The lipidomics of cell fate. This project aims to dissect the roles of lipids in cell fate. The study of lipids, or lipidomics, is an emerging and exciting area of biological science. The fundamental roles of lipids in development remain vastly understudied. This project will look at reprogramming of somatic cells into stem cells, their pluripotency and differentiation. This will be complemented with studies in the zebrafish, which permits the direct study of cell fate in vivo. This approach is ....The lipidomics of cell fate. This project aims to dissect the roles of lipids in cell fate. The study of lipids, or lipidomics, is an emerging and exciting area of biological science. The fundamental roles of lipids in development remain vastly understudied. This project will look at reprogramming of somatic cells into stem cells, their pluripotency and differentiation. This will be complemented with studies in the zebrafish, which permits the direct study of cell fate in vivo. This approach is a powerful way to unlock major events involved in development and to unmask the roles of lipids in these fundamental mechanisms.Read moreRead less
Assessing the mechanisms and dynamics of myelination in the brain. This project is expected to refine our understanding of brain plasticity by revealing how myelin plasticity optimises brain function in response to experience. Using a multidisciplinary approach incorporating animal studies, mathematical modelling and computational neuroscience, the project seeks to redefine our understanding of myelin remodelling using an entirely new integrated cell-to-system approach. The expected outcome is f ....Assessing the mechanisms and dynamics of myelination in the brain. This project is expected to refine our understanding of brain plasticity by revealing how myelin plasticity optimises brain function in response to experience. Using a multidisciplinary approach incorporating animal studies, mathematical modelling and computational neuroscience, the project seeks to redefine our understanding of myelin remodelling using an entirely new integrated cell-to-system approach. The expected outcome is fundamental knowledge revealing how myelination is dynamically regulated by neural activity throughout life. This may transform current understanding of neuroplasticity that could aid in the future development of strategies to improve brain health.Read moreRead less
Apoptotic signalling in virally infected and normal cells. Viral diseases contribute substantially to mortality and morbidity, in Australia and internationally. Emerging viral diseases, including H5N1 avian influenza, have the potential to severely impact on human health and the global economy. Concerns also exist that viruses may be used as bioweapons. This project seeks to define the mechanisms by which cell death occurs and is regulated in healthy cells, and how this is altered in virally inf ....Apoptotic signalling in virally infected and normal cells. Viral diseases contribute substantially to mortality and morbidity, in Australia and internationally. Emerging viral diseases, including H5N1 avian influenza, have the potential to severely impact on human health and the global economy. Concerns also exist that viruses may be used as bioweapons. This project seeks to define the mechanisms by which cell death occurs and is regulated in healthy cells, and how this is altered in virally infected or oncogenically transformed cells. Outcomes of this work may contribute to development of novel anti-cancer and anti-viral therapies, diagnostic reagents and vaccines.Read moreRead less
Countdown to death: defining new signalling events preceding cell death . This proposal aims to understand how programmed cell death molecular machineries promote innate immune responses and proliferation by identifying new molecules that regulate these fundamental biological processes. This project expects to enhance our basic understanding of cell death, cell proliferation and innate immunity using innovative approaches and to build interdisciplinary collaborations. The new generated knowledge ....Countdown to death: defining new signalling events preceding cell death . This proposal aims to understand how programmed cell death molecular machineries promote innate immune responses and proliferation by identifying new molecules that regulate these fundamental biological processes. This project expects to enhance our basic understanding of cell death, cell proliferation and innate immunity using innovative approaches and to build interdisciplinary collaborations. The new generated knowledge in these critical processes will be fertile ground to develop innovative applications in biomedical industries. This this will have a positive impact on the health and economy of Australian society.Read moreRead less
Crosstalk between cell survival and cell death pathways. This project aims to determine the precise molecular mechanisms underlying cell fate decisions. The dynamics between cell survival (autophagy) and cell death (apoptosis) are complex, involving significant crosstalk between these pathways. This is fundamentally important to cellular processes. Aberrant control of autophagy and apoptosis affects the function of all organisms as well as the development and treatment of diseases ranging from c ....Crosstalk between cell survival and cell death pathways. This project aims to determine the precise molecular mechanisms underlying cell fate decisions. The dynamics between cell survival (autophagy) and cell death (apoptosis) are complex, involving significant crosstalk between these pathways. This is fundamentally important to cellular processes. Aberrant control of autophagy and apoptosis affects the function of all organisms as well as the development and treatment of diseases ranging from cancer to heart disease. This project endeavours to advance our understanding of the proteins that interconnect autophagy and apoptosis. The results are expected to explain how cells determine their fate and inform future development of strategies to treat disease.Read moreRead less
Determining the molecular regulation of blood vessel development and angiogenesis. Abnormal blood vessel growth is associated with diseases including cancer, macular degeneration, diabetic retinopathy and chronic inflammation. This project focuses on understanding normal blood vessel growth in order to gather clues to help discover ways of preventing abnormal blood vessel growth during disease.
