Inhibiting Tumour Growth By Targeting EphA3 And Disrupting Tumour Stromal And Vascular Microenvironment
Funder
National Health and Medical Research Council
Funding Amount
$645,136.00
Summary
Tumours consist of cancer cells, tumour blood vessels and connective tissue, all of which are different to normal tissues. Many of the cells making up tumour vessels and connective tissue are recruited, during initial growth and subsequent spreading of tumours, from the bone marrow. Our research will examine the presence and function of the EphA3 receptor on these cells during tumour development and assess how our anti-EphA3 antibody inhibits tumour growth by targeting stroma and vasculature.
A Novel Approach To Restoration Of Tumour Suppression In Lung Cancer
Funder
National Health and Medical Research Council
Funding Amount
$598,604.00
Summary
Loss of a tumour suppressor is a key event in every cancer, including lung cancer. Therefore restoration of the expression and/or activity of the tumour suppressor is an attractive approach to anti-cancer treatment. In order to restore tumour suppression, a detailed understanding of the mechanism by which a given tumour suppressor is regulated is required. This application focuses on our discovery of a novel mechanism by which a key tumour suppressor of lung cancer is regulated.
Immunotherapy has recently shown promise in bone cancer. We have found that while immune modulators Il-6 and Ifn?? contribute to tumour suppression Il-23 promotes the growth of radiation-induced bone cancer. We have generated mouse models of bone cancer to investigate tumour growth and immune surveillance in immune competent mice with an overall aim of identifying therapeutic targets in this disease.
Identification Of The Molecular Hallmarks Of Naevi Progressing To Melanoma
Funder
National Health and Medical Research Council
Funding Amount
$314,644.00
Summary
Melanomas are amongst the most commonly occurring cancers in Australia with >136,000 people living with a previous melanoma diagnosis. One of the highest risk factors for developing melanoma is having a high number of moles (or naevi). It is therefore important to fully understand how and why naevi develop into melanoma. It is hoped that early detection markers will be identified which will help identify early melanomas and as such improve patient outcome.
Prostate cancer is the most common cancer in men, causing about 3,300 deaths per year. We have identified some small RNAs called microRNAs and other hormone regulators that can interfere with prostate cancer cell growth and signaling via the testosterone pathway. In this application we will be exploring the potential for each of these agents to reduce prostate cancer growth and the possibility that one or more could develop into a therapeutic target in the future.
Control Of Gastrointestinal Tumour Progression By Therapeutic Interference With Myeloid Derived Cells
Funder
National Health and Medical Research Council
Funding Amount
$758,678.00
Summary
Cancers of the stomach and the colon are a major health burden. Despite our increased molecular understanding of the mutation that cause these cancers our treatment options are very limited. Here we will use sophisticated and validated mouse models for these cancers to establish how blood-borne cells contribute to the growth and spreading of these cancer. We will use these models to establish highly effective treatment combinations of therapeutic agents that are already undergoing preclinical te ....Cancers of the stomach and the colon are a major health burden. Despite our increased molecular understanding of the mutation that cause these cancers our treatment options are very limited. Here we will use sophisticated and validated mouse models for these cancers to establish how blood-borne cells contribute to the growth and spreading of these cancer. We will use these models to establish highly effective treatment combinations of therapeutic agents that are already undergoing preclinical testing.Read moreRead less
FOXP3 Regulated MicroRNAs: A Novel Component Of FOXP3 Tumour Suppressor Function In Breast Epithelial Cells.
Funder
National Health and Medical Research Council
Funding Amount
$554,716.00
Summary
Until there is a cure, breast cancer research must continue to discover new targets for therapy. We have novel insight into a new tumour supressor; FOXP3, and have identified the genes it regulates in T cells. We can now apply this information to normal breast tissues to reveal the mechanism and targets that FOXP3 controls to prevent cancer
Nuclear Receptors And Triple Negative Breast Cancer
Funder
National Health and Medical Research Council
Funding Amount
$681,979.00
Summary
This project will explore the potential for a nuclear receptor known as the thyroid receptor to suppress growth of breast cancer using cell culture models and mouse models. We hope to show that activating the thyroid receptors leads to a reduction in breast cancer growth providing evidence that the thyroid receptor pathway could be targeted for therapy.
Selective Targeting Of Apoptotic Pathways For Therapy
Funder
National Health and Medical Research Council
Funding Amount
$518,159.00
Summary
The cells of all animals possess the ability to commit suicide. When this natural process of cell death is dysfunctional, diseases such as cancer arise. New anti-cancer drugs aimed at targeting key components of the cell death machinery are showing promise in some patients, but not all. Our aim is to determine whether targeting other cell death components could be a more effective approach. We will also develop new chemicals that could one day allow such strategies to be applied in the clinic.
Dissecting The Roles Of Steroid Hormone Receptors In The Mammary Gland
Funder
National Health and Medical Research Council
Funding Amount
$92,314.00
Summary
Breast cancer remains a major cause of death in women, requiring the development of highly efficient therapeutics. Research into the molecular and cellular mechanisms of the normal mammary gland is crucial. This project will increase our understanding of the normal roles of the estrogen and progesterone receptors. This research may have significant implications for clinical studies that use more targeted therapies.