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
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
Mapping networks governing cell state plasticity: how, where and when? Single cell organisms are the basic unit of life, yet, if they had not developed the ability to change cell states we would not exist today. Changing cell states lies at the core of almost every developmental and disease process in multicellular organisms. Building upon our fundamental discovery that stem cells and non-stem cells readily interconvert, we will now incorporate innovative cell systems and the development of our ....Mapping networks governing cell state plasticity: how, where and when? Single cell organisms are the basic unit of life, yet, if they had not developed the ability to change cell states we would not exist today. Changing cell states lies at the core of almost every developmental and disease process in multicellular organisms. Building upon our fundamental discovery that stem cells and non-stem cells readily interconvert, we will now incorporate innovative cell systems and the development of our new multi-layered systems biology strategy to elucidate the first comprehensive understanding of the cell biology that underlies cell state changes. These studies are a major step toward understanding the fundamentals of life. Read moreRead less
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
Discovery Early Career Researcher Award - Grant ID: DE120101242
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Regulation of germ cell number and quality by Fizzy-related protein. Females have a limited supply of eggs in their ovaries and it appears that the Fizzy-related gene (FZR1) is important in making sure this full complement is gained. By using novel mouse knockouts of the FZR1 gene, the project will determine how this protein functions at the earliest stages of egg development.
Discovery Early Career Researcher Award - Grant ID: DE210100103
Funder
Australian Research Council
Funding Amount
$459,674.00
Summary
Fortifying animal and plant germ cells against proteotoxic stress. Cellular stress is responsible for widespread inefficiencies in plant and animal reproduction. Using high resolution proteomics and cryo-electron microscopy, this project aims to investigate how plant and animal germ cells respond to environmental stresses that are known to disrupt fertility, and assess two novel strategies to decrease the sensitivity of cells to stress. This project is expected to generate new global knowledge i ....Fortifying animal and plant germ cells against proteotoxic stress. Cellular stress is responsible for widespread inefficiencies in plant and animal reproduction. Using high resolution proteomics and cryo-electron microscopy, this project aims to investigate how plant and animal germ cells respond to environmental stresses that are known to disrupt fertility, and assess two novel strategies to decrease the sensitivity of cells to stress. This project is expected to generate new global knowledge in the area of fertility regulation with the potential to improve the tolerance of crop species to heat stress, prevent economic losses and help to secure future food production. Further, this project has the intended benefit of improving the fertility of animal species that suffer from stress-induced infertility.
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Gamete-specific knockout of Fizzy-Related to examine its meiotic role in oocytes and sperm. Fizzy-Related is a gene that appears to be essential in making an ovulated egg, and it may also have an important role to play in making sperm. A mouse knockout will be generated to examine exactly how it functions; because it affects the egg number remaining in the ovary and egg quality Fizzy-Related may be eventually an important therapeutic target.
Endocardial sprouting and mechano-signalling in heart trabeculation. This project aims to understand how the ventricles, the pumping chambers of the mammalian heart, form during embryonic life. Critical is the elaboration of trabeculae, myocardial projections that form a sponge-like layer on the inner surface of the chamber wall and which play vital roles in contraction, oxygen and nutrient exchange, conduction and septation. The project expects to develop a deeper understanding of trabeculation ....Endocardial sprouting and mechano-signalling in heart trabeculation. This project aims to understand how the ventricles, the pumping chambers of the mammalian heart, form during embryonic life. Critical is the elaboration of trabeculae, myocardial projections that form a sponge-like layer on the inner surface of the chamber wall and which play vital roles in contraction, oxygen and nutrient exchange, conduction and septation. The project expects to develop a deeper understanding of trabeculation using high resolution, single cell methodologies, and to investigate how bio-mechanical forces from contraction or blood flow influence chambers formation.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100149
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
CyTOF platform for the Advanced Cytometry Facility: overcoming fluorescence spectral barriers to truly multiparametric cytometry by mass spectrometry. Cytometry by time-of-flight mass spectrometry platform for the Advanced Cytometry Facility: overcoming fluorescence spectral barriers to truly multiparametric cytometry by mass spectrometry: This project will provide a flow cytometer capable of analysing single cells by time-of-flight mass spectrometry. Antibody labels for cell components will ena ....CyTOF platform for the Advanced Cytometry Facility: overcoming fluorescence spectral barriers to truly multiparametric cytometry by mass spectrometry. Cytometry by time-of-flight mass spectrometry platform for the Advanced Cytometry Facility: overcoming fluorescence spectral barriers to truly multiparametric cytometry by mass spectrometry: This project will provide a flow cytometer capable of analysing single cells by time-of-flight mass spectrometry. Antibody labels for cell components will enable measurement of up to 100 parameters/cell. Developing analytical and modelling algorithms like Spanning tree Progression of Density normalised Events (SPADE), this project will aim to map the relationships of various unelucidated cell lineages, via functional pathway connections. New pathways thus revealed will enable elaboration and use of novel specific molecules in perturbational analyses to confirm and further enhance the understanding of these highly intricate, basic relationships. This will provide unparalleled insight, both into early development of stem cells and mechanisms of maintenance of homeostasis in differentiated cells.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100226
Funder
Australian Research Council
Funding Amount
$372,000.00
Summary
How innate lymphoid cells regulate mammalian lung development. This project aims to determine the ability of a subset of lung resident immune cells to promote normal lung development through the regulation of stem cells. The lung is constantly exposed to countless environmental challenges including microbes. Mammals’ local immune systems protect the lung from these challenges. This is particularly important in early-life when the lung is still developing. However, impaired lung development affec ....How innate lymphoid cells regulate mammalian lung development. This project aims to determine the ability of a subset of lung resident immune cells to promote normal lung development through the regulation of stem cells. The lung is constantly exposed to countless environmental challenges including microbes. Mammals’ local immune systems protect the lung from these challenges. This is particularly important in early-life when the lung is still developing. However, impaired lung development affects humans and livestock, costing >$3 billion p.a. The intended outcome is to identify basic biological processes involved in normal mammalian lung development, which may lead to strategies to prevent chronic lung diseases in humans and animals.Read moreRead less