Understanding how dynamic changes in chromatin composition control genome function. DNA is tightly packaged in eukaryotic cells as chromatin. Important genetic processes, such as transcription, require manipulation of chromatin structure to access the DNA. The cell sets up specialised chromatin structures to regulate these processes. Currently, precise molecular details of these specialised structures are limited. This project will push the envelope of an in vitro model chromatin system and dete ....Understanding how dynamic changes in chromatin composition control genome function. DNA is tightly packaged in eukaryotic cells as chromatin. Important genetic processes, such as transcription, require manipulation of chromatin structure to access the DNA. The cell sets up specialised chromatin structures to regulate these processes. Currently, precise molecular details of these specialised structures are limited. This project will push the envelope of an in vitro model chromatin system and determine the architecture of several chromatin states with unique functional implications inside the cell. This will unravel the molecular instructions that define how our genomes are organised, significantly advancing our knowledge of fundamental eukaryotic genome biology and paving the way for the future development of new tools and therapies.Read moreRead less
Are flavonoids metabolic regulators of plant development? This project will investigate the mechanisms of action of flavonoids, which are abundant and diverse plant products contained in all fruits and vegetables. We have very little knowledge on the range of activities this large class of natural compounds has in plants. This research will investigate the role of flavonoids in regulating plant development to identify flavonoids and their target proteins and genes that could alter plant develo ....Are flavonoids metabolic regulators of plant development? This project will investigate the mechanisms of action of flavonoids, which are abundant and diverse plant products contained in all fruits and vegetables. We have very little knowledge on the range of activities this large class of natural compounds has in plants. This research will investigate the role of flavonoids in regulating plant development to identify flavonoids and their target proteins and genes that could alter plant development in specific ways to create improved crops. This project will also strengthen Australia's expertise in proteomics, an important tool for the advancement of knowledge and application in biotechnology.Read moreRead less
Dissecting a RNA-histone variant interaction and its role in splicing. This project aims to define the molecular details of how a chromatin component, histone H2A.B, binds RNA and influences RNA splicing. This is unprecedented for histones, which are typically associated with DNA and transcriptional regulation. Over 90 per cent of human genes may be alternatively spliced. This explains how complex organisms develop from a limited set of genes, but how alternative splicing decisions are made is u ....Dissecting a RNA-histone variant interaction and its role in splicing. This project aims to define the molecular details of how a chromatin component, histone H2A.B, binds RNA and influences RNA splicing. This is unprecedented for histones, which are typically associated with DNA and transcriptional regulation. Over 90 per cent of human genes may be alternatively spliced. This explains how complex organisms develop from a limited set of genes, but how alternative splicing decisions are made is unclear. The intended outcome is to reveal links between chromatin, RNA splicing and gene expression regulation to explain how multicellular organisms have evolved. The translation of this knowledge will ultimately provide long-term economic and health benefits for Australia.Read moreRead less
New Methods for Structural Biology in Solution. This project aims to expand the range of applications of nuclear magnetic resonance (NMR) spectroscopy in pharmaceutical research, where NMR spectroscopy is already used routinely for the identification of chemical compounds that bind to protein targets. The techniques developed aim at providing rapid and broadly applicable tools for 3D structure determinations of chemical compounds bound to their protein target, identification of protein-protein i ....New Methods for Structural Biology in Solution. This project aims to expand the range of applications of nuclear magnetic resonance (NMR) spectroscopy in pharmaceutical research, where NMR spectroscopy is already used routinely for the identification of chemical compounds that bind to protein targets. The techniques developed aim at providing rapid and broadly applicable tools for 3D structure determinations of chemical compounds bound to their protein target, identification of protein-protein interaction sites and characterization of protein motions. The limits of NMR spectroscopy will be pushed to analyse systems of significantly increased molecular weights. The project includes applications to drug targets such as the dengue virus NS2B/NS3 protease.Read moreRead less
