Novel Candidate Genes, Lung Function And Allergic Airways Disease
Funder
National Health and Medical Research Council
Funding Amount
$581,892.00
Summary
We propose to study airway remodelling (structural changes to the airway) and in asthma using human samples and rodent models of asthma. We are particularly interested in investigating the role of trefoil peptide 2 and relaxin, two genes identified as determining lung function. To do this we need to understand the mechanisms of airway remodelling and its impact on disease severity in the patient. A strength of this study is availability of samples from a large study of human asthma.
Understanding Cell Signalling Mechanisms Activated By Relaxin Family Peptides: Targets With Therapeutic Potential
Funder
National Health and Medical Research Council
Funding Amount
$306,842.00
Summary
One of the most powerful ways that the activity of the cells that make up the tissues and organs of the body can be changed is by the interaction of chemicals with proteins called receptors located at the cell surface. The commonest type of receptor is called a G-protein coupled receptor as it is linked to mechanisms inside the cell by the G-proteins. These receptors are the most commonly targeted by pharmaceutical companies that wish to alter the responses of cells for therapeutic purposes and ....One of the most powerful ways that the activity of the cells that make up the tissues and organs of the body can be changed is by the interaction of chemicals with proteins called receptors located at the cell surface. The commonest type of receptor is called a G-protein coupled receptor as it is linked to mechanisms inside the cell by the G-proteins. These receptors are the most commonly targeted by pharmaceutical companies that wish to alter the responses of cells for therapeutic purposes and almost 2-3 of all drugs currently marketed work through these proteins. This project will examine the mechanisms whereby certain types of G-protein coupled receptor produce signals in cells and determine what are the critical areas of the receptor for these interactions. The receptors involved have been discovered only in the last 4 years and little is known of the ways these change the activity of cells. The substances acting on these receptors have potential for development as targets for drugs that have the potential to treat fibrosis which is a feature of many diseases including cardiac failure, kidney failure and lung disease.Read moreRead less
Determinants Of Binding And Activity Of G-protein Coupled Receptors RXFP1 And RXFP2; The Receptors For Relaxin And INSL3
Funder
National Health and Medical Research Council
Funding Amount
$531,696.00
Summary
Relaxin is a hormone which has long been known to have essential roles in pregnancy and birth. However it has also been demonstrated to have far broader involvement in the functioning of the kidney, heart and central nervous system. It is currently in clinical trials with our commercial partner BAS Medical for the treatment of congestive heart failure, cervical ripening and preeclampsia. Furthermore, relaxin shows enormous promise as an antifibrotic agent which has far-reaching therapeutic conse ....Relaxin is a hormone which has long been known to have essential roles in pregnancy and birth. However it has also been demonstrated to have far broader involvement in the functioning of the kidney, heart and central nervous system. It is currently in clinical trials with our commercial partner BAS Medical for the treatment of congestive heart failure, cervical ripening and preeclampsia. Furthermore, relaxin shows enormous promise as an antifibrotic agent which has far-reaching therapeutic consequences since fibrosis is a hallmark of all forms of progressive cardiovascular and renal disease and obstructive airway disease (asthma), which collectively contribute to 40-50% of deaths in developed countries. Research into the mechanisms whereby relaxin exerts its cellular effects has been limited by the inability of researchers to identify its receptor. We now know that relaxin acts through a novel G-protein coupled receptor (GPCR) Relaxin Family Peptide Receptor (RXFP) RXFP1 and will also acts on a related receptor RXFP2. The RXFP2 receptor is actually the receptor for a hormone with similarities to relaxin, INSL3. It is essential that an appreciation of RXFP receptor function is obtained not only for its important actions in pregnancy, but also for its clinical applications. In this regard, improved understanding of how relaxin and INSL3 interact with their receptors and how these receptors function is essential. We will continue our previously successful approaches to study the interaction of relaxin and INSL3 with these receptors and the mechanisms by which the receptors function. The knowledge gained will aid in the design of smaller, more potent and orally active forms of relaxin and INSL3 for future clinical applications. This multi-disciplinary approach will allow us to fully maximise the clinical potential of this enigmatic hormone.Read moreRead less
Mechanisms Of Impaired Uterine Vascularisation In Early Pregnancy.
