Wolbachia endosymbionts: novel strain dynamics in Australian Drosophila. This project aims to understand Wolbachia infections across Australian Drosophila flies. Wolbachia bacteria that live inside the cells of insects and other invertebrates are widely seen as a promising tool for pest and disease control. This project will assess the population distribution, host phenotypic effects, population dynamics and evolutionary context of multiple Wolbachia infections across Australian Drosophila flies ....Wolbachia endosymbionts: novel strain dynamics in Australian Drosophila. This project aims to understand Wolbachia infections across Australian Drosophila flies. Wolbachia bacteria that live inside the cells of insects and other invertebrates are widely seen as a promising tool for pest and disease control. This project will assess the population distribution, host phenotypic effects, population dynamics and evolutionary context of multiple Wolbachia infections across Australian Drosophila flies. The outcome will include new and novel strains for applied projects, new information on the fate of Wolbachia infections, and new insights into the factors that dictate the fate of Wolbachia infections across populations.Read moreRead less
The evolution of biological scaling. This project aims to understand why so few biological traits scale proportionally with body size. In contrast to previous mechanistic studies of this longstanding question, the problem will be approached from an evolutionary viewpoint, using artificial selection to engineer animals in which biological scaling laws are either broken or enhanced. By measuring the consequences of this for fitness, the project will provide a new understanding of how organismal si ....The evolution of biological scaling. This project aims to understand why so few biological traits scale proportionally with body size. In contrast to previous mechanistic studies of this longstanding question, the problem will be approached from an evolutionary viewpoint, using artificial selection to engineer animals in which biological scaling laws are either broken or enhanced. By measuring the consequences of this for fitness, the project will provide a new understanding of how organismal size and physiology evolve in nature. The approach should provide significant benefits to our understanding of the role of genetic constraints in hindering or facilitating biological adaptation, furthering our understanding of the capacity of animals to respond to environmental change.Read moreRead less
Do crayfish use the information carried by low-level electrical signals in the environment? Many vertebrates detect electric fields. Fish communicate electrically. No invertebrate has been shown to do so. We have evidence that crayfish change their behaviour following exposure to low-level, waterborne electrical signals. Crayfish behaviour is currently the preferred model for studying the neurobiology of social hierarchies in animals. Evidence that information is passing from either predators or ....Do crayfish use the information carried by low-level electrical signals in the environment? Many vertebrates detect electric fields. Fish communicate electrically. No invertebrate has been shown to do so. We have evidence that crayfish change their behaviour following exposure to low-level, waterborne electrical signals. Crayfish behaviour is currently the preferred model for studying the neurobiology of social hierarchies in animals. Evidence that information is passing from either predators or conspecifics through an undescribed electrosensory channel would fundamentally change the direction of that research. Behaviour modification using electrical signals could also prove to be a valuable tool in crustacean aquaculture. This is a proposal to discover the nature and behavioural implications of crayfish electroreception.Read moreRead less
Brain states and their roles in evasive behaviour. Using cutting-edge custom microscopy, neuroinformatics, and optogenetics in the larval zebrafish model, this project aims to describe the neurons, circuits, and networks that govern brain states. These brain states, by altering sensory-response relationships, allow animals to tune their behaviour to their circumstances, and the small transparent brains of zebrafish offer the possibility to observe activity across all neurons in the brain while t ....Brain states and their roles in evasive behaviour. Using cutting-edge custom microscopy, neuroinformatics, and optogenetics in the larval zebrafish model, this project aims to describe the neurons, circuits, and networks that govern brain states. These brain states, by altering sensory-response relationships, allow animals to tune their behaviour to their circumstances, and the small transparent brains of zebrafish offer the possibility to observe activity across all neurons in the brain while these processes occur in real time. Benefits would include knowledge gained about this fundamental property of the brain, further refinement of technologies in microscopy and biophyisics, and the training of Australia’s next generation of optical physicists, neuroscientists, and mathematicians. Read moreRead less
What is the biological significance of electrosensitivity in crayfish? The finding that an Australian crayfish responds to low-level electrical signals in the surrounding water is the first report of electrosensitivity in an aquatic invertebrate. This project will investigate its unknown biological significance. The results will impact on behavioural studies in all aquatic invertebrates because they will now have to consider this factor. Some other decapod crustaceans will almost certainly be fo ....What is the biological significance of electrosensitivity in crayfish? The finding that an Australian crayfish responds to low-level electrical signals in the surrounding water is the first report of electrosensitivity in an aquatic invertebrate. This project will investigate its unknown biological significance. The results will impact on behavioural studies in all aquatic invertebrates because they will now have to consider this factor. Some other decapod crustaceans will almost certainly be found to be electrosensitive. Not only are these important subjects for behavioural analysis, many form the basis of important commercial aquaculture industries. The outcomes will enhance Australia's scientific standing and provide opportunities for students to become leaders in a new field. Read moreRead less
