Flaviviral Proteases As Viable Targets For Antiinfective Drugs
Funder
National Health and Medical Research Council
Funding Amount
$620,716.00
Summary
Viruses hijack the machinery and nutrients of cells they infect in order to reproduce. We will study viral enzymes (proteases) essential for virus replication, use fluorescent probes to learn where the viral enzymes hide and act in infected cells, track the passage of drugs aimed at these enzymes, design drugs to block their actions and stop virus replication, and test antiviral activity against Dengue, West Nile, Japanese Encephalitis and Yellow Fever viruses which infect millions of people.
Disruption Of Proteolytic Cascades In The Skin:towards Halting The Atopic March
Funder
National Health and Medical Research Council
Funding Amount
$388,601.00
Summary
There are over 3000 named skin disorders which range in severity from the trivial including acne, to life threatening such as skin cancer. Many skin diseases result from a lack of control over the way the skin maintains itself. Cutting the connections that hold cells together is key to balancing loss of skin cells with their continuous replacement. This project focuses on making compounds to block skin cell shedding with the longer term aim of producing novel drugs to treat skin disease.
Control Of Proteases In Infectious, Degenerative And Cardiovascular Disease
Funder
National Health and Medical Research Council
Funding Amount
$11,668,789.00
Summary
Proteases are enzymes that control key processes in humans. The research in this program will result in major discoveries in the field of proteases and their inhibitors, with a focus on inflammatory, cardiovascular and degenerative disease. The knowledge gained from this strong foundation of fundamental research will underpin the translational outcomes necessary to combat the debilitating effects of immunological dysfunction, conformational and cardiovascular disease.
Plasmin is a complex enzyme that performs major roles in removal of blood clots, wound healing and in tumor metastasis. Here we will understand how plasmin function is regulated at the molecular level. These key insights will be of future use in the development of therapeutics targeting the plasmin system in cancer and clotting diseases.
I am a protein crystallographer determining the structures of medically important proteins such as proteases. I am also a bioinformatician leading the development of informatics systems for automated highthroughput crystallography, and bioinformatic analy
Design And Development Of Small Molecules To Regulate Protease Activated Receptor Type 2
Funder
National Health and Medical Research Council
Funding Amount
$439,500.00
Summary
A new class of proteins have been discovered on the surface of cells. These are activated by enzymes known as proteases and are therefore called Protease Activated Receptors (PARs). PARs appear to be very important 'sensors' of proteases outside cells, becoming activated in response to very low concentrations of proteases. This suggest that proteases may exert some of their biological effects through these receptors, which are now implicated in a growing number of diseases (e.g. thrombosis, card ....A new class of proteins have been discovered on the surface of cells. These are activated by enzymes known as proteases and are therefore called Protease Activated Receptors (PARs). PARs appear to be very important 'sensors' of proteases outside cells, becoming activated in response to very low concentrations of proteases. This suggest that proteases may exert some of their biological effects through these receptors, which are now implicated in a growing number of diseases (e.g. thrombosis, cardiovascular disorders, asthma, inflammatory bowel disease, Crohn's disease, pancreatitis, stomach and colon cancer, arthritis, and there may also be a role in wound healing). We are working towards dissecting the roles for one of these receptors (PAR2) in disease by developing small molecules for selective binding to this receptor. We will particularly distinguish between compounds that can activate (agonists) or deactivate (antagonists) the receptor. These experiments will involve computer-assisted compound design, structural comparisons between small molecules with activity and those without, and cellular studies designed to measure affinity, activation and deactivation of PAR2. The outcome will be a series of small molecules that bind tightly to the PAR2 receptor and have a well defined function (antagonist, agonist, partial agonist). While the above studies are in progress some peptides that are known to activate this receptor will be examined in rodent models of human disease (airways inflammation, pancreatitis, stomach and colon cancer, arthritis). Studies like this have been very revealing for us in the past (Nature 1999, 398, 156-160 A protective role for protease-activated receptors in the airways). Then the designed and developed compounds will also be examined for signs of therapeutic potential. The work will provide a better understanding of how this receptor works and a clearer picture of the role of this receptor in human disease.Read moreRead less
The West Nile Viral Protease, NS3: A Target For Antiviral Drug And Vaccine Design
Funder
National Health and Medical Research Council
Funding Amount
$230,500.00
Summary
