Cancer arises through a combination of common DNA mutations which are associated with very poor survival in certain cancers. However, the cause of these mutations was always believed to be external factors (eg. UV light, toxins), Our exciting preliminary results show internal molecules, called circular RNAs, can drive these mutations and this project will investigate how this occurs and study whether targeting these molecules can reduce the incidence of cancers.
Circular RNAs As Genome Destabilisers In Human Disease
Funder
National Health and Medical Research Council
Funding Amount
$2,163,220.00
Summary
Mutation of genes are hallmarks of both cancer and neurological disorders. My research group has identified roles for circular RNAs in both these processes. Now, we must close the loop by investigating the mechanism of these processes. This will inform not only why these genes are commonly mutated, but by exploiting the highly stable circular RNAs they may provide early prognostic/diagnostic biomarkers and even represent novel therapeutic targets for cancer and Huntington’s disease.
Uncovering New Epigenetic-based Regulatory Mechanisms Of Gene Expression: Novel Links Between Histone Variants, RNA Function And Disease
Funder
National Health and Medical Research Council
Funding Amount
$1,053,671.00
Summary
It is estimated that greater than 90% of human genes undergo alternative RNA splicing, which can explain how protein diversity is achieved with a limited number of genes. However, how alternative splicing patterns are established remains poorly understood but is an important question given that 15-50% of human disease mutations are associated with changes to the splicing patterns of RNA. We have uncovered a new splicing mechanism, which involves changing the way DNA is packaged in a cell.
The Role Of The Neuronal Splicing Factor A2BP1 In Autism Spectrum Disorders
Funder
National Health and Medical Research Council
Funding Amount
$396,412.00
Summary
Autism spectrum disorders (ASD) are characterized by language deficits, social impairments and repetitive-restrictive behaviors. ASD is one of the most highly heritable neuropsychiatric conditions, and at the same time genetically very heterogeneous. We have recently shown that shared gene expression abnormalities can be identified in postmortem brain from ASD patients. We now propose to investigate the mechanisms and functional consequences of gene expression abnormalities in ASD.
THE ROLE OF NOVEL TUMOUR SUPPRESSORS DURING DEVELOPMENT
Funder
National Health and Medical Research Council
Funding Amount
$200,880.00
Summary
Cancer is a disease that is likely to affect 1-4 people at some point in their lifetime. Therefore, understanding what causes cancer is of major importance to medical science. Cancers arise through the accumulation of mutations that alter normal cell proliferation control, differentiation or apoptosis (programed cell death). Many genes involved in cancer have been identified, however, there are likely to be many more genes, that when disrupted or misexpressed can lead to cancer. We are intereste ....Cancer is a disease that is likely to affect 1-4 people at some point in their lifetime. Therefore, understanding what causes cancer is of major importance to medical science. Cancers arise through the accumulation of mutations that alter normal cell proliferation control, differentiation or apoptosis (programed cell death). Many genes involved in cancer have been identified, however, there are likely to be many more genes, that when disrupted or misexpressed can lead to cancer. We are interested in the regulation of cell proliferation, and have been studying this in the genetically amenable animal model system, Drosophila. Central to the control of cell proliferation in all organisms are the Cyclin dependent protein kinases. Cyclin E-dependent protein kinase is required to drive cells from the G1 (resting state) into S phase (where DNA replication occurs). Correct control of Cyclin E is important in limiting cell proliferation and many cancer causing mutations result in up-regulation of this critical cell cycle regulator and premature entry into the cell cycle. We have used a genetic approach using a weak mutation in Drosophila Cyclin E to isolate mutations in other important regulators of the G1 to S phase transition. We have identified a number of genes that act to negatively regulate the cell cycle, 2 of which have characteristics typical of tumour suppressors. We have identified candidate genes for 3 of these mutations, all of which encode novel proteins related to mammalian proteins involved in negative regulation of cell proliferation or tumour suppressors. In this proposal we seek to determine the way in which these proteins function to control cell proliferation in Drosophila. Due to the remarkable conservation of genes involved in cell proliferation control through evolution, this study is likely to be highly relevant to the control of cell proliferation and the development of cancer in humans.Read moreRead less
Targeting The Oncoprotein MDMX As A Novel Treatment For Triple Negative Breast Cancer
Funder
National Health and Medical Research Council
Funding Amount
$561,672.00
Summary
Breast cancer (BrCa) is a leading cause of cancer death in women worldwide. BrCas unable to respond to current therapies have the worst outcomes. We propose a novel strategy to treat these cancers, based on our new findings. Our two protein targets are: (1) MDMX, that we found drives BrCa with its partner, (2) mutant p53, which causes cancer spread. We plan to directly target these drivers of aggressive BrCas, using new drugs that individually show great promise in trials in a number of cance
Deciphering The Role Of DNA Methylation In The Regulation Of Alternative Splicing
Funder
National Health and Medical Research Council
Funding Amount
$865,494.00
Summary
When a gene is turned on, the messenger RNA must be correctly processed to generate functional proteins. This ‘splicing’ process is essential for normal cellular activity, and is disrupted in many human diseases. We have discovered that an epigenetic modification, DNA methylation (mC), may control splicing. This project will investigate how mC influences splicing and use new epigenome-editing tools to control it, in order to ultimately understand and treat diseases involving aberrant splicing.