Exploiting the self-assembly of hydrophobin proteins to engineer functional nanostructuring surfaces. There is an increasing world-wide demand for advanced nano-biomaterials with novel properties. We will use natural hydrophobin proteins to coat nanodevices and make them more compatible with biological systems. Hydrophobin coatings will be applicable to biosensors, medical devices, diagnostics and drug delivery systems. The research will lead to an understanding of the basic mechanisms of protei ....Exploiting the self-assembly of hydrophobin proteins to engineer functional nanostructuring surfaces. There is an increasing world-wide demand for advanced nano-biomaterials with novel properties. We will use natural hydrophobin proteins to coat nanodevices and make them more compatible with biological systems. Hydrophobin coatings will be applicable to biosensors, medical devices, diagnostics and drug delivery systems. The research will lead to an understanding of the basic mechanisms of protein self-assembly and will have application outcomes that contribute to Australia being an important player in the field of nanotechnology. This is critical for Australia's long term competitiveness and productivity in and beyond the 21st century.Read moreRead less
Complex nano-systems for highly selective imaging and targeting of cells. The aim of the project is to design multi-functional nanoparticles that can be tracked by multiple bio-imaging techniques, such as magnetic resonance imaging (MRI) and positron emission tomography imaging. The nanoparticles are designed to be targetable to specific cell populations and capable of delivering drugs. The project plans to concentrate the MRI-active gadolinium into nanoparticles to generate enhanced images, and ....Complex nano-systems for highly selective imaging and targeting of cells. The aim of the project is to design multi-functional nanoparticles that can be tracked by multiple bio-imaging techniques, such as magnetic resonance imaging (MRI) and positron emission tomography imaging. The nanoparticles are designed to be targetable to specific cell populations and capable of delivering drugs. The project plans to concentrate the MRI-active gadolinium into nanoparticles to generate enhanced images, and to combine this with other imaging modalities to facilitate tracking and sensitivity. Expected outcomes would enable a new approach to extremely accurate and sensitive imaging of tumours to enable the imaging of much smaller tumours than currently possible. This would allow early therapeutic intervention. The nanoparticles are also designed to deliver a therapeutic payload to specific locations, avoiding systemic delivery of toxic anticancer drugs.Read moreRead less
Developing the basis for an quality control platform for human pluripotent stem cells and their differentiated derivatives. Biophotonic techniques based on spectroscopy have the potential to provide low-cost, automatable measurements for the quality control of stem and differentiated cells produced for use in industry and regenerative medicine. This project is aimed at acquiring the fundamental scientific knowledge base required to bring this about.
The MYB gene as a model for global transcriptional regulation: stopping, starting and looping. This project will study how transcriptional elongation controls the MYB gene, a key regulator of normal and cancerous growth and regulation. There are three major benefits that are likely to flow from the proposed research It will strengthen research in new and important areas of transcriptional regulation, by building research capacity in Australia in the area of gene expression, particularly with res ....The MYB gene as a model for global transcriptional regulation: stopping, starting and looping. This project will study how transcriptional elongation controls the MYB gene, a key regulator of normal and cancerous growth and regulation. There are three major benefits that are likely to flow from the proposed research It will strengthen research in new and important areas of transcriptional regulation, by building research capacity in Australia in the area of gene expression, particularly with respect to transcriptional elongation and long-range regulation. It will highlight a new approach to the therapeutic targeting of MYB in cancer: data generated from this research may enable us to target MYB expression in a range of cancers including breast cancer by inhibiting transcriptional elongation. And it will provide training in advanced molecular biology to postdoctoral scientists and students.Read moreRead less
A novel DNA damage repair protein as a regulator of DNA double strand break repair and genome integrity. This project aims to define the function of a novel DNA damage repair protein. These data will provide a better understanding of DNA repair biology and may reveal novel diagnostic and treatment options for many diseases associated with DNA repair defects, including cancer.