Directed Molecular Evolution Of G Protein-coupled Receptors For Stable And Functional Expression In Escherichia Coli
Funder
National Health and Medical Research Council
Funding Amount
$383,479.00
Summary
Approximately half of all prescription drugs on the market act on G protein coupled receptors (GPCRs). The mechanisms underlying GPCR function are mainly unknown due to a lack of structural information. No solved structures exist for any of the estimated 800 human GPCRs, making it difficult to design new drugs. By applying advanced protein engineering techniques I aim to produce human GPCRs in bacteria to ultimately acquire structural information, which will enable novel drug development.
Assembly And Function Of Two Interacting Oncogenic Scaffolds
Funder
National Health and Medical Research Council
Funding Amount
$705,585.00
Summary
Aberrant signaling by the protein kinase superfamily is a known driving force for many cancers and inflammatory diseases. Recently, a subset of kinase-like proteins, termed pseudokinases, have emerged as crucial regulators of kinase signalling pathways. This proposal focuses on elucidating the scaffolding function and assembly of two pseudokinases, termed SgK223 and SgK269, which display oncogenic properties and aims to understand how their signalling abilities are subverted in a disease state.
Design And Engineering Of Adnectins For Diagnosis And Therapy
Funder
National Health and Medical Research Council
Funding Amount
$803,152.00
Summary
This project aims to engineer a naturally-occurring human protein, called an adnectin, to produce molecules that are able to bind specific targets in the human body, and as such may be used in the diagnosis and therapy of a range of diseases.
Alzheimer’s disease (AD), is the most common form of dementia, accounting for between 50-70% of all cases. There is general agreement that current treatments for AD/dementia are inadequate so new treatment strategies are desperately needed. I am addressing these challenges by developing new technologies to generate next generation treatments for AD.
Crosstalk Between The Repressive Histone Methyltransferases PRC2 And G9A: Structure-function Investigation To Open New Therapeutic Opportunities
Funder
National Health and Medical Research Council
Funding Amount
$595,205.00
Summary
The gene expression programs need to be precisely regulated and the misregulation of these programs can cause a broad range of human diseases. My research will focus on two protein complexes, which heavily contribute to the regulation of gene expression. My study will open a new path for developing new therapeutic strategies.
The Role Of Copper In Ubiquitin-dependent Protein Degradation In Alzheimer's Disease
Funder
National Health and Medical Research Council
Funding Amount
$588,622.00
Summary
Ubiquitin’s are small proteins that tag other proteins in a process known as “Ubiquitination”. Often this is to target them for degradation once they are no longer needed i.e. to take out the rubbish. This process is disrupted in Alzheimer’s disease (AD), which may contribute to the disease. This project aims to find out if copper, an essential metal for life, is required for this process. Drugs that are designed to deliver copper to brain cells have been effective in small AD clinical trials.
Spatial And Temporal Dimensions Of Mu-opioid Receptor Signalling: Implications For The Development Of Tolerance
Funder
National Health and Medical Research Council
Funding Amount
$799,316.00
Summary
The use of morphine as an analgesic is still limited by undesirable side effects such as tolerance. Despite decades of research, the mechanisms behind the development of tolerance are poorly understood. The ? opioid receptor is a protein expressed at the surface of the cells that is the target of morphine. This project will investigate the signalling events triggered by opioids with unprecedented resolution and will aim to elucidate why morphine elicits more tolerance than other opioid drugs.
Understanding The Function And Regulation Of G Protein-coupled Receptor Signalosomes And Their Role As High Resolution Signalling Platforms
Funder
National Health and Medical Research Council
Funding Amount
$566,588.00
Summary
G protein-coupled receptors are specialised proteins located on the surface of cells. They are the targets of 50% of currently available pharmaceuticals, but these drugs are derived from limited knowledge of only a fraction of proteins. This proposal will examine exciting and novel properties of receptors that only occur following the assembly of the proteins into specialised networks within cells. The new information will expand our current knowledge, and facilitate future targeted drug design.
Signalosomes And Compartmentalisation In Cellular Homeostasis And Disease
Funder
National Health and Medical Research Council
Funding Amount
$473,646.00
Summary
G protein-coupled receptors are specialised proteins on the surface of cells. They are the targets of 30% of currently available pharmaceuticals. This proposal will examine exciting and novel properties of these proteins that only occur following their assembly into specialised networks in cells. The use of cutting-edge technology will allow us to understand the role of these networks in many diseases. The new information will expand our current knowledge, and facilitate targeted drug design.
Throughout our lives cells must die and be replenished. One way multicellular organisms remove unwanted cells is through a process called programmed cell death. This process eliminates redundant, damaged or infected cells by a program of cell suicide. We are studying the underlying molecular mechanisms of this cell suicide in order to design new pharmaceuticals to treat illnesses caused by a disruption in programmed cell death. The fine balance between living and dying cells must be maintained a ....Throughout our lives cells must die and be replenished. One way multicellular organisms remove unwanted cells is through a process called programmed cell death. This process eliminates redundant, damaged or infected cells by a program of cell suicide. We are studying the underlying molecular mechanisms of this cell suicide in order to design new pharmaceuticals to treat illnesses caused by a disruption in programmed cell death. The fine balance between living and dying cells must be maintained and if this balance is lost then disease may result. A reduced level of cell death may result in cancers while too many dying can contribute to degenerative diseases such as Alzheimer's disease and stroke. Currently many of these diseases do not have effective treatments. We will determine the three-dimensional structures of key proteins involved in programmed cell death and use this information to design drugs that can interfere with the molecular processes involved in signalling cell death. Such drugs may prove useful new therapies in a wide range of diseases caused by a breakdown in the biochemical paths to cell death.Read moreRead less