Many serious inflammatory diseases, such as arthritis, septic shock, lung shock and heart disease are poorly controlled with currently available drugs. There is much evidence that a circulating hormone system called complement is involved with exacerbating these diseases, yet there are no drugs available to counteract its effects. One powerful component of the complement system, called C5a, causes inflammation and is suspected of causing tissue damage and suffering in these and many other immune ....Many serious inflammatory diseases, such as arthritis, septic shock, lung shock and heart disease are poorly controlled with currently available drugs. There is much evidence that a circulating hormone system called complement is involved with exacerbating these diseases, yet there are no drugs available to counteract its effects. One powerful component of the complement system, called C5a, causes inflammation and is suspected of causing tissue damage and suffering in these and many other immune diseases. An agent that could block the effects of C5a could be very useful clinically. There is no such drug available as yet. We have developed powerful agents which specifically block C5a in laboratory tests on isolated cells and tissues, and now propose to test their effectiveness in rats in which the above human disease conditions are mimicked. Our preliminary results are very promising, and we will conduct further testing to determine the scope of the actions of the new drugs. One of our new agents is orally active in rats, and we will determine how the blood levels of the drug relate to its beneficial effects. We are also planning to develop agents that are more effective when given by mouth. The results could lead to a new type of anti-inflammatory drug for humans suffering from a variety of diseases that are poorly treatable at present.Read moreRead less
Agonists And Antagonists Of The Human Complement C3a Receptor
Funder
National Health and Medical Research Council
Funding Amount
$473,250.00
Summary
Many serious inflammatory diseases, such as arthritis, septic shock, lung shock, heart disease, atherosclerosis, multiple sclerosis, are poorly controlled with currently available drugs. There is a great deal of evidence that naturally occuring Complement proteins in human blood are involved in exacerbating these and many other human diseases, yet there are no good drugs available to counteract their effects. One of the most important complement proteins is known as C3a. It is called an anaphyla ....Many serious inflammatory diseases, such as arthritis, septic shock, lung shock, heart disease, atherosclerosis, multiple sclerosis, are poorly controlled with currently available drugs. There is a great deal of evidence that naturally occuring Complement proteins in human blood are involved in exacerbating these and many other human diseases, yet there are no good drugs available to counteract their effects. One of the most important complement proteins is known as C3a. It is called an anaphylatoxin and is thought to be a pivotal component of the complement system synthesized by the human body early on in the development of inflammatory and immune diseases. New compounds that could stimulate or block the activity of C3a are expected : (a) To lead us to a better understanding of how C3a binds to its receptors on immune cells and its role in the immune response to infection and injury, and (b) To enable the rapid development of an entirely new class of drugs for treating autoimmune and inflammatory diseases. No Complement-based drugs are yet available. It is not yet possible to examine detailed structures of the receptors on cells that interact with complement proteins. However it is possible to determine and analyse three dimensional structures of small molecules that can bind to human immune cells, and mimic or block effects of human C3a on cells, rat tissues, and in whole rats. We will identify and improve such small molecules by optimising their binding to immune cells, by tailoring them to selectively block or mimic just the effects of C3a, and by making them pharmacologically stable for administration (preferably by mouth) to rats (and humans). We will then test them in rats for potential future development into a completely new type of anti-inflammatory drug, one that treats inflammatory disease processes rather than just the symptoms like most current antiinflammatory drugs.Read moreRead less
Complement C5a Receptors , Placental Inflammation And Reproductive Impairment.
Funder
National Health and Medical Research Council
Funding Amount
$1,025,229.00
Summary
We are investigating how mothers may have health difficulties during pregnancy, such as high blood pressure, and how this can affect their fetuses' health. There is emerging evidence that an unhealthy placenta during pregnancy can greatly affect fetal development, and it seems that inflammation in the placenta during pregnancy may be a key factor in reducing fetal growth, resulting in low birth weight infants. Our studies are aimed at developing new treatments for this.
Potent Small Molecule Modulators Of A Complement Protein In Inflammation
Funder
National Health and Medical Research Council
Funding Amount
$689,428.00
Summary
We have invented powerful new compounds that act on the cell surface and regulate inflammation. We plan to (1) fine-tune our small molecules for optimal activity on different kinds of immune cells; (2) understand mechanisms by which the compounds affect cellular inflammatory responses; (3) evaluate the compounds as potential treatments in rodent models of inflammatory diseases implicated from cell studies. This study is anticipated to lead to clinical studies for a new kind of drug treatment.
Downsizing A Human Protein To Modulate Inflammatory Diseases
Funder
National Health and Medical Research Council
Funding Amount
$516,793.00
Summary
We have discovered how to downsize a human protein to very small molecules with the same activities and potencies. Small changes enable the compounds to powerfully block the actions of the protein. These small molecules are very stable in blood, whereas the protein deactivates in minutes. This project will develop the small molecules into experimental drugs and test them in human cells and proteins, and in rats to evaluate their potential for treating human inflammatory diseases.
Targeting Neuroinflammatory Pathways As Novel Treatments For Dementia
Funder
National Health and Medical Research Council
Funding Amount
$600,116.00
Summary
Australia has a rapid increase in its ageing population, and consequently an increase in detrimental age-related dementia and neurodegenerative diseases which are a major healthcare burden. Current treatments for diseases such as Alzheimer’s, Parkinson’s and Huntington’s are inadequate and there is a desperate need for new treatments. I have unique access to molecules that target two novel mechanisms for neurodegenerative diseases. This fellowship will explore their therapeutic potential.
Targeting Complement C5a Receptor 2 As A Disease-modifying Treatment For Motor Neuron Disease
Funder
National Health and Medical Research Council
Funding Amount
$636,329.00
Summary
Motor neuron disease (MND) is a devasting terminal condition that has no effective treatment. We have identified a novel drug which inhibits an immune protein that can potentially treat MND. In this project we will test this drug in rodent models of MND, and validate its effectiveness in relevant MND immune cells. Ultimately, this project will identify a new potential drug for MND.
Therapeutic Targeting Of Complement C5a Receptors In HuntingtonÍs Disease
Funder
National Health and Medical Research Council
Funding Amount
$468,312.00
Summary
HuntingtonÍs disease is a genetic neurodegenerative condition leading to progressive cognitive and motor deficits and eventual death. This research aims to explore the role of immune and inflammatory pathways in the progression of disease in patients suffering HuntingtonÍs disease, as well as in an animal model of this condition. By exploring these immune and inflammatory pathways, we aim to identify novel therapeutic targets to treat HuntingtonÍs disease.