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
Regulation of salt gland activity in the estuarine crocodile: phenotypic plasticity and control mechanisms. The estuarine crocodile excretes excess sodium and chloride ions through salt glands located on the tongue, enabling the crocodile to live in seawater. This study will investigate the regulation of salt gland secretory capacity and activity, by examining both the phenotypic plasticity of the gland to changes in environmental salinity and diet, and by determining the neural/humoral mech ....Regulation of salt gland activity in the estuarine crocodile: phenotypic plasticity and control mechanisms. The estuarine crocodile excretes excess sodium and chloride ions through salt glands located on the tongue, enabling the crocodile to live in seawater. This study will investigate the regulation of salt gland secretory capacity and activity, by examining both the phenotypic plasticity of the gland to changes in environmental salinity and diet, and by determining the neural/humoral mechanisms controlling secretory rate. In vivo measurements of blood flow and salt gland secretory rate, together with perfused gland preparations will reveal extrinsic and intrinsic factors controlling salt gland activity and the degree of coupling between blood flow and secretory rate.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
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 inhibition of muscle disuse atrophy in burrowing frogs. Prolonged muscle disuse, as a consequence of limb immobilisation, extended bed-rest or space travel, can lead to pathological changes resulting in muscle wasting. By examining a unique Australian frog that burrows underground and remains immobile for 9-12 months, and which shows no muscle wasting, we will significantly advance our understanding of the physiological mechanisms that inhibit muscle atrophy.
Benefits of conducting this r ....The inhibition of muscle disuse atrophy in burrowing frogs. Prolonged muscle disuse, as a consequence of limb immobilisation, extended bed-rest or space travel, can lead to pathological changes resulting in muscle wasting. By examining a unique Australian frog that burrows underground and remains immobile for 9-12 months, and which shows no muscle wasting, we will significantly advance our understanding of the physiological mechanisms that inhibit muscle atrophy.
Benefits of conducting this research will include:
- understanding the role of antioxidants and endogenous opioids in reducing muscle wasting
- training of postgraduate students
- stimulating collaboration between The University of Queensland and CSIRO Livestock Industries.Read moreRead less
Determinants of metabolic rate in animals. The metabolic rate of an animal represents its fundamental "cost of living" and varies dramatically (>100-fold) between different vertebrate species. We have proposed the "membrane pacemaker theory" to explain this variation and currently this is the only mechanistic explanation of metabolic variation between species. It has received significant international interest. A species metabolic rate and its maximum lifespan are connected but the precise mecha ....Determinants of metabolic rate in animals. The metabolic rate of an animal represents its fundamental "cost of living" and varies dramatically (>100-fold) between different vertebrate species. We have proposed the "membrane pacemaker theory" to explain this variation and currently this is the only mechanistic explanation of metabolic variation between species. It has received significant international interest. A species metabolic rate and its maximum lifespan are connected but the precise mechanistic link between them is unknown. We will investigate the mechanisms underlying the "membrane pacemaker theory" as an explanation of the metabolic rates of vertebrate species and its role in the determination of maximum lifespan.Read moreRead less
Uterodomes and the evolution of viviparity. We will test the hypothesis that uterodomes, which are cell structures unique to the early pregnant uterus in mammals, and the cellular changes accompanying their development, are essential to the evolution of viviparity in amniotes. The proposal stems from our recent discovery that uterodomes develop in the uteri of viviparous lizards as well as in mammals, suggesting key commonalities at the cellular level in the evolution of live birth across amnio ....Uterodomes and the evolution of viviparity. We will test the hypothesis that uterodomes, which are cell structures unique to the early pregnant uterus in mammals, and the cellular changes accompanying their development, are essential to the evolution of viviparity in amniotes. The proposal stems from our recent discovery that uterodomes develop in the uteri of viviparous lizards as well as in mammals, suggesting key commonalities at the cellular level in the evolution of live birth across amniote vertebrates. We will take advantage of the unique combination of placental types among Australian lizards, including a species with both oviparous and viviparous populations.Read moreRead less