A role for sleep in optimising attention. All animal brains are prediction machines, which allows even tiny flies to effectively navigate complex environments. To predict what will happen next is important for guiding attention, but also for detecting anything surprising. This project aims to understand how prediction is optimized by sleep in Drosophila flies. We aim to use electrophysiology and calcium imaging to map visual prediction error signals across the fly brain, and then determine how g ....A role for sleep in optimising attention. All animal brains are prediction machines, which allows even tiny flies to effectively navigate complex environments. To predict what will happen next is important for guiding attention, but also for detecting anything surprising. This project aims to understand how prediction is optimized by sleep in Drosophila flies. We aim to use electrophysiology and calcium imaging to map visual prediction error signals across the fly brain, and then determine how genetically controlled delivery of sleep regulates the quality and distribution of these signals. This knowledge will benefit our understanding of how brains balance a capacity for prediction versus surprise, by examining how evolution has solved this difficult problem in the smallest brains.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100565
Funder
Australian Research Council
Funding Amount
$422,107.00
Summary
A novel role for saturated fatty acids in learning and memory. This project aims to characterise the novel role of the phospholipase A1 pathway in neurotransmission, generating new knowledge on how the saturated fatty acid changes in neurons affect the mobility of neurotransmitter receptors and synaptic vesicles. Learning and memory are thought to result from long-lasting changes in synaptic strength. Whereas the role of polyunsaturated fatty acids in these functions is well known, recent findin ....A novel role for saturated fatty acids in learning and memory. This project aims to characterise the novel role of the phospholipase A1 pathway in neurotransmission, generating new knowledge on how the saturated fatty acid changes in neurons affect the mobility of neurotransmitter receptors and synaptic vesicles. Learning and memory are thought to result from long-lasting changes in synaptic strength. Whereas the role of polyunsaturated fatty acids in these functions is well known, recent findings suggest an unprecedented role for the generation of saturated free fatty acids by phospholipase A1-enzyme. Expected outcomes of this project will be to provide novel conceptual insights into learning, memory and brain capacity.Read moreRead less
Computational neuroanatomy: analysis of neural connections in the primate brain. This project will map the full network of connections between brain cells, using a computer graphics database that will consolidate data from hundreds of experiments. This will allow the first realistic simulations of neural activity, and will provide new insights about the structure and function of the nervous system.
Polarization vision: insights from biological systems for imaging solutions. This project aims to discover how invertebrate and vertebrate model species see linearly polarised light by constructing a novel instrument to determine limits to sensitivities, as well as animals' ability to distinguish small differences in degree and angle of linear polarisation. The project aims to predict how this might be affected as environments change. A clear understanding of biological solutions to polarisation ....Polarization vision: insights from biological systems for imaging solutions. This project aims to discover how invertebrate and vertebrate model species see linearly polarised light by constructing a novel instrument to determine limits to sensitivities, as well as animals' ability to distinguish small differences in degree and angle of linear polarisation. The project aims to predict how this might be affected as environments change. A clear understanding of biological solutions to polarisation perception can inform the design and development of novel bio-inspired imaging sensors that will be particularly suited to small, autonomous robots.Read moreRead less
Intra and intermolecular steps underpinning vesicular priming. This project aims to discover how secretory vesicles fuse with the plasma membrane, a process called priming. The fusion of secretory vesicles by exocytosis underpins neuronal communication. Despite efforts to understand vesicular fusion, how these vesicles become fusion-competent upon arrival at the plasma membrane is unknown. This project will use single molecule imaging to assess mobility changes of key priming molecules and uncov ....Intra and intermolecular steps underpinning vesicular priming. This project aims to discover how secretory vesicles fuse with the plasma membrane, a process called priming. The fusion of secretory vesicles by exocytosis underpins neuronal communication. Despite efforts to understand vesicular fusion, how these vesicles become fusion-competent upon arrival at the plasma membrane is unknown. This project will use single molecule imaging to assess mobility changes of key priming molecules and uncover their diffusional signature during priming. It intends to build a comprehensive model of molecular interactions that make a recently docked vesicle fusion-competent. This understanding is key to unravelling how the brain worksRead moreRead less
Comprehending and modelling the workings of the animal brain. Truly understanding how the brain operates is a grand challenge of 21st century neuroscience. Progress toward this goal can be made through studying small-brained animals, like the honey bee. This project aims to use microscopy and pharmacology to analyse the neural mechanisms by which bees learn and classify complex things. This will enable the construction of a computational model of decision making in the bee brain. Analysing this ....Comprehending and modelling the workings of the animal brain. Truly understanding how the brain operates is a grand challenge of 21st century neuroscience. Progress toward this goal can be made through studying small-brained animals, like the honey bee. This project aims to use microscopy and pharmacology to analyse the neural mechanisms by which bees learn and classify complex things. This will enable the construction of a computational model of decision making in the bee brain. Analysing this model will test what is understood about the operation of the animal brain, and what simulates it. This project aims to reveal how neural circuits make complex decisions; establish key principles and foundational studies for comprehending larger more complex brains, and yield new approaches to machine learning.Read moreRead less
Neural mechanisms of vestibular perception in zebrafish. This project aims to understand vestibular processing by removing physical movement. The vestibular system allows us to perceive gravity and movement, but it is not understood how the brain processes information from vestibular sensors in the inner ear. This project will exert forces on the zebrafish’s inner ear with a laser, stimulating the vestibular sense. This means that the animal will experience vestibular stimuli while stationary, a ....Neural mechanisms of vestibular perception in zebrafish. This project aims to understand vestibular processing by removing physical movement. The vestibular system allows us to perceive gravity and movement, but it is not understood how the brain processes information from vestibular sensors in the inner ear. This project will exert forces on the zebrafish’s inner ear with a laser, stimulating the vestibular sense. This means that the animal will experience vestibular stimuli while stationary, allowing calcium imaging of neurons that respond to vestibular cues and optogenetics to stimulate or silence these neurons. This is expected to reveal which cells and circuits mediate vestibular perception, processing and behaviour.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL140100197
Funder
Australian Research Council
Funding Amount
$2,970,898.00
Summary
Revealing the invisible: new principles of vision in Australian animals. Revealing the invisible: new principles of vision in Australian animals. This project aims to reveal how the visual systems of marine creatures from the Great Barrier Reef receive and interpret colour and polarisation information, much of which is invisible to the human eye. It aims to utilise this data to tackle fundamental questions in neuroscience and inform bio-inspired camera design and machine-vision solutions. The re ....Revealing the invisible: new principles of vision in Australian animals. Revealing the invisible: new principles of vision in Australian animals. This project aims to reveal how the visual systems of marine creatures from the Great Barrier Reef receive and interpret colour and polarisation information, much of which is invisible to the human eye. It aims to utilise this data to tackle fundamental questions in neuroscience and inform bio-inspired camera design and machine-vision solutions. The resulting new generation of polarisation cameras will be used to characterise the environments, animals and brains that inspired them in the first place. This will help the understanding of how nervous systems convey information and may improve our ability to detect dysfunction in neurons and other cells.Read moreRead less
Neuro-ecology: information processing under natural conditions. Not enough is known about how sensory information is processed through the brain under natural environmental conditions. This project will shed light on how information processing changes with context and will help explain why even those animals with the smallest brains are much more versatile and robust than our most advanced robots.
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