Proteolytic And Non-proteolytic Roles For PSA And Related Kallikrein Serine Proteases In Prostate Cancer Progression
Funder
National Health and Medical Research Council
Funding Amount
$480,128.00
Summary
Prostate cancer is the most frequently occurring cancer in men in Western countries. Prostate cancer metastasis to bone and other organs is the painful end stage of this disease. The level of prostate specific antigen (PSA) in blood is often used as a marker of prostate cancer. PSA is one of 15 related enzymes in the kallikrein family of enzymes, which may be involved in breakdown of the tissue that surrounds cells in the prostate. As prostate cancer metastasis first requires spread from the pri ....Prostate cancer is the most frequently occurring cancer in men in Western countries. Prostate cancer metastasis to bone and other organs is the painful end stage of this disease. The level of prostate specific antigen (PSA) in blood is often used as a marker of prostate cancer. PSA is one of 15 related enzymes in the kallikrein family of enzymes, which may be involved in breakdown of the tissue that surrounds cells in the prostate. As prostate cancer metastasis first requires spread from the primary tumour and out of the prostate, it is possible that high production of these kallikrein enzymes by prosttae cancer cells may increase the ability of these cells to metastasise. In previous work, we have studied prostate cancer cells that we have engineered to make the kallikreins, PSA and kallikrein 4. Those cells that make PSA or kallikrein 4 are more elongated in shape and are better able to move across a porous barrier. Another important change is that these cells stop producing a protein that is usually found on the surface of these cells and is important for helping cells to stay attached to each other. When this protein is lost, these tumour cells no longer stay attached to each other and are more likely to move out of the prostate and spread into other parts of the body. The changes we observed in the cells that produce PSA and kallikrein 4 are typical of these more aggressive cancer cells. In this project, we will look at how PSA and kallikrein 4 cause the cells to undergo these changes. The majority of prostate cancer deaths arise from cancer that has spread from the primary tumour and out of the prostate capsule. This project aims to further understand the causes of prostate cancer spread and metastasis. This is a vital research priority if we are to address the mortality associated with prostate cancer metastasis and may lead to new treatment approaches for advanced metastic prostate cancer.Read moreRead less
I am a nutritional scientist with a research focus on gastrointestinal function and energy intake regulation in humans. The aim of my research is to understand (1) how any changes in gut function in obesity derail the appetite-regulatory and, thus, reinforce weight gain, ans (2) the role of gut function in the pathophysiology of digestive symptoms in patients with functional dyspepsia.
Factors Regulating The Temporal And Spatial Assembly Of G-protein Coupled Receptor-mediated Arrestin Complexes
Funder
National Health and Medical Research Council
Funding Amount
$472,770.00
Summary
G-protein coupled receptors are proteins that are present at the surface of most cells in the human body. They recognise and bind to specific molecules, such as hormones, the act of which results in a specific signal being transmitted into the cell. This signal alters the function of the cell and so it is critical that it is appropriate, both in type and duration. G-protein coupled receptors and the molecules that activate them provide an essential function within the human body for communicatin ....G-protein coupled receptors are proteins that are present at the surface of most cells in the human body. They recognise and bind to specific molecules, such as hormones, the act of which results in a specific signal being transmitted into the cell. This signal alters the function of the cell and so it is critical that it is appropriate, both in type and duration. G-protein coupled receptors and the molecules that activate them provide an essential function within the human body for communicating between cells, and consequently between organs. They are a major mechanism by which nerve signals are transmitted and hormones regulate bodily functions. They are therefore an important target for pharmaceuticals, with up to 50% of ethical drugs and many drugs of abuse acting upon them. It is critical to understand how these receptors alter cellular function once they receive an appropriate signal, but it is also essential to know how such responses are switched off. Arrestins are proteins within cells that interact with G-protein coupled receptors to 'arrest' their signalling. They desensitise the cell to continuous stimulation, but also act to resensitise the cell to respond to future, separate signals. Recently, they have also been shown to provide alternative mechanisms of altering cellular activity by interacting with other cellular proteins. These interactions greatly increase the potential ways in which a cell can respond once a G-protein coupled receptor is activated. Understanding the resulting complexity is essential if we are to fully exploit the vast therapeutic potential of this important receptor family.Read moreRead less
A Solution To The Parathyroid Gland Secretion Problem
Funder
National Health and Medical Research Council
Funding Amount
$508,003.00
Summary
Parathyroid hormone is the master hormone regulator of whole body calcium metabolism and a powerful new treatment for osteoporosis but the mechanism by which its natural secretion is controlled has never been solved. In this project we will apply new insights and advanced technical approaches to resolve this most fundamental question of calcium homeostasis, namely how parathyroid hormone secretion is controlled.
The steroid hormone aldosterone controls salt balance and hence, blood pressure. It also has been shown to have a significant role in cardiac failure. Although drugs that block the aldosterone receptor are beneficial in the treatment of heart failure, they are limited by potassium retention in the kidney. In order to develop tissue-specific blockers of the aldosterone receptor, it is necessary to identify mechanisms by which the receptor can be activated and/or blocked in these tissues.