Differential roles of gene family members in development of a cell lineage. This project aims to investigate how a family of genes influence cells in the testis to become mature sperm. Testicular cells regulate gene activity via the Snail family of proteins during sperm development, and interruption of their activities reduces fertility in mice and fruit flies. The project aims to use genetic, cell biological and biochemical studies in Drosophila and mice to compare different Snail family protei ....Differential roles of gene family members in development of a cell lineage. This project aims to investigate how a family of genes influence cells in the testis to become mature sperm. Testicular cells regulate gene activity via the Snail family of proteins during sperm development, and interruption of their activities reduces fertility in mice and fruit flies. The project aims to use genetic, cell biological and biochemical studies in Drosophila and mice to compare different Snail family proteins in spermatogenesis. The outcomes will define the different roles of highly similar proteins from the same family in differentiation of a single cell lineage. This is important in generating functional tissues using in vitro laboratory approaches or understanding how normal development and developmental disorders arise.Read moreRead less
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
Mechanism and function of dying cell disassembly. This project aims to elucidate the molecular machinery that disassembles dying cells, and the role of this process in cell clearance. Billions of cells in the body die daily as part of normal turnover. Dying cells must be rapidly removed, as their accumulation can interfere with normal tissue functions. To efficiently clear dead cells, dying cells can disassemble into smaller fragments that neighbouring cells engulf. Understanding the mechanistic ....Mechanism and function of dying cell disassembly. This project aims to elucidate the molecular machinery that disassembles dying cells, and the role of this process in cell clearance. Billions of cells in the body die daily as part of normal turnover. Dying cells must be rapidly removed, as their accumulation can interfere with normal tissue functions. To efficiently clear dead cells, dying cells can disassemble into smaller fragments that neighbouring cells engulf. Understanding the mechanistic basis and function of dying cell disassembly is expected to generate knowledge of the downstream consequence of cell death. This breakthrough will be important in many fields of research including cell biology and biochemistry, and generate basic knowledge that can ultimately be applied in medical science to understand or treat pathological conditions associated with cell death.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140100500
Funder
Australian Research Council
Funding Amount
$383,066.00
Summary
Unravelling the holistic genetic control of vertebrate development. Understanding the genetic regulation of embryo formation is the cornerstone of developmental biology. As four per cent of Australian children are born with some form of prenatal defect, understanding the basic biology of embryogenesis is paramount for long-range development of future therapies. We have identified a highly conserved transcription factor, Grhl3, which regulates multiple stages of embryonic formation. Using advance ....Unravelling the holistic genetic control of vertebrate development. Understanding the genetic regulation of embryo formation is the cornerstone of developmental biology. As four per cent of Australian children are born with some form of prenatal defect, understanding the basic biology of embryogenesis is paramount for long-range development of future therapies. We have identified a highly conserved transcription factor, Grhl3, which regulates multiple stages of embryonic formation. Using advanced genetic models, this project will characterise the role of Grhl3 in the regulation of cellular migration and craniofacial skeleton and brain development. The project will also identify the target genes which Grhl3 regulates. The identification of such transcriptional networks is imperative to understanding the holistic molecular control of embryogenesis.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150100538
Funder
Australian Research Council
Funding Amount
$342,000.00
Summary
Understanding the role of miRNAs in the biology of ageing muscle. Skeletal muscle is the largest organ in the body and plays a vital role in maintaining independent living and social interaction. As it ages, skeletal muscle loses its ability to build up new muscle proteins. However, the principles underlying the biology of skeletal muscle ageing are not well understood. MicroRNAs (MiRNAs) are essential regulators of skeletal muscle biology. Whether they play a role in the ageing process and how ....Understanding the role of miRNAs in the biology of ageing muscle. Skeletal muscle is the largest organ in the body and plays a vital role in maintaining independent living and social interaction. As it ages, skeletal muscle loses its ability to build up new muscle proteins. However, the principles underlying the biology of skeletal muscle ageing are not well understood. MicroRNAs (MiRNAs) are essential regulators of skeletal muscle biology. Whether they play a role in the ageing process and how they regulate muscle protein synthesis as we age has not been investigated. This project aims to identify the MiRNA species involved in muscle protein synthesis and will provide a better understanding of the biology of ageing skeletal muscle.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100011
