Pathogen recognition and plant-defence activation by a novel Fusarium wilt-resistance protein from tomato. The devastating effects of Fusarium wilt disease of tomato is a threat to one of Australia's most economically important horticultural crops. Resistant tomato varieties offer the most effective means of control but the fundamental mechanisms underlying this resistance are yet to be understood. This research will increase our understanding of resistance to Fusarium wilt disease. The knowledg ....Pathogen recognition and plant-defence activation by a novel Fusarium wilt-resistance protein from tomato. The devastating effects of Fusarium wilt disease of tomato is a threat to one of Australia's most economically important horticultural crops. Resistant tomato varieties offer the most effective means of control but the fundamental mechanisms underlying this resistance are yet to be understood. This research will increase our understanding of resistance to Fusarium wilt disease. The knowledge gained will assist in the development of new robust, sustainable approaches to disease control, as well as the development of pre-emptive strategies to avert major outbreaks, which will ensure reliable productivity and minimal economic losses into the future.Read moreRead less
Translocation of secreted effector proteins from fungal pathogens into host plant cells. Every year, fungal diseases of plants cause huge losses in agricultural productivity and extensive environmental damage in Australia. Disease control in major crops, like wheat, currently relies heavily on breeding for disease resistance. However, fungal pathogens continually adapt to overcome plant defences, necessitating identification of new sources of resistance. The research in this project will eluc ....Translocation of secreted effector proteins from fungal pathogens into host plant cells. Every year, fungal diseases of plants cause huge losses in agricultural productivity and extensive environmental damage in Australia. Disease control in major crops, like wheat, currently relies heavily on breeding for disease resistance. However, fungal pathogens continually adapt to overcome plant defences, necessitating identification of new sources of resistance. The research in this project will elucidate the molecular basis of a new aspect of the establishment of plant infection by fungi, and in so doing will provide new avenues for the development of novel disease resistance strategies, with relevance in particular to devastating cereal diseases like wheat rust.Read moreRead less
Role of fungal secreted proteins as plant disease effectors. Many crop diseases are economically significant threats to agricultural productivity in Australia, with rust fungi in particular being a major problem for cereal grain production. Current methods of rust disease control are based on breeding for resistance but continued adaption by rust fungi to overcome plant defences means there is an urgent need for new methods of crop protection. This project will investigate molecular processes ....Role of fungal secreted proteins as plant disease effectors. Many crop diseases are economically significant threats to agricultural productivity in Australia, with rust fungi in particular being a major problem for cereal grain production. Current methods of rust disease control are based on breeding for resistance but continued adaption by rust fungi to overcome plant defences means there is an urgent need for new methods of crop protection. This project will investigate molecular processes underlying fungal infection of plants, focusing on mechanisms that enable fungi to take over the metabolism of infected cells. The research will provide basic knowledge for development of novel and durable disease resistance strategies.Read moreRead less
Establishing the role of heterotrimeric G-proteins in plant defence. Agriculture is an important economic activity in Australia that resulting in considerable export revenues. Agricultural losses caused by plant pathogens account for millions of dollars every year and have profound economic and social implications.
The proposed research will explore new approaches to increase plant resistance to pathogens using a previously unkown component of this network: G-proteins and could ultimately reduc ....Establishing the role of heterotrimeric G-proteins in plant defence. Agriculture is an important economic activity in Australia that resulting in considerable export revenues. Agricultural losses caused by plant pathogens account for millions of dollars every year and have profound economic and social implications.
The proposed research will explore new approaches to increase plant resistance to pathogens using a previously unkown component of this network: G-proteins and could ultimately reduce dependency on toxic chemical products.Read moreRead less
Characterisation Of A New Family Of Proteins Involved In Cell Signalling, RNA Metabolism And Cancer
Funder
National Health and Medical Research Council
Funding Amount
$200,880.00
Summary
We have discovered a novel RNA-binding protein (G3BP-2) that is involved in responding to external signals, such as growth factors, at the level of gene expression. Other RNA-binding proteins belonging to the same broad group of proteins are responsible for a host of disease states in mammals including mental retardation, myotonic dystrophy, Huntington?s disease and cancers. Considering the wealth of knowledge accumulated that implicates these proteins to human dysfunction surprisingly few of th ....We have discovered a novel RNA-binding protein (G3BP-2) that is involved in responding to external signals, such as growth factors, at the level of gene expression. Other RNA-binding proteins belonging to the same broad group of proteins are responsible for a host of disease states in mammals including mental retardation, myotonic dystrophy, Huntington?s disease and cancers. Considering the wealth of knowledge accumulated that implicates these proteins to human dysfunction surprisingly few of these RNA-binding proteins have been identified. We have shown that the novel protein discovered in our laboratory is perturbed in cancer and we are interested in characterising its putative role in cancer. The results established in our laboratory so far would indicate that generally, G3BP-2 is expressed in normal tissue and it expression changes in some cancers studied so far. Considering that G3BP-2 lies in a pathway known to be involved in cancer progression it is important to understand what effects the inappropriate expression of G3BP-2 may have on cancer progression and survival. This project is designed to characterise what signals the cell uses to control these proteins and in turn which genes these may effect. In this way we may be able to determine how external signals may effect tumour progression and on what genes this influence is expressed. It would be hoped that this project would increase our understanding of cancer and potentially lead to new diagnostic reagents and therapies in the treatment of cancer.Read moreRead less
A novel link between plant pathogen defence and DNA repair capability. Plants and plant-based industries are essential for the provision of food, clothing and building materials and underpin the economies of rural communities. Plant yield and quality and the biodiversity of natural systems are dramatically reduced by disease. The fundamental knowledge gained from our research will enable manipulation of the factors that enhance disease resistance resulting in a significant benefit to Australian ....A novel link between plant pathogen defence and DNA repair capability. Plants and plant-based industries are essential for the provision of food, clothing and building materials and underpin the economies of rural communities. Plant yield and quality and the biodiversity of natural systems are dramatically reduced by disease. The fundamental knowledge gained from our research will enable manipulation of the factors that enhance disease resistance resulting in a significant benefit to Australian agriculture and protection of our natural resources. The current reliance for disease control on chemicals that damage the environment will be reduced and our research will contribute directly to the provision of cheaper, simpler and more effective methods of control.
