Novel Soluble Guanylate Cyclase Activators For Pulmonary Artery Hypertension
Funder
National Health and Medical Research Council
Funding Amount
$474,087.00
Summary
Pulmonary hypertension (elevated blood pressure in the lungs) is a life-threatening condition with few treatment options. We have recently identified a new class of drug that may improve blood vessel function in the lungs and thereby provide a new drug for the management of this group of patients.
Development Of A New High Throughput Screen For Drug Binding To HERG K+ Channels
Funder
National Health and Medical Research Council
Funding Amount
$351,320.00
Summary
Inadvertent drug block of hERG, a potassium channel in the heart, can cause cardiac arrhythmias and sudden cardiac death. Screening for hERG toxicity has become a major hurdle for development of new drugs. We will use a mutant hERG protein that has enhanced drug binding to develop a high throughput test for hERG toxicity. Identification of dangerous drugs early in the drug discovery process will save the pharmaceutical industry millions of dollars in the costs of brining new drugs to market.
Development Fo A Novel Treatment For Asthma: The Identification Of Lead Small Molecule Antagonists Of The IL-13/IL-13 Re
Funder
National Health and Medical Research Council
Funding Amount
$99,750.00
Summary
In developed countries Asthma ranks among the most common chronic illnesses. Over two million Australians now have this condition and the cost to our community is estimated to be in excess of $720 million per annum. In 1996 researchers at The Walter and Eliza Hall Institute discovered a new member of the cytokine receptor family, IL-13Ra1, which further research has strongly implicated in the pathology of this disease. The main goal of the proposed research is to discover small molecule antagoni ....In developed countries Asthma ranks among the most common chronic illnesses. Over two million Australians now have this condition and the cost to our community is estimated to be in excess of $720 million per annum. In 1996 researchers at The Walter and Eliza Hall Institute discovered a new member of the cytokine receptor family, IL-13Ra1, which further research has strongly implicated in the pathology of this disease. The main goal of the proposed research is to discover small molecule antagonists of IL-13Ra1 and to identify those suitable for development as novel asthma therapeutics.Read moreRead less
Developing Novel Anti-cancer Agens By High Throughput Chemical Screens For Small Molcules That Modulate The Pro-survival
Funder
National Health and Medical Research Council
Funding Amount
$125,000.00
Summary
Cancer is the second commonest cause of deaths in our community. Unfortunately, treatment often fails or causes unwanted side effects. This proposal seeks to discover and develop a novel class of anti-cancer drugs that act by directly activating programmed cell death (apoptosis). The Bcl-2 proteins are key regulators of cell death and by exploiting knowledge about these prime targets for cancer therapy, we aim to discover drugs that are potentially of considerable medical and commercial value.
Se015: A Developmental Drug For The Treatment Of Brain Tumours
Funder
National Health and Medical Research Council
Funding Amount
$304,206.00
Summary
Primary malignant brain tumors are amongst the most lethal forms of human cancers with median survival for these patients being only around 1 year. In spite of the advent of new targeted therapies for some cancers the prognosis for these patients remains dismal. Worldwide, more than 95% of all people who contract the disease will die of it. This is because there are no effective therapies and all current treatments are only palliative, seeking to lesson the distressing suffering associated with ....Primary malignant brain tumors are amongst the most lethal forms of human cancers with median survival for these patients being only around 1 year. In spite of the advent of new targeted therapies for some cancers the prognosis for these patients remains dismal. Worldwide, more than 95% of all people who contract the disease will die of it. This is because there are no effective therapies and all current treatments are only palliative, seeking to lesson the distressing suffering associated with disease progression. Nearly all therapies that have shown some efficacy in treating cancer, such as chemotherapy and radiation have a mode of action whereby they attempt to kill cancer cells by inflicting enough damage to the cancer cells that they induce them to commit cell suicide, a process called apoptosis. Unfortunately, cancer cells can become resistant to these therapies by activating the cells' own signaling pathways that normally block apoptosis. One of the key pathways that has been implicated in resistance to apoptosis in human cancers is the PI3K-Akt pathway. This pathway is overactivated in many advanced human tumors, particularly in glioblastoma. We have discovered a compound, Se015, which can effecitively block this pathway in brain cancer cells and is able to dramatically improve the effectiveness of both chemotherapy and radiation in killing these cells. We have confirmed the efectiveness of Se015 in preliminary animal models of brain cancer, where we have shown that Se015 demonstrated no noticeable toxicity and was active when taken orally. We now need to explore further the molecular mode of action of Se015, as well as complete our animal studies with the eventual aim of initiating a small trial of Se015 in glioblastoma patients in the forseeable future.Read moreRead less
Developing Anti-Inflammatory Drugs Based On Inhibition Of A Human Enzyme
Funder
National Health and Medical Research Council
Funding Amount
$160,000.00
Summary
