Interplay Between Mutant P53 And PML; Implications For Tumourigenesis.
Funder
National Health and Medical Research Council
Funding Amount
$483,737.00
Summary
The most important agent of the body for fighting cancer is the cellular protein p53. In more than 50% of all human cancers, it looses its anticancer properties through mutation. In an insidious manner this new mutant form then acts to promote cancer. To better treat cancer we need to understand how mutant p53 functions. We will study how it interacts with its molecular partners in cancer cells.
Investigating The Role Of Mutant P53 And MCL-1 In The Sustained Growth Of MYC Lymphomas And Strategies For Targeted Therapy
Funder
National Health and Medical Research Council
Funding Amount
$616,940.00
Summary
A large number of human cancers have abnormal expression of a protein called MYC, leading to rapid growth. We found that when another protein called MCL-1 was inactivated, the lymphomas regressed. Importantly, mutations in the tumour suppressor gene called p53 are frequently found in cancer cells and we noticed that this could reduce the dependency on MCL-1. We aim to investigate this further in this grant proposal, in part using a novel drug that targets MCL-1.
Learning The Mechanisms Of Programmed Cell Death And Tumour Suppression To Develop Novel Cancer Therapies
Funder
National Health and Medical Research Council
Funding Amount
$863,910.00
Summary
Our bodies prevent the development of cancer through tumour suppressive processes, which also affect the outcome of cancer therapy. Programmed cell death (apoptosis) is one such process, and defects in apoptosis promote cancer development and impair the response of tumour cells to anti-cancer therapies. My laboratory uses molecular biology and cell biology approaches to investigate the mechanisms of cell death and tumour suppression, partnering with pharma to develop novel cancer therapies.
We recently discovered a new way to treat melanoma by inhibiting a protein called MDM4 that is important in promoting tumor growth in ~2/3 of melanomas. In this proposal, we will extend this work to see if anti-MDM4 therapy is effective in laboratory models that are more relevant to patients and in combination with other melanoma therapies. We will also explore additional ways of inhibiting MDM4 that may make anti-MDM4 therapy even more potent.