The West Nile Virus (WNV) was first isolated from a woman in the West Nile region of Uganda in 1937. It is one of ~70 known flaviviruses (e.g. Dengue fever, Yellow fever, West Nile, Kunjun, Japanese encephalitis, St. Louis encephalitis, tick-borne encephalitis, Australian encephalitis and the related hepatitis C virus) which annually infect hundreds of millions of people worldwide, particularly in tropical and sub-tropical areas, and cause major public health problems. WNV is endemic in the Midd ....The West Nile Virus (WNV) was first isolated from a woman in the West Nile region of Uganda in 1937. It is one of ~70 known flaviviruses (e.g. Dengue fever, Yellow fever, West Nile, Kunjun, Japanese encephalitis, St. Louis encephalitis, tick-borne encephalitis, Australian encephalitis and the related hepatitis C virus) which annually infect hundreds of millions of people worldwide, particularly in tropical and sub-tropical areas, and cause major public health problems. WNV is endemic in the Middle East, parts of Africa and Europe, but recent epidemics in Israel (1998), Romania (1996), United States (1999), and UK (2003) have been characterized by severe symptoms , severe neurological pathology, and fatalities. In the USA alone there were 4,156 infections and 284 deaths in 2002, 9122 infections and 223 deaths in 2003, and this mosquito borne virus has quickly spread since 1999 through all USA states and into Canada and Mexico (http:--www.cdc.gov-ncidod-dvbid-westnile-index.htm). No treatments or vaccines are available. This project focuses on an enzyme, known as the West Nile Virus NS3 protease, that is essential for replication of the virus. By studying the enzyme in the laboratory we can design small molecules that can block its function and these have real potential as leads for development of drug treatments for people infected by this virus. A precedent is the success of inhibitors of HIV-1 protease that are the most effective treatment for humans with HIV-infections. Our studies will also be used to develop potential vaccines. The science involves experts on protease enzymes, drug design and development, virology including West Nile virology, and vaccine development. We expect to generate drug and vaccine candidates and new information for their development that is at the cutting edge of West Nile Virus research.Read moreRead less
Regulation Of The Cardiovascular Disease-Associated Protease Inhibitor Cystatin C For Therapeutic Application
Funder
National Health and Medical Research Council
Funding Amount
$498,505.00
Summary
Proteases can contribute to atherosclerosis, so they are normally controlled by the endogenous inhibitor, Cystatin C (Cst C). Some conditions cause reduction in Cst C levels and hence disease. On the other hand, excess Cst C can form toxic aggregates. In this project, we will identify mechanisms controlling Cst C expression and aggregation to find therapeutic strategies to treat cardiovascular diseases associated with Cst C.
Regulation Of Synthesis, Dimerisation And Secretion Of The Amyloidogenic Protease Inhibitor Cystatin C
Funder
National Health and Medical Research Council
Funding Amount
$423,565.00
Summary
The cells that compose our tissues are embedded in a complex mesh of extracellular proteins (for example collagen) that provide support, strenght and elasticity to the tissues. This extracellular matrix is not static; it is constantly remodelled when, for example, the cells of the immune system move through interstitial spaces to monitor the healthiness of the tissues. When infections or injuries occur, the inflammatory reactions that develop, and the processes involved in tissue repair, also in ....The cells that compose our tissues are embedded in a complex mesh of extracellular proteins (for example collagen) that provide support, strenght and elasticity to the tissues. This extracellular matrix is not static; it is constantly remodelled when, for example, the cells of the immune system move through interstitial spaces to monitor the healthiness of the tissues. When infections or injuries occur, the inflammatory reactions that develop, and the processes involved in tissue repair, also involve profound changes in the composition of the extracellular matrix. Such processes are also important for tumour growth; the cancer cells need to clear their way through interstitial space to escape to circulation and metastasize. During all these processes, the cells release to the extracellular space proteases that degrade collagen and the other components of the extracellular matrix. Obviously, these proteases must be tightly regulated to prevent them running out of control, so the cells also produce inhibitors of the proteases. The amount of proteases and inhibitors contained in the extracellular space must be maintained properly. If this equilibrium is disrupted, this can lead to pathology For instance, atherosclerosis is caused in part by excessive proteolysis of the blood vessel wall. In this project we want to study the mechanisms of one of the most abundant and important inhibitors of extracellular proteolysis: Cystatin C. We have discovered that certain cells of the immune system called dendritic cells posses interesting mechanisms to regulate how much Cystatin C they secrete. Furthermore, one of this mechanisms, which consists of pairing the protein to produce inactive dimers, may be the cause of some diseases characterised by accumulation of Cystatin C in the extracellular space. Our study may allow us to design therapies for the treatment of pathologies associated with defective or excessive production of Cystatin C.Read moreRead less