Human secretory phospholipases A2 have been associated with inflammatory diseases for many years, yet very few truly potent inhibitors of the human enzymes sPLA2 (isoforms IIa, V or X) are known due to a range of problems relating to the lipid nature of substrates, unavailability of enzymes, enzyme assays that do not correlate with in vivo data. Although there remains controversy about which enzyme is responsible in vivo for degrading membrane phospholipids to inflammatory mediators like arachid ....Human secretory phospholipases A2 have been associated with inflammatory diseases for many years, yet very few truly potent inhibitors of the human enzymes sPLA2 (isoforms IIa, V or X) are known due to a range of problems relating to the lipid nature of substrates, unavailability of enzymes, enzyme assays that do not correlate with in vivo data. Although there remains controversy about which enzyme is responsible in vivo for degrading membrane phospholipids to inflammatory mediators like arachidonate, PAF, prostaglandins, leukotrienes, etc. there is a consensus that blockade of phospholipid metabolism would represent a major advance on NSAIDs as antiinflammatory agents. No sPLA2-IIa inhibitor is available yet in man. We aim to create an attractive data package showing proof of concept for a potent new type of antiinflammatory drug. This data will give us an improved negotiating position in our commercialisation of a new drug with potential multi-billion dollar markets as diverse as arthritis, asthma, reperfusion injury, organ transplantation and many other currently intractable human ailmentsRead moreRead less
Development Of Novel Anti-cancer And Immunosuppressive Drugs Derived From Pineapple Stems
Funder
National Health and Medical Research Council
Funding Amount
$469,500.00
Summary
We have discovered two molecules from pineapple stems that show anti-tumour activity in laboratory studies. One molecule, called ananain, blocks a cancer causing protein called Ras, which is defective in approximately 30% of all cancers. The other molecule, called canizain, stimulates the bodies own immune system to target and kill cancer cells. The proposed research seeks to provide proof of concept of the use of ananain and canizain as drug development targets. Once this early proof of princip ....We have discovered two molecules from pineapple stems that show anti-tumour activity in laboratory studies. One molecule, called ananain, blocks a cancer causing protein called Ras, which is defective in approximately 30% of all cancers. The other molecule, called canizain, stimulates the bodies own immune system to target and kill cancer cells. The proposed research seeks to provide proof of concept of the use of ananain and canizain as drug development targets. Once this early proof of principle phase has been completed, we believe that ananain and canizain would be extremely attractive targets for further investment by a major pharmaceutical company.Read moreRead less
Development Of Pthaladyn-based Dynamin I-selective Inhibitors For Treatment Of Epilepsy
Funder
National Health and Medical Research Council
Funding Amount
$564,310.00
Summary
About 1% of the World�s population suffers from epilepsy; 30% fail to respond to anti-epileptic drugs (AED). Current AED development pathways have changed little in the past 20 years with the majority of current AEDs dampening the release of crucial chemical signals 24/7. Our new drugs, which inhibit a protein called dynamin, are only recruited at the onset of a seizure. Our approach will significantly enhance the day to day lives of those afflicted by epilepsy.
Development Of A Protein Tyrosine Kinase Inhibitor For Modification Of GAG Chains And Prevention Of Atherosclerosis
Funder
National Health and Medical Research Council
Funding Amount
$389,778.00
Summary
The major health issue in Australia is vascular and cardiovascular disease resulting from obesity and diabetes. Whilst prevention strategies based on lifestyle changes are preferable, treating cardiovascular risk factors with the latest drugs has been shown to produce significant benefits. There is however a large group of patients who still acquire cardiovascular disease in spite of drug therapy. New therapies are required and these will most likely target blood vessels directly. We have identi ....The major health issue in Australia is vascular and cardiovascular disease resulting from obesity and diabetes. Whilst prevention strategies based on lifestyle changes are preferable, treating cardiovascular risk factors with the latest drugs has been shown to produce significant benefits. There is however a large group of patients who still acquire cardiovascular disease in spite of drug therapy. New therapies are required and these will most likely target blood vessels directly. We have identified a biochemical mechanism that represents a prime target for vascular wall directed therapy and we aim to exploit the therapeutic potential of this pathway by developing a drug to prevent atherosclerosis. A group of large molecules which have recently received increasing attention are the proteoglycans, combined protein-sugar molecules which are heavily coated with negatively charged groups. The binding and retention of lipids in the wall of the blood vessel is the main cause of atherosclerosis. Specifically, the length of the sugar (GAG) chains on the proteoglycans determines the binding of the lipids. We have discovered a new class of inhibitors which directly target proteoglycan synthesis in the vessel wall and greatly reduce the interaction between proteoglycans and lipids. We wish to demonstrate the efficacy of our compound in an animal model with the aim to produce a marked reduction in the rate and extent of development of atherosclerosis. This would lay the foundation for the compound to be taken into human safety trials and subsequently develop an agent for the prevention of atherosclerosis and a thus a reduction in cardiovascular disease.Read moreRead less