This program of research is firmly focussed on the basic mechanisms involved in normal functioning of cells and tissues, followed by a step by step process to understand the abnormal or the diseased. The disease states we are investigating involve the blood and blood vessels, and when there is malfunction it may contribute to conditions as diverse as atherosclerosis, thrombosis, inflammation and cancer. The program thus addresses the fundamentals of diseases which are responsible for most deaths ....This program of research is firmly focussed on the basic mechanisms involved in normal functioning of cells and tissues, followed by a step by step process to understand the abnormal or the diseased. The disease states we are investigating involve the blood and blood vessels, and when there is malfunction it may contribute to conditions as diverse as atherosclerosis, thrombosis, inflammation and cancer. The program thus addresses the fundamentals of diseases which are responsible for most deaths in our society. We will use technology which is proven to provide precise information, the molecular and biochemical processes responsible for cell function (or malfunction). However in each individual project there will be a clear path to a clinical use, diagnostic or therapeutic. Indeed in a number of the components of the program there are already potential treatments and diagnostics in development and trial.Read moreRead less
Selective secretion: a novel mechanism of protein trafficking and its role in Phytophthora pathogenicity. Agriculturally important crops and over 3,000 Australian native plants are susceptible to diseases caused by Phytophthora, fungus-like pathogens that live in the soil. Economic losses exceed $200m pa and natural ecosystems are being destroyed on a vast scale. Phytophthora control depends upon a limited number of chemical inhibitors to which resistance has already emerged. New control stra ....Selective secretion: a novel mechanism of protein trafficking and its role in Phytophthora pathogenicity. Agriculturally important crops and over 3,000 Australian native plants are susceptible to diseases caused by Phytophthora, fungus-like pathogens that live in the soil. Economic losses exceed $200m pa and natural ecosystems are being destroyed on a vast scale. Phytophthora control depends upon a limited number of chemical inhibitors to which resistance has already emerged. New control strategies are urgently needed. This research will investigate a novel mechanism for release of infection material recently discovered in Phytophthora cells, and will increase our understanding of how Phytophthora infects host plants, providing vital information required for the development of new, environmentally-safe inhibitors. Read moreRead less
New methods for structure analysis of proteins and protein interactions. This project will advance nuclear magnetic resonance (NMR) technologies pioneered at the Australian National University which employ site-specific attachment of paramagnetic metal tags to proteins. A new and diverse set of strategies will dramatically extend the range of applications to targets of interest in the fight against cancer and bacterial infections.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883032
Funder
Australian Research Council
Funding Amount
$1,300,000.00
Summary
800 MHz NMR spectrometer for biomolecular structure-function analysis. An understanding of how organisms function at the molecular level is central to developing the ability to fight many diseases in a rational way. This equipment will provide the capability for many different laboratories around NSW and the ACT to advance our knowledge at this fundamental level, primarily by examining the structures and functions of biomolecules such as proteins.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0561173
Funder
Australian Research Council
Funding Amount
$207,189.00
Summary
High throughput proteomics - Thermo Finnigan ProteomeX LCQ Integrated Proteomics Workstation. As research in the biological sciences moves into post-genomics era, so attention has focused on the development of technologies capable of characterizing the molecular complexity inherent in the proteome. Recent technical innovations in this field have resulted in the advancement of mass spectrometers that are capable of exemplifying unknown proteins with great efficiency. These new technologies are ....High throughput proteomics - Thermo Finnigan ProteomeX LCQ Integrated Proteomics Workstation. As research in the biological sciences moves into post-genomics era, so attention has focused on the development of technologies capable of characterizing the molecular complexity inherent in the proteome. Recent technical innovations in this field have resulted in the advancement of mass spectrometers that are capable of exemplifying unknown proteins with great efficiency. These new technologies are central to any institution committed to the development of a competitive research nexus in biological sciences. The purpose of this application is to upgrade the mass spectrometry facility at the University of Newcastle such that it is able to provide cutting edge support to the extensive scientific community within the Hunter region.Read moreRead less
