Molecular toxinology of Australia's lesser known venomous snakes. This proposal represents a tremendous opportunity for biodiscovery from venomous snakes. This will be achieved through the researchers' unique approach of investigating previously unmapped venom systems for divergent, bioactive proteins. An understanding of venomous animal protein evolution great potential in drug discovery and other commercial applications. This project will provide Australian graduate and post-graduate stude ....Molecular toxinology of Australia's lesser known venomous snakes. This proposal represents a tremendous opportunity for biodiscovery from venomous snakes. This will be achieved through the researchers' unique approach of investigating previously unmapped venom systems for divergent, bioactive proteins. An understanding of venomous animal protein evolution great potential in drug discovery and other commercial applications. This project will provide Australian graduate and post-graduate students with finely tuned skills in cutting edge methodological techniques and a fluent understanding of molecular evolution, preparing them to be internationally competitive scientists.Read moreRead less
High-throughput microfluidic approach to mapping hierarchies of interactions in the gene regulation machinery. The exploration of protein-protein interactions networks is becoming an extremely active area of research in life sciences. The current project will develop new approaches to accelerate the discovery of novel interacting proteins participating in gene regulation, in order to understand how cells differentiate into different tissues and organs.
Mitochondria as sensors of environmental threats. This project aims to understand how energy-generating mitochondria control immune responses, both in immune cells called macrophages and in the nematode Caenorhabditis elegans (a free-living roundworm used as a model organism to study gene function and evolutionary biology). The project expects to advance knowledge of how a process called mitochondrial fission enables cells to respond to environmental threats. Expected outcomes include important ....Mitochondria as sensors of environmental threats. This project aims to understand how energy-generating mitochondria control immune responses, both in immune cells called macrophages and in the nematode Caenorhabditis elegans (a free-living roundworm used as a model organism to study gene function and evolutionary biology). The project expects to advance knowledge of how a process called mitochondrial fission enables cells to respond to environmental threats. Expected outcomes include important conceptual advances in cell biology and genetics, new international and national collaborations, and improved methods for cell biology research. Anticipated benefits include a knowledge base that can be indirectly applied in the long term in the development of new strategies to combat infections.Read moreRead less
Cellular Ageing: Is the Plasma Membrane the Control Hub? This project aims to determine whether the plasma membrane lipid composition is a major driver of cellular ageing. It expects to generate new knowledge in the molecular mechanism of cellular ageing, utilising our team’s deep expertise in lipid biology, bioinformatics, biophysics, extracellular vesicle biology and cellular ageing. Expected outcomes include the identification of novel cellular ageing markers and anti-ageing targets while als ....Cellular Ageing: Is the Plasma Membrane the Control Hub? This project aims to determine whether the plasma membrane lipid composition is a major driver of cellular ageing. It expects to generate new knowledge in the molecular mechanism of cellular ageing, utilising our team’s deep expertise in lipid biology, bioinformatics, biophysics, extracellular vesicle biology and cellular ageing. Expected outcomes include the identification of novel cellular ageing markers and anti-ageing targets while also cementing long-standing partnerships and fostering new interdisciplinary collaborations. This cellular ageing study will provide novel insights into the basic principles of cellular behaviour, e.g. growth, differentiation, communication and death, reinforcing Australia’s leadership in biological science.Read moreRead less
Novel approaches for structural and functional analysis of the protein complex COG, a tether that controls intra-Golgi trafficking. Production and engineering of proteins are key methodologies of the life sciences in general and biotechnology in particular. Our ability to produce and analyse protein-based components of the cell determines the expense and speed of discovery, as well as the creation of new vaccines, drugs, and diagnostic methods. The current project aims to develop new approaches ....Novel approaches for structural and functional analysis of the protein complex COG, a tether that controls intra-Golgi trafficking. Production and engineering of proteins are key methodologies of the life sciences in general and biotechnology in particular. Our ability to produce and analyse protein-based components of the cell determines the expense and speed of discovery, as well as the creation of new vaccines, drugs, and diagnostic methods. The current project aims to develop new approaches for protein production and to apply them to the analysis of the basic mechanisms of cell self-maintenance.Read moreRead less
NmlR-dependent thiol-based redox systems and their role in global stress responses in bacteria. All cells sense changes to their environment and respond by altering their metabolism. A major environmental change is oxidative stress which damages cells. Cells have the ability to sense oxidative stress and alter metabolic processes to defend against the damage that it elicits. This proposal will characterize a novel oxidative stress defense system that is found in a number of bacterial pathogens t ....NmlR-dependent thiol-based redox systems and their role in global stress responses in bacteria. All cells sense changes to their environment and respond by altering their metabolism. A major environmental change is oxidative stress which damages cells. Cells have the ability to sense oxidative stress and alter metabolic processes to defend against the damage that it elicits. This proposal will characterize a novel oxidative stress defense system that is found in a number of bacterial pathogens that need to defend themselves against attack by the host. The project may identify new ways to manage these bacterial pathogens. It may also provide an insight into oxidative stress defense processes that are linked to pathologies in humans.Read moreRead less
The role of human single stranded DNA binding protein 1 in the repair of stalled DNA replication forks. It is vital that human cells protect their genetic code in order to prevent cancer. This project will look at how cells do this, with the aim of finding new ways to protect us from cancer.
Comparing properties of innate immune proteins of bats and humans. Supra-molecular protein complexes known as signalosomes drive our innate immune response by forming large signaling hubs capable of recruiting downstream effectors. This project aims to compare the properties and structure of human and bat signalosomes and discover the molecular origins of the “supra-immunity” of bats. In this context, the project expects to generate new knowledge concerning the fundamental molecular mechanisms t ....Comparing properties of innate immune proteins of bats and humans. Supra-molecular protein complexes known as signalosomes drive our innate immune response by forming large signaling hubs capable of recruiting downstream effectors. This project aims to compare the properties and structure of human and bat signalosomes and discover the molecular origins of the “supra-immunity” of bats. In this context, the project expects to generate new knowledge concerning the fundamental molecular mechanisms that regulate the signalosomes. The intended outcome is to answer the long-standing question of control of speed and amplitude of innate immune response at the molecular level. Both locally and internationally, this new approach should provide benefits across structural biology, molecular evolution and biotechnology.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
The protein import machinery of peroxisomes. The peroxisome is a subcellular organelle essential for cellular metabolism. Our understanding of the formation, or biogenesis, of the peroxisome has advanced to the stage where many of the proteins involved in this process have been identified. What is less clear is how these proteins interact to form functional macromolecular complexes in the cell. In this project we will use biochemical approaches to isolate protein complexes involved in peroxisome ....The protein import machinery of peroxisomes. The peroxisome is a subcellular organelle essential for cellular metabolism. Our understanding of the formation, or biogenesis, of the peroxisome has advanced to the stage where many of the proteins involved in this process have been identified. What is less clear is how these proteins interact to form functional macromolecular complexes in the cell. In this project we will use biochemical approaches to isolate protein complexes involved in peroxisome biogenesis. These studies will help to elucidate the molecular mechanisms of peroxisome biogenesis and contribute to an understanding of organelle biogenesis generally.Read moreRead less