The basis of recognition and disposal of dysfunctional proteins by clusterin. When proteins become damaged they can precipitate. A blood protein called clusterin prevents precipitation of damaged proteins. Clusterin does this by forming complexes with the damaged proteins. Clusterin is the first blood protein known to do this. We will discover which parts of clusterin are responsible for this activity. We will also discover whether cells can take up and dispose of the complexes of clusterin and ....The basis of recognition and disposal of dysfunctional proteins by clusterin. When proteins become damaged they can precipitate. A blood protein called clusterin prevents precipitation of damaged proteins. Clusterin does this by forming complexes with the damaged proteins. Clusterin is the first blood protein known to do this. We will discover which parts of clusterin are responsible for this activity. We will also discover whether cells can take up and dispose of the complexes of clusterin and damaged proteins. This work is important because some diseases (eg, Alzheimers disease) involve the toxic effects of abnormal protein precipitation. Understanding how clusterin works may help in developing better treatments for these diseases.Read moreRead less
Structural and functional characterisation of PI3Kgamma, uniquely activated by p101. The movement of cells is involved in all aspects of life including development, growth and maintenance of organisms. In spite of this, our understanding of the mechanism involved in cell migration is limited. There are a number of conditions in which the ability to control cell movement would be of significant benefit. Examples include autoimmune conditions, asthma and cancer, the social and economic burdens ....Structural and functional characterisation of PI3Kgamma, uniquely activated by p101. The movement of cells is involved in all aspects of life including development, growth and maintenance of organisms. In spite of this, our understanding of the mechanism involved in cell migration is limited. There are a number of conditions in which the ability to control cell movement would be of significant benefit. Examples include autoimmune conditions, asthma and cancer, the social and economic burdens of which account for billions of dollars and millions of Australians. This project aims to understand one of the major mechanisms that controls cell migration, which is expected to produce significant economic and social outcomes in the areas of basic science knowledge, human health, and biotechnology. Read moreRead less