Probing the four photosynthetic membrane protein complexes at work in situ in leaves. This proposal aims at sustainable improvements in plant productivity and photosynthetic adaptation in drastic Australian climates. In photosynthesis, membranes with the four multiprotein complexes use sunlight to make compounds that drive carbon assimilation. Instead of the usual dissection of photosynthetic membranes, this project will develop and refine the applicant's rapid, reliable, non-intrusive technique ....Probing the four photosynthetic membrane protein complexes at work in situ in leaves. This proposal aims at sustainable improvements in plant productivity and photosynthetic adaptation in drastic Australian climates. In photosynthesis, membranes with the four multiprotein complexes use sunlight to make compounds that drive carbon assimilation. Instead of the usual dissection of photosynthetic membranes, this project will develop and refine the applicant's rapid, reliable, non-intrusive techniques to probe the four membrane complexes at work in their native state in leaves. Two portable commercial instruments will potentially emerge from the techniques. This novel non-reductionist approach will identify key limitations to photosynthetic performance under stress, and insights into improvements for primary plant productivity.Read moreRead less
Control of actin assembly by cell-cell adhesion: molecular effectors and higher order function. Functional cooperation between the actin cytoskeleton and cadherin cell-cell adhesion molecules plays critical roles during development and morphogenesis. This proposal builds on my lab's recent discovery that E-cadherin interacts with and regulates the Arp2/3 actin nucleator complex, a central determinant of actin assembly in cells. We will explore key implications of this finding, concentrating on d ....Control of actin assembly by cell-cell adhesion: molecular effectors and higher order function. Functional cooperation between the actin cytoskeleton and cadherin cell-cell adhesion molecules plays critical roles during development and morphogenesis. This proposal builds on my lab's recent discovery that E-cadherin interacts with and regulates the Arp2/3 actin nucleator complex, a central determinant of actin assembly in cells. We will explore key implications of this finding, concentrating on defining the molecular mechanisms that regulate Arp2/3 and actin assembly in cadherin-based adhesion. Our work combines molecular characterization of regulatory mechanisms and proteomic searches for new regulators, with tests of the higher-order function of this novel process in cell adhesion and recognition.Read moreRead less
Balancing cadherin-actin cooperation: the key regulatory role of Ena/VASP proteins. This project analyses a fundamental mechanism of how cells work together in tissues. Understanding the fundamental mechanisms of how cells work will provide important basic scientific information to enrich the scientific expertise in Australia and its part in the international community, generate insights relevant for understanding human disease and physical degeneration, and support the training of young scienti ....Balancing cadherin-actin cooperation: the key regulatory role of Ena/VASP proteins. This project analyses a fundamental mechanism of how cells work together in tissues. Understanding the fundamental mechanisms of how cells work will provide important basic scientific information to enrich the scientific expertise in Australia and its part in the international community, generate insights relevant for understanding human disease and physical degeneration, and support the training of young scientists in Australia.Read moreRead less
The cellulose synthase complex of the Arabidopsis primary cell wall. The polysaccharide cellulose is the basis for the wood and cotton fibre industries of Australia and much of our research on the mechanism of synthesis has been supported by those industries over the past decade. The present project focuses on the proteins making cellulose and how they organised into functional complexes that are able to make cellulose. The knowledge it provides, together with that from other projects, will move ....The cellulose synthase complex of the Arabidopsis primary cell wall. The polysaccharide cellulose is the basis for the wood and cotton fibre industries of Australia and much of our research on the mechanism of synthesis has been supported by those industries over the past decade. The present project focuses on the proteins making cellulose and how they organised into functional complexes that are able to make cellulose. The knowledge it provides, together with that from other projects, will move us towards the situation where we can manipulate the rate at which cellulose is produced and change its detailed properties. This opens the way to industry producing fibres with more desirable properties and producing novel cellulose-based materials tailored to specific applications.Read moreRead less
Functional Genomic Analysis of Exported DNAJ Molecules in the Malaria Parasite Plasmodium falciparum. Malaria is not only a global health problem, but also affects countries surrounding Australia like PNG and Indonesia, reducing the region's stability and prosperity. Environmental changes and increased mobility of people (eg. aid and security personnel) make Australia itself more prone to malaria. The project will translate recent genomic data into functional insights using frontier technology t ....Functional Genomic Analysis of Exported DNAJ Molecules in the Malaria Parasite Plasmodium falciparum. Malaria is not only a global health problem, but also affects countries surrounding Australia like PNG and Indonesia, reducing the region's stability and prosperity. Environmental changes and increased mobility of people (eg. aid and security personnel) make Australia itself more prone to malaria. The project will translate recent genomic data into functional insights using frontier technology to identify new intervention targets for P. falciparum infection. Developing novel targets is mandated by humanity, and also to safeguard Australia's region against the social and economical implication of this disease. An Australian developed intervention would increase the global visibility of its science, leading to increased investments.Read moreRead less
Sugar transporters in coral symbiosis and origin of parasitism. We aim to identify how symbiotic algae feed sugar to their coral hosts. Corals need this algal sugar to exist, but no one knows how it is transferred, so understanding this crucial mechanism is hugely significant. The first benefit of this research will be a fundamental understanding about how two organisms (algae and coral) cooperate to build habitats like the Great Barrier Reef. We also aim to explore whether coral/algal coopera ....Sugar transporters in coral symbiosis and origin of parasitism. We aim to identify how symbiotic algae feed sugar to their coral hosts. Corals need this algal sugar to exist, but no one knows how it is transferred, so understanding this crucial mechanism is hugely significant. The first benefit of this research will be a fundamental understanding about how two organisms (algae and coral) cooperate to build habitats like the Great Barrier Reef. We also aim to explore whether coral/algal cooperation paved the way for the origin of parasitism. The second key outcome will be to identify the precise molecular mechanism that allowed parasitism to arise. This will benefit us through understanding the origins of important diseases such as human malaria and related infections of livestock and wildlife.
