The Microniche: A Novel In-vitro And In-vivo Prostate Cancer Model System
Funder
National Health and Medical Research Council
Funding Amount
$561,012.00
Summary
Maintaining primary prostate cancer cells (PCa) in vitro remains an enormous challenge for the field, and this obstructs efforts to systematically characterize cell behaviour and quantify drug response. Our group recently developed a 3-demsensional (3D) organoid culture system that does maintain PCa in vitro, and here we will integrate this technology with our 3D bone maorrow niche model system to better characterize PCa bone metastases and identify new clinical treatment regimes.
Targeting A Master Regulator Of Tumour Cell Plasticity As A New Adjuvant Therapy For Prostate Cancer
Funder
National Health and Medical Research Council
Funding Amount
$780,338.00
Summary
Prostate cancer (PCa) claims the lives of over 3,000 Australian men each year. This highlights the urgent need to identify new molecular targets that can be developed as additional therapies for men with PCa. Our team has identified the protein, Zeb1, to be highly expressed in aggressive and treatment resistant forms of PCa. This study aims to characterise the role of Zeb1 in the lethal progression of PCa and to develop a new therapeutic agent to inhibit the production of ZEB1 by cancer cells.
Determining The Origin Of Lethal Metastases In Multifocal Primary Prostate Cancer
Funder
National Health and Medical Research Council
Funding Amount
$696,470.00
Summary
New biomarkers are required to accurately predict lethal prostate cancer from benign, indolent disaese that doesn't require expensive treatment. To do this relies on finding molecular differences between disease states. Advancements in high throughput genomic technologies enables us to now probe the lethal prostate cancer genome and transcriptome and distinguish this disease state from other forms of prostate cancer.
Geldanamycin Derivatives: Novel Inhibitors Of Androgen Signalling For The Treatment Of Metastatic Prostate Cancer
Funder
National Health and Medical Research Council
Funding Amount
$316,320.00
Summary
Prostate cancer is a major health problem in Western Countries including Australia, where it is the most common newly diagnosed invasive cancer and the second leading cause of cancer deaths in men. Although there have been improvements in the diagnosis of prostate cancer, many men are still diagnosed with disease that already has or will spread to other sites such as lymph nodes and bone (ie metastatic disease). For those men with metastatic disease, reduction in testicular androgens by surgical ....Prostate cancer is a major health problem in Western Countries including Australia, where it is the most common newly diagnosed invasive cancer and the second leading cause of cancer deaths in men. Although there have been improvements in the diagnosis of prostate cancer, many men are still diagnosed with disease that already has or will spread to other sites such as lymph nodes and bone (ie metastatic disease). For those men with metastatic disease, reduction in testicular androgens by surgical or medical means (ie androgen ablation) is the only effective treatment option available. However, androgen ablation is only palliative, and treatment failure is common, with less than 20% of patients surviving more than 5 years. Recent evidence suggests that the androgen receptor, which mediates the growth regulatory effects of androgens, such as testosterone, is often defective in prostate tumour cells. These altered or mutant receptors may be inappropriately activated and stimulate tumour growth which may explain why treatment fails in a subset of men with advanced prostate cancer. The major objective of our current proposal is to evaluate a novel approach for the treatment of prostate cancer which, based upon our preliminary results, has the potential to be effective even if alterations are present in the androgen receptor. Specifically, we will examine the effectiveness of derivatives of a natural product, the antibiotic geldanamycin, to inhibit prostate tumour growth. The current studies therefore have the potential to result in improved treatment approaches for advanced prostate cancer.Read moreRead less
A Targeted Drug Delivery System For Treatment Of Bone Metastasis
Funder
National Health and Medical Research Council
Funding Amount
$243,607.00
Summary
The most common site where cancer spreads is the bone. Once it happens, it can dramatically affect patient’s quality of life and chance of survival. Current treatments are mostly palliative or associate with acute side effects due to systematic administration of anticancer drugs and their inability to selectively target the diseased area. This study aims to develop a nanocarrier that can uptake, protect and deliver anticancer drugs to the affected site in bone.
The Ghrelin Axis As A Target For Prostate Cancer Therapy
Funder
National Health and Medical Research Council
Funding Amount
$585,497.00
Summary
Prostate cancer affects one in nine Australian men in their lifetime, and although there have been great advances in treatments, advanced prostate cancer remains incurable. Current treatments often lead to side effects which affect quality of life. We have found that the appetite hormone, ghrelin, stimulates prostate cancer cell growth and may be a useful target for prostate cancer therapy. We predict that targeting the ghrelin axis will prevent some of the side effects of other treatments that ....Prostate cancer affects one in nine Australian men in their lifetime, and although there have been great advances in treatments, advanced prostate cancer remains incurable. Current treatments often lead to side effects which affect quality of life. We have found that the appetite hormone, ghrelin, stimulates prostate cancer cell growth and may be a useful target for prostate cancer therapy. We predict that targeting the ghrelin axis will prevent some of the side effects of other treatments that reduce quality of life for patients.Read moreRead less
Understanding And Manipulating The Epigenetic Networks That Define Osteosarcoma
Funder
National Health and Medical Research Council
Funding Amount
$80,467.00
Summary
Osteosarcoma is the most common type of bone cancer and the fifth most common form of cancer in children. Although osteosarcoma begins in bones, the cancer often spreads to other parts of the body. Patients have a very poor chance of survival if their cancer has spread. We will use mouse and human models of osteosarcoma to improve our understanding of how the cancer is different from the normal bone forming cells. This information will help us to find new treatments to improve patient outcomes.
Defining Stromal-Cancer Cell Interactions For Xenografting Human Prostate Cancer
Funder
National Health and Medical Research Council
Funding Amount
$559,635.00
Summary
Prostate Cancer research continues to be hindered by a lack of laboratory models to understand disease progression and design new drugs to cure the disease. In this study, we propose to use a new and reliable method of growing human prostate cancer tissue in mice. Using this model, we will investigate the role of hormone signalling and cellular communication in prostate cancer that may lead to new therapies for men diagnosed with organ-confined disease.
Estrogen Therapy For Castrate Resistant Prostate Cancer
Funder
National Health and Medical Research Council
Funding Amount
$531,690.00
Summary
Withdrawal of male hormones in men with prostate cancer is effective therapeutically because it causes cell death in most of the tumour. However the remaining cells (called castrate resistant cells), give rise to recurrent disease that inevitably kills the patient. This project aims to test if our compound will kill these cells and prevent recurrence or if it has any benefit for the patients who have incurable disease.
Some advances have been made in identifying genetic factors that underlie susceptibility to prostate cancer but few explain multiple-cases of prostate cancer in families. Linkage studies show that the unexplained familial aggregations of prostate cancer are likely to be explained by mutations in many genes. This research will utilize our prior research, our extensive research resources, new technology and supercomputing to identify genetic factors associated with prostate cancer susceptibility.