Funder
National Health and Medical Research Council
Funding Amount
$570,414.00
Summary
Vascular dysfunction and reduced blood flow to the placenta are underlying causes of pre-eclampsia and hypertension in pregnant women. Our proposal will identify if low circulating levels of the hormone relaxin are causes of abnormal development of the uterine vasculature in early pregnancy. This knowledge will enable us to develop new treatments to improve health outcomes in women at high risk of developing these diseases during their pregnancy.
The Structural Basis Of The Interaction Of Human Relaxins With Their Receptors.
Funder
National Health and Medical Research Council
Funding Amount
$489,000.00
Summary
Human Gene 2 (H2) relaxin is a peptide hormone structurally related to insulin and has numerous biological actions related to its roles during pregnancy. It exerts these primarily by inducing the breakdown of collagen and the formation of new blood vessels while simultaneously stimulating tissue growth and inhibiting cell death. Its functions have led to several potential therapeutic roles for relaxin being explored. These include the treatment of fibrotic disorders and peripheral vascular disea ....Human Gene 2 (H2) relaxin is a peptide hormone structurally related to insulin and has numerous biological actions related to its roles during pregnancy. It exerts these primarily by inducing the breakdown of collagen and the formation of new blood vessels while simultaneously stimulating tissue growth and inhibiting cell death. Its functions have led to several potential therapeutic roles for relaxin being explored. These include the treatment of fibrotic disorders and peripheral vascular disease. H2 relaxin is the principal expression product in vivo and has been shown to exert a wide range of physiological responses beyond those normally associated with pregnancy. We have recently discovered another human - H3 - relaxin that is expressed primarily in the brain which strongly suggests a neuropeptide role. Surprisingly, H2 and 3 relaxins each act via different G-protein coupled receptors. We will perform detailed structure-function studies to determine how these relaxins impart their specific biological actions. Modern chemical synthesis protocols will be used to prepare each of these complex peptides in adequate quantities for detailed secondary and tertiary structural study. Analogues containing modified residues and global domains will be prepared and assayed for characteristic relaxin agonist and antagonist activity. Sophisticated biomolecular interaction analyses will be used to identify differences in receptor binding regions for the two relaxins. The results, together with those obtained by three-dimensional structural analysis using NMR spectroscopy, will allow us to ultimately define the key features of the H2 and 3 hormones that are responsible for selective receptor binding and specific relaxin activity. We will then be able to design smaller, more stable, orally active relaxin mimetics. Such compounds will have great potential for therapeutic application in the treatment of fibrosis or as biological and pharmacological probes of relaxin action.Read moreRead less
The Structural Basis Of The Interaction Of Human Relaxins With Their Receptors.
Funder
National Health and Medical Research Council
Funding Amount
$573,807.00
Summary
Relaxin is a peptide that is involved in the regulation of the birth process. It has considerable promise as an anti-fibrotic agent. Recently, another relaxin-like peptide, relaxin-3, was identified and shown to be brain-specific. It modulates the stress response and appetite. Both relaxins act upon different receptors to elicit their biological effects. To exploit their clinical potential, we will determine how these peptides selectively bind and ativate their individual receptors.
