Integrative Genomics And Prediction Of Cardiovascular Disease
Funder
National Health and Medical Research Council
Funding Amount
$766,820.00
Summary
Technologies that measure whole molecular systems are just beginning to reveal the complexity of living organisms and the underlying molecular networks that govern them. Cardiovascular diseases emerge out of these networks as a result of genetic and molecular perturbations. This project aims to characterize the role molecular networks play in cardiovascular disease risk as well as how they react to genetic risk factors. In doing so, it will identify potential therapeutics and personalized approa ....Technologies that measure whole molecular systems are just beginning to reveal the complexity of living organisms and the underlying molecular networks that govern them. Cardiovascular diseases emerge out of these networks as a result of genetic and molecular perturbations. This project aims to characterize the role molecular networks play in cardiovascular disease risk as well as how they react to genetic risk factors. In doing so, it will identify potential therapeutics and personalized approaches to target pathogenesis.Read moreRead less
Discovering The Genetic Causes Of Congenital Heart Disease Using Systems Biology
Funder
National Health and Medical Research Council
Funding Amount
$419,180.00
Summary
Congenital heart disease (CHD) affects one in one hundred live-born babies, representing a significant health burden in Australia and worldwide. My research team is using state-of-the-art DNA sequencing technology to sequence the entire genome of hundreds of patients with CHD and their family members. My research program develops fast and reliable computer software to accelerate the discovery of the genetic causes of CHD, and make personalised genome-based medicine a reality.
Identifying Molecular Signatures Of Type 1 Diabetes.
Funder
National Health and Medical Research Council
Funding Amount
$49,442.00
Summary
Type 1 diabetes is caused by loss of the insulin-producing beta cells of the pancreas. Certain white blood cells of the immune system direct a damaging inflammatory response towards beta cells. Patients become ill once most of the beta cells are destroyed. This project aims to identify molecular signatures within subjects' blood which reflect the destruction. These markers will help predict diabetes risk, assess severity and response to treatment, as well as define targets for intervention.
Understanding the evolution of the alternation of generations in the land plant life cycle. This project will investigate the genetic basis and evolution of the land plant life cycle, in which both haploid and diploid phases consist of complex multicellular bodies. The project's findings, which will be made using two model laboratory plants, will be applicable to all plants and will help understand important processes such as pollen and seed production.
Molecular mechanisms that generate muscle cell type diversity. The general aim of this project is to exploit the advantages of the zebrafish system and our access to the embryology of Australian shark species to generate an understanding of the basis for muscle fibre diversity and evolution. While there is some understanding of the fundamental genetic basis of how to make an individual muscle cell from a nascent myoblast there is far less knowledge on how individual muscle cells generate mature ....Molecular mechanisms that generate muscle cell type diversity. The general aim of this project is to exploit the advantages of the zebrafish system and our access to the embryology of Australian shark species to generate an understanding of the basis for muscle fibre diversity and evolution. While there is some understanding of the fundamental genetic basis of how to make an individual muscle cell from a nascent myoblast there is far less knowledge on how individual muscle cells generate mature muscle types and patterns. The intended outcome of this research is to generate understanding of the complex molecular basis of muscle patterning in the simple paradigm of the zebrafish myotome that could be applied across the vertebrate phylogeny.Read moreRead less
Development and evolution of land plant shoots. How do plants grow and develop their wonderful diversity of forms, from cereal crops to eucalypt forests? The project aims to understand basic mechanisms of plant development via comparative studies using the model angiosperm, Arabidopsis, and the liverwort, Marchantia, which possesses a simplified genome. Comparative studies of the genetic basis of the body plan, branching, and hormonal action could unlock their evolutionary elaboration from the s ....Development and evolution of land plant shoots. How do plants grow and develop their wonderful diversity of forms, from cereal crops to eucalypt forests? The project aims to understand basic mechanisms of plant development via comparative studies using the model angiosperm, Arabidopsis, and the liverwort, Marchantia, which possesses a simplified genome. Comparative studies of the genetic basis of the body plan, branching, and hormonal action could unlock their evolutionary elaboration from the simpler liverworts to more complex flowering plants. The project may generate new understanding of the principles of how genes and hormones control the architecture of plant shoot systems, and support the targeted selection of new agricultural plants.Read moreRead less
The major histocompatibility complex and scent-mediated mate choice in a Procellariiform, Gould's petrel. In Australia, there are 25 species of Procellariiformes listed as threatened or endangered under the Environment Protection and Biodiversity Conservation Act 1999. Formulating comprehensive conservation plans for endangered species requires a good understanding of the species' breeding biology yet virtually nothing is known about the mechanisms involved in mate choice in the procellariiforms ....The major histocompatibility complex and scent-mediated mate choice in a Procellariiform, Gould's petrel. In Australia, there are 25 species of Procellariiformes listed as threatened or endangered under the Environment Protection and Biodiversity Conservation Act 1999. Formulating comprehensive conservation plans for endangered species requires a good understanding of the species' breeding biology yet virtually nothing is known about the mechanisms involved in mate choice in the procellariiforms. A better understanding of the traits these long-lived birds use when choosing their lifelong breeding partner could greatly benefit conservation strategies designed to protect them. This could be particularly beneficial where translocation is an option because birds being translocated could be assessed for compatibility prior to translocation.Read moreRead less
Mapping EQTL To Dissect The Genetic Basis Of Complex Trait Variation
Funder
National Health and Medical Research Council
Funding Amount
$719,525.00
Summary
People vary in traits such as height and blood pressure and in their susceptibility to common disease. Part of these differences between individuals is because of their genetic make-up. This research is about understanding which of the genes are involved in common variation and how they work. In particular, the researchers investigate if variation in DNA sequence causes genes to be expressed more or less and how gene expression affects risk of disease.
Squamous cell carcinoma of the skin is extremely common in Australia, resulting in disfiguring surgeries and deaths. Although cumulative sun exposure is important, some people are very susceptible, and we do not know why. This project hinges on the notion that skin cancer is a complex (many genes involved). We will utilize novel systems to harness this complexity to understand why some people are resistant and others very susceptible so as to design appropriate control measures and treatments.
Using Systems Biology To Model And Predict Human Diseases
Funder
National Health and Medical Research Council
Funding Amount
$423,326.00
Summary
In the last decade, technological advances have driven the study of biology towards the statistical and computational sciences. Researchers are now able to differentiate and quantify biomolecules at levels previously unimaginable, allowing us to study their interactions and relationships to health and disease in an unbiased, systems-level manner. With expertise in bioinformatics, biostatistics and systems biology, I am uniquely placed to address these challenges.