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
Cool mammals: responding to thermal and energetic challenges in the Australian tropics. A detailed understanding of thermal biology and energy use of mammals is essential for predicting how they will respond to climate change. As little is known about the functional and behavioural traits of Australian tropical mammals, the proposed work investigating the thermal energetics and foraging biology of eleven native species will result in a significant advancement in knowledge. This information will ....Cool mammals: responding to thermal and energetic challenges in the Australian tropics. A detailed understanding of thermal biology and energy use of mammals is essential for predicting how they will respond to climate change. As little is known about the functional and behavioural traits of Australian tropical mammals, the proposed work investigating the thermal energetics and foraging biology of eleven native species will result in a significant advancement in knowledge. This information will provide wildlife managers with an additional tool for making sound science-based decisions for the conservation of wildlife now and in the future. The project will train students, improve international collaboration, and substantially enhance the international scientific standing of Australia.Read moreRead less
Vulnerability to cocaine use: discovering common mechanisms conserved across animal phyla. Drug abuse costs Australia an estimated $ 20 billion each year, and research is urgently needed to understand how drugs cause long-term behavioural dysfunction. Our research will identify the basal cellular mechanisms underlying drug abuse and addiction, which are likely to be the best targets for therapies to prevent and cure addiction. Our findings are also relevant to other neuropsychiatric disorders r ....Vulnerability to cocaine use: discovering common mechanisms conserved across animal phyla. Drug abuse costs Australia an estimated $ 20 billion each year, and research is urgently needed to understand how drugs cause long-term behavioural dysfunction. Our research will identify the basal cellular mechanisms underlying drug abuse and addiction, which are likely to be the best targets for therapies to prevent and cure addiction. Our findings are also relevant to other neuropsychiatric disorders related to drug abuse (e.g. depression, anxiety) that are on the increase in Australia. Our work will enhance Australia's reputation for neuroscience research, and will provide training for students in neuropharmacology and molecular neurobiology.Read moreRead less
Brain lateralization: its function, evolution, development and change with ageing. Brain research is undoubtedly one of the key research fields today. This project involves highly innovative research at the highest international level, keeping Australia at the forefront of research on brain lateralization, a very important field of brain research in humans and animals (co-founded by the applicant). This project 1) investigates dynamic changes of the developing, mature and ageing brain for vital ....Brain lateralization: its function, evolution, development and change with ageing. Brain research is undoubtedly one of the key research fields today. This project involves highly innovative research at the highest international level, keeping Australia at the forefront of research on brain lateralization, a very important field of brain research in humans and animals (co-founded by the applicant). This project 1) investigates dynamic changes of the developing, mature and ageing brain for vital functions using animal models, thus contributing importantly to our understanding of normal functions of the human brain, including some forms of mental dysfunction and also ageing; 2) trains postgraduate students at the highest standards and 3) maintains important collaboration with colleagues in Europe. Read moreRead less
How does habitat complexity drive motor ageing and fitness in wild mammals? This project aims to demonstrate how habitat complexity shapes motor ageing in wild dasyurid marsupials, and to improve these animals’ motor function, slow its decline and increase reproductive output via behavioural and physiological changes. Motor decline should dramatically impact an animal growth, survival and reproduction by affecting how it moves through habitats when foraging, seeking mates, or escaping from preda ....How does habitat complexity drive motor ageing and fitness in wild mammals? This project aims to demonstrate how habitat complexity shapes motor ageing in wild dasyurid marsupials, and to improve these animals’ motor function, slow its decline and increase reproductive output via behavioural and physiological changes. Motor decline should dramatically impact an animal growth, survival and reproduction by affecting how it moves through habitats when foraging, seeking mates, or escaping from predators. However, little is known about the environmental drivers of motor ageing in wild animals. Our project addresses an important gap in the field of evolutionary ecology. Since decline in muscle function affects the quality of Australian's life, our work could lead to important economic and health implications.Read moreRead less
Higher cognition and hemispheric specialization in an avian species: referential and intentional communication. We will discover whether alarm calls of Australian magpies, noted for their outstanding range of vocalisations, are referential (signalling predator type and location) and intentional (vocalised in specific contexts). Such complex communication , once thought to be unique to humans, has been found in some mammals and just one avian species, the domestic chick. This project will be the ....Higher cognition and hemispheric specialization in an avian species: referential and intentional communication. We will discover whether alarm calls of Australian magpies, noted for their outstanding range of vocalisations, are referential (signalling predator type and location) and intentional (vocalised in specific contexts). Such complex communication , once thought to be unique to humans, has been found in some mammals and just one avian species, the domestic chick. This project will be the first such investigation of an avian species in its natural habitat. This is important also because bird and mammalian brains are organised differently and birds offer a unique opportunity to discover whether one hemisphere is specialised for this purpose.Read moreRead less
Coping with forest fires: is mammalian torpor a crucial survival strategy? Forest fires result in habitat degradation and can kill native mammals. Currently little is known about the behaviour of individual mammals during and after fires. This project will generate the first quantitative information worldwide about behavioural and physiological responses of small mammals to fire, and test whether use of torpor increases survival.
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
Evolution of intelligence in small brains: how to navigate the messy natural outdoors smartly. This project unravels how small-brained desert ants navigate expertly using simple and coarse-grade visual cues, focusing on 1) how they use skylines, where the tops of terrestrial objects meet the sky, and 2) how they search efficiently for goals. The outcomes will be invaluable for designing robots that can navigate in the messy natural outdoors.
Becoming expert navigators with tiny brains: Learning in desert ants. Desert ants with tiny brains learn to use their surrounding visual landscape to navigate. This project investigates in detail how they do that in a few carefully orchestrated trips around their nest called learning walks. Desert ants are known now to use magnetic cues to orient during their learning walks. The project also probes the role that magnetic cues play in the ants’ learning, as well as the sensory basis of the percep ....Becoming expert navigators with tiny brains: Learning in desert ants. Desert ants with tiny brains learn to use their surrounding visual landscape to navigate. This project investigates in detail how they do that in a few carefully orchestrated trips around their nest called learning walks. Desert ants are known now to use magnetic cues to orient during their learning walks. The project also probes the role that magnetic cues play in the ants’ learning, as well as the sensory basis of the perception of magnetic cues. Geomagnetic cues in the area of the nest will be artificially manipulated to test how ants use this cue. Probing the use of magnetic cues has potential benefits for projects of artificial autonomous navigation in situations when visual cues are unavailable, such as exploring a deep mine.
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