2017 - Funded Research

An accurate estimate of the effect of treatments on a patient’s wellbeing would help predict the best management strategy for men with localised or advanced prostate cancer. Using tumour samples from patients, we will investigate new ways to predict disease outcomes and drug resistance using information from DNA sequencing.

The side effects of prostate cancer treatments can change the type of bacteria living in the gut, causing problems such as diarrhoea. This study will explore whether exercise can improve the gut bacteria of prostate cancer patients receiving hormone therapy. The project will ask if a 12-week exercise medicine program can improve the gut health.

Men with prostate cancer benefit from radiotherapy because their tumour is specifically targeted, minimising damage to the rest of the body. Previous studies showed that giving the radiation dose in a tight lattice pattern, with quickly changing high and low doses, leaves just enough cells struggling to stay alive that they signal each other and all die. This immune response has worked so well in the laboratory, we are planning to test this in a world-first clinical trial in Australia patients.

Cancer immunotherapies use a patient's own immune system to fight the tumour. Dr Teng's laboratory showed that combining an immunotherapy with a drug that prevents bone destruction worked effectively to suppress prostate cancer growth in mice. This study will ask how this drug combination has superior anti-cancer activity, and whether it can benefit men with advanced prostate cancer.

This project aims to discover new drug targets for neuroendocrine prostate cancer, a particularly aggressive form of this disease. Current clinical therapies are ineffective at inhibiting the growth and spread of this type of prostate cancer. This study aims to establish new strategies to specifically kill neuroendocrine prostate cancer.

Neuroendocrine prostate cancers are highly aggressive tumours that often arise when hormone therapies stop working. Some tumours have neuroendocrine cells present prior to hormone therapy. This study will investigate the properties of early-stage prostate cancers that have neuroendocrine cells, and compare them to the end-stage, lethal neuroendocrine tumours.

Cancer cells use more energy than normal cells to grow, move and resist treatment. Fats are the main energy source for prostate cancer cells. The conversion of fats into energy is performed by specific enzymes. When these enzymes' actions are enhanced, this can fuel tumour growth. This study aims to understand the role of an important enzyme in prostate cancer growth and therapy resistance.

The current PSA test needs to be more effective and reliable. A personalised approach to modify this test could improve its effectiveness. This study will comprehensively analyse how an inherited factor affects PSA’s role in disease progression. The outcomes from this study may lead to a new type of PSA test that has the potential to save and improve the lives of men with prostate cancer.