Characterisation Of The Tumour Suppressor Function Of Caspase-2
Funder
National Health and Medical Research Council
Funding Amount
$605,096.00
Summary
Aberrant cell death (apoptosis) is associated with many diseases including cancer. Apoptosis is mediated by a group of enzymes called caspases. Recently we have discovered that one of these enzymes, caspase-2, acts as a tumour suppressor. We now wish to validate this finding in several preclinical models of cancer and understand precisely how caspase-2 works to safeguard cells against cancer development. These studies will help better understand cancer and ways to treat it.
Identiification Of Novel Biomarkers And Therapeutic Targets For The Treatment Of Pancreatic Cancer
Funder
National Health and Medical Research Council
Funding Amount
$362,463.00
Summary
Pancreatic cancer is a devastating disease with an appalling prognosis - only 6% of patient survive 5 years after diagnosis. The aim of this research is to use new technologies to find out how pancreatic cells become malignant and why the cancerous cells are so drug resistant. The goal is to ideantify cell markers to guide drug treatment design and new targets for antibody therapy. By combining emerging technologies we hope to achieve break-through outcomes in the treatment of pancreatic cancer.
The Role Of Clathrin In The Spindle Assembly Checkpoint And As An Anti-cancer Target
Funder
National Health and Medical Research Council
Funding Amount
$651,768.00
Summary
Cell division produces two daughter cells. Incorrect localisation and modification of proteins that regulate mitosis cause errors that can lead to cancer. As well as using a unique machinery mitosis uses proteins involved in non-cell cycle pathways. This project investigates the role during mitosis of one such protein: clathrin. We will identify lead clathrin inhibitory compounds, pitstops, that have potential anti-cancer properties, ultimately to be used as a chemotherapy agent.
Targeting Survival Pathways To Overcome The Resistance Of Human Melanoma To Treatment
Funder
National Health and Medical Research Council
Funding Amount
$332,123.00
Summary
Melanoma is a major Australian health problem. This is believed to be due to resistance of melanoma cells to cell death associated with inappropriate activation of survival signalling pathways. My previous studies have provided a number of insights into resistance mechanisms of melanoma cells to apoptosis. I wish to understand more fully the molecular basis of the survival signalling pathways, and to identify new therapeutic targets for overcoming resistance of melanoma to treatment.
Apoptosis And Stem Cells In Cancer Development And Therapy
Funder
National Health and Medical Research Council
Funding Amount
$22,852,198.00
Summary
To improve cancer therapy, we are studying two cancer hallmarks: enhanced cell survival and stem cell-like behaviour. As we discovered, cell death is often blocked in cancer cells. Hence, we are attempting to develop drugs that flip the natural ‘cell death switch’. Stem cells are rare cells that generate entire tissues, as we showed for the breast. Certain cancers may be driven by ‘rogue’ stem cells. If so, eradication of these rare cells within the bulk tumour may require novel therapies.
Targeting mitochondria with mitocans to treat cancer: mechanistic aspects. Mitochondria are the power-house of the cell and also the reservoir of proteins causing the demise of cancer cells, therefore suppressing tumour progression. This project proposes a novel way to modify certain compounds, increasing their level in mitochondria in order to maximise their anti-cancer effect.
I am a cell biologist/geneticist focusing on understanding tumourigenesis. Cancer is a multigenic and complicated disease, involving interactions between the tumour and normal tissue. I use the genetically tractable model organism, the vinegar fly, Drosophila, to model cancer in situ and identify novel genes that drive cancer. My 5 year career plan is to use the Drosophila system to model cooperative tumourigenesis in epithelial and brain tissues and translate this to human cancer.
How do mechanical cues regulate tissue renewal and tumour progression? Imbalances between cell production and cell death in tissues can be catastrophic, leading to major global health issues such as cancer. This project will use modified mice and protein-protein interaction based techniques to identify how changes in the mechanical properties of tissues regulate the balance between cell production and cell death.
Role of endocytic mechanisms in mammalian cytokinesis. Cell division requires endocytic proteins and failed cell division can contribute to cancer. This project aims to understand how endocytic proteins function to complete cell division successfully and has implications for the development of chemotherapeutic agents to treat cancer.