Deciphering Signalling Pathways Regulating Iron Homeostasis
Funder
National Health and Medical Research Council
Funding Amount
$407,402.00
Summary
Iron overload and anaemia are two of the most significant health problems affecting humans. Understanding how the body regulates iron levels is key to our understanding of these disorders and to the future development of new therapies. This research is aimed at understanding how a hormone produced in the liver called hepcidin that maintains iron balance is regulated. This research may lead to novel therapies aimed at correcting the iron balance in conditions of iron overload or anaemia.
Innate Immune Signalling In Mycobacterium Tuberculosis Infection
Funder
National Health and Medical Research Council
Funding Amount
$562,857.00
Summary
Tuberculosis (TB) is a major global health threat that causes 1.5 million deaths every year. This study will characterise a new molecular control mechanism that optimises the immune response to the bacteria that cause TB and determine how it contributes to controlling the infection. Such knowledge is essential to help improve patient management and develop better treatments for this devastating disease.
Regulation of glutamate receptor dynamics in mammalian central neurons. This proposal aims to understand the molecular mechanisms of neuronal communication and how neurons modify their synaptic strength. Although these processes are essential for normal brain function, the precise underlying mechanisms are still not well understood. This project will combine biochemical, molecular and cell biological assays, as well as electrophysiological measurements, to provide mechanistic insights into the m ....Regulation of glutamate receptor dynamics in mammalian central neurons. This proposal aims to understand the molecular mechanisms of neuronal communication and how neurons modify their synaptic strength. Although these processes are essential for normal brain function, the precise underlying mechanisms are still not well understood. This project will combine biochemical, molecular and cell biological assays, as well as electrophysiological measurements, to provide mechanistic insights into the molecular processes that control glutamate receptor trafficking in the postsynaptic compartment. This will elucidate how neural plasticity is generated and maintained, information that is critical for our understanding of sensory processing, learning and memory throughout life.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100546
Funder
Australian Research Council
Funding Amount
$372,000.00
Summary
Activity-dependent regulation of glutamate receptor trafficking in neurons. This proposal aims to understand the molecular mechanisms of neuronal communication and how neurons modify their synaptic strength. Although these processes are essential for normal brain function, the precise underlying mechanisms are not well understood. This project will use structural, biochemical, molecular and cell biological assays to study the molecular processes that control glutamate receptor trafficking in the ....Activity-dependent regulation of glutamate receptor trafficking in neurons. This proposal aims to understand the molecular mechanisms of neuronal communication and how neurons modify their synaptic strength. Although these processes are essential for normal brain function, the precise underlying mechanisms are not well understood. This project will use structural, biochemical, molecular and cell biological assays to study the molecular processes that control glutamate receptor trafficking in the postsynaptic compartment. It will elucidate how neural plasticity is generated and maintained, information critical for understanding sensory processing, learning and memory throughout life. The findings could identify cellular targets for interventions to enhance cognitive performance and maintain optimal brain function.Read moreRead less
Control of selective microRNA release via exosomes and microvesicles. This project aims to improve our understanding of cell-to-cell communication. Cells release genetic material including microRNAs in lipid membrane-enclosed vesicles (called exosomes and microvesicles) to alter neighbouring and distant cells. Recent research shows that the contents of these vesicles are regulated by cell state, however, the molecular mechanisms are not yet known. This project will investigate the hypothesis tha ....Control of selective microRNA release via exosomes and microvesicles. This project aims to improve our understanding of cell-to-cell communication. Cells release genetic material including microRNAs in lipid membrane-enclosed vesicles (called exosomes and microvesicles) to alter neighbouring and distant cells. Recent research shows that the contents of these vesicles are regulated by cell state, however, the molecular mechanisms are not yet known. This project will investigate the hypothesis that changes in the RNA-binding protein composition of cholesterol-rich membranes mediate the selection of miRNA loaded in the vesicles. This knowledge may increase our understanding of mechanisms of disease because this mode of cell-to-cell communication is disrupted or hijacked in pathologies. Future translation in diverse applications may improve human, animal and plant health.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100524
Funder
Australian Research Council
Funding Amount
$365,057.00
Summary
Manipulating selected inflammatory responses in macrophages. This project aims to define the structural and functional interactions of a new transmembrane adaptor SCIMP. SCIMP has recently been shown to effect the inflammatory pathway. The project outcomes will include the first structure of this unconventional complex. The project will have significant flow on benefits including new knowledge and new protein methodologies for end-users in research and industry, and ultimately economic impact.