Novel G-protein Coupled Receptors LGR7 And LGR8; The Receptors For Relaxin And Insulin-like Peptide 3 (INSL3)
Funder
National Health and Medical Research Council
Funding Amount
$496,500.00
Summary
Relaxin is a hormone which has long been known to have essential roles in pregnancy and birth. However it has also been demonstrated to have far broader involvement in the functioning of the kidney, heart and central nervous system. Furthermore, mice lacking relaxin show increased collagen, or fibrosis, in their internal organs and skin as they age. This progressive fibrosis leads to problems with bodily functions. Treatment of these mice with relaxin reverses the fibrosis and restores function, ....Relaxin is a hormone which has long been known to have essential roles in pregnancy and birth. However it has also been demonstrated to have far broader involvement in the functioning of the kidney, heart and central nervous system. Furthermore, mice lacking relaxin show increased collagen, or fibrosis, in their internal organs and skin as they age. This progressive fibrosis leads to problems with bodily functions. Treatment of these mice with relaxin reverses the fibrosis and restores function, hence relaxin has great potential as a treatment for fibrotic diseases. Anti-fibrotic drugs are a major target for drug companies as suitable compounds are not currently available. Research into the mechanisms whereby relaxin exerts its cellular effects has been limited by the inability of researchers to identify its receptor. We now know that relaxin acts through a novel G-protein coupled receptor (GPCR) LGR7 and will also act on a related receptor LGR8. The LGR8 receptor is actually the receptor for a hormone with similarities to relaxin, INSL3. It is essential that an appreciation of relaxin receptor function is obtained not only for its important actions in pregnancy, but also for its clinical applications. In this regard, improved understanding of how relaxin interacts with these two receptors is essential. We will use our expertise in producing these hormones together with molecular techniques to produce the receptor, to study the interaction of relaxin and INSL3 with these receptors and the subsequent cellular events that occur. Furthermore, to more effectively use relaxin as a drug, we need to discover a smaller, more potent and orally active form of the hormone. We will develop novel technologies to aid in the discovery of the next generation of relaxin drugs. This multi-disciplinary approach will allow us to fully maximise the clinical potential of this enigmatic hormone.Read moreRead less
Relaxin Signalling In The Endometrium And The Regulation Of Early Pregnancy
Funder
National Health and Medical Research Council
Funding Amount
$466,125.00
Summary
Relaxin is a hormone, that is made in the ovary and the uterus, and plays a very important role in supporting the growth and development of the uterus so that the young embryo can implant properly. In fact, early pregnancy loss is associated with altered levels of relaxin in the blood. Very little is known about how relaxin works in the uterus. This project aims to address this important function, and makes use of cultured uterine cells prepared from tissues taken from women undergoing hysterect ....Relaxin is a hormone, that is made in the ovary and the uterus, and plays a very important role in supporting the growth and development of the uterus so that the young embryo can implant properly. In fact, early pregnancy loss is associated with altered levels of relaxin in the blood. Very little is known about how relaxin works in the uterus. This project aims to address this important function, and makes use of cultured uterine cells prepared from tissues taken from women undergoing hysterectomy for fibroids or similar illnesses. When these cells are grown in culture, we can mimic in vitro many of the events that occur in early pregnancy, causing the cells to differentiate and grow just as they would in vivo. Relaxin appears to exert its important effects on these cells by causing the concentration of the second messenger cAMP in the so-called stromal cells to increase greatly and in a sustained manner. It is this cAMP which is then responsible for many of the changes which are essential for healthy pregnancy. A knowledge of the molecular mechanisms behind these effects would help us firstly to understand how the uterus becomes receptive to an implanting embryo, and may explain why some women lose their babies in early pregnancy, or develop some of the negative symptoms associated with placental development such as growth restriction and preeclampsia. Relaxin appears to stimulate cells through the mediation of a new type of cell surface receptor, called LGR7. Whilst structurally this receptor looks like those for many other hormones, belonging to the group of so-called G-protein coupled receptors, it does not behave like these in natural uterine cells. Instead it appears to make use of completely new signaling pathways inside the cells. This project aims to unravel and understand these new pathways, thus providing information not only of importance for diagnosis and treatment of early pregnancy problems, but also of relevance for all other similar receptors.Read moreRead less
Relaxin-3 Systems In Brain: Validation Of Neural Targets And Functional Roles
Funder
National Health and Medical Research Council
Funding Amount
$537,579.00
Summary
Our laboratory recently discovered the brain 'transmitter' called 'relaxin-3', and are researching how it affects brain activity and animal physiology and behaviour. Findings suggest that relaxin-3 can modulate memory, responses to stress and other complex behaviours. Identifying the various actions of relaxin-3 in the brain could provide potential new treatments for conditions such as anxiety-depression, cognitive deficits (dementia) and schizophrenia.