Epilepsy is a very common and serious brain disorder. Epilepsy often includes other disabilities, reduction in quality of life and is associated with increased risk of early death. 30% of people with epilepsy are unable to gain control of their seizures with currently available medications. The genetic causes of the large majority of epilepsy cases have not yet been found. This project aims to identify new genetic causes of epilepsy and its related disorders.
Understanding The Genetic Basis Of Breast Cancer: Translation To Primary And Secondary Prevention
Funder
National Health and Medical Research Council
Funding Amount
$2,731,372.00
Summary
We have identified >200 regions of the genome that contain variants that increase breast cancer risk. I will now focus on the main challenges i.e. to a) find the remaining genetic risk factors that will collectively explain all of the genetic risk, b) understand how these work, in particular which genes they influence and c) apply this knowledge to find and develop new drugs. Importantly, such drugs could be used not only to treat breast cancer, but also to prevent it in high-risk women.
Identification Of Parkinson's Disease Genes In Queensland Families Showing Patterns Of Mendelian Inheritance.
Funder
National Health and Medical Research Council
Funding Amount
$466,759.00
Summary
In rare cases, Parkinson's disease can be inherited through the generations of a family and it is possible to identify genetic changes that lead to this type of disease. This project aims to use new genetic sequencing technologies in several Australian families with inherited PD to find new genes that cause disease. This research will not only help these families but will teach us more about the reasons brain cells degenerate in this condition and other similar age-related brain diseases.
Transforming The Diagnosis And Management Of Severe Neurocognitive Disorders Through Genomics
Funder
National Health and Medical Research Council
Funding Amount
$2,499,330.00
Summary
Neurocognitive disorders (NCD) are one of the most common genetic conditions in our society and it results with a need for ongoing permanent care for many affected people. Until recently, only 30% of people with NCD could be diagnosed but this has changed with the availability of genomic testing where all genes can be tested at once. The use of genomics in the CRE will lead to new NCD genes being identified and this information being translated into a clinical setting.
Cancer is a genetic disease – it occurs because of genetic changes in the body that change how a cell grows, and because it occurs more often in people who have an inherited predisposition to cancer. My aim is to uncover more of the genetic events that give rise to cancer, particularly of the breast, ovary and stomach, so that we can identify people at high risk, and advice them accordingly, and also so that we can devise better treatments directed at particular genetic alterations.
I aim to decipher the role of heritable, genetic DNA variation in human neurological disease. I will use next generation genomics technologies together with sophisticated cellular models to address the important questions of the biology of epilepsy and intellectual disability in particular. I aim to develop a treatment for a specific type of epilepsy, which affects only girls from the age of 6 months. My ultimate goal is to improve the life of the patients and their relatives.
Population Genetics And Functional Genomics Approaches To Improve Outcomes For Patients With Colorectal Cancer
Funder
National Health and Medical Research Council
Funding Amount
$466,492.00
Summary
Colorectal cancer (CRC) is the third leading cause of cancer related death in Australia, and the 5-year survival rate for metastatic disease remains below 10%. Over the next 4 years, my translational research program will focus on improving patient outcomes in four ways: Discovery of inherited variants affecting CRC risk and progression, tumour molecular classification, discovery of markers for prognosis and drug response, and elucidation of the molecular mechanisms driving CRC development.