Novel Skeletal Muscle Enriched Genes In Muscle Biology And Disease
Funder
National Health and Medical Research Council
Funding Amount
$900,467.00
Summary
Each year hundreds of Australians are born with genetic muscle diseases, however, current methods fail to identify the causative disease gene in ~50% of patients. Here we will use expression patterns in skeletal muscle to prioritize novel candidate disease causing genes. We will functionally test the role of genes expressed in skeletal muscle cells using novel experimental assays. Uniquely, we will for the first time incorporate a novel class of gene (long non-coding RNAs) into our study.
Identification And Characterisation Of Genes Causing Autosomal Dominant Nocturnal Frontal Lobe Epilepsy (ADNFLE) And Related Phenotypes
Funder
National Health and Medical Research Council
Funding Amount
$376,640.00
Summary
Epilepsy affects approximately 2% of the population at some stage of their lives. We have recently identified two new genes involved in the development of a type of epilepsy known as ADNFLE. We aim to identify further epilepsy genes by sequencing ADNFLE patients who do not yet have identified mutations. We also aim to identify the genes interacting with the genes we have identified, increasing our understanding of the cellular networks involved in the development of epilepsy.
Identification And Characterisation Of Novel FLT3-ITD Co-operating Mutations
Funder
National Health and Medical Research Council
Funding Amount
$659,245.00
Summary
Acute myeloid leukaemia is a cancer of the blood and bone marrow. We have identified new genes that act with the known oncogene FLT3-ITD in myeloid disease. We will examine in detail how these new genes contribute to the development of AML. This will aid in the development of new therapies for groups of AML patients with these mutations.
Dnmt3L Haploinsufficent Retrotransposition Leads To Genetic Hypermutation
Funder
National Health and Medical Research Council
Funding Amount
$613,982.00
Summary
This project aims to demonstrate the critical importance of DNA methylation as a cause of mutation and thus genetic diseases, many instances of sterility and low fertility, and cancers. Because DNA methylation can be partially determined by substrate availability, a demonstration of the importance of DNA methylation vis a vis mutation rates will refine our understanding of the impact of metabolism and nutrition on mutation rate as a cause of human disease.
Analysis Of Circulating Tumour DNA For Mutational Characterisation And Tracking Disease Progression In Multiple Myeloma
Funder
National Health and Medical Research Council
Funding Amount
$908,676.00
Summary
Multiple myeloma is cancer of plasma cells in the bone marrow and presents at multiple sites with dissimilar genetic information (GI) across these sites. Invasive biopsies of multiple sites are required to determine the GI. Cancer cells shed small amounts of DNA into the blood stream and this circulating DNA (ctDNA) contains GI from multiple cancer sites. This project will evaluate the utility of ctDNA to determine GI and to predict treatment response in MM patients.
The Role Of EphA2 Signalling And Environmental Modifiers In Cataract.
Funder
National Health and Medical Research Council
Funding Amount
$591,547.00
Summary
In cataract the clear lens in the eye becomes opaque causing blindness. Cataract is very common in the elderly, but is rarely also seen in babies and children. In babies certain gene defects, and in the elderly the genes and environmental factors contribute to cataract. The EPHA2 gene causes cataract in both young and old people. This project aims to understand how EPHA2 and other related genes cause cataract in young and old people, to prevent, delay or improve its treatment in the future.
Gene Discovery In Large Multiplex Families With Autism Spectrum Disorders
Funder
National Health and Medical Research Council
Funding Amount
$879,279.00
Summary
Autism spectrum disorders (ASD) are neurodevelopmental disorders of childhood with lifelong impact. ASD are characterised by deficits in communication, language development and restricted behaviours or interests. ASD have a genetic basis likely due to multiple genes but the cause is not known in more than 75% of cases. This project will discover genes associated with ASD by studying large families in which several children have ASD and identify new targets for treatment.
The Landscape Of Cancer Genes And Associations With Prognosis In Breast Cancer Diagnosed In Premenopausal Women
Funder
National Health and Medical Research Council
Funding Amount
$700,512.00
Summary
Using state of the art technology, the purpose of this project is understand the implications of known cancer mutations in breast cancer diagnosed in premenopausal ER-positive breast cancer. Mutations are abnormalities in the DNA of genes that can provide a signal for uncontrolled growth, a hallmark of cancer. The unique aspect of this project is use of tissue samples from patients who were diagnosed with breast cancer at a young age. This information will help us develop new treatments.
Detection Of Somatic Mutations In Sporadic Epilepsies
Funder
National Health and Medical Research Council
Funding Amount
$1,256,166.00
Summary
Finding genetic causes of epilepsies is essential for refining treatments and genetic counseling. Genetic mutations may occur after fertilization (somatic mutations). These can be difficult to detect by routine genetic tests. We aim to identify somatic mutations by: very deep sequencing of blood to find low concentrations of mutations, analysing DNA from the cerebrospinal fluid, and analysing DNA obtained from the back of the nose which is closely related to brain tissue.
Somatic Retrotransposition Drives Neoplastic Mutagenesis In Glioblastoma Multiforme
Funder
National Health and Medical Research Council
Funding Amount
$667,342.00
Summary
Retrotransposons are mobile genes that copy-and-paste themselves in our genome. Previously thought to represent “junk DNA”, retrotransposons are increasingly found to play major roles in biology. In a recent landmark publication in Nature, we demonstrated that retrotransposons move in the healthy human brain. In the current study, we will use cutting-edge technologies to determine whether brain cancer can occur as a result. This will provide new perspectives of the genetic basis for cancer.