Mechanisms And Patterns Of Post-Transcriptional Gene Control
Funder
National Health and Medical Research Council
Funding Amount
$707,370.00
Summary
Genetic information resides in the DNA of our genome; however, to use this information it must be transcribed into chemically related RNA molecules, collectively known as the transcriptome. While different body cells carry the same genome, they differ widely in their transcriptome composition. To understand how cells properly utilise their transcriptomes we will characterise the marks and binding partners found on RNA in the context of cardiac and cancer biology.
MRNA Surveillance In Human Disease: Molecular Determinants Of Nonsense-mediated MRNA Decay
Funder
National Health and Medical Research Council
Funding Amount
$474,517.00
Summary
Inherited diseases are a common cause of human disability, illness and suffering. It has been estimated that 5-10% of the population will be affected by disorders with a genetic component. Thus studies on mechanisms of inherited diseases, especially those relating to genetic mechanisms with relevance across a wide range of individual disorders and gene mutations, are of great significance in diagnosis, molecular pathology and the eventual development of therapeutics. While there are many types o ....Inherited diseases are a common cause of human disability, illness and suffering. It has been estimated that 5-10% of the population will be affected by disorders with a genetic component. Thus studies on mechanisms of inherited diseases, especially those relating to genetic mechanisms with relevance across a wide range of individual disorders and gene mutations, are of great significance in diagnosis, molecular pathology and the eventual development of therapeutics. While there are many types of mutations, one relatively common type is called a premature termination mutation. Premature termination mutations introduce an inappropriate genetic signal that tells the cells to stop the formation of proteins before they are complete. This would result in the production of a protein that is shorter than normal, and these short proteins could be quite abnormal and drastically affect the normal function of cells. To overcome this, cells have developed elegant strategies that involve the deployment of quality control, or surveillance, mechanisms to remove the mutant gene product before it can be converted into an abnormal protein. This process is called nonsense mediated decay. Nonsense mediated decay is a complex process and some of the key components have been identified by studies on a small number of genes. However, our studies have identified several previously unknown aspects of the process that suggest that the currently held view of how nonsense mediated decay works is only the beginning of the story and further important complexity exists. The proposed research will explore the basic mechanisms of the surveillance process and determine the signals that initiate nonsense mediated decay. Since premature termination mutations cause one-third of all inherited genetic disorders, our studies will provide new insights into the surveillance mechanisms and will have wide applicability to our understanding of the basis of inherited disease.Read moreRead less
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.
Characterising The Topology And Function Of The Human M5C RNA Methylome
Funder
National Health and Medical Research Council
Funding Amount
$602,537.00
Summary
The role of the modified base 5-methylcytosine (m5C) as an epigenetic mark in DNA is well appreciated and intensely studied. By comparison, the cellular functions of the same base modification in RNA molecules, which function as working copies of the DNA genome, are poorly understood. This project will apply next generation sequencing technology to chart the occurrence of m5C in eukaryotic cellular RNAs and endeavour to unravel its function(s) in human biology and cancer.
Alterations In Secretion And Gene Expression In Pancreatic Beta Cells Exposed To Lipid.
Funder
National Health and Medical Research Council
Funding Amount
$425,250.00
Summary
The project is aimed at a better understanding of the way in which fats control gene expression in the pancreatic beta cells of the islets of Langerhans. Because changes in gene expression are to likely to explain why exposure of these cells to fat disrupts their ability to release insulin, identification of these genes could explain why only some obese people develop Type 2 diabetes.
Heterogeneous Nuclear Ribonucleoprotein Role In Alternative RNA Splicing And Human Disease
Funder
National Health and Medical Research Council
Funding Amount
$254,250.00
Summary
Control of the use of DNA, gene expression, is vital to all living organisms, especially in development and disease. The information in the genes of DNA is transferred to an intermediate molecule, mRNA, in a process called transcription. The genetic information in the mRNA is subsequently used, in the process called translation, to make the protein encoded by the original gene. The switching on and off of DNA appears to be most frequently controlled at the transcription step but recently it has ....Control of the use of DNA, gene expression, is vital to all living organisms, especially in development and disease. The information in the genes of DNA is transferred to an intermediate molecule, mRNA, in a process called transcription. The genetic information in the mRNA is subsequently used, in the process called translation, to make the protein encoded by the original gene. The switching on and off of DNA appears to be most frequently controlled at the transcription step but recently it has become apparent that there are many post-transcriptional events that govern how efficiently the genetic information is ultimately converted to protein molecules. An important step is the cutting out of parts (introns) of the RNA molecule that is copied from DNA, and splicing of the retained sections (exons). During this process the RNA may also lose one or more of its exons. As a result of this variable retention of exons a single gene may produce many isoforms of the protein it encodes. By this mechanism the roughly 30,000 genes in the human genome can give rise to potentially hundreds of thousands of proteins. RNA splicing connects to cancer in two ways. First, changes in the concentrations of the proteins that control splicing may change the isoforms, resulting in changes that lead to uncontrolled cell proliferation. Secondly, DNA mutations that affect the splicing process can also vary the ratios of the isoforms produced from a gene: if this occurs in a protein that is involved in the growth of cells this too may lead to cancer. In this project we will study the molecular mechanism of this alternative splicing, and particularly a group of proteins that generally favour the excision of some exons, with a focus on cancer cells. Recent publications have highlighted the potential for the therapeutic use of drugs that target the splicing apparatus: it is anticipated that studies of alternative splicing will underpin development of new therapeutic agents.Read moreRead less
Post-transcriptional Gene Regulation In RNA-granules
Funder
National Health and Medical Research Council
Funding Amount
$533,274.00
Summary
This project is focused on understanding pathways that regulate RNA metabolism and development. Using the powerful C. elegans model organism (nonpathogenic roundworm) we will undertake experiments to identify pathways that regulate how some mRNAs are stored and later activated during reproduction. The outcomes of these experiments should provide many interesting clues as to how development is regulated by posttranscriptional mechanisms, and have broad relevance to other tissues and organisms.