Cell-specific Regulation Of The MicroRNA/RNAi Pathway
Funder
National Health and Medical Research Council
Funding Amount
$659,390.00
Summary
MicroRNAs are a group of molecules that are critical for controlling the activity of genes. They function in a diverse range of biological systems, such the brain and immune system. Although we know that these molecules are important, how they are made in cells is still poorly understood. Because these molecules have potential therapeutic applications, it is essential that we gain a precise understanding of their biology before we will be able to apply these to medicine.
MRNA Surveillance In Human Genetic Disease: Molecular Determinants Of Nonsense-mediated MRNA Decay
Funder
National Health and Medical Research Council
Funding Amount
$371,275.00
Summary
In about 1/3 of inherited disorders the mutations introduce an abnormal stop signal into the gene so that cells risk producing truncated or erroneous proteins. To prevent this cells have developed control surveillance mechanisms called Nonsense Mediated mRNA Decay (NMD). We have found a new form of NMD and our studies are directed determining how this works in cells, which genes use this pathway, and the consequences of this for human genetic disease.
MicroRNAs are a group of molecules that are critical for controlling the activity of genes. They function in a diverse range of biological systems, from early embryonic development to adult organs, such as the brain and immune system. Although we know that these molecules are important, there remain major gaps in our understanding of how they are produced. Thus, the goal of our research is to understand how cells make these molecules.
An unusual type of molecule, circular RNA, was recently discovered to be present in human cells, and to potentially affect the ability of cancer cells in invade and metastasise. We will investigate the interactions these circular RNA molecules have with other molecules, what functions they have, and how they affect cancer cell invasion and metastasis. This could potentially reveal new ways of intervening in cancer metastasis, leading to new therapeutic modalities for cancer patients.
A New Function For Histone Variants In The Tissue-specific Regulation Of Pre-mRNA Splicing
Funder
National Health and Medical Research Council
Funding Amount
$657,224.00
Summary
It is estimated that greater than 90% of human genes undergo alternative RNA splicing, which can explain how protein diversity is achieved with a limited number of genes. However, how alternative splicing patterns are established remains poorly understood but is an important question given that 15-50% of human disease mutations are associated with changes to the splicing patterns of RNA. We have uncovered a new splicing mechanism, which involves changing the way DNA is packaged in a cell.
DBHS Protein RNA Interactions In Health And Disease
Funder
National Health and Medical Research Council
Funding Amount
$748,073.00
Summary
In cells involved in cancer, the interactions of DBHS proteins with each other, and with nucleic acids (eg RNA) are different to those in healthy cells. Only once we understand how DBHS proteins interact with some important RNA molecules, and how these interactions affect cell biology, can we begin to open up new pathways for therapy. This proposal aims at understanding and explaining this complex aspect of biology.
Molecular Insights Into Long Noncoding RNA-protein Complexes: Important Gene Regulators In Cancer
Funder
National Health and Medical Research Council
Funding Amount
$388,927.00
Summary
Cancer cells turn good genes off and bad ones on: but how do they do this? Recent breakthroughs suggest that noncoding RNA, produced from so-called ‘junk’ DNA, is important. One such noncoding RNA forms paraspeckles, a novel component of the cell machinery. Here, we will pick apart the way paraspeckles are organised and function, to develop them as a prototype for designing anti-cancer treatments against noncoding RNAs.
Understanding The Post-transcriptional Regulatory Roles Of The Hu Family Of RNA-binding Proteins Using HITS-CLIP
Funder
National Health and Medical Research Council
Funding Amount
$588,422.00
Summary
Differentiation of embryonic stem cells into differentiated states such as neurons requires complex changes in a cell's post-transcriptional gene regulation. The Hu family of proteins likely plays a critical role in this regulation, as they can bind message untranslated regions and change whether these messages ultimately make protein products or not. In this application we investigate the function of the Hu proteins in regulating specific mRNAs that we have recently identified.
Tapping The Power Of Pluripotency: The Role Of HMGA1 In Stem Cell Self-renewal And Cell Fate Transitions
Funder
National Health and Medical Research Council
Funding Amount
$520,314.00
Summary
Stem-cell-based therapies have great potential as new treatments for degenerative and genetic diseases. However, to ensure we move in the right direction, we need a detailed understanding of stem cell properties. We have recently identified a novel mechanism for controlling stem-cell-like properties in both normal and cancer stem cells. In this project, we will further investigate this new means of controlling stem cells, which could revolutionise future therapeutic strategies for many diseases.
A Novel Molecular Mechanism Controlling Myelopoiesis
Funder
National Health and Medical Research Council
Funding Amount
$878,439.00
Summary
The immune system is comprised of many different cell types, each with a specialised function. Many are short-lived and must be continually replenished throughout life. Abnormalities in this process underlie many human diseases, including immunodeficiency, autoimmunity and cancer. We have discovered a novel molecular mechanism that is critical for the production of immune cells. This project will investigate how this mechanism is controlled and the impacts on myelodysplastic syndromes.