Tumour Induced Innate Immune Responses That Control Breast Cancer Metastases
Funder
National Health and Medical Research Council
Funding Amount
$596,164.00
Summary
The mechanisms of breast cancer spread to bone are largely unknown. We have found that cross-talk between tumour cells and the immune system exists to induce anti-tumour immune responses. By decreasing the release of proteins known to activate immune responses (type I interferons), tumour cells can hide from such responses and spread to tissues such as bone. We aim to identify the immune responses activated by type I IFN and if restoration of these pathways can block breast cancer spread to bone ....The mechanisms of breast cancer spread to bone are largely unknown. We have found that cross-talk between tumour cells and the immune system exists to induce anti-tumour immune responses. By decreasing the release of proteins known to activate immune responses (type I interferons), tumour cells can hide from such responses and spread to tissues such as bone. We aim to identify the immune responses activated by type I IFN and if restoration of these pathways can block breast cancer spread to bone.Read moreRead less
Each year, 18,000 Australian men are diagnosed with prostate cancer. While current treatments are designed to directly target cancer cells, the tumour-associated stroma is also recognised to play a pivotal in the establishment and progression of prostate cancer. This grant aims to investigate the contribution of stromal Hedgehog signalling, with the view to creating new treatment strategies that will treat the entire tumor environment.
Elucidating The In Vivo Role Of The Pro-survival Gene Mcl-1 In Mammary Gland Development And Breast Cancer
Funder
National Health and Medical Research Council
Funding Amount
$664,691.00
Summary
Breast cancer strikes one in 8 women by age 85 and is a major cause of morbidity and mortality. Despite recent improvements, the immense breast cancer burden demands new strategies that will radically improve patient outcomes. This project will address a hallmark of cancer: evasion of apoptosis. Understanding the molecular events that promote tumour survival and resistance to therapy represents a key area in cancer biology that has yet to be properly applied to breast cancer.
Much of the death and suffering caused by cancer is associated with secondary tumours, but alot remains to be learned about how cancer spreads through the patient's body. This project will determine how genes that enable the growth of tumours work with other genes that enable cancer cells to detach from the tumour, enabling them to enter the bloodstream and form secondary tumours in other organs.
Cells have the ability to commit suicide in a process called apoptosis. Developing new treatments and drugs that harness the ability of cancer cells to commit suicide (undergo apoptosis) would represent a new and potentially valuable therapeutic approach. We have identified a number of previously unrecognized ways of triggering apoptosis in cancer cells of the blood (leukemias). We propose to use our approaches to find more effective ways of treating cancers in the future.
Targeting Cancer-initiating Cells With DNA Methyltransferase Inhibitors: Single-cell Analysis To Decipher Molecular Mechanisms And Improve Efficacy.
Funder
National Health and Medical Research Council
Funding Amount
$175,000.00
Summary
Certain cancer cells, termed cancer-initiating cells (CICs), have special properties allowing them to drive cancer growth and disease progression. These cells are particularly sensitive to low-dose treatment with drugs called DNA methyltransferase inhibitors. Using cutting-edge "single-cell" technologies this project will determine how these drugs target CICs and identify new ways to increase treatment efficacy. This work will identify new clinical opportunities for prevention of cancer relapse.
Transient Tissue ‘priming’ Via FAK Inhibition To Impair Pancreatic Cancer Progression And Improve Sensitivity To Gemcitabine/Abraxane
Funder
National Health and Medical Research Council
Funding Amount
$643,848.00
Summary
The success of cancer drugs is dependent on many factors including the properties of the tumour tissue. As a tumour grows it changes the tissue around it, and this affects response to treatment. Combining classical biology with engineering to generate 3D models that mimic tumours, along with cutting-edge imaging technology and mouse models, we will target FAK-controlled cancer cell pathways that sense tissue changes, together with already approved cancer drugs to improve patient outcome.
How Does The Tumour Suppressor: Nerfin-1 Prevent Dietary Dependent Tumour Growth?
Funder
National Health and Medical Research Council
Funding Amount
$630,942.00
Summary
The influence of diet has been linked to tumour growth for decades, however, there is little scientific evidence to support or disprove this. In this study, we will assess the effect of diet on tumours in fruit flies. The metabolic genes which regulate the growth of fly tumours will then be studied in human brain tumours. Our studies will ultimately shed light on how tissue growth is controlled by dietary intake, and have the potential to inform the way that we treat and manage human cancers.
Targeting Homeobox Genes In Acute Myeloid Leukaemia
Funder
National Health and Medical Research Council
Funding Amount
$658,739.00
Summary
Acute myeloid leukaemia (AML) is a common blood cancer with dire clinical prognosis due to a lack of targeted molecular therapies. In this proposal we will identify new ways of targeting transcription factor proteins that are overexpressed in AML and promote leukaemia by repressing normal cellular growth controls. This may lead to novel methods to target leukaemic stem cells to specifically eliminate myeloid leukemia
Role Of INPP4B And Related Proteins In Human Cancer.
Funder
National Health and Medical Research Council
Funding Amount
$650,694.00
Summary
Breast cancer is the most common malignancy among females, affecting 1 in 9 women. Cells normally divide only when they receive a stimulus. The PI3K pathway, which responds to these stimuli, has been implicated in cancer and when mutated induces cells to multiply uncontrollably and invade surrounding tissue. This grant aims to characterise the role of a cancer suppressing gene and a related family member play in the development of human breast cancer.