Fluorine-labelled proteins for NMR spectroscopy. The technique developed in this project has direct impact on pharmaceutical research: NMR spectroscopy is used routinely to identify chemical compounds that bind to protein targets. This project includes the development of novel assignment techniques of 19F-labelled proteins, so that 19F-NMR can be used to detect specific binding interactions. One of the methods proposed here is designed to reveal structural information about the binding mode in s ....Fluorine-labelled proteins for NMR spectroscopy. The technique developed in this project has direct impact on pharmaceutical research: NMR spectroscopy is used routinely to identify chemical compounds that bind to protein targets. This project includes the development of novel assignment techniques of 19F-labelled proteins, so that 19F-NMR can be used to detect specific binding interactions. One of the methods proposed here is designed to reveal structural information about the binding mode in solution with atomic detail. This knowledge can significantly accelerate drug development. It is otherwise only available from crystal structures that can not always be determined.Read moreRead less
New Methods for Structural Biology in Solution. New technologies will be developed that are sufficiently rapid and inexpensive to compete with and replace the mutagenesis experiments that biologists usually perform to identify and characterize the functionally important parts of a protein. Nuclear magnetic resonance (NMR) spectroscopy techniques in combination with various selective labelling schemes will be developed with the goal of identification and structural characterization of protein-lig ....New Methods for Structural Biology in Solution. New technologies will be developed that are sufficiently rapid and inexpensive to compete with and replace the mutagenesis experiments that biologists usually perform to identify and characterize the functionally important parts of a protein. Nuclear magnetic resonance (NMR) spectroscopy techniques in combination with various selective labelling schemes will be developed with the goal of identification and structural characterization of protein-ligand interactions at increased rates and enhanced accuracy. In addition, the three-dimensional structures of proteins and protein domains of biologically important functions and unknown fold will be determined by NMR. The project aims at techniques of direct impact in pharmaceutical industry.Read moreRead less
Connecting soil nitrogen and plant uptake for greener agriculture. This project will use synthetic organic chemistry, biochemistry, root and rhizosphere biology and rhizosphere modelling to establish detailed mechanistic knowledge of the nitrogen (N) transport and uptake processes at the soil-root interface to develop new, efficient urease and nitrification inhibitors for reliable provision of N to the plant/root system. The reduction of excessive N fertilisation has significant environmental be ....Connecting soil nitrogen and plant uptake for greener agriculture. This project will use synthetic organic chemistry, biochemistry, root and rhizosphere biology and rhizosphere modelling to establish detailed mechanistic knowledge of the nitrogen (N) transport and uptake processes at the soil-root interface to develop new, efficient urease and nitrification inhibitors for reliable provision of N to the plant/root system. The reduction of excessive N fertilisation has significant environmental benefits by reducing greenhouse gas emissions and water pollution. This project will lead to a breakthrough for the triple challenge of food security, environmental degradation and climate change, while improving plant productivity and increasing the profitability of agriculture through lower fertiliser costs.Read moreRead less
Using the fractionation of hydrogen and carbon isotopes to analyse the mechanisms of the primary processes of photosynthesis. The primary processes of CO2 fixation and reduction in photosynthesis leave their signatures in the isotopic composition of organic matter. Although these signatures are used widely in geochemistry, biology and climatology to infer the dynamics and history of the biosphere, the information they provide about the mechanisms of the processes that produce them has not been e ....Using the fractionation of hydrogen and carbon isotopes to analyse the mechanisms of the primary processes of photosynthesis. The primary processes of CO2 fixation and reduction in photosynthesis leave their signatures in the isotopic composition of organic matter. Although these signatures are used widely in geochemistry, biology and climatology to infer the dynamics and history of the biosphere, the information they provide about the mechanisms of the processes that produce them has not been exploited fully. We propose to map the underlying biochemistry responsible for fractionation of hydrogen isotopes, to assess its ability to indicate the water relations of plants, and to use carbon-isotope discrimination to probe the catalytic chemistry of the CO2-fixing enzyme, Rubisco.Read moreRead less