Defining the membrane protein cargo transported by Retromer. This project aims to define the role of Retromer, a protein machine that directs the organisation and movement of proteins within the cell. The function of proteins is dependent on how they travel through the various regions or compartments within the cell. One intracellular compartment, termed endosomes, is central to this dynamic process. Intracellular transport of biomolecules through the endosomal organelle is critical for normal c ....Defining the membrane protein cargo transported by Retromer. This project aims to define the role of Retromer, a protein machine that directs the organisation and movement of proteins within the cell. The function of proteins is dependent on how they travel through the various regions or compartments within the cell. One intracellular compartment, termed endosomes, is central to this dynamic process. Intracellular transport of biomolecules through the endosomal organelle is critical for normal cellular processes such as signalling and development. Endosomal transport occurs within membrane domains and membrane vesicular carriers formed by Retromer. This project aims to define the transmembrane proteins sorted by the distinct retromer complexes that form within the cell and the sorting signals essential for their correct trafficking and localisation.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140100558
Funder
Australian Research Council
Funding Amount
$389,220.00
Summary
Caveolae as structural mechanosensors: a link between the intra and extracellular environments? How cells perceive and respond to mechanical cues are fundamental questions in cellular biology. Caveolae are invaginations of the plasma membrane which flatten into the bulk membrane in response to increased membrane tension. This project aims to validate this response at the molecular level in a physiological context. Specifically, the project will investigate how the caveola response coordinates wi ....Caveolae as structural mechanosensors: a link between the intra and extracellular environments? How cells perceive and respond to mechanical cues are fundamental questions in cellular biology. Caveolae are invaginations of the plasma membrane which flatten into the bulk membrane in response to increased membrane tension. This project aims to validate this response at the molecular level in a physiological context. Specifically, the project will investigate how the caveola response coordinates with the extracellular matrix as well as study the fate of caveolar proteins released from caveolae. Besides the establishment of new methodologies, the findings will highlight the role of caveolae in the short and long term adaptive responses to mechanical cues and enhance understanding of how cells integrate the extracellular and intracellular environments.Read moreRead less
The role of zinc in synaptic transmission in the central nervous system. By regulating the strength of synaptic transmission between neurons, zinc exerts dynamic control over many physiological processes including memory formation, fear conditioning and movement control. Zinc also controls neuronal cell death pathways. There is currently much controversy about the concentration that zinc reaches in the synaptic cleft and the length of time it remains elevated. By defining these parameters, this ....The role of zinc in synaptic transmission in the central nervous system. By regulating the strength of synaptic transmission between neurons, zinc exerts dynamic control over many physiological processes including memory formation, fear conditioning and movement control. Zinc also controls neuronal cell death pathways. There is currently much controversy about the concentration that zinc reaches in the synaptic cleft and the length of time it remains elevated. By defining these parameters, this project aims to understand which proteins zinc acts upon and the molecular mechanisms by which it exerts its synapse-modulating effects. The outcomes of this project could lead to better understanding of zinc dynamics that could underpin future research into many physiological processes.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120102321
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Exploiting pathogen-host interactions to dissect the mammalian endocytic pathway. Salmonella manipulates the cells of the human body to cause disease. Understanding the molecular machinery that controls this process will provide profound insight into how the bacteria orchestrates this manipulation as well as provide possible avenues for intervention and even cures for diseases like typhoid fever.