Imaging the generation and recall of protective antiviral immune responses in vivo. Our understanding of the in vivo dynamics of cellular immune responses to infectious diseases is poor. This project will utilise advanced intravital imaging combined with novel tools to dissect the cellular events involved in the generation and recall of T cell responses to localised virus infection, combined with a detailed functional analysis of the lymphoid organ stroma. Such fundamental information will contr ....Imaging the generation and recall of protective antiviral immune responses in vivo. Our understanding of the in vivo dynamics of cellular immune responses to infectious diseases is poor. This project will utilise advanced intravital imaging combined with novel tools to dissect the cellular events involved in the generation and recall of T cell responses to localised virus infection, combined with a detailed functional analysis of the lymphoid organ stroma. Such fundamental information will contribute to the development of new generation vaccines and therapies to protect against tissue-specific infectious diseases, cancers and autoimmune diseases.Read moreRead less
How is the blood cell population size controlled? Macrophage-like cells are an ancient animal blood cell lineage critically important for development, immunity, and homeostasis. This fellowship seeks to reveal the genes and control mechanisms used by animals to achieve an optimally-sized army of these cells - to contain threats for survival upon infection, heal following acute stress exposures, or for development, ongoing maintenance, and repair of wear and tear. By marrying the genetic tractabi ....How is the blood cell population size controlled? Macrophage-like cells are an ancient animal blood cell lineage critically important for development, immunity, and homeostasis. This fellowship seeks to reveal the genes and control mechanisms used by animals to achieve an optimally-sized army of these cells - to contain threats for survival upon infection, heal following acute stress exposures, or for development, ongoing maintenance, and repair of wear and tear. By marrying the genetic tractability of the model organism Drosophila and its simple, yet conserved blood cell system, this project will yield new insights into the mechanisms that govern the animal blood cell population. This will benefit our fundamental understanding of how animals maximise their health throughout life.Read moreRead less
Modelling the human nervous system with human pluripotent stem cells. The human nervous system is one of the most complex structures evolved to date. In order to understand how it functions, and dysfunctions in a diseased state, it is fundamental to decipher how it develops to generate various neuronal populations that form this elaborate network. Human stem cells provide a valuable source to study such processes. The aim of this project is to use human stem cells to study how early progenitor c ....Modelling the human nervous system with human pluripotent stem cells. The human nervous system is one of the most complex structures evolved to date. In order to understand how it functions, and dysfunctions in a diseased state, it is fundamental to decipher how it develops to generate various neuronal populations that form this elaborate network. Human stem cells provide a valuable source to study such processes. The aim of this project is to use human stem cells to study how early progenitor cell types that structure the nervous system are generated and how their neuronal derivatives form connectivity and functional synapses. The outcome of these studies is that we will establish a cellular model of human neurogenesis that can be utilised to study developmental disease processes.Read moreRead less
Structural investigations into the regulation of programmed cell death. One in three men and one in four women in Australia will develop cancer by the age of 75 at current incidence rates. At its heart, cancer is a disease of uncontrolled cell proliferation. One of the body's main defence mechanisms against excess cell proliferation is Programmed Cell Death, a process which becomes dysfunctional in cancer cells. This work will provide three dimensional images of the machinery that controls Progr ....Structural investigations into the regulation of programmed cell death. One in three men and one in four women in Australia will develop cancer by the age of 75 at current incidence rates. At its heart, cancer is a disease of uncontrolled cell proliferation. One of the body's main defence mechanisms against excess cell proliferation is Programmed Cell Death, a process which becomes dysfunctional in cancer cells. This work will provide three dimensional images of the machinery that controls Programmed Cell Death. This information is critical for the development of drugs designed to re-initiate Programmed Cell Death in cancer cells.Read moreRead less