A perimeter defence in Australian processionary caterpillars. Microscopic, detachable hairs on processionary caterpillars cause clinical reactions when they enter the skin or internal tissues of humans and animals. There is a time delay between exposure and the most serious effects, inferring an action more complex than simple irritation. The project aims to test a novel mechanism – how the hairs form a perimeter defence around caterpillars that primes the immune system of potential predators, ....A perimeter defence in Australian processionary caterpillars. Microscopic, detachable hairs on processionary caterpillars cause clinical reactions when they enter the skin or internal tissues of humans and animals. There is a time delay between exposure and the most serious effects, inferring an action more complex than simple irritation. The project aims to test a novel mechanism – how the hairs form a perimeter defence around caterpillars that primes the immune system of potential predators, how these hairs function within the layered caterpillar defensive system and how far setae can disperse. The research will inform relevant authorities and in particular veterinarians of the risks being exposed to processionary caterpillar hairs and add to the theory of predator-prey interaction.Read moreRead less
Assessing gene function in the developing vertebrate brain using zebrafish as a model system. Although the vertebrate brain is the most complicated biological tissue it arises from a very simple sheet of cells during embryogenesis. Groups of nerve cells begin to communicate with each other through long interconnecting processes called axons. This project seeks to understand the role of specific genes in this process. This is the first time that the mechanisms controlling the growth of the ear ....Assessing gene function in the developing vertebrate brain using zebrafish as a model system. Although the vertebrate brain is the most complicated biological tissue it arises from a very simple sheet of cells during embryogenesis. Groups of nerve cells begin to communicate with each other through long interconnecting processes called axons. This project seeks to understand the role of specific genes in this process. This is the first time that the mechanisms controlling the growth of the earliest axons in the vertebrate brain will be examined in a living brain. Our analysis is expected to discover genes that are targets for manipulation of axon growth.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100949
Funder
Australian Research Council
Funding Amount
$365,058.00
Summary
Did colour vision evolve in the dark? This project aims to investigate the ability of fishes to perceive colour in dim-light conditions by studying representatives from two delicate and endangered ecosystems, coral reefs (nocturnal fish) and the deep-sea. Through a multidisciplinary approach to understanding colour vision and animal behaviour, this study expects to fill a knowledge gap in visual neuroscience and ecology while adding to the understanding of how marine creatures see and interact. ....Did colour vision evolve in the dark? This project aims to investigate the ability of fishes to perceive colour in dim-light conditions by studying representatives from two delicate and endangered ecosystems, coral reefs (nocturnal fish) and the deep-sea. Through a multidisciplinary approach to understanding colour vision and animal behaviour, this study expects to fill a knowledge gap in visual neuroscience and ecology while adding to the understanding of how marine creatures see and interact. This should provide benefits in conservation and management strategies and may also inspire the development of new sensor technologies.Read moreRead less
Combining biomechanics and movement ecology of kangaroos and relatives. Kangaroos and their relatives are unique in their body form, hopping gait and by the fact that increased speed does not come at an increased energetic cost. This project aims to build 3D musculoskeletal models to understand how muscles and tendons interact, enabling greater distances to be travelled using less energy. Further, it will use animal tracking devices and machine-learning tools to quantify movements in the wild. T ....Combining biomechanics and movement ecology of kangaroos and relatives. Kangaroos and their relatives are unique in their body form, hopping gait and by the fact that increased speed does not come at an increased energetic cost. This project aims to build 3D musculoskeletal models to understand how muscles and tendons interact, enabling greater distances to be travelled using less energy. Further, it will use animal tracking devices and machine-learning tools to quantify movements in the wild. This framework will provide novel insights into how energetics, morphology, and habitat have shaped the evolution of this unique group. This may open doors to a range of future ecological, physiological, and conservation studies and provide biological inspiration for energetically efficient robotic and assistive devices.Read moreRead less
Connectomes arising: linking structure and function in neocortical wiring. The cerebral cortex underpins human cognition, yet exactly how it becomes connected is unknown due to a lack of live developmental assays. We overcome this using prematurely born marsupials, which allow to study cortical development from embryo-like stages with remarkable resolution. This project will study how neural activity arises as the first connections are formed, and link functional and structural networks across d ....Connectomes arising: linking structure and function in neocortical wiring. The cerebral cortex underpins human cognition, yet exactly how it becomes connected is unknown due to a lack of live developmental assays. We overcome this using prematurely born marsupials, which allow to study cortical development from embryo-like stages with remarkable resolution. This project will study how neural activity arises as the first connections are formed, and link functional and structural networks across development in vivo. Experimental manipulations of activity, and computational models will discover developmental rules for precise wiring of cortical connections. Benefits include new methods to study cortical development, and outlining electrical, molecular and neuroanatomical signatures of early mammalian brain formation.Read moreRead less
Molecular mechanisms that regulate the kinetics of neurotransmitter release. Information processing in the human brain plays important roles in normal behaviour and cognition, most of which require rapid and precisely timed neurotransmitter release. However, the molecular mechanisms that control the speed and timing of this release remain largely unclear. This research project will use a novel mix of electrophysiology, electron microscopy, genetics, biochemistry, and imaging to investigate how t ....Molecular mechanisms that regulate the kinetics of neurotransmitter release. Information processing in the human brain plays important roles in normal behaviour and cognition, most of which require rapid and precisely timed neurotransmitter release. However, the molecular mechanisms that control the speed and timing of this release remain largely unclear. This research project will use a novel mix of electrophysiology, electron microscopy, genetics, biochemistry, and imaging to investigate how the speed of neurotransmitter release is controlled by the most important synaptic protein UNC-13 and its binding partners. This project expects to generate significant knowledge in the area of synaptic transmission. The outcomes will deepen our understanding of neuronal communication and information processing in the brain.Read moreRead less
Environmental and physiological drivers of immune function in frogs. This project aims to investigate how ultraviolet B radiation and temperature interact during early development to influence amphibian physiology. The environment can shape ecological processes through effects on an individuals' physiology. The project will combine genetic, biochemical and physiological approaches to investigate the effects of ultraviolet B and temperature on a key fitness determinant – immune system function. T ....Environmental and physiological drivers of immune function in frogs. This project aims to investigate how ultraviolet B radiation and temperature interact during early development to influence amphibian physiology. The environment can shape ecological processes through effects on an individuals' physiology. The project will combine genetic, biochemical and physiological approaches to investigate the effects of ultraviolet B and temperature on a key fitness determinant – immune system function. The project expects to provide information on how environmental conditions experienced during development influence the growth and fitness of frogs. This will improve our capacity to forecast potential ecological-level effects of environmental change on amphibians.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
Neuronal Control of Adaptive Walking. This project seeks to understand how signals from the brain control motor circuits so that an animal can adaptively walk across varying terrains in pursuit of its ever-changing goals. It will focus on the fruit fly, Drosophila, as a model. The fly is an agile walker, its nervous system has been almost fully mapped at the synaptic level, and genetic reagents are available to selectively measure or manipulate the activity of single neurons. This project specif ....Neuronal Control of Adaptive Walking. This project seeks to understand how signals from the brain control motor circuits so that an animal can adaptively walk across varying terrains in pursuit of its ever-changing goals. It will focus on the fruit fly, Drosophila, as a model. The fly is an agile walker, its nervous system has been almost fully mapped at the synaptic level, and genetic reagents are available to selectively measure or manipulate the activity of single neurons. This project specifically focuses on the circuits that generate forward and backward walking, and switch between the two. It will enhance Australia's capacity in connectome-driven neuroscience research, deliver fundamental insights into neuronal motor control, and inspire the design of more agile robots.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