Development Of Peptide-based Scaffolds For Intracellular Cancer Targets
Funder
National Health and Medical Research Council
Funding Amount
$1,479,836.00
Summary
The overall aim of this project is to develop peptide-based drugs that are able to cross cell membranes and inhibit specific targets inside cells leading to more effective, safer and cost effective drugs for cancer. One potential outcome of the project will be new drug leads to treat melanoma and leukemia that are likely to be less toxic, more potent and less likely to develop resistance than current treatments.
The Molecular Basis Of Cytochrome P450 Ligand Binding: Towards Predicting Enzyme Substrate Selectivity And Drug-drug Interaction Potential
Funder
National Health and Medical Research Council
Funding Amount
$558,447.00
Summary
Cytochrome P450 (CYP) enzymes play a pivotal role in the metabolism (i.e. chemical breakdown) of drugs, a process that is essential for their detoxification and elimination from the body. This project will combine advanced computational and experimental approaches to elucidate the molecular basis for the binding of drugs to CYP enzymes, which is crucial for the design of drugs with favourable metabolic properties and decreased propensity for harmful interactions with co-administered drugs.
Development Of Small Molecule Antagonists Of HGF/SF And MET Signalling To Treat Metastatic Cancer
Funder
National Health and Medical Research Council
Funding Amount
$353,866.00
Summary
The spread of cancer throughout the body, metastasis, is the major cause of death from cancer. The MET receptor plays a crucial role in over 60% of all metastases and several approaches to block its activity are currently in clinical trials. This project will use a new approach to develop small molecule inhibitors that block the MET receptor from interacting with another protein, HGF/SF. Small molecules that block this interaction will be highly effective treatments against metastatic cancers.
We aim to develop a new class of cholesterol-lowering drugs by blocking the interaction between a protein in the blood called PCSK9 and its receptor, which is implicated in cholesterol absorption. We will do this by designing small stable peptides (mini proteins) that mimic part of the receptor and have the potential to interfere with the normal PCSK9 binding process. These drugs should be less expensive and potentially less immunogenic than competing therapies based on antibodies.
Cryptococcal Phospholipases: Structure, And Potential Targets For Therapeutics
Funder
National Health and Medical Research Council
Funding Amount
$511,650.00
Summary
Mortality and morbidity from invasive fungal infections have increased substantially over the past two decades, especially in immunocompromised patients, such as those with AIDS. Antifungal drugs marketed at present are not very effective or are toxic. There is a need to identify new metabolic and structural targets, some of which are responsible for fungal virulence, as potential areas for development of new drugs. One such virulence factor discovered in our laboratory is an enzyme secreted by ....Mortality and morbidity from invasive fungal infections have increased substantially over the past two decades, especially in immunocompromised patients, such as those with AIDS. Antifungal drugs marketed at present are not very effective or are toxic. There is a need to identify new metabolic and structural targets, some of which are responsible for fungal virulence, as potential areas for development of new drugs. One such virulence factor discovered in our laboratory is an enzyme secreted by the pathogenic fungus, Cryptococcus neoformans, which is acquired by inhalation into the lungs where it can cause lesions, and eventually spreads to other parts of the body, including the brain (median mortality, 17%). This enzyme breaks down cell membranes, aiding invasion into the host lungs and other tissues, and is called phospholipase B (PLB). It is also produced by several other pathogenic fungi, and is different from human phospholipases. In this project we aim to understand how the PLB is constructed, so that we can work out where the cell membrane components bind to it. We will then design drugs which can bind to the PLB enzyme in place of membrane components and in this way block its harmful effects. We will test the effects of such drugs to make sure they do not interfere with human enzyme systems. Inhibitory compounds may also be able to kill the cryptococcal cells, especially if administered together with currently used therapies. Drugs developed to treat Cryptococcus will then be applicable to other systemic fungal infections - a major advance in the treatment of fungal disease, and a saving of some A$60,000 per patient (estimated from a recent U.S. study).Read moreRead less
A common characteristic of cancer is the failure of cells to die when they normally would. One of the problems with many cancer therapies is that they rely on the integrity of signalling pathways to the normal ‘death machinery’ of the cell to do their job. By understanding how the molecular death machine operates we are fashioning new drugs that can target it directly, thus bypassing the very pathways that are so frequently disrupted in tumour cells.
Structure-based Drug Design For Neuroprotection From Traditional Chinese Medicine
Funder
National Health and Medical Research Council
Funding Amount
$245,968.00
Summary
In the proposed research, three novo approaches for drug discovery will be explored: 1) The important neurodegenerative disease relevant protein JNK3 crystals will be used as the probe to fish out the potential inhibitors from Traditional Chinese Medicine (TCM); 2) Instead of individual drug components, the mixture of TCM will be used directly; 3) The composition of a TCM library are not randomly chosen but have been used in China for hundreds to thousands of years in curing neurodegenerative di ....In the proposed research, three novo approaches for drug discovery will be explored: 1) The important neurodegenerative disease relevant protein JNK3 crystals will be used as the probe to fish out the potential inhibitors from Traditional Chinese Medicine (TCM); 2) Instead of individual drug components, the mixture of TCM will be used directly; 3) The composition of a TCM library are not randomly chosen but have been used in China for hundreds to thousands of years in curing neurodegenerative disease.Read moreRead less
Structure-based Design Of Inhibitors Of PimA - A New Target For Tuberculosis Therapy
Funder
National Health and Medical Research Council
Funding Amount
$666,246.00
Summary
Tuberculosis (TB) is a devastating disease that kills 2 million people worldwide each year and affects one-third of the entire human population. Bacterial resistance to existing antibiotics is an ever increasing problem, highlighting the need to develop new anti-TB drugs. The aim of this project is to develop specific inhibitors to target a protein that is essential for the survival of the tuberculosis bacterium.
Structural And Drug Discovery Studies Of Medically Important Protein Complexes
Funder
National Health and Medical Research Council
Funding Amount
$438,577.00
Summary
My research is focused on structural studies of medically important biological systems, where specific protein complex formation contributes to human illnesses. I use X-ray crystallography to visualize the whole complex at atomic resolution as well as to determine whether binding partners have undergone changes in shape upon complex formation. This structural information then helps me in drug design with goals to either disrupt or modulate the complex.