Using Genetically Manipulated Mice To Study The Pathophysiologic Consequences Of Castration-induced Prostatic Cell Death
Funder
National Health and Medical Research Council
Funding Amount
$455,250.00
Summary
Prostate cancer is the second leading cause of cancer death among Australian men. The disease is incurable once it spreads beyond the confines of the prostate gland. Hormonal treatments can keep the cancer at bay for a number of years until they are no longer effective. Hormonal treatments cause shrinkage of prostate cancer because they interfere the function of the male hormone, testosterone, which encourages growth of prostate cancer. Hence, there is a need for other treatments that may improv ....Prostate cancer is the second leading cause of cancer death among Australian men. The disease is incurable once it spreads beyond the confines of the prostate gland. Hormonal treatments can keep the cancer at bay for a number of years until they are no longer effective. Hormonal treatments cause shrinkage of prostate cancer because they interfere the function of the male hormone, testosterone, which encourages growth of prostate cancer. Hence, there is a need for other treatments that may improve the quality of life and survival of prostate cancer patients. It appears that a cancer patient can make immune cells known as T cells, which can recognise his own tumour but which are prevented from destroying the tumour. Using a mouse model of prostate cancer, we wish to understand how prostate tumours act to prevent immune destruction in circumstances that are common to the treatment of human prostate cancer. For example, hormonal treatments produce dead prostate cancer cells that will be cleared by the body's professional scavenger cells in a way that suppresses an active immune response against the tumour. To learn how the removal of dead cells suppresses the immune response, we propose to perturb the normal clearance of dead prostate cells by at least two means. First, we will study mice that have an inherited deficiency in the removal of dead cells. Second, these mice will be given a growth factor to produce an excess of immune stimulating cells known as dendritic cells in the prostate gland. The dendritic cell is the main type of cell that initiates immune responses. We will investigate whether the greater number of dendritic cells, which were put into the prostate gland by the growth factor, can remove the dead prostate cells in a way that excites rather than suppresses the anti-tumour immune response. Positive results obtained from these studies may lead to the design of new treatments for advanced prostate cancer.Read moreRead less
A Tumor Specific Variant Of The EGFR: Characterization And Target For Immunotherapy.
Funder
National Health and Medical Research Council
Funding Amount
$85,570.00
Summary
Antibodies are a major component of the bodies immune system that bind (i.e. stick) to foreign substances such as viruses. Once bound, these antibodies can activate other parts of the immune system, which help destroy the foreign substance. Analogous to the situation above, a number of institutions are testing antibodies that bind to cancer cells, in order to determine if they are able to destroy these cells. This therapeutic approach requires an antibody that specifically binds to cancer cells ....Antibodies are a major component of the bodies immune system that bind (i.e. stick) to foreign substances such as viruses. Once bound, these antibodies can activate other parts of the immune system, which help destroy the foreign substance. Analogous to the situation above, a number of institutions are testing antibodies that bind to cancer cells, in order to determine if they are able to destroy these cells. This therapeutic approach requires an antibody that specifically binds to cancer cells but not normal cells. In this proposal, we wish to test a novel antibody that binds to a protein on the cell surface called the EGF receptor. While the EGF receptor is found on the surface on many cells, our antibody recognizes a modified version of the EGF receptor that is found exclusively on cancer cells. Previous EGF receptor antibodies tested in the clinic all recognized the normal EGF receptor and thus proved unsuitable as they bound to cells in the liver causing significant side effects. It is anticipated that the specificity of our novel antibodies will overcome this problem. Eventually this antibody could be used to treat patients with brain, breast, prostate and lung cancer. We will also conduct a number of studies to determine the function of this modified receptor. This work will improve our understanding of those events associated with development of tumors.Read moreRead less