Interactions Between Integrative Genomic Islands And Plasmids; Role In The Spread And Loss Of Antibiotic Resistance And Pathogenicity Determinants
Funder
National Health and Medical Research Council
Funding Amount
$776,465.00
Summary
Mobile elements that integrate into bacterial chromosomes at a specific site contribute pathogenicity and antibiotic resistance determinants to their bacterial host but only a few are able to move themselves into new hosts. Some plasmids and some elements can help certain others. In this project, genetic approaches will be used to investigate how plasmids and integrative elements help one another move into a new bacterium or compete with one another to stay in the same cell.
Understanding The Role Of SSB1 In Embryonic Development And Genome Maintenance
Funder
National Health and Medical Research Council
Funding Amount
$620,716.00
Summary
Normally DNA exists as a double helix where two strands are zipped together. When single-stranded (ss) DNA is exposed during various cellular processes it can be easily damaged and degraded by cellular enzymes, but is protected by ssDNA binding proteins (SSBs). We have identified two new SSBs (SSB1 and SSB2) that play a crucial role in DNA repair and will investigate the role and physiological function of these important proteins.
Immunoglobulin Germline Genes, BCR Repertoire Development And Disease Susceptibility. An Investigation Of Haplotypic Variation Between Individuals
Funder
National Health and Medical Research Council
Funding Amount
$519,828.00
Summary
The immune system is capable of making a repertoire of protective antibodies including literally tens of millions of different specificities. These are produced by permutations and combinations of a small set of ‘germline’ genes. This project will analyse how individual variations in the germline genes lead to individual differences in the repertoires of available antibodies, and will investigate whether or not such differences contribute to our susceptibility to infection and autoimmune disease ....The immune system is capable of making a repertoire of protective antibodies including literally tens of millions of different specificities. These are produced by permutations and combinations of a small set of ‘germline’ genes. This project will analyse how individual variations in the germline genes lead to individual differences in the repertoires of available antibodies, and will investigate whether or not such differences contribute to our susceptibility to infection and autoimmune diseases.Read moreRead less
HIV infection is a dynamic process, in which the host immune response tries to control viral growth and keep up with the rapid evolution of the virus. This project assembles an interdisciplinary team of mathematicians and biologists to use a modelling approach to understand the dynamics of viral infection, viral evolution, and immune control in the infected individual. The insights gained from this project will help in the development of new drug and vaccination strategies.
Directed Evolution Of AAV Capsid Variants For Enhanced Targeted Genome Editing In The Human Liver
Funder
National Health and Medical Research Council
Funding Amount
$386,012.00
Summary
Liver transplantation is often the only treatment option available for patients with severe liver disease, and is complicated by a shortage of donor organs and the need for life-long drug therapy to prevent rejection. Repair of a patient’s own liver by gene therapy is a promising alternative. This project focuses on developing the technology required to undertake precise correction of genetic spelling errors in diseased liver cells without the need to first remove them from the body.
Telomere Structural Abnormalities In Cells Using Alternative Lengthening Of Telomeres
Funder
National Health and Medical Research Council
Funding Amount
$522,122.00
Summary
The continuing growth of cancers depends on their cells being able to prevent shortening of chromosome ends (telomeres). Some cancers, including very aggressive brain and connective tissue tumours, achieve this via the Alternative Lengthening of Telomeres (ALT) process. We have evidence that the telomere structure of normal cells prevents ALT. Here we will examine how the telomere structure of ALT-positive cancer cells is changed, and whether reversing these changes inhibits ALT.