Structural studies of plant disease resistance proteins. Plant cells have evolved a gene-for-gene disease resistance mechanism, involving an interaction of a plant-derived receptor with a specific pathogen-derived molecule. Currently, plant breeders are restricted to the resistance genes available in particular crop species or sexually compatible relatives. In the last few years, several plant disease resistance genes have been identified, providing a foundation for studying the molecular basis ....Structural studies of plant disease resistance proteins. Plant cells have evolved a gene-for-gene disease resistance mechanism, involving an interaction of a plant-derived receptor with a specific pathogen-derived molecule. Currently, plant breeders are restricted to the resistance genes available in particular crop species or sexually compatible relatives. In the last few years, several plant disease resistance genes have been identified, providing a foundation for studying the molecular basis of the resistance process. We propose to obtain three-dimensional structural information on representative R proteins and their ligand complexes. This will form the basis for modifying existing resistance genes to confer resistance to new diseases, resulting in large economic benefits.Read moreRead less
Reverse chemical proteomics: harnessing yeast display for drug discovery. This project aims to develop a technique that can rapidly identify the cellular protein targets of biologically active natural products. This project expects to provide fundamental biological and chemical insights into Australia's unique biodiversity that will facilitate the development of new therapeutic agents and agrochemicals based on leads provided by Nature. Expected outcomes of this project include an optimised and ....Reverse chemical proteomics: harnessing yeast display for drug discovery. This project aims to develop a technique that can rapidly identify the cellular protein targets of biologically active natural products. This project expects to provide fundamental biological and chemical insights into Australia's unique biodiversity that will facilitate the development of new therapeutic agents and agrochemicals based on leads provided by Nature. Expected outcomes of this project include an optimised and validated platform technology for accelerating drug discovery and development. This should substantially reduce the costs associated with fighting human and animal diseases, leading to improved health, productivity and quality of life.Read moreRead less
Molecular basis of the interaction between plant disease resistance proteins and pathogen avirulence proteins. Management of crop diseases involves the integrated use of resistant cultivars and the application of chemical pesticides. Many diseases, however, including rust, continue to pose an economically significant threat to agricultural productivity in Australia. The research outlined in this proposal aims to understand the mechanisms, at a molecular and structural level, that enable resistan ....Molecular basis of the interaction between plant disease resistance proteins and pathogen avirulence proteins. Management of crop diseases involves the integrated use of resistant cultivars and the application of chemical pesticides. Many diseases, however, including rust, continue to pose an economically significant threat to agricultural productivity in Australia. The research outlined in this proposal aims to understand the mechanisms, at a molecular and structural level, that enable resistant plants to detect and respond to pathogen attack. The outcomes of this currently unavailable fundamental understanding will enable new, durable and more effective resistance genes to be engineered. Therefore, the work has significant economic and environmental implications for agricultural crop plant productivity in this country.Read moreRead less
TRANSCRIPTIONAL AND FUNCTIONAL CONSEQUENCES OF STAT3 ACTIVATION IN THE HEART
Funder
National Health and Medical Research Council
Funding Amount
$413,694.00
Summary
Recent statistics show that the disease known commonly as heart failure accounts for about 3000 deaths each year in Australia. Worldwide, a staggering 10 million people are thought to currently suffer from heart failure, with this number continuing to rise despite decreasing numbers of people suffering from other forms of heart and blood vessel disease. What causes a healthy heart to fail remains unclear, although in some circumstances failure is known to be initiated by genetic factors, viral f ....Recent statistics show that the disease known commonly as heart failure accounts for about 3000 deaths each year in Australia. Worldwide, a staggering 10 million people are thought to currently suffer from heart failure, with this number continuing to rise despite decreasing numbers of people suffering from other forms of heart and blood vessel disease. What causes a healthy heart to fail remains unclear, although in some circumstances failure is known to be initiated by genetic factors, viral factors, alcoholism, high blood pressure, or when the heart is damaged in a heart attack. We are interested in the molecular mechanisms that underlie the progression of the normal heart to failure. In 2003 we reported on altered signalling pathways in the failing human heart, and noted the increased phosphorylation of a spliceform of the transcription factor STAT3 in patients with heart failure. In this project, we will evaluate a larger group of heart failure patients for changes in phosphorylation of their STAT3 proteins. We will also increase the expression of an activated form of the STAT3 proteins in rat heart cells, and check whether there are accompanying changes in gene expression profiles that indicate a potential role in heart failure, or whether these cells are now predisposed to die. This will be extended with the use of transgenic animals (mice) engineered to overexpress activated STAT3 proteins. Again, we will focus on gene expression profiles. We will also evaluate whether the hearts of these animals are more likely to fail, either as the animals age, or when external stresses are experienced. With this information, we will be able to state whether STAT3 is a contributor to heart failure, and therefore whether it is an attractive target for future therapies aimed at reducing the morbidity and mortality of heart failure worldwide.Read moreRead less
