Discovery Early Career Researcher Award - Grant ID: DE240100561
Funder
Australian Research Council
Funding Amount
$462,237.00
Summary
Understanding how platelets mediate new neuron formation in the adult brain. Exercise boosts the generation of new nerve cells from adult neural stem cells in the part of the brain responsible for learning and memory, the hippocampus. This project aims to investigate the mechanisms behind this effect, in particular, how blood cells known as platelets mediate this process. The expected outcomes include the discovery of new communication pathways between platelets and the brain following exercise ....Understanding how platelets mediate new neuron formation in the adult brain. Exercise boosts the generation of new nerve cells from adult neural stem cells in the part of the brain responsible for learning and memory, the hippocampus. This project aims to investigate the mechanisms behind this effect, in particular, how blood cells known as platelets mediate this process. The expected outcomes include the discovery of new communication pathways between platelets and the brain following exercise and will determine the importance of these blood cells in mediating brain function. This will help to explain how exercise affects the brain and may benefit Australian society through the implementation of new methods to support learning and memory in schools and workplaces, thereby enhancing performance and productivity.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL190100062
Funder
Australian Research Council
Funding Amount
$3,130,000.00
Summary
A new functional approach to coral reefs. This project aims to identify the key ecosystem functions that are needed to sustain coral reefs and determine their susceptibility to disturbance. Around the world coral reefs are changing fast, challenging traditional scientific, management, and governance approaches. This project plans to address this challenge by implementing a new, functional, approach exploiting a unique combination of evolutionary and ecological methodologies. Expected outcomes in ....A new functional approach to coral reefs. This project aims to identify the key ecosystem functions that are needed to sustain coral reefs and determine their susceptibility to disturbance. Around the world coral reefs are changing fast, challenging traditional scientific, management, and governance approaches. This project plans to address this challenge by implementing a new, functional, approach exploiting a unique combination of evolutionary and ecological methodologies. Expected outcomes include a global overview of ecosystem function and an in-depth understanding of how ecosystems change over time. This is likely to result in specific, and practical, management objectives by identifying crucial ecosystem functions that support reefs and the people who rely on them. Read moreRead less
Regulation of cell proliferation and survival by the ubiquitin system. This project aims to investigate how the fundamental processes of cell division and cell death are controlled at the molecular level by protein degradation enzymes (known as ubiquitin ligases), and how these regulate cellular homeostasis. Using interdisciplinary approaches incorporating proteomics, biochemistry, and molecular cell biology, this project seeks to delineate the components of signalling pathways implicated in the ....Regulation of cell proliferation and survival by the ubiquitin system. This project aims to investigate how the fundamental processes of cell division and cell death are controlled at the molecular level by protein degradation enzymes (known as ubiquitin ligases), and how these regulate cellular homeostasis. Using interdisciplinary approaches incorporating proteomics, biochemistry, and molecular cell biology, this project seeks to delineate the components of signalling pathways implicated in the degradation of proteins implicated in cell division and cell death. Expected outcomes include an increased understanding of how proteins are specifically selected for degradation. Protein degradation pathways operate with remarkable selectivity and this work is expected to illuminate the mechanisms of substrate targeting. The biochemical approaches will provide insight and impact in the areas of cell signaling, organelle biology and cell biology.Read moreRead less
Role of Tau and Synapsin in clustering distinct synaptic vesicle pools. Neurotransmitter-containing synaptic vesicles (SVs) are highly enriched in specific locations of brain cells, called nerve terminals via an unknown mechanism. The clustering of SVs depend on the phosphorylation of an unknown set of proteins. Two key proteins have been identified for their phosphorylation pattern and their potential to form membraneless compartments: tau and synapsin. Using highly innovative single-molecule s ....Role of Tau and Synapsin in clustering distinct synaptic vesicle pools. Neurotransmitter-containing synaptic vesicles (SVs) are highly enriched in specific locations of brain cells, called nerve terminals via an unknown mechanism. The clustering of SVs depend on the phosphorylation of an unknown set of proteins. Two key proteins have been identified for their phosphorylation pattern and their potential to form membraneless compartments: tau and synapsin. Using highly innovative single-molecule super-resolution microscopy, this grant will uncover how tau and synapsin phosphorylation controls the clustering of SVs thereby regulating neurotransmitter release. This project uses improved nanoscopic technologies and international
collaborations to unveil novel avenues in our understanding of brain communication.Read moreRead less
