Chemical staples and chemical probes to dissect dynamins cellular roles. Modulation of protein structure drives cellular function. Dynamin GTPase forms at least two macromolecular structures with different cellular functions. The drivers behind these different structures is unknown. In this project we will leverage our discoveries, and planned enhancements, of chemical biology probes that will modulate dynamin activity by inhibiting at three distinct sites, and one site that stimulates dynamin a ....Chemical staples and chemical probes to dissect dynamins cellular roles. Modulation of protein structure drives cellular function. Dynamin GTPase forms at least two macromolecular structures with different cellular functions. The drivers behind these different structures is unknown. In this project we will leverage our discoveries, and planned enhancements, of chemical biology probes that will modulate dynamin activity by inhibiting at three distinct sites, and one site that stimulates dynamin activity. It is known that Dynamin helices and rings are believed responsible for at least three in cell biological functions: in hormone, neutral and receptor internalisation; cellular mitosis and in actin dynamics. Prior to this work we have lacked the tools to understand the role of shape modulation of protein function.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100164
Funder
Australian Research Council
Funding Amount
$310,000.00
Summary
A facility for ex-vivo molecular imaging. The facility will allow a consortium of Australian researchers to create an integrated facility for imaging biological receptors in tissue, bringing together laboratory, radiochemistry and imaging expertise. Digital data at each site will be able to be viewed and analysed remotely.
Resurrecting Ancient Proteins to Unlock New Catalytic Activity. This project aims to study the proteins that nature uses to make penicillin and related antibiotics, and their prehistoric ancestors. By doing so, the project expects to deepen understanding of these important processes, open up ways to make new antibiotics, and generate new knowledge about protein evolution. Intended outcomes include new biocatalysts based on the ancient ones, new antibiotic compounds active against resistant bacte ....Resurrecting Ancient Proteins to Unlock New Catalytic Activity. This project aims to study the proteins that nature uses to make penicillin and related antibiotics, and their prehistoric ancestors. By doing so, the project expects to deepen understanding of these important processes, open up ways to make new antibiotics, and generate new knowledge about protein evolution. Intended outcomes include new biocatalysts based on the ancient ones, new antibiotic compounds active against resistant bacteria, and a richer understanding of how these proteins have evolved over the last 4 billion years. This promises significant benefits in the form of new ways to address the challenge posed by antimicrobial resistance to antibiotics, which is a serious threat to the continued effectiveness of current antibiotics.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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668382
Funder
Australian Research Council
Funding Amount
$1,000,000.00
Summary
e-Research Infrastructure for the Molecular and Materials Structure Sciences. Understanding molecular and materials structure in atomic detail is vital to a knowledge-based economy and a healthy society. The development of smart materials, nanotechnological devices, hydrogen storage materials, molecular switches, magnets and sensors, for example, depends on knowledge of three-dimensional atomic structure. Cures for illnesses such as SARS, AIDS and Alzheimer's disease and understanding the aging ....e-Research Infrastructure for the Molecular and Materials Structure Sciences. Understanding molecular and materials structure in atomic detail is vital to a knowledge-based economy and a healthy society. The development of smart materials, nanotechnological devices, hydrogen storage materials, molecular switches, magnets and sensors, for example, depends on knowledge of three-dimensional atomic structure. Cures for illnesses such as SARS, AIDS and Alzheimer's disease and understanding the aging process depends on knowledge of biomolecular structure. The deployment and development of automation-enhanced remote access to structural instruments through the web will greatly enhance Australian structure-based research, and make this science accessible to the public. Read moreRead less
Unleashing the Hidden Chemical Diversity in Australian Fungi. This project aims to exploit an exclusive genomic resource consisting of >150 unique Australian filamentous fungi that has been built in a university-industry collaboration for genomic-guided biodiscovery. The genome sequence of these fungi revealed extensive hidden genetic instructions for production of novel biologically active molecules. The project will apply cutting-edge synthetic biology and chemical tools to tap into the hidden ....Unleashing the Hidden Chemical Diversity in Australian Fungi. This project aims to exploit an exclusive genomic resource consisting of >150 unique Australian filamentous fungi that has been built in a university-industry collaboration for genomic-guided biodiscovery. The genome sequence of these fungi revealed extensive hidden genetic instructions for production of novel biologically active molecules. The project will apply cutting-edge synthetic biology and chemical tools to tap into the hidden genomic potential of these Australian fungi. Expected outcomes of this project include new fine chemicals and lead molecules with desirable bioactivies. This will provide significant benefits to Australia's economy through the discovery of new pharmaceuticals, veterinary products and agrichemicals.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120102687
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Development of sensors for biological redox state. The plethora of antioxidant supplements on the market to prevent aging and disease highlights the great importance of oxidation state in the body. This project involves the development of chemical compounds that can be used to measure oxidation state in living tissue by Magnetic Resonance Imaging (MRI) or microscopy and help us understand various diseases.
Micro-dissection of clathrins role in mitosis via chemical biology probes. This project aims to contribute to understanding the molecular mechanisms of the role of a key protein, clathrin, in cell division. In doing so it expects to reveal new approaches to stop uncontrolled cell division and proliferation, the hallmarks of cancer. The outcomes could in the long term inform breakthroughs in cancer treatment, significant enhancements in life quality and a reduction in cancer death rates.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100170
Funder
Australian Research Council
Funding Amount
$580,000.00
Summary
Bioaffinity mass spectrometry infrastructure to identify small molecules binding to therapeutic targets. The development of anti-infective therapies is challenging because the underlying biology and biochemistry of pathogen virulence is not yet completely understood. This mass spectrometer facility will be used to identify small molecules suited for development into new therapies for malaria, tuberculosis and HIV.
Surface Chemistry meets Cell Biology: Molecular Level Control of Surface Architecture for Cell Adhesion and Migration. Biotechnological applications such as tissue engineering, bone supports, implantable materials, cell assays and biosensors all require detailed knowledge of how cells interact with their environment. The proposed research aims to provide this knowledge by developing unique modified surfaces to investigate white blood cell migration and adhesion. Additional expected outcome will ....Surface Chemistry meets Cell Biology: Molecular Level Control of Surface Architecture for Cell Adhesion and Migration. Biotechnological applications such as tissue engineering, bone supports, implantable materials, cell assays and biosensors all require detailed knowledge of how cells interact with their environment. The proposed research aims to provide this knowledge by developing unique modified surfaces to investigate white blood cell migration and adhesion. Additional expected outcome will contribute to our understanding of the many fundamental cellular processes such as cell growth, differentiation and cell death as well as the molecular basis of diseases such as inflammation, cancer, cardiovascular diseases and wound healing. This research program will establish Australia as a leading force in this new research field.Read moreRead less