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Biogenesis of secretory organelles and the function of adhesins secreted during the establishment of plant disease. Many agriculturally important crops and Australian native plants are susceptible to diseases caused by species of Phytophthora, a fungus-like organism that lives in the soil. Economic losses due to Phytophthora diseases are estimated to exceed $200 million per annum and the scale of environmental damage in natural ecosystems is huge. Currently, control of Phytophthora diseases la ....Biogenesis of secretory organelles and the function of adhesins secreted during the establishment of plant disease. Many agriculturally important crops and Australian native plants are susceptible to diseases caused by species of Phytophthora, a fungus-like organism that lives in the soil. Economic losses due to Phytophthora diseases are estimated to exceed $200 million per annum and the scale of environmental damage in natural ecosystems is huge. Currently, control of Phytophthora diseases largely depends on a very small number of effective chemicals and there is an imminent risk of the development of pathogen resistance. This research will increase our understanding of how Phytophthora spores infect host plants and will identify suitable targets for the development of novel, environmentally safe chemicals that inhibit disease development.Read moreRead less
Regulation Of The Tumour Suppressors APC And BRCA1 By Nuclear Export
Funder
National Health and Medical Research Council
Funding Amount
$530,874.00
Summary
Cancer cells lack the ability to control their own growth, and thus continously divide in their local environment, leading to tumour formation. Tumour suppressor proteins, like APC and BRCA1, normally function as regulators to help cells respond to outside signals and to stop growing when necessary. The inactivation and altered cellular localisation of tumour suppressor proteins can contribute to cancer development. We have found that the APC and BRCA1 proteins, whose inactivation leads to devel ....Cancer cells lack the ability to control their own growth, and thus continously divide in their local environment, leading to tumour formation. Tumour suppressor proteins, like APC and BRCA1, normally function as regulators to help cells respond to outside signals and to stop growing when necessary. The inactivation and altered cellular localisation of tumour suppressor proteins can contribute to cancer development. We have found that the APC and BRCA1 proteins, whose inactivation leads to development of colon cancer and breast cancer, respectively, contain signals that dictate their movement within the cell. Our novel preliminary findings reveal that APC and BRCA1 are able to move in and out of the cell nucleus. We aim to define how this occurs, and examine how the regulation of their cellular location affects the normal function of these cancer-suppressing proteins. Finally, abnormalities in the nuclear passage of APC or BRCA1 might explain their altered cellular location in cancer cells.Read moreRead less
Regulated Shuttling Of Beta-catenin And IQGAP1 Between Nucleus And Plasma Membrane In Migrating Cells
Funder
National Health and Medical Research Council
Funding Amount
$511,703.00
Summary
Inherited gene mutations that cause colon cancer kill 4,700 Australians every year. About 1 in 21 Australians develop colorectal cancer by age 75. Activation of the beta-catenin protein is a critical switch in the path to colon cancer. We discovered that beta-catenin, and another protein it interacts with called IQGAP1, move between different cellular compartments. We plan to study this process in more detail, as it relates to how beta-catenin works and to understanding its role in cancer.
Targeting of lipid transfer proteins and other secreted plant defence proteins by pathogen effectors. Australia depends on plant products for much of its export income and plant diseases are a continual threat to these earnings. New insights into plant disease resistance mechanisms will provide new opportunities to find solutions to disease problems. Often this involves transfer of knowledge gained in simple model plant systems to more complicated crop plant systems. Work on the role of lipid tr ....Targeting of lipid transfer proteins and other secreted plant defence proteins by pathogen effectors. Australia depends on plant products for much of its export income and plant diseases are a continual threat to these earnings. New insights into plant disease resistance mechanisms will provide new opportunities to find solutions to disease problems. Often this involves transfer of knowledge gained in simple model plant systems to more complicated crop plant systems. Work on the role of lipid transfer proteins in the tomato model system will advance our knowledge of fundamental disease and disease resistance processes and ultimately enable technological innovations to improve disease resistance, reduce pesticide usage and lower crop production costs.Read moreRead less