I am a Molecular Biologist who has built up a large set of transgenic animal models based around the NPY system to use them in an integrated physiology approach to investigate important regulatory mechanisms in the interaction of the brain with peripheral
Analysis Of The Plasmodium Falciparum M18 Aspartyl Aminopeptidase
Funder
National Health and Medical Research Council
Funding Amount
$613,683.00
Summary
Malaria remains a major cause of death and disease in many parts of the world. There is widespread resistance to all currently used drugs and an urgent need for new treatmants. We have identified the malaria enzyme, aspartyl aminopeptidase as a new drug target. This proposal will investigate the biological role of this enzyme and has the potential to identify new compounds which may be effective antimalarial drugs.
Analysis Of The Interaction Of The T-cell Oncoproteins Scl And Lmo2 In T Cell Acute Lymphoblastic Leukaemia
Funder
National Health and Medical Research Council
Funding Amount
$179,149.00
Summary
Leukaemic cells frequently contain alterations to the chromosomes which contribute to the generation of the leukaemia by causing the expression of cancer-promoting genes. In the case of T cell acute lymphoblastic leukaemia (T-ALL), the most frequent target of chromosomal alterations is the Stem Cell Leukaemia gene, or SCL. In leukaemic cells, the SCL protein is found to be associated with another protein, called Lmo2, the gene for which is also activated due to chromosomal alterations in T-ALL. ....Leukaemic cells frequently contain alterations to the chromosomes which contribute to the generation of the leukaemia by causing the expression of cancer-promoting genes. In the case of T cell acute lymphoblastic leukaemia (T-ALL), the most frequent target of chromosomal alterations is the Stem Cell Leukaemia gene, or SCL. In leukaemic cells, the SCL protein is found to be associated with another protein, called Lmo2, the gene for which is also activated due to chromosomal alterations in T-ALL. It is thought that these two proteins must bind each other to cause leukaemia, but this has never been proven. This project aims to test whether removal of SCL and Lmo2 is able to stop the progress of leukaemias which they initiate. We will do this by overexpressing SCL and Lmo2 to establish leukaemia in mice, then removing these genes to see if the leukaemia is cured. We will then test whether removal of the endogenous SCL protein is able to stop the onset and progress of leukaemias initiated by Lmo2. We will do this by removing SCL in mice which overexpress Lmo2. Lastly we will generate mutant SCL proteins which are unable to interact with Lmo2, and co-express these along with Lmo2 in mice to assess whether they are able to co-operate with Lmo2 in causing leukaemia. We predict these mutants which are unable to bind to Lmo2 will be unable to co-operate with it in causing leukaemia. This will identify regions of these proteins which can be used as targets for anti-leukaemia drug development.Read moreRead less
Targeted Alpha Therapy: Development Of A New Treatment For Metastatic Cancer
Funder
National Health and Medical Research Council
Funding Amount
$394,400.00
Summary
Breast cancer is the most commonly diagnosed, malignant cancer in women and prostate cancer is the most common non-life style related cancer in men. In spite of the most aggressive therapy, a significant percentage of men and women die of secondary disease (metastases) which usually spreads in the early stages. Currently, therapy is limited to chemotherapy and hormone therapy, both of which show clinical improvement but long term survival is uncertain. Targeted alpha therapy (TAT) is a new cance ....Breast cancer is the most commonly diagnosed, malignant cancer in women and prostate cancer is the most common non-life style related cancer in men. In spite of the most aggressive therapy, a significant percentage of men and women die of secondary disease (metastases) which usually spreads in the early stages. Currently, therapy is limited to chemotherapy and hormone therapy, both of which show clinical improvement but long term survival is uncertain. Targeted alpha therapy (TAT) is a new cancer treatment that we are developing in mouse models of human breast and prostate cancer. With TAT we are exploiting the fact that aggressive breast and prostate cancer cells, but not normal cells, express a particular tissue-barrier degrading protein system (uPA) which is specifically recognised by a natural inhibitor protein (PAI2). This protein inhibitor is labeled with a highly effective cell killing agent, a radioisotope that emits high energy