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Investigation of a Phagocytic Synapse in the Uptake of Apoptotic Cells. Rapid clearance of cells that die by apoptosis is crucial for embryonic development, tissue turnover, and after inflammatory events. Specialised phagocytes engulf the apoptotic cell corpses in a way that minimises inflammation and prevents autoimmunity. Genetic studies have identified the key evolutionary receptors involved, but the molecular basis of this phagocytosis is still poorly understood. We have developed, and seek ....Investigation of a Phagocytic Synapse in the Uptake of Apoptotic Cells. Rapid clearance of cells that die by apoptosis is crucial for embryonic development, tissue turnover, and after inflammatory events. Specialised phagocytes engulf the apoptotic cell corpses in a way that minimises inflammation and prevents autoimmunity. Genetic studies have identified the key evolutionary receptors involved, but the molecular basis of this phagocytosis is still poorly understood. We have developed, and seek to establish, an integrated model that incorporates new findings to explain how the distinctive functions of specialised receptors can be orchestrated to achieve this function. A successful outcome to the project will provide new knowledge of value to human health.Read moreRead less
A Structural Investigation Into Events Within The Immunological Synapse. The proposed research program, using laboratory-based and synchrotron-based radiation, will provide significant fundamental insight into the processes that control infection. Investigating processes central to immunity is important, as it will further our understanding of these critically-important events. Such knowledge will increase Australia's international research standing, as well as having the potential to generat ....A Structural Investigation Into Events Within The Immunological Synapse. The proposed research program, using laboratory-based and synchrotron-based radiation, will provide significant fundamental insight into the processes that control infection. Investigating processes central to immunity is important, as it will further our understanding of these critically-important events. Such knowledge will increase Australia's international research standing, as well as having the potential to generate novel therapies, such as immunosuppressants.Read moreRead less
Adrenomedullin: a specific regulator of venous vessel integrity. Arteries and veins display different adhesive properties, which enable them to fulfil their physiological roles. We are yet to understand the mechanisms that establish and maintain adhesive function in different vessel types. We have discovered that signalling by the peptide Adrenomedullin (ADM) is a key mediator of adhesion, only in veins but not arteries. This project aims to utilise innovative models (zebrafish, mouse and bioeng ....Adrenomedullin: a specific regulator of venous vessel integrity. Arteries and veins display different adhesive properties, which enable them to fulfil their physiological roles. We are yet to understand the mechanisms that establish and maintain adhesive function in different vessel types. We have discovered that signalling by the peptide Adrenomedullin (ADM) is a key mediator of adhesion, only in veins but not arteries. This project aims to utilise innovative models (zebrafish, mouse and bioengineered vessels) to identify the biochemical and mechanical mechanisms by which ADM controls venous adhesion. Outcomes will improve our understanding on how vessel integrity is controlled across vessel types and will expand the scope of Australian research by informing efforts to vascularise engineered tissues.Read moreRead less
Molecular basis of the antimicrobial activity of the floral defensin, NaD1, for the plant pathogen Fusarium oxysporum. Filamentous fungi are responsible for many major plant diseases that result in devastating crop losses and food spoilage world wide. Currently there are no resistant cultivars or adequate chemical controls for many of these diseases. The plant defensin, NaD1, stops the growth of many pathogens, including the recalcitrant fungi Fusarium oxysporum and Botrytis cinerea, and has bee ....Molecular basis of the antimicrobial activity of the floral defensin, NaD1, for the plant pathogen Fusarium oxysporum. Filamentous fungi are responsible for many major plant diseases that result in devastating crop losses and food spoilage world wide. Currently there are no resistant cultivars or adequate chemical controls for many of these diseases. The plant defensin, NaD1, stops the growth of many pathogens, including the recalcitrant fungi Fusarium oxysporum and Botrytis cinerea, and has been shown to protect transgenic cotton against fungal infection in glasshouse and field trials. NaD1 has potential application for durable, broad spectrum fungal disease control in crops. This will lead to both environmental and economic benefits to Australia. Read moreRead less