Super-resolving neurotransmitter release machinery during priming. Understanding how neurons communicate in the brain is one of the most challenging feats in neuroscience. The assembly of the molecular machinery involved in communication is unknown. This grant aims to understand how priming molecules Munc18 and Munc13, undergo a series of molecular steps leading to the release of neurotransmitter. Using innovative single-molecule super-resolution imaging we will uncover how Munc18 and Munc13 are ....Super-resolving neurotransmitter release machinery during priming. Understanding how neurons communicate in the brain is one of the most challenging feats in neuroscience. The assembly of the molecular machinery involved in communication is unknown. This grant aims to understand how priming molecules Munc18 and Munc13, undergo a series of molecular steps leading to the release of neurotransmitter. Using innovative single-molecule super-resolution imaging we will uncover how Munc18 and Munc13 are spatially and temporally organised to mediate communication. By elucidating how nanoclustering of these essential proteins enables key steps, this grant will reveal how brain cells communicate. This may then provide new opportunities to optimise underlying functions such as cognition, sensory and motor processing.Read moreRead less
Placental nutrient transport shows how complex traits evolve. This project aims to use amino acid transport in the vertebrate placenta as a model to demonstrate how genes are recruited and modified to produce a major organ. Using an innovative combination of a new technology, selected reaction monitoring, and transcriptomic and molecular approaches, plus carefully selected Australian species pairs, this project will study the evolution of a complex trait (placental amino acid transport). The pr ....Placental nutrient transport shows how complex traits evolve. This project aims to use amino acid transport in the vertebrate placenta as a model to demonstrate how genes are recruited and modified to produce a major organ. Using an innovative combination of a new technology, selected reaction monitoring, and transcriptomic and molecular approaches, plus carefully selected Australian species pairs, this project will study the evolution of a complex trait (placental amino acid transport). The project will provide fundamental advances in our knowledge of the nutrient transport during pregnancy that is required to produce a healthy baby.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100585
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
Does foot shape even matter? Rethinking the function of the human foot. Human feet are unique in shape and structure, having evolved to allow upright locomotion. Despite their importance, we don’t understand how foot shape and structure facilitates upright locomotion.This DECRA aims to explore the relationship between foot morphology and foot function. I will close a large knowledge gap by applying novel experimental and shape modelling approaches to provide unprecedented insights into human foo ....Does foot shape even matter? Rethinking the function of the human foot. Human feet are unique in shape and structure, having evolved to allow upright locomotion. Despite their importance, we don’t understand how foot shape and structure facilitates upright locomotion.This DECRA aims to explore the relationship between foot morphology and foot function. I will close a large knowledge gap by applying novel experimental and shape modelling approaches to provide unprecedented insights into human foot function. The primary expected outcome is a detailed understanding of how foot shape and structure influences our ability to walk and run. This research will create a paradigm shift in how we think about feet in the context of human evolution, human athletic performance and athletic footwear design.Read moreRead less
Migration-Dependent Signalling in Macrophages . The project aims to investigate a mechanism of communication used by immune cells to guide each other towards sites of damage. The project will characterise newly revealed cell signalling membrane trails left behind by migrating cells, utilising biochemistry, innovative imaging and microscopy and a transparent zebrafish model to view cell migration through living tissues. Expected outcomes include new fundamental knowledge in the area of immune cel ....Migration-Dependent Signalling in Macrophages . The project aims to investigate a mechanism of communication used by immune cells to guide each other towards sites of damage. The project will characterise newly revealed cell signalling membrane trails left behind by migrating cells, utilising biochemistry, innovative imaging and microscopy and a transparent zebrafish model to view cell migration through living tissues. Expected outcomes include new fundamental knowledge in the area of immune cell migration with relevance to the basic biology of inflammation, repair and regeneration and new innovations for cell imaging. Significant benefits are expected to arise from this new knowledge and from advanced skills training and improved national capabilities in bio-imaging and analysis.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
Decoding the spatiotemporal control of DNA replication and repair. DNA replication is the fundamental mechanism of genetic inheritance and essential for all cellular life. This project aims to inform our understanding of how human cells coordinate the DNA replication machinery in time and space to accurately copy the human genome. By applying multiple innovative approaches and employing an interdisciplinary research team, this project is anticipated to generate new knowledge that explains how th ....Decoding the spatiotemporal control of DNA replication and repair. DNA replication is the fundamental mechanism of genetic inheritance and essential for all cellular life. This project aims to inform our understanding of how human cells coordinate the DNA replication machinery in time and space to accurately copy the human genome. By applying multiple innovative approaches and employing an interdisciplinary research team, this project is anticipated to generate new knowledge that explains how the human genome is replicated. This knowledge is expected to generate research publications of high quality and provide economic benefits, such as unlocking new potentially patentable DNA technologies. Read moreRead less