Mechanism Of Interaction Of VWC Domains And Consequence For Protein Function
Funder
National Health and Medical Research Council
Funding Amount
$516,803.00
Summary
More than 1000 proteins contain a type of module known as the VWC domain. These domains are discreet sections of the protein that are very important for how the protein works. Proteins containing this domain are involved in normal functioning of the human body and in diseases of the nervous system and blood, among others. The main function of the VWC domain is to link proteins together in complexes. How this is achieved is not known and is what we aim to discover.
Recent evidence suggests that the Siah proteins are involved in sensing low oxygen levels in cells, and subsequently activating processes to help the cell survive under these conditions. Low oxygen conditions occur in cancer and sites of inflammation, suggesting that inhibiting Siah may improve patient outcomes in diseases such as cancer and arthritis. We aim to perform a high throughput screen for drugs that inhibit Siah protein function and to test these in cancer cells.
Role Of FHA Domains As Protein-protein Interaction Modules In Cell Signalling
Funder
National Health and Medical Research Council
Funding Amount
$191,973.00
Summary
The proper processing of information in cells involves the association of different proteins to signalling complexes. We will decipher the role the so-called FHA module plays in the formation of protein complexes. FHA modules are present in several proteins that are important for the repair of damaged DNA and the stability of chromosomes. Understanding the structure and function of this module will be relevant for various forms of cancer where DNA is damaged.
Investigation Of An LMO4- And BRCA1 -containing Complex Involved In Breast Cancer
Funder
National Health and Medical Research Council
Funding Amount
$440,250.00
Summary
Breast cancer will affect one in twelve Australian women and a quarter of those will die from breast cancer. At present we still know little about what causes the disease, and there is currently a lot of activity in the field of breast cancer research that will ultimately increase our ability to both detect its development at early stages and to provide effective treatments for the disease. We do know that losing the function of a few genes (breast cancer susceptibility genes) leads to a very hi ....Breast cancer will affect one in twelve Australian women and a quarter of those will die from breast cancer. At present we still know little about what causes the disease, and there is currently a lot of activity in the field of breast cancer research that will ultimately increase our ability to both detect its development at early stages and to provide effective treatments for the disease. We do know that losing the function of a few genes (breast cancer susceptibility genes) leads to a very high likelihood of developing cancer, and we know that the normal roles of the proteins that are produced from these genes are to prevent cancers from occurring in a spontaneous fashion. However, the inheritance of mutations in breast cancer susceptibility genes accounts for only a few percent of breast cancer cases. A recently discovered protein, known as LMO4, has been found at abnormal levels in over 50% of non-inherited breast tumors. This protein has been found to both interact with the protein from the most commonly occurring breast cancer susceptibility gene, known as BRCA1, and to prevent the normal activity of BRCA1. Thus, if we could develop reagents that prevent LMO4 from interacting with BRCA1, we could use those reagents as lead compounds for the development of anti-breast cancer drugs. Before we can develop such reagents we need to fully understand both what these proteins look like and how they interact. We already know that two other proteins, known as ldb1 and CtIP are involved in the LMO4:BRCA1 interaction. We will investigate the ways in which all of these proteins interact, from determining how strong each interaction is, to getting atomic level information about which surfaces of the proteins make the most contribution to each interaction. This should let us identify good targets for the design and development of anti-breast cancer drugs.Read moreRead less
Molecular Mechanisms Of Disease In The Collagen VI-related Muscular Dystrophies
Funder
National Health and Medical Research Council
Funding Amount
$519,715.00
Summary
The inherited muscular dystrophies are an important cause of disability in Australia. This project concentrates on the second most common group of congenital muscular dystrophies - those caused by mutations in collagen VI and its interacting partners. We will determine how mutations affect the structure of the protein and how the muscle is disrupted by the mutations. This work will open the way for research into potential therapies. We will also find new genes that cause muscular dystrophy.
FHA Domain-dependent Functions Of Cell Cycle Checkpoint Kinases
Funder
National Health and Medical Research Council
Funding Amount
$235,500.00
Summary
Human chromosomes as carriers of the genetic information are constantly subjected to DNA damage. This usually occurs spontaneously, simply as a result of oxidation of DNA residues as a byproduct of cellular energy consumption or as a result of errors during chromosome duplication in growing cells, and is compounded by chemical or physical agents, for example carcinogens, UV rays or X-rays. DNA damage can have severe consequences if not properly repaired, leading to genomic instability with loss ....Human chromosomes as carriers of the genetic information are constantly subjected to DNA damage. This usually occurs spontaneously, simply as a result of oxidation of DNA residues as a byproduct of cellular energy consumption or as a result of errors during chromosome duplication in growing cells, and is compounded by chemical or physical agents, for example carcinogens, UV rays or X-rays. DNA damage can have severe consequences if not properly repaired, leading to genomic instability with loss of vast tracts of DNA or inappropriate genome rearrangements, that may ultimately give rise to cancer. To prevent such dire consequences, all organisms from yeast to man contain molecular checkpoints that sense the presence of DNA damage and then activate a cellular response program that includes damage repair and prevention of cell division while damage persists. These molecular checkpoints are highly conserved throughout evolution which allows us to analyse the details involved in simple organisms such as yeast, to draw general conclusions on their function in more complex human cells. Along these lines, we are studying the function of two yeast proteins that are similar to the human Chk2 protein, a tumour suppressor that is mutated in a subset of families suffering from the Li-Fraumeni multi-cancer syndrome. We have identified new pathways by which these proteins contribute to the survival of cells after treatment with DNA damaging agents and will further charaterise these in the present proposal.Read moreRead less