Protein degradation in mammals. One mechanism by which the regulation of protein turnover occurs is the balance between the activity of enzymes responsible for the ubiquitination and deubiquitination of target proteins. The majority of targets of this second family of enzymes are unknown. This project proposes a method for the identification of the targets of two specific mammalian deubiquitinating enzymes in order to understand their function and to begin to explore this new research field. ....Protein degradation in mammals. One mechanism by which the regulation of protein turnover occurs is the balance between the activity of enzymes responsible for the ubiquitination and deubiquitination of target proteins. The majority of targets of this second family of enzymes are unknown. This project proposes a method for the identification of the targets of two specific mammalian deubiquitinating enzymes in order to understand their function and to begin to explore this new research field. Knowledge about this new aspect of protein degradation could provide a powerful tool to test the effect of the stabilisation or removal of specific proteins in the cell and also to develop new technologies in protein production.Read moreRead less
Protein trafficking pathways in fungal rust pathogens of plants. This project aims to investigate protein trafficking pathways in fungal rusts of plants. These are devastating diseases that cause major losses in agricultural crops including wheat. Little is known of how these fungi form long and intimate relationships with plants to extract their nutrients. Using both model and agriculturally important fungi, the project will try to identify proteins that are transferred within the fungus and to ....Protein trafficking pathways in fungal rust pathogens of plants. This project aims to investigate protein trafficking pathways in fungal rusts of plants. These are devastating diseases that cause major losses in agricultural crops including wheat. Little is known of how these fungi form long and intimate relationships with plants to extract their nutrients. Using both model and agriculturally important fungi, the project will try to identify proteins that are transferred within the fungus and to the plant host to modify the infection. It will also identify fungal proteins needed to deliver trafficked proteins to plants. These discoveries ultimately may be translated into control strategies for these costly diseases.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.
Understanding the molecular basis of fungal rust diseases in plants. This project aims to utilise structural biology, biochemistry and molecular biology approaches to substantially deepen our understanding of rust fungi-plant interactions. Fungal rust pathogens cause disease and significant yield losses in our most important food crops. During colonisation, rust fungi utilise secreted effector proteins to cause plant disease. Effectors can also be recognised by plant immunity receptors, leading ....Understanding the molecular basis of fungal rust diseases in plants. This project aims to utilise structural biology, biochemistry and molecular biology approaches to substantially deepen our understanding of rust fungi-plant interactions. Fungal rust pathogens cause disease and significant yield losses in our most important food crops. During colonisation, rust fungi utilise secreted effector proteins to cause plant disease. Effectors can also be recognised by plant immunity receptors, leading to resistance. The intended outcome of this work is to generate knowledge that can be used for the development of disease management and engineering strategies to protect plants from rust fungi. This should provide significant benefits to agricultural productivity and global food security.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100323
Funder
Australian Research Council
Funding Amount
$431,000.00
Summary
Synthetic biology to engineer novel disease resistance in cereal crops. This project aims to engineer disease resistance in crops to dangerous fungal pathogens. The strategy is to exploit our knowledge of the plant immune system using structural biology and directed evolution of natural resistance genes, improving their ability to recognise and respond to fungal attack. Fungal pathogens cause some of the most harmful crop diseases in Australia and worldwide. The rapid evolution of fungi overcome ....Synthetic biology to engineer novel disease resistance in cereal crops. This project aims to engineer disease resistance in crops to dangerous fungal pathogens. The strategy is to exploit our knowledge of the plant immune system using structural biology and directed evolution of natural resistance genes, improving their ability to recognise and respond to fungal attack. Fungal pathogens cause some of the most harmful crop diseases in Australia and worldwide. The rapid evolution of fungi overcomes natural plant resistance and management of these diseases is a major challenge to agriculture. Expected outcomes of the project include engineered wheat plants with more effective disease resistance, reducing fungicide usage. This project intends to accelerate crop breeding and contribute to world food security.Read moreRead less