Exploring Roles For MicroRNAs In Cancer Using Bioinformatics And Gene Expression Tools.
Funder
National Health and Medical Research Council
Funding Amount
$292,639.00
Summary
microRNAs are newly discovered chemicals that were the subject of the 2006 Nobel Prize in Medicine. These chemicals decrease the amount of specific molecular ‘targets’ in cells, and play an important role in cancer. Currently we do not understand how these chemicals choose their targets, and we propose to use a computer-based approach to discover how they affect genes in cancer. This will improve our understanding of cancer and thereby lead to the discovery of novel anti-cancer therapies.
I am a molecular biologist determining the mechanisms of eukaryotic mRNA translation and its regulation by RNA-binding proteins and noncoding RNA. In collaborative work I extend these basic science objectives into the medical research areas of cardiology
A Comprehensive Analysis Of Myb Target Genes Involved In Myelopoiesis And Myeloid Transformation
Funder
National Health and Medical Research Council
Funding Amount
$511,294.00
Summary
The MYB gene is essential for both normal blood cell formation and the growth of leukaemia cells. It acts by switching other genes (target genes) on and off. This project aims to advance our understanding of how MYB functions, by carrying out a comprehensive search for MYB target genes. In particular it will focus on target genes that help explain MYB's ability to control cellular growth and maturation. Some of these target genes may provide leads for future anti-cancer drug development.
Macrophages are a key component of the immune system; thier functions include killing of pathogens as well as cancerous cells. Macrophage lineage cells are derived from stem cells within the bone marrow and thier differentiation, proliferation and survival is mediated by a particular growth factor termed colony stimulating factor-1 (CSF-1). The understanding of how macrophage lineage cells develop will help us to treat many diseases including certain cancers (such as leukemia), arthritis and inf ....Macrophages are a key component of the immune system; thier functions include killing of pathogens as well as cancerous cells. Macrophage lineage cells are derived from stem cells within the bone marrow and thier differentiation, proliferation and survival is mediated by a particular growth factor termed colony stimulating factor-1 (CSF-1). The understanding of how macrophage lineage cells develop will help us to treat many diseases including certain cancers (such as leukemia), arthritis and inflammation, and disorders of the immune system. The action of CSF-1 is mediated by the CSF-1 receptor (CSF-1R) which, when activated, controls gene regulation. In this proposal we will study CSF-1R activation and identify the genes regulated by CSF-1 with a view to characterize genes critical for macrophage development. These genes may provide potential targets for new pharmacological agents.Read moreRead less
Functional Validation Of FoxP3 Target Genes In Human Regulatory T Cells
Funder
National Health and Medical Research Council
Funding Amount
$545,341.00
Summary
Using DNA based technologies we have focused on rare white blood cells known as regulatory T cells. These cells are policeman of the immune system and are responsible for maintaining balanced immune reactions, and preventing attack against harmless substances. These cells prevent autoimmune disease in healthy individuals, and only by first understanding how they work normally can we investigate and correct the defects in autoimmune diseases such as type 1 diabetes.
Microarrays are a new technology for measuring the relative expression levels of thousands of genes simultaneously. They allow medical researchers to take a genome-wide look at which genes are active in a particular tissue type in an organism at a particular time. Many biomedical and biological research groups in Australia have recently untaken microarray experiments for the first time or are planning microarray experiments in the near future. Microarray experiments produce massive amounts of in ....Microarrays are a new technology for measuring the relative expression levels of thousands of genes simultaneously. They allow medical researchers to take a genome-wide look at which genes are active in a particular tissue type in an organism at a particular time. Many biomedical and biological research groups in Australia have recently untaken microarray experiments for the first time or are planning microarray experiments in the near future. Microarray experiments produce massive amounts of information and the study of how to extract this information is still in a fledgling state. This project will solve a number of fundamental problems in microarray data analysis. The emphasis is not on special methods of down-stream analysis but on basic issues which are common to all microarray experiments. The project will determine how tissue samples from different organisms should be combined in complex experiments. It will develop methods for evaluating the quality of results from microarray experiments. It will make microarray analysis less sensitive to production artifacts. It will make novel use of serial analysis of gene expression (SAGE), a more accurate but more expensive and less available technology, to calibrate the results of microarray experiments. The results will be applied during the lifetime of the project to a number of experiments at the Walter and Eliza Hall Institute and the University of Melbourne on blood cell development, cell growth and proliferation, resistance to malaria and leishmaniasis parasites, and Down syndrome.Read moreRead less
Translational Control Of Gene Expression And The Choice Between Cell Death And Proliferation
Funder
National Health and Medical Research Council
Funding Amount
$378,000.00
Summary
Proteins carry out most enzymatic and structural functions in a cell. Thus, the kinds of protein molecules that are found in a given cell determine its characteristics and cells respond to changes in their environment by adjusting the abundance of some or many proteins in their collection. The instructions for the assembly of proteins are encoded in the genes and this information is expressed via intermediary molecules called messenger (m)RNA. Both, transcription of the genes into mRNA molecules ....Proteins carry out most enzymatic and structural functions in a cell. Thus, the kinds of protein molecules that are found in a given cell determine its characteristics and cells respond to changes in their environment by adjusting the abundance of some or many proteins in their collection. The instructions for the assembly of proteins are encoded in the genes and this information is expressed via intermediary molecules called messenger (m)RNA. Both, transcription of the genes into mRNA molecules and their subsequent translation by the ribosomes into protein are tightly controlled steps in the gene expression pathway. Erroneous gene expression is a major factor in human disease and dysregulation of translation is linked to a growing spectrum of illnesses such as cancer and cardiovascular disease, viral infection, and less frequent hereditary syndromes. The project proposed here is prompted by emerging evidence for a role of translational regulation in controlling the balance between cell death and survival. Tipping this balance has disastrous consequences for an organism as evidenced by its involvement in many major disorders (e. g. stroke, heart failure, neurodegeneration, AIDS, cancer, autoimmunity). Our aim is to test the hypothesis that a putative translational regulator termed p97-DAP5-NAT1, and a specialised mechanism of translation initiation by internal ribosome entry are important for the maintenance of this balance. To investigate this, we will employ DNA chips, a novel tool from Genomics research that allows the measurement of the levels of thousands of mRNA molecules in a single experiment. It is conceivable that knowledge of these special mechanisms of translation will lead to novel targets for therapeutic intervention, and this work will contribute some of the experimental tools to explore these avenues in the future.Read moreRead less