Real-time Imaging Of Cell Cycle Progression In Melanoma
Funder
National Health and Medical Research Council
Funding Amount
$526,911.00
Summary
Melanoma is the most aggressive skin cancer and is highly therapy resistant, reasons of which are poorly understood. Here we hypothesise that differences in the growth capacity of melanoma cells in different tumour regions contribute to therapy resistance. We will use a novel microscopic system that allows us to visualise division of individual melanoma cells in intact tumours in real time. Using this system, we will test the effects of targeted therapies on melanoma cell growth and survival.
Regulation Of ERK Driven Cell Proliferation By The Actin Cytoskeleton
Funder
National Health and Medical Research Council
Funding Amount
$920,972.00
Summary
The cells in your body respond to external signals and control their proliferation by transmitting signals from one part of the cell to another. This has usually been thought to involve the movement of signals through a liquid medium without the involvement of any machinery to control the movement. The project aims to test the role of the architecture of the cells in physically moving a growth signal from one place to another. We think that the architecture involved plays a key role in cancer.
Real-time Optical Window Imaging Of AKT-FRET Biosensor Mice To Maximise PI3K/AKT Drug Targeting Within The Hypoxic Microenvironment Of Pancreatic Cancer.
Funder
National Health and Medical Research Council
Funding Amount
$683,447.00
Summary
Inefficient drug response in solid tumour tissue is often a limiting factor in the clinical effectiveness of cancer therapies. Using cutting-edge imaging technology and 3D models that mimic the disease, we have mapped areas of poor drug response within distinct regions of tumours with low oxygen levels known as hypoxia. Here, we will specifically target factors limiting efficient drug targeting in these areas to improve the encouraging anti-cancer profile of AKT inhibitors in pancreatic cancer.
Molecular Pathways Mediating The Anti-tumour Activity Of WIF1
Funder
National Health and Medical Research Council
Funding Amount
$462,342.00
Summary
Osteosarcoma is the most common bone cancer. Treatment often entails aggressive surgery with intensive chemotherapy, although one third of those diagnosed will still die from this disease. We have found that the molecule WIF1 can suppress osteosarcoma growth. In this project we aim to identify genetic modifiers of WIF1, potential WIF1 interactors and define active domains of WIF1 for the development of more effective targeted therapeutics for osteosarcoma.
PARP And PI3K Inhibition In Pancreatic Cancer: Intravital Insights And ‘fine-tune’ Priming Using AKT And Single/double-strand DNA Break Biosensor Mice.
Funder
National Health and Medical Research Council
Funding Amount
$760,505.00
Summary
Inefficient drug response in solid tumour tissue is often a limiting factor in the clinical effectiveness of cancer therapies. Using cutting-edge imaging technology and 3D models that mimic the disease, we can map areas of poor drug response within distinct regions of tumours with chemotherapy. Here, we will shift factors limiting efficient drug targeting in these areas to improve the encouraging anti-cancer profile of PI3K and DNA repair inhibitors in pancreatic cancer.
Endosomal Reactive Oxygen Species In Tumour Angiogenesis
Funder
National Health and Medical Research Council
Funding Amount
$633,739.00
Summary
Cancer claims more lives worldwide than any other disease affecting millions of people annually. Tumours grow and spread in the body by acquiring their own blood vessels that provide them with nutrients and oxygen. We have identified a new protein called NADPH oxidase that promotes the development of these new blood vessels in tumours. We propose to test new drugs that block NADPH oxidase activity to stop the development of new blood vessels for the potential treatment of cancer
Cell survival and death are controlled by two processes known as apoptosis and autophagy. Apoptosis eliminates damaged cells whereas autophagy gets rid of faulty components in the cell. The Bcl-2 proteins regulate both processes. It is well established that dysfunctional Bcl-2 regulation leads to cancer. In this project, we aim to investigate if deregulated Bcl-2 control of autophagy also has a key role in cancer progression and to obtain a molecular picture of how this control is exerted.