Use Of Circulating Tumour DNA To Characterise The Mutational Landscape Of Marginal Zone Lymphoma, Monitor Treatment Response And Detect Emergence Of Resistance
Funder
National Health and Medical Research Council
Funding Amount
$128,224.00
Summary
Marginal zone lymphoma (MZL) is a subtype of B-cell non-Hodgkin lymphoma for which the molecular drivers of disease are poorly understood. We hypothesise that circulating tumour DNA may be ideal for characterising the genetic mutations that underpin MZL, monitoring treatment response and detecting emergence of resistance. This non-invasive method of disease monitoring has the potential to transform management of cancers such as MZL, identify new treatment options and improve survival outcomes.
Fighting Epidermal Skin Cancers By Targeting Epidermal Clones That Accumulate Mutations
Funder
National Health and Medical Research Council
Funding Amount
$1,149,373.00
Summary
Common skin cancers such as basal and squamous cell carcinomas (BCC and SCC) are by far the most frequent cancer worldwide and require over a million interventions per year in Australia. This project will identify the skin cells that are most susceptible to give rise to cancer if excessively exposed to the sun and explores ways to prevent cancer formation. This will inform on new strategies to prevent new skin cancer development.
In melanoma we hypothesise there is a series of as yet unidentified gene fusions which provide oncogenic stimulatory signals that promote tumour growth and that these novel fusion products are excellent targets for the design of new therapies to treat melanoma. The aims of this study are to identify oncogenic fusions in melanoma, to assess which of these are recurrent, and to demonstrate that the resulting fusion proteins provide a selective growth and-or survival advantage to the tumour cell.
It is seldom the initial cancer that kills the patient; most deaths are due to its metastatic spread throughout the body. Survival after the onset of a brain metastasis is dismal. Current understanding of cancer spread to the brain is poor and yet an ability to inhibit this process would save thousands of lives each year. Using rare tissue resources and cutting-edge technologies, this project will elucidate molecular features of brain metastases that can be exploited to generate new treatments.