of this industry is threatened by climate change, particularly its impact on the reproduction and development of oysters. Our study will identify how oysters respond to chronic multigenerational exposure to ocean acidification and temperature, & identify physiological mechanisms and genes associated with climate change adaptation. This work will maintain Australia's position at the forefront of climate change research on marine ecosystems.Read moreRead less
The role of epigenetics in conferring resilience to environmental change. This project aims to determine whether epigenetic mechanisms confer resilience to environmental change in natural populations. Understanding epigenetic mechanisms is significant because they can mediate compensatory responses by animals to rapid environmental change. This project intends to link molecular changes to ecological outcomes to determine rapid remodeling of phenotypes to maintain fitness in variable environments ....The role of epigenetics in conferring resilience to environmental change. This project aims to determine whether epigenetic mechanisms confer resilience to environmental change in natural populations. Understanding epigenetic mechanisms is significant because they can mediate compensatory responses by animals to rapid environmental change. This project intends to link molecular changes to ecological outcomes to determine rapid remodeling of phenotypes to maintain fitness in variable environments. The project would benefit Australia’s research capacity and training, and the efficacy of conserving our natural environment.Read moreRead less