Biosynthesis and functions of two phytotoxins in Septoria nodorum blotch. This project aims to investigate how a fungal plant pathogen makes and uses small bioactive molecules to facilitate infection. It will characterise the function of the genes and enzymes involved in the biosynthesis of a light-activated phytotoxic molecule and a potential anti-plant defence molecule found in the pathogenic wheat fungus Parastagonospora nodorum, and investigate their contribution to disease development. Expe ....Biosynthesis and functions of two phytotoxins in Septoria nodorum blotch. This project aims to investigate how a fungal plant pathogen makes and uses small bioactive molecules to facilitate infection. It will characterise the function of the genes and enzymes involved in the biosynthesis of a light-activated phytotoxic molecule and a potential anti-plant defence molecule found in the pathogenic wheat fungus Parastagonospora nodorum, and investigate their contribution to disease development. Expected outcomes include better understanding of plant-microbe interactions, disease management strategies, technologies for identifying biosynthetic pathways in other fungi, and enzyme technology for synthesising molecules. This could lead to new herbicides, biopesticides and drugs.Read moreRead less
Fungal Ribosomally Synthesised and Post-translationally Modified Peptides. Fungi produce an array of molecules called secondary metabolites (SMs) that impact on everyday life (e.g. penicillin). This project aims to investigate a new class of fungal peptide SMs called RiPPs which are structurally unique from existing molecules and offer the exciting prospect of harbouring new and novel biological activities. This project expects to discover the mechanisms of RiPP synthesis and their biological ro ....Fungal Ribosomally Synthesised and Post-translationally Modified Peptides. Fungi produce an array of molecules called secondary metabolites (SMs) that impact on everyday life (e.g. penicillin). This project aims to investigate a new class of fungal peptide SMs called RiPPs which are structurally unique from existing molecules and offer the exciting prospect of harbouring new and novel biological activities. This project expects to discover the mechanisms of RiPP synthesis and their biological roles in plant pathogenic fungi, and uncover and engineer novel RiPPs with desired bioactivities. The expected outcome from this project will be a seminal advance in fungal SM biology which should provide significant benefits through the generation of exciting new lead molecules for the agricultural and medical industries.Read moreRead less
Development of new herbicides targeting enzymes involved in the biosynthesis of branched-chain amino acids. Modern agriculture is heavily reliant on the use of herbicides. An inevitable consequence of herbicide usage is that resistant weeds will develop. Therefore, there is a continuing need to develop new herbicides to kill these resistant species. Herbicides interact with vulnerable molecular targets in plants, such as photosynthesis or the biosynthesis of certain amino acids. This project wil ....Development of new herbicides targeting enzymes involved in the biosynthesis of branched-chain amino acids. Modern agriculture is heavily reliant on the use of herbicides. An inevitable consequence of herbicide usage is that resistant weeds will develop. Therefore, there is a continuing need to develop new herbicides to kill these resistant species. Herbicides interact with vulnerable molecular targets in plants, such as photosynthesis or the biosynthesis of certain amino acids. This project will attempt to develop new herbicides that act upon two molecular targets that are not exploited by herbicides that are used currently. We will design, synthesize and test a variety of new compounds as potential environmentally-benign herbicides.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
Design and evaluation of new environmentally-benign herbicides that inhibit branched-chain amino acid biosynthesis. Herbicides interfere with processes that occur in plants, such as photosynthesis or the biosynthesis of certain amino acids. In this project we will focus on branched-chain amino acid biosynthesis, designing and evaluating inhibitors of the first two enzymes in this process. Based on their three dimensional structures we will develop an understanding of the molecular features that ....Design and evaluation of new environmentally-benign herbicides that inhibit branched-chain amino acid biosynthesis. Herbicides interfere with processes that occur in plants, such as photosynthesis or the biosynthesis of certain amino acids. In this project we will focus on branched-chain amino acid biosynthesis, designing and evaluating inhibitors of the first two enzymes in this process. Based on their three dimensional structures we will develop an understanding of the molecular features that contribute to a potent inhibitor and those that are required for it to be effective upon plants. Using this information we will design and synthesis new compounds as potential environmentally-benign herbicides.Read moreRead less
CRISPR-based pathway activation for bioactive molecule discovery in fungi. Fungi produce an incredible array of unique bioactive molecules, many of which have contributed greatly to humanity (e.g. the antibiotic penicillin, which has saved millions of lives since its discovery). DNA sequencing has revealed many fungi contain the genetic instructions to produce new molecules that have not been seen previously. However, these genes are “switched off" by default and cannot be accessed. This project ....CRISPR-based pathway activation for bioactive molecule discovery in fungi. Fungi produce an incredible array of unique bioactive molecules, many of which have contributed greatly to humanity (e.g. the antibiotic penicillin, which has saved millions of lives since its discovery). DNA sequencing has revealed many fungi contain the genetic instructions to produce new molecules that have not been seen previously. However, these genes are “switched off" by default and cannot be accessed. This project will develop innovative new methods to "hot-wire" these genes, allowing them to turn on and produce a treasure trove of new bioactive molecules. The outcomes of this project will transform our abilities to tap into the hidden potential of fungi to generate new lead molecules for the agricultural and medical industries.Read moreRead less