Signaling in the crypt: a novel metabolic pathway in intestinal stem cells. The gut is the most rapidly renewing tissue in the body, driven by a highly active stem cell niche. Bile acids are emerging as critical regulators of this stem cell niche and disruption of bile acid homeostasis has profoundly adverse effects on intestinal renewal and hence gut health. We are addressing a critical gap in our understanding of how bile acids are controlled within stem cell niche. The aim of the project is ....Signaling in the crypt: a novel metabolic pathway in intestinal stem cells. The gut is the most rapidly renewing tissue in the body, driven by a highly active stem cell niche. Bile acids are emerging as critical regulators of this stem cell niche and disruption of bile acid homeostasis has profoundly adverse effects on intestinal renewal and hence gut health. We are addressing a critical gap in our understanding of how bile acids are controlled within stem cell niche. The aim of the project is to define the critical role of a novel enzyme called UGT8 in controlling intestinal stem cell response to bile acids; this is achieved by modulating UGT8 activity in intestinal stem cell models and determining the effects on stem cell function and the key signalling pathways that control intestinal homeostasis and renewal.Read moreRead less
Airway Epithelial IAPs And Their Interaction With Zn Ions
Funder
National Health and Medical Research Council
Funding Amount
$260,779.00
Summary
The air we breathe contains a variety of harmful substances. Damage to the lining involves death of the ciliated cells that line the airways. We have shown that zinc protects these cells from premature death. This application focuses on a family of proteins called IAPs which bind zinc and regulate cell death in other tissues. This project focusses on how the IAPs and Zn may act together to mainitain healthy airways and how abnormalities of these may occur in people with asthma.
Discovery Early Career Researcher Award - Grant ID: DE210100604
Funder
Australian Research Council
Funding Amount
$436,600.00
Summary
How do cells sense and react to mechanical forces? There is accumulating evidence that mechanical forces exerted on tissues and cells strongly influences their behaviour. My research aims to understand how cells sense and respond to forces experienced throughout life. Using a combination of three-dimensional cell and tissue culture methods, I will investigate how compressive forces change the biochemistry of cells and their functionality. This work is aimed at generating fundamental knowledge to ....How do cells sense and react to mechanical forces? There is accumulating evidence that mechanical forces exerted on tissues and cells strongly influences their behaviour. My research aims to understand how cells sense and respond to forces experienced throughout life. Using a combination of three-dimensional cell and tissue culture methods, I will investigate how compressive forces change the biochemistry of cells and their functionality. This work is aimed at generating fundamental knowledge to improve our comprehension of how cells respond to force. The expected outcome is a greater understanding of mechanical and biochemical relationships between cells and the environment, to inform fields of tissue engineering of culture scaffolds to better mimic natural cell-tissue settings.Read moreRead less
New mechanisms regulating the biogenesis of extracellular vesicles. Extracellular vesicles are small packages that contain active components derived from the cell of origin. These vesicles, released by most cell types, are critical for communication between cells. However, the processes of their formation and release remain poorly understood. This project aims to explore how ubiquitination, a type of protein modification system, controls the production of extracellular vesicles. Using a strong c ....New mechanisms regulating the biogenesis of extracellular vesicles. Extracellular vesicles are small packages that contain active components derived from the cell of origin. These vesicles, released by most cell types, are critical for communication between cells. However, the processes of their formation and release remain poorly understood. This project aims to explore how ubiquitination, a type of protein modification system, controls the production of extracellular vesicles. Using a strong collaborative team and highly innovative approaches, the project will generate new knowledge to inform how cells communicate. Expected outcomes include knowledge of broad significance to cell biology, that can be leveraged to develop extracellular vesicles as tools for various biotechnology applications in the future.Read moreRead less
Defining how cells relay mechanical signals to changes in cell architecture. Mechanical signals play crucial roles in shaping organs and entire organisms during development, though how these signals are relayed to changes in cell architecture is a major unanswered question. Within vascular networks, mechanical signals including fluid flow, tension and stretch play key roles in vessel patterning, identity and maturation. This application aims to employ cutting-edge technologies to determine how t ....Defining how cells relay mechanical signals to changes in cell architecture. Mechanical signals play crucial roles in shaping organs and entire organisms during development, though how these signals are relayed to changes in cell architecture is a major unanswered question. Within vascular networks, mechanical signals including fluid flow, tension and stretch play key roles in vessel patterning, identity and maturation. This application aims to employ cutting-edge technologies to determine how the atypical cadherin FAT4 relays mechanical signals including flow and tension to the lymphatic endothelial cell skeleton, thereby enabling changes in cell shape important for building lymphatic vessels. This project will increase our understanding of how cells sense touch and may be applied for tissue engineering purposes.
