Insulin-like Growth Factor (IGF)-II Binding Specificity Of IGF Binding Protein-6: Structural And Functional Studies.
Funder
National Health and Medical Research Council
Funding Amount
$265,630.00
Summary
Insulin-like growth factor II (IGF-II) is a protein which is involved in normal growth. However, in some circumstances it may also stimulate cancer growth. IGF binding protein-6 (IGFBP-6) binds to IGF-II and stops its activity. One of the major challenges of modern biology is understanding why some proteins bind to other proteins. Proteins fold in various ways and have specific three-dimensional structures. Two proteins which bind strongly to each other have structures which fit each other like ....Insulin-like growth factor II (IGF-II) is a protein which is involved in normal growth. However, in some circumstances it may also stimulate cancer growth. IGF binding protein-6 (IGFBP-6) binds to IGF-II and stops its activity. One of the major challenges of modern biology is understanding why some proteins bind to other proteins. Proteins fold in various ways and have specific three-dimensional structures. Two proteins which bind strongly to each other have structures which fit each other like a 'lock and key'. The aim of this project is to understand how IGFBP-6 binds to IGF-II by looking at its three-dimensional structure. Using this information, it may be possible to develop new treatments which can inhibit IGF-II activity and therefore may be useful in the treatment of some cancers.Read moreRead less
SPECIFIC MODIFICATION OF SKELETAL MUSCLE RYANODINE RECEPTOR ACTIVITY
Funder
National Health and Medical Research Council
Funding Amount
$411,000.00
Summary
The project will have implications for muscle fatigue, which is a public health issue in an aging population, and for neuromuscular diseases and muscle weakness. The ryanodine receptor (RyR) calcium release channel regulates changes in calcium concentrations inside the muscle cell that are essential for respiration and movement. Defects in expression of RyRs results in death in utero or at birth. The RyR is also important in many other tissues, where it acts either alone or in combination with a ....The project will have implications for muscle fatigue, which is a public health issue in an aging population, and for neuromuscular diseases and muscle weakness. The ryanodine receptor (RyR) calcium release channel regulates changes in calcium concentrations inside the muscle cell that are essential for respiration and movement. Defects in expression of RyRs results in death in utero or at birth. The RyR is also important in many other tissues, where it acts either alone or in combination with a second type of calcium channel, to regulate the changes in the concentrations of calcium ions within the cell, which are essential for a variety of processes including cardiac contraction, vascular constriction, neuronal activity and immune responses. Despite its importance, little is known about the regulation of the RyR channel opening during contraction in skeletal muscle or the mechanisms of ion movement through its pore. It is often difficult to define the specific role of RyRs in intact tissues because of the lack of specific probes for the channel. The RyR is an obvious target for therapeutic drugs to modify muscle contraction, but has not been used as such because of the lack of specific and reversible drugs. Muscle performance is reduced, and fatigue is rapid, in neuromuscular disease. Performance can be improved by variety of drugs like anabolic steroids which unfortunately have additional adverse actions. The aims of the project are (a) to discover more about the regulation of, and ion conduction pathway through, the skeletal muscle RyR channel, (b) to identify compounds that can be used as specific probes for RyR activity and (c) to identify compounds that might in the future provide the basis for development of the RyR as a therapeutic target.Read moreRead less
Endocrine And Autocrine Regulation Of Breast Cancer Cell Growth By IGF Binding Protein-3 (IGFBP-3).
