Targeting MicroRNA-driven Mesenchymal To Epithelial Transition To Suppress Prostate Cancer Metastasis
Funder
National Health and Medical Research Council
Funding Amount
$741,831.00
Summary
Prostate cancer kills ~3,000 men per year in Australia. The development of metastasis is the major cause of prostate cancer-associated death and has limited treatment options. In this study, we will characterise the role of a group of molecules, termed microRNAs, in prostate cancer metastasis. We will also test whether targeting microRNAs using novel drugs termed antagomiRs is an effective strategy to inhibit metastasis and thereby improve prostate cancer mortality.
MicroRNAs are small molecules that modulate the expression of most genes and so affect nearly every biological process and pathology although, they were only discovered in humans less than 10 years ago. The bottleneck in discovering the functions of miRNAs is in identifying their molecular targets, the majority of which remain unknown. We aim to comprehensively identify direct target genes of epithelial-specific microRNAs and to confirm a number of them by gene target validation approaches.
Role Of The MiR-200 Target Quaking In Alternative Splicing During EMT And Cancer Progression
Funder
National Health and Medical Research Council
Funding Amount
$443,160.00
Summary
The spread of cancer to other organs involves cancer cells changing to a more aggressive state and is a major cause of cancer related death. MicroRNAs are a class of genes that control whether cancer cells become more aggressive by regulating other genes. In this project we will examine the function of a new microRNA target which controls the cancer cell aggression. The outcome will be a better understanding of how cancers spread and the identification of new therapeutic targets.
Characterising Novel Alternative Splicing Networks That Promote Tumour Cell Plasticity
Funder
National Health and Medical Research Council
Funding Amount
$609,329.00
Summary
During cancer progression, tumour cells can change their properties and become more aggressive and resistant to therapies. We have identified an important regulator of this tumour cell transition, called “Quaking”, which causes widespread changes in gene splicing. We aim to investigate how "Quaking" causes changes in gene splicing and what the effects of these splicing changes are in tumour cells.