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The molecular interactome and functions of circular RNAs. This project aims to identify the functions of circular RNAs, the most contemporary and enigmatic family of RNA molecules. While their abundance suggests they are important, it is unclear how they function at the molecular level. This project aims to delineate circular RNA function by systematically identifying their interacting partners at the DNA, RNA and protein levels, the so-called molecular interactome. This project will reprogram e ....The molecular interactome and functions of circular RNAs. This project aims to identify the functions of circular RNAs, the most contemporary and enigmatic family of RNA molecules. While their abundance suggests they are important, it is unclear how they function at the molecular level. This project aims to delineate circular RNA function by systematically identifying their interacting partners at the DNA, RNA and protein levels, the so-called molecular interactome. This project will reprogram embryonic stem cells to model developmental processes and is designed to validate circular RNA research. Together, the benefits include a higher-quality research workforce by mentoring students, refining fundamental tenets of RNA biology and may extend to improving health in the long-term.Read moreRead less
Normal heart development before birth. This project aims to understand how the fetal heart can develop normally with much less oxygen than an adult heart uses. Regulation of fetal heart proliferation is not well understood but changes in oxygen levels and non-coding RNAs are implicated. Using advanced imaging techniques to measure blood flow in blood vessels to the fetal heart and molecular probes to assess cell function and microarrays to measure non-coding RNA, the project expects to generate ....Normal heart development before birth. This project aims to understand how the fetal heart can develop normally with much less oxygen than an adult heart uses. Regulation of fetal heart proliferation is not well understood but changes in oxygen levels and non-coding RNAs are implicated. Using advanced imaging techniques to measure blood flow in blood vessels to the fetal heart and molecular probes to assess cell function and microarrays to measure non-coding RNA, the project expects to generate new knowledge about mechanisms of fetal heart cell proliferation. Ultimately, this new knowledge could lead to non-invasive approaches to detect and treat abnormal fetal heart growth in animals and humans.Read moreRead less
How do mechanical cues regulate tissue renewal and tumour progression? Imbalances between cell production and cell death in tissues can be catastrophic, leading to major global health issues such as cancer. This project will use modified mice and protein-protein interaction based techniques to identify how changes in the mechanical properties of tissues regulate the balance between cell production and cell death.
TREX-mediated nuclear mRNA export in neuronal differentiation and function. This project aims to study nucleus-to-cytoplasm information flow and the cellular toolbox required for this process. To ensure competitive growth and survival, plant and animal cells have sophisticated mechanisms of information transfer. One such process is efficient export of molecules from the cell nucleus (the coding space) to the cell cytoplasm (the protein synthesis space). This project will use a cell-based system ....TREX-mediated nuclear mRNA export in neuronal differentiation and function. This project aims to study nucleus-to-cytoplasm information flow and the cellular toolbox required for this process. To ensure competitive growth and survival, plant and animal cells have sophisticated mechanisms of information transfer. One such process is efficient export of molecules from the cell nucleus (the coding space) to the cell cytoplasm (the protein synthesis space). This project will use a cell-based system that can precisely control different aspects of the toolbox performance to understand this process. The knowledge and resources generated can be used to develop products or services with tangible economic and health benefits.Read moreRead less
Regulation of autophagy dependent cell and tissue deletion. This project aims to elucidate novel mechanisms that regulate autophagy-depdendent cell death during animal development. It will combine the power of Drosophila genetics with multidisciplinary approaches, such as proteomics, bioinformatics and cell biology. Given the conserved nature of autophagy the oucomes will provide highly topical and exciting new knowledge of broad biological significance. The project will help establishing inter ....Regulation of autophagy dependent cell and tissue deletion. This project aims to elucidate novel mechanisms that regulate autophagy-depdendent cell death during animal development. It will combine the power of Drosophila genetics with multidisciplinary approaches, such as proteomics, bioinformatics and cell biology. Given the conserved nature of autophagy the oucomes will provide highly topical and exciting new knowledge of broad biological significance. The project will help establishing international collaborations, enhancing Australia’s competitiveness and reputation in an important area of research, and provide training of HDR students in skills across a range of areas. In the long-term the research findings may translate into improved agriculture, food production and human health outcomes.Read moreRead less