The Role Of Novel And Essential Bromodomain Proteins In Coordinating Malaria Parasite Gene Regulation And Their Potential As Anti-malarial Targets
Funder
National Health and Medical Research Council
Funding Amount
$689,034.00
Summary
Malaria kills over 400,000 people a year and new therapies are needed. Malaria parasites activate groups of genes by novel mechanisms that could be targeted by drugs. We will characterise a novel group of proteins to identify those that activate genes essential for parasite survival. We will also search for molecules that inhibit the proteins and kill malaria parasites. Thus we will discover how parasites control their genes and identify drug targets and inhibitors for drug development.
Blood clotting is dependent upon platelets. A decline in platelet number, or thrombocytopenia, is a life threatening condition that can result from various diseases or importantly as a side effect of chemotherapy. We are investigating the control of platelet production. A long term goal is to stimulate platelet production in patients by boosting the natural pathways or to generate platelet producing cells for transfusion from a patient's own skin cells by genetic reprogramming.
Improving Outcomes For Cancer Patients By Targeting The Epigenome
Funder
National Health and Medical Research Council
Funding Amount
$2,258,892.00
Summary
The most commonly mutated proteins in cancer involve so called epigenetic regulators, a class of proteins that regulate access to our DNA to control gene expression, DNA repair and replication. We and others have recently developed a variety of drugs to help inhibit the aberrant activity of these epigenetic proteins. My research will focus on ways to improve the efficacy of these existing drugs and find new epigenetic therapies to improve the survival of patients with a broad range of cancers.
Defining The Genes That Dictate The Cellular Response To Tumour Protein TP53 Activation
Funder
National Health and Medical Research Council
Funding Amount
$784,896.00
Summary
The tumour suppressor TP53 prevents the growth of abnormal cells by activating processes such as cell death and irreversible growth arrest. A cell will undergo only one of these possible responses, but it is not known why some cells die and others only stop growing. We will use innovative methods to define the genes that dictate the cellular response to TP53 activation. This research has implications for cancer, as many therapeutics aim to permanently kill cancer cells by activating TP53.
Snail Family Proteins Regulate Stem Cell Differentiation
Funder
National Health and Medical Research Council
Funding Amount
$288,650.00
Summary
This research aims to discover the role of a family of genes in regulating stem cells. These genes are known to turn other genes off and we have shown that this family is required to maintain stem cells in animal tissues. The current research seeks to determine which genes are normally switched off in order to maintain normal stem cells. We also aim to determine if turning these genes on leads to cancer formation.
Identification Of The Conformation Dependant Targets Of Autoimmune Disease Linked Variation In Human Regulatory T Cells
Funder
National Health and Medical Research Council
Funding Amount
$1,001,815.00
Summary
Specialised immune cells called regulatory T cells act as the policemen of the immune system, preventing the immune system attacking itself, but still fighting infections. If these cells do not work properly, autoimmune diseases such as type 1 diabetes or IBD can arise, because of immune attack on normal body tissue by mistake. In order to explain how this goes wrong we need to carefully identify all of the gene interactions in these cells including interactions over long distances in the DNA.
Uncovering The Epigenetic Landscape That Regulates Human Transcriptional Memory
Funder
National Health and Medical Research Council
Funding Amount
$708,208.00
Summary
The ‘T cells’ in our bodies develop a memory of previous infections so that we do not become ill from them again. However, we do not fully understand how this memory works and it fails as we get old. We will use cutting-edge techniques to examine the detailed molecular wiring that ‘remembers’ viruses and see how it changes over time. This is hoped to facilitate the design of new age-specific vaccines and drugs and promote a more personalised approach to preventing and treating immune diseases.