Using High-throughput Genomics To Reveal The Deleterious Genetic Changes That Underlie Paediatric Leukoencephalopathies
Funder
National Health and Medical Research Council
Funding Amount
$1,003,712.00
Summary
There has been an explosion of high-throughput DNA sequencing technologies in the past five years, which have the potential to completely revolutionise medicine and scientific research. Here we present a series of studies showing the successful application of this technology to children with genetic disorders of the central nervous system. This proposal seeks to expand this study to a large cohort of similarly affected paediatric patients.
Mechanistic And Functional Drivers Of Neochromosome Evolution
Funder
National Health and Medical Research Council
Funding Amount
$763,771.00
Summary
Neochromosomes are Frankenstein chromosomes--massive extra chromosomes that are stitched together from 100s of pieces of normal chromosomes. They are found in 3% of cancers, but are common in some types, such as liposarcoma. We have mapped their structure and found they form through punctuated chromosome shattering and gene amplification. We will investigate the precise molecular mechanisms that cause this and the recurrent transcriptional and epigenetic drivers lead to their formation.
Determining Shared Genetic Control Of RNA Transcription Across 45 Human Tissue Types
Funder
National Health and Medical Research Council
Funding Amount
$264,684.00
Summary
There is strong evidence that much of the genetic susceptibility to disease acts through altering way genes are turned into proteins via RNA transcripts. One important problem in using transcriptomic data to study diseases is that the genetic control of RNA transcription is known to vary between tissues. This study will use new methods and RNA data from 45 human tissues to show the degree of common genetic control for each RNA transcript between each pair of tissues.
Mechanisms Of Antibiotic-induced Persistent Bacterial Infection
Funder
National Health and Medical Research Council
Funding Amount
$632,048.00
Summary
Golden staph still causes significant human infections and resistance to antibiotics is an ever growing problem with this bacteria. This project will determine how resistance to some antibiotics is also changing the bacteria to promote persistent, difficult to treat infections. The insights from this study will help understand evolution of this bacteria, and help design new strategies for management.
Identification Of Glaucoma Susceptibility Variants By Exome Sequencing In Extended Pedigrees Showing Prior Evidence Of Gene Segregation.
Funder
National Health and Medical Research Council
Funding Amount
$694,002.00
Summary
Primary open angle glaucoma is a chronic eye disease and one of the leading causes of visual impairment and blindness worldwide. This study will use cutting-edge genetic methods to look at the entire coding component of the human genome (exome) in 271 individuals from large glaucoma families. Our previous studies have shown that these families carry genetic variants that increase disease risk. In this investigation we aim to identify these genes, with the hope they may offer novel targets for tr ....Primary open angle glaucoma is a chronic eye disease and one of the leading causes of visual impairment and blindness worldwide. This study will use cutting-edge genetic methods to look at the entire coding component of the human genome (exome) in 271 individuals from large glaucoma families. Our previous studies have shown that these families carry genetic variants that increase disease risk. In this investigation we aim to identify these genes, with the hope they may offer novel targets for treatment or diagnosis.Read moreRead less
Epigenetic Signatures Of Abnormal Adult Neurogenesis In Rett Syndrome
Funder
National Health and Medical Research Council
Funding Amount
$869,332.00
Summary
Rett syndrome (RTT) is a severe neurodevelopmental condition arising in early childhood. In Australia, RTT affects an estimated 1/8500 females. The vast majority of RTT patients carry a single mutation in the gene MeCP2. Recent advances in genetic engineering may allow MeCP2 mutations to be corrected in patients. This study will assess whether other molecular factors are involved in the RTT phenotype in patient neurons, and whether these factors are likely to be corrected by MeCP2 gene therapy.
Reducing Pertussis Burden By Optimising Molecular Epidemiological Surveillance Of Epidemic Bordetella Pertussis In Australia
Funder
National Health and Medical Research Council
Funding Amount
$487,258.00
Summary
Australia has experienced a prolonged epidemic of pertussis from 2008 to 2012 and is currently experiencing another epidemic. In this project, we aim to elucidate the evolutionary dynamics of the epidemics by genome sequencing and develop a practical high throughput culture independent method for epidemiological typing. The outcomes will be highly significant for surveillance of pertussis infections and designing strategies for control and prevention of pertussis.
Does Mobile DNA Activity Contribute To Reproductive Failure?
Funder
National Health and Medical Research Council
Funding Amount
$389,076.00
Summary
One in four pregnancies in Australia will end in miscarriage. Infertility affects about 15% of Australian couples and is highly correlated with increasing maternal age. In this study, we will use cutting edge single-cell genomic approaches to investigate the activity of mobile DNA elements or “jumping genes” as a previously unexplored cause of reproductive failure, including spontaneous miscarriage and age-related female infertility.
Schizophrenia affects 1 in 100 people, and yet its causes remain largely unclear. To improve understanding, treatment and management of the disease, the team performing this research will evaluate whether mobile DNA elements found in our genome are activated by stress and thereby alter how brain cells work in individuals affected by schizophrenia. They will also test whether mobile DNA can be blocked by drugs, perhaps revealing new strategies to treat the disease.
Chronic pain will affect most of us at one point in our life, and there is a need for new drugs to manage this condition. The goal of this project is to use a combined state-of-the-art genetics approaches in fruit flies, mice, rats, and humans, to identify and validate new genes that contribute to chronic pain, with the clear long term possibility to develop new strategic therapies to treat chronic pain disease.