Regulation of mRNA translation by the microtubule-associated protein Tau. This project aims to understand the molecular processes in a cell type and subcellular compartment that underlies learning and memory formation. Fundamental neuronal functions such as synaptic strengthening and memory formation are dependent on the tightly regulated process of protein translation. The kinase Fyn (which is localised to dendritic spines where memories are formed) activates the ERK/S6 pathway leading to massi ....Regulation of mRNA translation by the microtubule-associated protein Tau. This project aims to understand the molecular processes in a cell type and subcellular compartment that underlies learning and memory formation. Fundamental neuronal functions such as synaptic strengthening and memory formation are dependent on the tightly regulated process of protein translation. The kinase Fyn (which is localised to dendritic spines where memories are formed) activates the ERK/S6 pathway leading to massive translation of the scaffolding protein Tau. More importantly, the activation of this cascade is Tau-dependent. This project aims to determine how Tau activates this pathway, and to decipher the physiological role of the Tau/Fyn/Tau feedback loop. This will inform our understanding of the molecular regulation of learning and memory.Read moreRead less
Molecular determinants of inflammatory caspase activity upon inflammasomes. Most processes fundamental to life rely on the timely, and regulated, execution of cellular functions. The innate immune system, in which both timing and regulation is paramount, rapidly detects invading microbes and induces a measured and timely antimicrobial response to clear infection. This project aims to address a key knowledge gap by characterising a mechanism for timely and controlled immune system activation and ....Molecular determinants of inflammatory caspase activity upon inflammasomes. Most processes fundamental to life rely on the timely, and regulated, execution of cellular functions. The innate immune system, in which both timing and regulation is paramount, rapidly detects invading microbes and induces a measured and timely antimicrobial response to clear infection. This project aims to address a key knowledge gap by characterising a mechanism for timely and controlled immune system activation and immune cell death via the non-canonical inflammasome. We do not currently understand how some immune pathways are turned on or off. This project will yield fundamental insight into mechanisms of mammalian inflammasome, inflammation and anti-microbial responses.Read moreRead less
A novel mechanism of host defence via macrophage extracellular traps. Animal health relies upon innate immune cells to rapidly detect invading microbes and induce inflammatory and antimicrobial responses to clear infection. Mechanisms of inflammation and immune defence are only partly understood. This project aims to elucidate a novel innate immune pathway (the inflammasome) that drives inflammatory cell death and antimicrobial defence. Using innovative multidisciplinary methods, this project wi ....A novel mechanism of host defence via macrophage extracellular traps. Animal health relies upon innate immune cells to rapidly detect invading microbes and induce inflammatory and antimicrobial responses to clear infection. Mechanisms of inflammation and immune defence are only partly understood. This project aims to elucidate a novel innate immune pathway (the inflammasome) that drives inflammatory cell death and antimicrobial defence. Using innovative multidisciplinary methods, this project will yield exciting new knowledge of mechanisms of inflammation and anti-microbial responses, and new paradigms for inflammasome action. Expected outcomes and benefits include high-impact publications, international collaboration, world-class training for young scientists, and new knowledge for future commercialisation.Read moreRead less
A molecular timer for inflammation and cell death. This project aims to improve our understanding of the timely function of the immune system. Most processes fundamental to life rely on the timely execution of cellular functions. One biological system in which timing is paramount is the immune system. Organismal health relies upon this front-line defence system for rapidly detecting invading microbes and inducing an appropriate, and timely, antimicrobial response to clear infection. We do not cu ....A molecular timer for inflammation and cell death. This project aims to improve our understanding of the timely function of the immune system. Most processes fundamental to life rely on the timely execution of cellular functions. One biological system in which timing is paramount is the immune system. Organismal health relies upon this front-line defence system for rapidly detecting invading microbes and inducing an appropriate, and timely, antimicrobial response to clear infection. We do not currently understand how immune responses are temporally coordinated. This proposal aims to address this key knowledge gap by characterising a novel molecular timer that dictates the co-ordinated timing of immune responses and immune cell death. These studies may yield fundamental insight into mammalian anti-microbial mechanisms.Read moreRead less
A role for the actin cytoskeleton in suppression of prion pathology in yeast. The discovery that proteins as well as DNA carry genetic information is leading to a re-think of the mechanisms that program cell behaviour. There is a link between proteins that suppress cancer and protein inheritance. This project explores how heritable changes in proteins control cell behaviour and the implications of this for the origin of cancer.
Signal transduction and the control of bacterial respiration by the NtrYX two component regulatory system. This proposal will define the structural and functional properties of the NtrYX two component signal transduction and define its role in the regulation of respiratory gene expression. The human pathogen Neisseria gonorrhoeae will be used as a model organism for a diverse range of 'oxidase positive' bacteria that possess NtrYX. The outcome will be a major contribution to the understanding of ....Signal transduction and the control of bacterial respiration by the NtrYX two component regulatory system. This proposal will define the structural and functional properties of the NtrYX two component signal transduction and define its role in the regulation of respiratory gene expression. The human pathogen Neisseria gonorrhoeae will be used as a model organism for a diverse range of 'oxidase positive' bacteria that possess NtrYX. The outcome will be a major contribution to the understanding of way in which respiratory gene expression is controlled in bacterial species for which Escherichia coli is not a suitable model. 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
Mechanotransduction: a new paradigm for cadherin junction biology. Cell adhesion is necessary to hold the cells in our tissue together, and is essential for organ function. It is essential for adhesion junctions to resist force that would break them apart. This project investigates how adhesion junctions sense and respond to force acting on cells.
A molecular investigation into the naïve T cell repertoire. This project aims to interrogate the relationship between T cell receptor (TCR) recognition modes and T cell recruitment and activation. CD8+ T cells are important for adaptive immunity. Their recognition, via TCR, of peptides bound to MHC class I antigen-presenting molecules (pMHCI), initiates a signalling cascade which activates T cells effector functions. All structural information on TCR recognition of pMHCI is based on TCRs prevale ....A molecular investigation into the naïve T cell repertoire. This project aims to interrogate the relationship between T cell receptor (TCR) recognition modes and T cell recruitment and activation. CD8+ T cells are important for adaptive immunity. Their recognition, via TCR, of peptides bound to MHC class I antigen-presenting molecules (pMHCI), initiates a signalling cascade which activates T cells effector functions. All structural information on TCR recognition of pMHCI is based on TCRs prevalent in immune responses, and all recognise pMHCI using a conserved orientation. This project aims to use this observation to study the relationship between TCR recognition modes and T cell recruitment and activation.Read moreRead less
How filopodia connect macrophages to the outside world. Fundamental to life is the ability of cells to sense their surroundings and respond accordingly. This project aims to generate a biological understanding of how certain immune cells carry out such processes, thus enabling them to combat infections.