Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100001
Funder
Australian Research Council
Funding Amount
$345,475.00
Summary
Pushing the limits of fluorescence microscopy with adaptive optics. This project aims to establish an adaptive optics, super-resolution optical microscopy facility to image cellular events with the highest possible spatial resolution, in a whole cell or tissue context. Sophisticated computer-controlled deformable mirrors will be used to correct the way light is distorted as it passes through specimens, thereby overcoming aberrations found in thick and complex samples. This adaptive optics system ....Pushing the limits of fluorescence microscopy with adaptive optics. This project aims to establish an adaptive optics, super-resolution optical microscopy facility to image cellular events with the highest possible spatial resolution, in a whole cell or tissue context. Sophisticated computer-controlled deformable mirrors will be used to correct the way light is distorted as it passes through specimens, thereby overcoming aberrations found in thick and complex samples. This adaptive optics system will enable researchers to study complex behaviour of biological specimens, at the optical resolution limit in plant and animal tissues, leading to basic biology and biotechnology outcomes in biofuels, biomaterials and biomedicines.Read moreRead less
Understanding the potency and role of individual stem cells in the skin using Rainbow technology. To renew itself, the skin and its components rely on the activity of stem cells. This project will define more precisely the role of each individual stem cell by labelling them with a unique colour and following its fate. This project has the potential to change our current view on how the skin maintains and repairs itself.
Controlling the first step of differentiation of embryonic cells. This project aims to improve understanding of how diverse cell types are generated for building the body plan of the embryo. The first step of embryonic cell lineage differentiation takes place at early gastrulation when the multipotent embryonic cells acquire the attributes of specific tissue lineages. This project intends to elucidate how inductive signals and gene function are integrated to drive the lineage choice of the naïve ....Controlling the first step of differentiation of embryonic cells. This project aims to improve understanding of how diverse cell types are generated for building the body plan of the embryo. The first step of embryonic cell lineage differentiation takes place at early gastrulation when the multipotent embryonic cells acquire the attributes of specific tissue lineages. This project intends to elucidate how inductive signals and gene function are integrated to drive the lineage choice of the naïve cells, by tracking the impact of the activity of signalling pathways and gene regulation on cell differentiation. This may deliver insights into the temporal hierarchy and functional attributes of the molecular switches that control stem cell differentiation. Expected outcomes may have applications in tissue engineering.Read moreRead less
A molecular paradigm of organ formation during embryonic development: the role of RhoGTPase. How do cells in the embryo acquire the correct shape and structure to form tissues and organs? This project will reveal the genes and proteins required for the formation of the early gut and associated organs and will enhance our understanding of how organs are constructed from the building blocks in the embryo.
Enhancing neurogenesis in the adult primate brain. New neurons are robustly generated in the subependymal zone (SEZ) during human development. Thus, the SEZ may represent an endogenous modifiable source of neurons to enhance plasticity and therapeutic potential in the brain. However, despite our preliminary data, SEZ neurogenesis beyond the first months of life is controversial. This project aims to understand changes in the capacity for human SEZ proliferation from birth through to ageing and w ....Enhancing neurogenesis in the adult primate brain. New neurons are robustly generated in the subependymal zone (SEZ) during human development. Thus, the SEZ may represent an endogenous modifiable source of neurons to enhance plasticity and therapeutic potential in the brain. However, despite our preliminary data, SEZ neurogenesis beyond the first months of life is controversial. This project aims to understand changes in the capacity for human SEZ proliferation from birth through to ageing and whether neurogenesis may be induced by inflammation in the adult. Using transcriptomics we will also determine how the neurogenic environment changes with age/inflammation. This project is an important step in proving that the brain's potential to generate new neurons extends beyond infancy.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: LE150100161
Funder
Australian Research Council
Funding Amount
$540,000.00
Summary
A multi-omics platform for molecular evolution and developmental biology. A multi-omics platform for molecular evolution and developmental biology: The proposed multi-omics platform will provide the computational environment (consisting of data, computer hardware, software and workflows) required to undertake large scale 'omics based research projects within molecular evolution and developmental biology. The platform architecture is designed to accommodate the requirements of data intensive rese ....A multi-omics platform for molecular evolution and developmental biology. A multi-omics platform for molecular evolution and developmental biology: The proposed multi-omics platform will provide the computational environment (consisting of data, computer hardware, software and workflows) required to undertake large scale 'omics based research projects within molecular evolution and developmental biology. The platform architecture is designed to accommodate the requirements of data intensive research in a collaborative environment where datasets, tools and workflows can be shared. Bringing together complementary expertise in molecular evolution and developmental biology, the platform will provide the opportunity to perform integrative analysis across genomes, transcriptomes, proteomes, metabalomes and epigenomes, providing a unique collaborative analytical platform for Australian researchers.Read moreRead less
Role of Musashi in the regulation of cell cycle proteins. We have identified a protein family that directs cell fate and maintains male fertility. This project will provide new avenues for generation of contraceptives in male animals and to regulate stem cells for production of specialised cell types in biotechnological applications.
The structure of heteromeric amyloid fibrils with signaling activity. This project aims to determine the composition, structure and properties of important protein complexes involved in a newly identified cell death pathway known as necroptosis. This cell death pathway removes unwanted or damaged cells during development or infection. These necroptosis protein complexes are unusual because they have a fibrillar amyloid structure, contain more than one protein type in the fibrils and have a funct ....The structure of heteromeric amyloid fibrils with signaling activity. This project aims to determine the composition, structure and properties of important protein complexes involved in a newly identified cell death pathway known as necroptosis. This cell death pathway removes unwanted or damaged cells during development or infection. These necroptosis protein complexes are unusual because they have a fibrillar amyloid structure, contain more than one protein type in the fibrils and have a functional, signalling role. The research will determine how these fibrils form and how the structures confers biological function. It could identify features in these fibrils that can be targeted as a means of ultimately preventing tissue damage after heart attack and stroke.Read moreRead less
Inhibiting protein-protein interactions involved in neural development and disease. This project will determine the molecular mechanisms by which the protein LMO4 (a regulator of brain development) binds to DEAF1 (which also regulates neural development) and CtIP (which protects against tumour formation). This will allow a set of reagents to be developed to help determine the functions of LMO4, and may ultimately be used to treat disease.