Macrophage Migration Inhibitory Factor (MIF) And P53 In Rheumatoid Arthritis .
Funder
National Health and Medical Research Council
Funding Amount
$333,055.00
Summary
Rheumatoid arthritis (RA) is an inflammatory disease affecting approximately 1% of the population. It is characterised by severe inflammation and destruction of joints resulting in significant health problems. The lining tissue of joints is known to be infiltrated by inflammatory cells. In addition to this infiltration of inflammatory cells, there is overgrowth of the normal lining cells of joints. These overgrowing cells contribute significantly to joint damage by invading cartilage and bone an ....Rheumatoid arthritis (RA) is an inflammatory disease affecting approximately 1% of the population. It is characterised by severe inflammation and destruction of joints resulting in significant health problems. The lining tissue of joints is known to be infiltrated by inflammatory cells. In addition to this infiltration of inflammatory cells, there is overgrowth of the normal lining cells of joints. These overgrowing cells contribute significantly to joint damage by invading cartilage and bone and allowing inflammatory cells to reach these areas. The abnormal growth of these cells has been related to the malfunction of certain genes that usually restrain abnormal growth. These genes called tumour suppressor genes are known to be damaged in joint lining cells derived from RA. The best known of these abnormal tumour suppressor genes is called p 53. The product of the p53 gene, the p 53 protein, is particularly important in slowing down the growth of cells. The applicant has recently shown that an inflammatory product called MIF is released in large quantities by joint lining cells in RA. Previous studies by the applicant have shown that blocking MIF using an antibody almost completely prevents arthritis development in a rat model. These studies indicate that MIF is likely to be an important contributor to disease in RA. Recent preliminary studies in the applicant s laboratory have shown that MIF can decrease p53 levels in joint lining cells from RA patients and also that MIF can increase the growth rate of these cells. These preliminary data indicate that MIF may contribute significantly to disease in RA by overriding control of normal cell growth by p53. Confirmation and full exploration of the regulation of p53 expression and function by MIF may highlight a novel way to treat the excessive growth and invasion by joint lining cells which characterises RA.Read moreRead less
Macrophage Migration Inhibitory Factor (MIF): Pathological And Therapeutic Significance In Post- Infarct Inflammation
Funder
National Health and Medical Research Council
Funding Amount
$547,577.00
Summary
Ischemic heart injury mediated by the inflammatory response has a significant impact on the prognosis. MIF is a central factor mediating and amplifying the inflammatory response but its role in heart disease remains largely untested. This project will study, for the first time, the crucial role of MIF in ischemic heart disease and will establish important experimental evidence for developing new anti-inflammation therapeutic strategies against ischemic heart injury.
In this study, mouse models of disease will be used to determine the mechanisms by which the proinflammatory molecule called MIFpromotes the development of insulin resisitance and type 2 diabetes. We will also test whether therapeutic blockade of MIF can prevent the progression of disease in mice with established type 2 diabetes. Studies on tissue samples obtained from human patients will be used to confirm the human relevance of these findings.
Insulin-like Growth Factor Binding Protein-3 (IGFBP-3) Sensitivity And Signalling In Breast Cancer
Funder
National Health and Medical Research Council
Funding Amount
$414,343.00
Summary
The growth of all tissues in the body depends on many growth factors, hormones and other proteins which work together to control cell division. Some of these factors stimulate the division of the cells which make up the body tissues, and some inhibit it, so that a balance of these stimulators and inhibitors ensures that tissues do not grow too fast, or too large. The development of breast cancer and the growth of breast tumours is thought to be due to uncontrolled or faulty actions of the protei ....The growth of all tissues in the body depends on many growth factors, hormones and other proteins which work together to control cell division. Some of these factors stimulate the division of the cells which make up the body tissues, and some inhibit it, so that a balance of these stimulators and inhibitors ensures that tissues do not grow too fast, or too large. The development of breast cancer and the growth of breast tumours is thought to be due to uncontrolled or faulty actions of the proteins and hormones which regulate the way breast cells multiply. One protein which normally regulates the division of breast cells is IGFBP-3. We have found that in some breast cancer cells, IGFBP-3 is no longer able to inhibit cell division, and this may lead to tumour growth and invasion of other tissues. We are interested in finding out how IGFBP-3 normally controls breast cell proliferation, and why some breast cancers are resistant to IGFBP-3. To do this, we will use normal breast cells in culture to examine how IGFBP-3 interacts with other cellular factors to prevent cell division. We will then look at whether the breast cancer cells have changed so that they are no longer able to recognise IGFBP-3 as an inhibitory protein. This may be because of changes in the way IGFBP-3 binds to the breast cancer cell, or because of changes in the way it interacts with other proteins in the cell. Because IGFBP-3 is made by normal and breast cancer cells, we will also study whether the IGFBP-3 being made by breast cancer cells is normal, or if it changed in some way that makes it inactive. By understanding why some breast cancers are not inhibited by IGFBP-3, we will be able to design new and better methods of preventing, detecting and treating the growth of all breast tumours.Read moreRead less
Regulating Platelet Thrombus Formation By Inhibitory Co-receptors
Funder
National Health and Medical Research Council
Funding Amount
$441,000.00
Summary
Platelets are a specialised adhesive cell essential for normal blood clotting. Following induction of blood vessel injury, platelets stick to sites of injury and activation mediate platelet spreading, aggregation and stable blood clot formation. Platelet adhesion to components of the blood vessel in flowing blood is central to blood clot formation. We are studying the role of inhibitory receptors that regulate the platelet adhesion phase on the blood vessel surface. We have knockout mice that la ....Platelets are a specialised adhesive cell essential for normal blood clotting. Following induction of blood vessel injury, platelets stick to sites of injury and activation mediate platelet spreading, aggregation and stable blood clot formation. Platelet adhesion to components of the blood vessel in flowing blood is central to blood clot formation. We are studying the role of inhibitory receptors that regulate the platelet adhesion phase on the blood vessel surface. We have knockout mice that lack a specific protein, Platelet Endothelial Cell Adhesion Molecule-1 (PECAM-1) that we can use to study its functional role in blood clot models. We are developing transgenic mice to examine the important structural domains in PECAM-1 that lead to regulation of blood clots. The knowledge gained from this work will help to improve our understanding of the regulatory processes which influence the formation of a stable blood clot. This information is relevant to many human diseases including heart attack and stroke.Read moreRead less
The Role Of Src Family Tyrosine Kinases In Inflammatory Lung Disease And Cancer
Funder
National Health and Medical Research Council
Funding Amount
$535,333.00
Summary
We aim to learn why some people develop COPD, a serious lung disease, and adenocarcinoma, a common fatal lung cancer. COPD is mostly caused by cigarette smoke which induces lung inflammation. Lung inflammation, which involves macrophage activation, is a major cancer risk. Macrophages can destroy lung tissue, and they may promote cancer development. We will study the role of Src kinases, which can regulate macrophage activation, which may lead to new treatments for these diseases.