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
Early stress experiences and stress resilience in pigs. Animal stress has substantial implications on animal productivity, health and welfare of farm animals and thus farm profitability. This project aims to examine the stress resilience in pigs. Modern pig farming is a major source of food, providing substantial nutritional, social and economic benefits in Australia and worldwide. Animal welfare is of increasing concern to the public, consumers and pork producers, and stress vulnerability is an ....Early stress experiences and stress resilience in pigs. Animal stress has substantial implications on animal productivity, health and welfare of farm animals and thus farm profitability. This project aims to examine the stress resilience in pigs. Modern pig farming is a major source of food, providing substantial nutritional, social and economic benefits in Australia and worldwide. Animal welfare is of increasing concern to the public, consumers and pork producers, and stress vulnerability is an animal health and production problem in the life of the commercial pig. This project will generate new knowledge on early life management to endow stress resilience in pigs, with expected benefits for animal welfare, farm productivity and profitability.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
Discovery Early Career Researcher Award - Grant ID: DE200100620
Funder
Australian Research Council
Funding Amount
$424,856.00
Summary
Phenotypic plasticity of reef fish vision in a changing world. This project aims to investigate why fishes have more colour vision channels than any other vertebrate on the planet by studying representatives from the most vibrant ecosystem on earth, the Great Barrier Reef. It is currently not clear how vision is controlled on the molecular level and how this translates to the performance and survival of an animal. Through an innovative approach to understanding colour vision and animal behaviour ....Phenotypic plasticity of reef fish vision in a changing world. This project aims to investigate why fishes have more colour vision channels than any other vertebrate on the planet by studying representatives from the most vibrant ecosystem on earth, the Great Barrier Reef. It is currently not clear how vision is controlled on the molecular level and how this translates to the performance and survival of an animal. Through an innovative approach to understanding colour vision and animal behaviour, this project expects to advance Australia’s leadership in neuroscience and ecology, while also increasing the capacity for international collaborations. Beyond the scientific benefit, it will create public awareness about an endangered ecosystem, inform reef guardianship and may inspire new sensory technology.Read moreRead less
Quiet sleep is for repair, active sleep is for learning. Sleep is thought to achieve many different functions, from brain waste clearance to regulating emotions and perception. Understanding sleep functions in animal models has been difficult because sleep has been typically reduced to a single state. Our discovery of distinct sleep stages in the fruit fly provides a powerful way to study how different conserved sleep functions are regulated. This project will use new strategies for manipulating ....Quiet sleep is for repair, active sleep is for learning. Sleep is thought to achieve many different functions, from brain waste clearance to regulating emotions and perception. Understanding sleep functions in animal models has been difficult because sleep has been typically reduced to a single state. Our discovery of distinct sleep stages in the fruit fly provides a powerful way to study how different conserved sleep functions are regulated. This project will use new strategies for manipulating sleep stages in flies to understand their respective physiology and functions. We will test our hypothesis that different categories of sleep functions have been segregated by evolution into different stages: a quiet stage concerned primarily with brain repair and an active stage important for learning.
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How brains become lateralised. This project aims to understand how the left and right sides of the brain become specialised for different cognitive functions, a phenomenon called lateralisation. Lateralisation is one of the least understood organisational principles of the brain, yet is crucial to the way we think and behave. Manifested most clearly as handedness, the brain is lateralised for many cognitive tasks such as language, reasoning, memory and emotion. However, the developmental origin ....How brains become lateralised. This project aims to understand how the left and right sides of the brain become specialised for different cognitive functions, a phenomenon called lateralisation. Lateralisation is one of the least understood organisational principles of the brain, yet is crucial to the way we think and behave. Manifested most clearly as handedness, the brain is lateralised for many cognitive tasks such as language, reasoning, memory and emotion. However, the developmental origin and anatomical substrate of most cognitive asymmetries are unknown. This project will use a chick model of brain lateralisation to quantify and localise to specific brain circuits the patterns of differential gene expression that give rise to anatomical and functional asymmetries.Read moreRead less