Identifying Target Genes For Novel Anti-epileptic Therapies In The Mouse
Funder
National Health and Medical Research Council
Funding Amount
$469,802.00
Summary
Epilepsy is a disease which affects 2-4% of the population. There are a wide range of drugs available to treat the condition but there is consistently 30-40% of patients who do not respond well to any of these drugs and who continue to have seizures. The reason that there are no drugs available for these people is that most of the drugs available have been designed along the same principles. A new set of principles is needed to develop new drugs which will be able to treat those people not respo ....Epilepsy is a disease which affects 2-4% of the population. There are a wide range of drugs available to treat the condition but there is consistently 30-40% of patients who do not respond well to any of these drugs and who continue to have seizures. The reason that there are no drugs available for these people is that most of the drugs available have been designed along the same principles. A new set of principles is needed to develop new drugs which will be able to treat those people not responding to current therapy. This project is designed to identify new biologic pathways which may be interrupted with drugs to prevent seizures in people with epilepsy. This project uses a procedure to induce mutations into genes in mice and then screens for mice which do not seize when challenged with a drug which generates seizures in mice. Genetic studies will identify the mutated genes and these will be used as potential targets for new therapies or will identify new biological pathway which should expand the use of future anti-epileptic drugs.Read moreRead less
Combining PI3K, CDK4/6 Pathway Inhibitors And Immunotherapies In Triple-negative Breast Cancer (TNBC): A Novel Therapy Combination
Funder
National Health and Medical Research Council
Funding Amount
$626,345.00
Summary
Triple-negative breast cancer (TNBC) has the worst prognosis of all breast cancer subtypes, classically affecting young women and characterized by a lack of effective therapies. We show that blocking both PI3K and CDK4/6 pathways together effectively reduces TNBC growth in mice and can enhance anti-tumour immune responses. We aim to understand how these drugs work together and if adding immunotherapy can improve responses. Our project could provide a new treatment approach for TNBC patients.
Characterisation Of Two Novel Markers Of Osteosarcoma Metastasis As Potential Therapeutic Targets
Funder
National Health and Medical Research Council
Funding Amount
$624,500.00
Summary
Osteosarcoma (OS) is the most common bone tumour in children and adolescents. In spite of aggressive chemotherapy, OS tumours that metastasise to the lungs result in dismal long-term survivals of only 10-20%. For these patients, new treatment options are desperately needed. In this proposal we show compelling data identifying two new markers of OS metastasis. This research aims to validate the suitability of these novel markers as therapeutic targets to prevent OS metastasis.
Understanding The Role Of The Essential Regulator WalKR In Staphylococcus Aureus
Funder
National Health and Medical Research Council
Funding Amount
$555,239.00
Summary
Staphylococcus aureus is one of the most common human bacterial pathogens. This project aims to characterise an important global control system in S. aureus, and determine if chemical inhibitors of this control system could be used to treat S. aureus disease in the future.
For 60 years, we have had only 3 effective cancer treatments: surgery, radiation and chemotherapy, often used in combination.The last 5 years have produced a powerful fourth treatment: the patient's own immune system.The long standing collaborations and synergies of our multi-disciplinary teams have already underpinned many recent advances in immune-based therapies: we are now poised to develop several further immunotherapies and on track to test them in patients during the term of this grant.
Epilepsy is one of the most common chronic neurological disorders; it affects 1% of the world’s population, yet about 1 in 3 patients fail to achieve seizure control with current drugs. We will improve the properties of small molecules (drugs) that specifically target the GTPase activity of the enzyme dynamin, to reduce seizure effect in the brain by a novel mechanism. We will optimize and pre-clinically test these future chemical entities as potential anti-epileptic drugs.
In 2013 there were ~200 million clinical cases of malaria, causing ~600,000 deaths. All antimalarial drugs are now associated with malaria parasite resistance. Thus, new therapies are urgently needed, including new drugs to prevent this disease. We have made the exciting discovery that an existing antimalarial drug can kill malaria parasites in a unique, previously unknown, manner. Here, we will investigate how this occurs and develop new drug candidates for malaria prevention.
Structure-based Design Of Novel Therapeutics For Multi-drug Resistant Neisseria Gonorrhoeae
Funder
National Health and Medical Research Council
Funding Amount
$669,148.00
Summary
Multiple drug resistance (MDR) in bacteria represents one of the most intractable problems facing modern medicine. The recent superbug, MDR-Neisseria gonorrhoeae (MDR-Ng), causes the sexually transmitted infection gonorrhoeae. A multi disciplinary team with expertise in structural biology, medicinal chemistry and bacteriology will establish a comprehensive knowledge base aimed at developing new antibiotics to treat MDR-Ng by targeting a bacterial protein virulence factor.
Development Of Small Molecule Modulators Of Apoptosis
Funder
National Health and Medical Research Council
Funding Amount
$621,558.00
Summary
Cancers rely on the deregulation of key cellular pathways. Along with biological and genetic tools, small molecules are powerful probes to understand these mechanisms. During the course of this research program, we will develop new and drug-like molecules that reinstate the cell death process to combat malignancies. This research will bring important advances for potential chemotherapies and create probes to better understand the biology of programmed cell death processes.