Quantifying environmental constraints on animal behaviour. This project aims to determine how habitat structure, weather and motion vision influence animal behaviour. Motion vision controls locomotion, foraging, evading predators and communicating. However, information on the conditions for motion vision in natural environments is limited. To address this, this project will combine field techniques with tools from 3D animation and computer vision. The project will focus on Australia’s dragon liz ....Quantifying environmental constraints on animal behaviour. This project aims to determine how habitat structure, weather and motion vision influence animal behaviour. Motion vision controls locomotion, foraging, evading predators and communicating. However, information on the conditions for motion vision in natural environments is limited. To address this, this project will combine field techniques with tools from 3D animation and computer vision. The project will focus on Australia’s dragon lizards, and place their motion displays in a visual-ecological context. The expected outcome is a more complete picture of the signalling context, which could advance sensory ecology, vision science and animal behaviour, with practical applications in artificial intelligence and derived benefits for education and community engagement in biology.Read moreRead less
Mapping a complete visual circuit in zebrafish. Our senses perceive the outside world and permit appropriate behaviours, but the underlying brain circuits are poorly understood. This project will use new technologies to observe all active brain cells in zebrafish during the important behaviour of visual predator avoidance and characterise the underlying circuits comprehensively. This approach's significance is in its breadth, spanning functional imaging, anatomy, computational modelling, and beh ....Mapping a complete visual circuit in zebrafish. Our senses perceive the outside world and permit appropriate behaviours, but the underlying brain circuits are poorly understood. This project will use new technologies to observe all active brain cells in zebrafish during the important behaviour of visual predator avoidance and characterise the underlying circuits comprehensively. This approach's significance is in its breadth, spanning functional imaging, anatomy, computational modelling, and behaviour, with the major outcome of producing the first complete map of a visual behaviour at the level of brain circuits and the individual brain cells composing them. Benefits will include new insights into visual processing and the refinement of new genetic, optical, and informatics approaches.Read moreRead less
Visual processing of objects defined by coherent motion. Although the human brain can easily decode the complex visual scene, little is known about how the responsible neural circuits operate. For example, how is it that a camouflaged animal, such as a moth on the bark of a tree, becomes visible once it moves? To better understand the processes, this project aims to determine how different visual areas of the brain interact with each other to create a network that is responsible for detecting ....Visual processing of objects defined by coherent motion. Although the human brain can easily decode the complex visual scene, little is known about how the responsible neural circuits operate. For example, how is it that a camouflaged animal, such as a moth on the bark of a tree, becomes visible once it moves? To better understand the processes, this project aims to determine how different visual areas of the brain interact with each other to create a network that is responsible for detecting moving camouflaged objects. Knowing this will enable us to better understand the organisation and limitations of the brain.Read moreRead less
Manipulative tests of metabolic theory. This project aims to take a new interdisciplinary approach to understanding how energy flows through individuals, populations, communities, and ecosystems. The project expects to develop a new framework for understanding the function of biological systems, bringing together the fields of physiology, ecology, and evolutionary biology, generating research publications, and training students in interdisciplinary research. The proposed research is anticipated ....Manipulative tests of metabolic theory. This project aims to take a new interdisciplinary approach to understanding how energy flows through individuals, populations, communities, and ecosystems. The project expects to develop a new framework for understanding the function of biological systems, bringing together the fields of physiology, ecology, and evolutionary biology, generating research publications, and training students in interdisciplinary research. The proposed research is anticipated to provide a means for understanding how management interventions can alter energy flows in biological systems, bringing benefits across the areas of climate change adaptation, conservation science, agriculture and aquaculture, and fisheries management.Read moreRead less
The physics and biology of hearing in larval fish. Using the zebrafish model and an array of cutting-edge biophysics and neuroscience tools, this project aims to provide the first complete map of a functioning auditory system. This is significant because it has previously been impossible to study the brain at the levels of single cells, circuits, and brain-wide networks simultaneously. Expected outcomes include detailed descriptions of information flow through a simple brain and the ways that br ....The physics and biology of hearing in larval fish. Using the zebrafish model and an array of cutting-edge biophysics and neuroscience tools, this project aims to provide the first complete map of a functioning auditory system. This is significant because it has previously been impossible to study the brain at the levels of single cells, circuits, and brain-wide networks simultaneously. Expected outcomes include detailed descriptions of information flow through a simple brain and the ways that brain cells and circuits communicate to process information. Benefits include knowledge gained about sensory systems in nature, future biomimetic approaches for information processing, and the training of the next generation of Australian researchers in cutting edge optical physics and neuroscience.Read moreRead less