Funder
Australian Research Council
Funding Amount
$900,000.00
Summary
Integrated Multimodal System for Multiplexed Imaging of Signal Transduction. This project will introduce a unique microscopy platform and associated technologies into the Australian research environment that will enable researchers to redefine our understanding of molecular signal transduction. The instrumentation will enable the multidimensional imaging of live cells with unprecendented speed and sensitivity. The featured imaging modalities will enable the integration of distinct biological, ....Integrated Multimodal System for Multiplexed Imaging of Signal Transduction. This project will introduce a unique microscopy platform and associated technologies into the Australian research environment that will enable researchers to redefine our understanding of molecular signal transduction. The instrumentation will enable the multidimensional imaging of live cells with unprecendented speed and sensitivity. The featured imaging modalities will enable the integration of distinct biological, biochemical and chemical probes with a focus on minimizing phototoxicity. Expected outcomes include new fundamental knowledge on molecular signal transduction and cell heterogeneity; development of novel probes and methodologies and the development of new and existing interdisciplinary research collaborations. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100066
Funder
Australian Research Council
Funding Amount
$440,000.00
Summary
Mass Cytometry: A breakthrough in multidimensional systems biology. Mass cytometry - a breakthrough in multidimensional systems biology: Mass Cytometry by Time of Flight marries the resolution, specificity and sensitivity of atomic stable isotope mass spectrometry to the high-throughput, single-cell analytical advantages of flow cytometry. Using molecular probes conjugated with stable isotope tags, a large increase is possible in the number of simultaneous quantitative measurements in complex sa ....Mass Cytometry: A breakthrough in multidimensional systems biology. Mass cytometry - a breakthrough in multidimensional systems biology: Mass Cytometry by Time of Flight marries the resolution, specificity and sensitivity of atomic stable isotope mass spectrometry to the high-throughput, single-cell analytical advantages of flow cytometry. Using molecular probes conjugated with stable isotope tags, a large increase is possible in the number of simultaneous quantitative measurements in complex samples. These parameters, denoting cell type, function and signalling status, will make possible future advances in the understanding of the diversity of cell phenotype and function with a systems biology approach. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100090
Funder
Australian Research Council
Funding Amount
$700,000.00
Summary
Three-dimensional cryo electron microscopy facility. The three-dimensional cryo-electron microscopy facility will let us visualise plants, pathogens and nanomachines with resolution not previously possible allowing us to see into cells and diseases with vastly more detail. Our world-class experts will provide regional and national researchers access to cutting-edge technology complementary to the Australian Synchrotron.
Control of cell fate decisions in neurogenesis: use of embryonic stem cells to investigate key signalling systems and gene expression programs. Human embryonic stem cells (hESC) have the potential to provide an unlimited source of specific subtypes of human neurons for basic studies in neuroscience and biomedical applications. The use of hESC is limited at present by a lack of control over lineage commitment during differentiation in vitro. This project will use engineered reporter hESC lines t ....Control of cell fate decisions in neurogenesis: use of embryonic stem cells to investigate key signalling systems and gene expression programs. Human embryonic stem cells (hESC) have the potential to provide an unlimited source of specific subtypes of human neurons for basic studies in neuroscience and biomedical applications. The use of hESC is limited at present by a lack of control over lineage commitment during differentiation in vitro. This project will use engineered reporter hESC lines to investigate which cell signalling pathways and gene expression programs are involved in controlling cell fate. The project will result in improved protocols for hESC differentiation allowing enrichment of cultures with specific neuronal subtypes, and significant advances in the understanding of neuronal lineage commitment and maturation during brain development. 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