alpha particles with a short range of only a few cell diameters . The alpha-labeled PAI2 selectively kills cancer cells at their most malignant stage by targeting the uPA system on these cells. Another benefit of TAT is that little radiation damage occurs to nearby or distant normal cells. Thus side-effects would be minimised. The outcome of our research to date has been to show the potential of our unique TAT approach as a possible new therapy for breast and prostate cancer. This therapy may well prove beneficial for other cancers. Further safety evaluations studies in mice will be followed by a dose tolerance clinical trial in humans. We expect to be able to show that our TAT will regress breast and prostate cancer tumours without complications in mice. The human trials will show the tolerance limits to TAT. If successful, TAT could provide the basis for a major change in prognosis and quality of life of breast and prostate cancer patients.Read moreRead less
Characterization Of The 72 KDa Inositol Polyphosphate 5-phosphatase
Funder
National Health and Medical Research Council
Funding Amount
$454,050.00
Summary
Cells respond to external signals and the enviroment to undergo cell growth, secretion and or other specialized functions including control of cell death and or cell size. We have identified a new enzyme (72 kDa 5-phosphatase) which resides inside the cell, which we have evidence plays a role in regulating both the movement of intracellular vesicles and also lipid signals stimulated by insulin. We have characterised the phospholipids that the enzyme cleaves and demonstrated the generation of new ....Cells respond to external signals and the enviroment to undergo cell growth, secretion and or other specialized functions including control of cell death and or cell size. We have identified a new enzyme (72 kDa 5-phosphatase) which resides inside the cell, which we have evidence plays a role in regulating both the movement of intracellular vesicles and also lipid signals stimulated by insulin. We have characterised the phospholipids that the enzyme cleaves and demonstrated the generation of new cell signals at specific subcellular localizations on intracellular membranes. We predict the generation of these specific lipid signals may play a significant role in controlling the transport of intracellular cargo to specific sites in the cell. In this grant proposal we aim to examine the regulation of specialised cargo called the glucose transporter, which is found in fat and muscle cells, and also the mannose 6-phosphate receptor, which regulates the trafficking of specific enzymes which mediate digestion of proteins. These studies include the clarification of which phospholipid signals the enzyme terminates and where in the cell this occurs. Secondly, we will examine the movement of the glucose transporter GLUT-4 in unstimulated cells and in response to insulin and furthermore how expression of the novel enzyme regulates its movement. We will also examine the movement of the mannose 6-phosphate receptor and the specific phospholipid signals which control the route the receptor traffics, using inhibitors of lipid signals and expression of lipid phosphatases and kinases. We will also examine how our novel enzyme forms complexes with other molecules in the cell and characterise these novel molecules using basic biochemical assessment of enzyme activity and function. Finally we will examine the regulation of intracellular messages by our novel enzyme following insulin stimulation, which facilitates glucose uptake into the cell.Read moreRead less
Regulation Of Protein Kinases And Their Substrates
Funder
National Health and Medical Research Council
Funding Amount
$553,197.00
Summary
Our research is concerned with the control of the body's energy metabolism via an enzyme called AMPK. This enzyme is at the hub of metabolic control in response to diet and exercise. AMPK controls energy expenditure in response to demand as well as appetite. It is well recognized that diet and sedentary life-styles are major contributors to obesity and cardiovascular disease. We are testing how a new drug activates AMPKand how energy expenditure can be increased.
Epilepsy is a very common and serious brain disorder. Epilepsy often includes other disabilities, reduction in quality of life and is associated with increased risk of early death. 30% of people with epilepsy are unable to gain control of their seizures with currently available medications. The genetic causes of the large majority of epilepsy cases have not yet been found. This project aims to identify new genetic causes of epilepsy and its related disorders.