Defining The Genes That Dictate The Cellular Response To Tumour Protein TP53 Activation
Funder
National Health and Medical Research Council
Funding Amount
$784,896.00
Summary
The tumour suppressor TP53 prevents the growth of abnormal cells by activating processes such as cell death and irreversible growth arrest. A cell will undergo only one of these possible responses, but it is not known why some cells die and others only stop growing. We will use innovative methods to define the genes that dictate the cellular response to TP53 activation. This research has implications for cancer, as many therapeutics aim to permanently kill cancer cells by activating TP53.
Integrating Biology And Medicine To Develop 3D-structure Guided Drug Design For Treatment Of Cardiovascular Disease
Funder
National Health and Medical Research Council
Funding Amount
$978,832.00
Summary
Calcium channel inhibitors are commonly prescribed for the treatment of heart disorders such as angina, hypertension, arrhythmias and hypertrophic heart disease. This class of drugs is one of the leading causes of drug-related fatalities. The impediment to designing better drugs is a lack of understanding of the 3 dimensional (3D) structure of the calcium channel. We will enable for the first time a 3D structure blueprint for the design of safe and highly selective calcium channel therapeutics.
Investigating A New Regulator Of Cardiac Rhythm In Development And Disease
Funder
National Health and Medical Research Council
Funding Amount
$1,022,704.00
Summary
Cardiac arrhythmias affect a high proportion of the population (2-5%) and can cause sudden death. Whilst the aetiology of arrhythmia can vary, there are clear genetic causes. Unfortunately, our knowledge of the genetic contributors is incomplete, hampering efforts to interpret genetic sequencing information. This project will undertake functional analyses of a novel arrhythmia gene and establish where, when and how it is required for correct cardiac rhythm.
A Cellular Identity Crisis: Deciphering How Mammary Epithelial Cells Form And Maintain Their Identity
Funder
National Health and Medical Research Council
Funding Amount
$843,826.00
Summary
The ability to regenerate human organs from adult cells efficiently and without error is a major goal of biomedical research in Australia, with significant economic benefits. As one of the most regenerative organs in a woman's body, the breast is an excellent model to study mechanisms that underpin tissue growth and regrowth. Moreover, as these pathways are often hijacked by cancer, this research has important implications for the development of new targeted therapies to treat breast cancer.
Oncogenic Determinants Of The Immune Response In Acute Myeloid Leukaemia
Funder
National Health and Medical Research Council
Funding Amount
$588,144.00
Summary
There is an urgent need to develop new therapies for patients with AML. We have shown that the body's own immune system can target certain types of AML. We will determine how these types of AML change to escape control from the immune system and how this can be reversed to re-engage the anti-AML immune response. Using patient samples, we will determine how the anti-AML immune response changes during the course of standard therapy in order to best combine it with immune-targeted therapies.
From Functional Genomics To Precision Medicine: Identifying The Cause And Finding Optimal Therapy For Oral Squamous Cell Carcinoma
Funder
National Health and Medical Research Council
Funding Amount
$855,992.00
Summary
There is an alarming increase in mouth cancer in young patients who have never smoked. This is a debilitating and potentially fatal cancer without many treatment options. If the patient survives, the quality of life is usually very poor. Our team of medical, genetic, and mathematics experts are dedicated to finding the cause, and developing new treatments, for young non-smoking patients affected by this devastating cancer.
HARNESSING T CELL QUALITY FOR PANDEMIC PREPAREDNESS
Funder
National Health and Medical Research Council
Funding Amount
$503,146.00
Summary
Developing highly effective vaccines is critical to rapidly combat global pandemics. To generate a protective antibody response against novel viruses, a vaccine must elicit a targeted B cell response supported by effective CD4 T cell help. We propose that existing CD4 T cell memory can be harnessed to rapidly and effectively support B cell responses to novel vaccine candidates. This work will contribute to pandemic preparedness strategies and improve the development pathway for new vaccines.
Facial paralysis results in loss of the ability to blink, which is the primary means of protecting and lubricating the eye. The eye becomes dry and ulcerated and eventually vision loss ensues. No therapy exists that can reliably restore blink and hence treatment is mostly palliative today. BLINC is an implantable device that artificially restores eye closure. It is wirelessly powered and readily implantable. BLINC has achieved eye closure similar to natural blinking in human cadaveric models.
Improving Cardiac Valve Implant Outcomes With Advanced Computer Simulation
Funder
National Health and Medical Research Council
Funding Amount
$593,367.00
Summary
This project focuses on improving heart valve procedures, specifically focusing on new transcatheter techniques of heart valve implantation. The research uses advanced imaging and computer simulation techniques to predict the outcome and improve minimally invasive heart procedures.
Predictive Models To Design And Develop New Antibiotics Derived From The Community For Open Antimicrobial Drug Discovery
Funder
National Health and Medical Research Council
Funding Amount
$977,427.00
Summary
With the rise of infections from multidrug-resistant bacteria, and limited antibiotics in the development pipeline, new strategies are required to generate novel antibiotics. This project will apply artificial intelligence methods to study a unique dataset generated over five years with the help of over 300 academic groups around the world. It will produce predictive models that will then be applied to design new antibiotics, which will be synthesized and tested for antimicrobial activity.