Funder
National Health and Medical Research Council
Funding Amount
$497,250.00
Summary
The insulin-like growth factor (IGF) system of growth factors and their regulatory proteins is essential for normal growth, but is also involved in a number of overgrowth disorders. Some clinical studies have shown that a high level of IGF-I in the blood increases the risk of breast cancer in some women, but if the protein which carries it in the circulation, IGFBP-3, is also high, the risk is reduced. It has therefore been suggested that IGFBP-3 may be useful in the treatment of breast cancer. ....The insulin-like growth factor (IGF) system of growth factors and their regulatory proteins is essential for normal growth, but is also involved in a number of overgrowth disorders. Some clinical studies have shown that a high level of IGF-I in the blood increases the risk of breast cancer in some women, but if the protein which carries it in the circulation, IGFBP-3, is also high, the risk is reduced. It has therefore been suggested that IGFBP-3 may be useful in the treatment of breast cancer. This is supported by laboratory studies showing that IGFBP-3 can inhibit cell division and stimulate cell death in many cell types, including breast cells. However, some cells are resistant to IGFBP-3 s inhibitory effects, and in some cases IGFBP-3 may stimulate cells to grow and divide. In fact, the amount of IGFBP-3 present in breast tumours is highest in the fastest growing, most malignant tumours, suggesting that IGFBP-3 may be stimulating their growth. Our laboratory data indicates that breast cancer cells which produce a high level of IGFBP-3 grow faster as tumours than cells which produce little or no IGFBP-3. We believe that this is because IGFBP-3 interacts with another hormone system which is involved in rapid tissue growth, the EGF system, and increases its ability to stimulate breast cells to divide. These observations raise a number of important questions: how does IGFBP-3 interact with the EGF system to stimulate tumour growth; does IGFBP-3 from the blood promote the growth of EGF-sensitive tumours; and can the interaction between IGFBP-3 and the EGF system be abolished, or switched from growth stimulatory to growth inhibitory, thus inhibiting tumour growth. Answering these questions will provide important new information regarding IGFBP-3 s stimulatory and inhibitory actions, and the role of endocrine IGFBP-3 in tumour growth, and have the potential to lead to the development of novel therapies involving IGFBP-3 for the treatment of overgrowth disorders.Read moreRead less
Molecular Characterisation Of The Ligand-binding Domain Of The Mineralocorticoid Receptor
Funder
National Health and Medical Research Council
Funding Amount
$215,183.00
Summary
The steroid hormone aldosterone regulates blood pressure by controlling sodium retention. The important role of this hormone in blood pressure control is underlined by the fact that all known monogenetic hypertensive conditions involve aldosterone or sodium reabsorption. Aldosterone works by activating an intracellular 'receptor' protein that in turn switches on specific genes. The products of these genes act to produce sodium retention. Antagonists (blockers) of this receptor are used in the tr ....The steroid hormone aldosterone regulates blood pressure by controlling sodium retention. The important role of this hormone in blood pressure control is underlined by the fact that all known monogenetic hypertensive conditions involve aldosterone or sodium reabsorption. Aldosterone works by activating an intracellular 'receptor' protein that in turn switches on specific genes. The products of these genes act to produce sodium retention. Antagonists (blockers) of this receptor are used in the treatment of hypertension but have undesirable side effects. The design of new, more specific, antagonists has been slow because we do not understand how these drugs bind to the receptor and what effect they have on the protein. How the aldosterone receptor functions is poorly understood. This project aims to investigate the receptor in detail. We are in the process of determining regions of the receptor structure important for hormone binding. This information is vital for the design of new antagonists. The aldosterone receptor is unusual in that it is also activated by cortisol, a steroid hormone involved in stress and inflammation. By examining hormone binding it may be possible to determine if the two steroids activate the receptor in the same way. An understanding of how both natural hormones and synthetic antagonists function is impossible without thorough study of the receptor itself. We intend to examine fundamental aspects of aldosterone receptor function. In particular we wish to identify proteins that interact with the receptor. These proteins either enhance or inhibit the ability of the receptor to switch on genes and are vital to explaining the actions of both natural hormones and synthetic antagonists. Results from these experiments should advance our understanding of the basic biology of aldosterone action and its role in cardiovascular biology, and lead to the design of better receptor antagonists for use in the treatment of hypertension and cardiac fibrosis.Read moreRead less
Epidermal Growth Control In Psoriasis And Normal Skin
Funder
National Health and Medical Research Council
Funding Amount
$451,980.00
Summary
Our skin protects us from damage, dehydration, infection and harmful UV radiation. At the same time, we expect it to remain healthy, smooth and looking good. How the skin, and more particularly its upper layer, the epidermis, adapts to all these requirements is a complex problem yet to be fully understood. This question forms the basis of our project proposal. The epidermis is a continuously self-renewing tissue, in which cells have an average life of 30 days before they are invisibly shed to th ....Our skin protects us from damage, dehydration, infection and harmful UV radiation. At the same time, we expect it to remain healthy, smooth and looking good. How the skin, and more particularly its upper layer, the epidermis, adapts to all these requirements is a complex problem yet to be fully understood. This question forms the basis of our project proposal. The epidermis is a continuously self-renewing tissue, in which cells have an average life of 30 days before they are invisibly shed to the outside. In normal states and when responding to injury or disease, this cell turnover speed can be finely tuned, for example accelerated in the case of a healing wound. In contrast, if damaged by the sun, epidermal cells undergo a form of cell suicide (apoptosis) to prevent tumours forming from cells with damaged genes. This changing turnover speed is controlled by a series of growth factors, or cytokines. Insulin-like growth factor-I (IGF-I) is a unique cytokine that can control both cell turnover rate, and cell death. We aim to uncover the complex biochemical interactions that allow the epidermal IGF-I system to achieve this seemingly contradictory task. This study is important because when the epidermis loses the ability to finely tune its turnover speed, ulcers, sun damage, the common skin disorder psoriasis, or worse still, skin tumours, arise. This project explores ways of manipulating the IGF-I system to prevent this, and builds on some technology developed by the research group that has already proven effective in the control of psoriasis. The project also promises to discover undiscovered growth regulators that could be used in new gene therapies for skin overgrowth diseases.Read moreRead less