Deciphering The Role Of Scribble In Development And Disease
Funder
National Health and Medical Research Council
Funding Amount
$628,789.00
Summary
Scribble is a protein that controls the orientation and organization of all cells within our body. Mutations in the Scribble gene are found in many cancers and also in some patients with spina bifida, however how these mutations cause these diseases is not understood. Here we propose experiments that can be used to link Scribble mutations to specific cellular functions. This information will help us design new therapies to treat diseases driven by tissue disorganization such as cancer.
Understanding How Defects In Chromosome Structure Can Cause Disease
Funder
National Health and Medical Research Council
Funding Amount
$546,557.00
Summary
The correct folding of DNA is critical to a cell's survival. This is orchestrated by a special class of proteins called the condensins. Defects in condensin lead to aberrant chromosome folding and disease. We aim to understand how condensin folds chromosomes and why mutations in condensin are increasingly associated with disease.
The Role Of A New Class Of Chromatin Organising Hub
Funder
National Health and Medical Research Council
Funding Amount
$1,145,450.00
Summary
Within the cell nucleus, specific proteins weave DNA into structured loops that are vital for normal cell function. By studying the molecules involved, we have uncovered a ‘dock’ that controls this DNA architecture. We will define the components and function of this ‘dock’, and the resulting rapid cell death that occurs if it is disrupted. We will explore this cell death pathway thoroughly because we think it may help us to develop new cancer therapies.
Links between DNA replication and chromosome end maintenance. This project aims to increase knowledge of the way in which cells maintain their genomes, including the ends of their chromosomes, to enable their own survival. The ends of chromosomes (telomeres) are essential for survival and proliferation of the cells of most organisms. This project aims to determine the molecular details of a recently discovered link between telomere maintenance and the way cells maintain the integrity of their ge ....Links between DNA replication and chromosome end maintenance. This project aims to increase knowledge of the way in which cells maintain their genomes, including the ends of their chromosomes, to enable their own survival. The ends of chromosomes (telomeres) are essential for survival and proliferation of the cells of most organisms. This project aims to determine the molecular details of a recently discovered link between telomere maintenance and the way cells maintain the integrity of their genome. This is likely to lead to increased understanding of the fundamental biological process of genome maintenance, representing a significant scientific advance. The project expects to have far-reaching implications for biotechnology applications that require the survival of cells.Read moreRead less
Role Of Bak And Bax Membrane Anchors In Targeting And Apoptotic Pore Formation.
Funder
National Health and Medical Research Council
Funding Amount
$352,319.00
Summary
In cancer cells the normal process of cell death (called apoptosis) is defective, helping abnormal cells to grow and multiply unchecked. The Bak and Bax proteins are members of the Bcl-2 family of apoptosis regulators, and play a pivotal role in mediating cell death. By defining how these proteins form a pore in mitochondria, the point of no return in cell death, will help the development of novel anti-cancer agents that target the Bcl-2 family in general, and Bak and Bax in particular.
Identification of Biological pathways regulated by circular RNAs. Circular RNAs (circRNAs) are a, recently discovered molecule. circRNAs are highly abundant and expressed in a tissue and disease specific manner. Yet, currently the understanding of how circRNAs regulate biological processes is very poor. This project aims to use pooled shRNA libraries to screen a large panel of cell lines and systematically identify cellular activities that are regulated by circRNAs. The expected outcome of this ....Identification of Biological pathways regulated by circular RNAs. Circular RNAs (circRNAs) are a, recently discovered molecule. circRNAs are highly abundant and expressed in a tissue and disease specific manner. Yet, currently the understanding of how circRNAs regulate biological processes is very poor. This project aims to use pooled shRNA libraries to screen a large panel of cell lines and systematically identify cellular activities that are regulated by circRNAs. The expected outcome of this study will be a catalogue of functionally active circRNAs. Over the past decades, the wealth of knowledge on the function of linear mRNAs has had a significant impact on medicine and agriculture. Similarly understanding how circRNAs regulate cellular activities may have an analogous impact on humans.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100584
Funder
Australian Research Council
Funding Amount
$424,636.00
Summary
DNA Replication Stress: Characterizing ground zero for genomic instability. The overarching goal of this research is to gain insights into key underlying molecular causes of, and responses to, DNA replication stress - one of the most fundamental biological processes enabling life as we know it. I will use advanced interdisciplinary imaging techniques to directly visualize DNA replication stress structures within cells in order to better understand how cells stop this stress from progressing into ....DNA Replication Stress: Characterizing ground zero for genomic instability. The overarching goal of this research is to gain insights into key underlying molecular causes of, and responses to, DNA replication stress - one of the most fundamental biological processes enabling life as we know it. I will use advanced interdisciplinary imaging techniques to directly visualize DNA replication stress structures within cells in order to better understand how cells stop this stress from progressing into DNA damage. Insights into these processes will have the potential to improve preventative and therapeutic approaches to diseases such as cancer and neurodegeneration. Read moreRead less
Spatial Arrangement And Three-dimensional Structure Of Human Centromeres
Funder
National Health and Medical Research Council
Funding Amount
$283,000.00
Summary
Centromeres occur at the main constriction of chromosomes. They allow duplicated chromosomes to divide, control cell division and are involved in the control of gene expression. Faulty centromeres are found in many types of cancer and in other genetic diseases. They are also implicated in extra-chromosome disorders such as Down syndrome. Centromeres have a different structure to the rest of the chromosome and it is this structure we wish to study. We want to see how centromere DNA folds up tight ....Centromeres occur at the main constriction of chromosomes. They allow duplicated chromosomes to divide, control cell division and are involved in the control of gene expression. Faulty centromeres are found in many types of cancer and in other genetic diseases. They are also implicated in extra-chromosome disorders such as Down syndrome. Centromeres have a different structure to the rest of the chromosome and it is this structure we wish to study. We want to see how centromere DNA folds up tightly at the centromere. We also want to find out why centromeres locate in certain regions of the nucleus, because this may influence how the centromere works and how they regulate genes. Human centromeres come in many sizes and forms; by looking at a wide range of human centromeres, common structural and spatial properties will emerge. We have discovered very small centromeres - neocentromeres - which are much easier to study than other centromeres. We have used these centromeres to construct human minichromosomes, which we believe represent the main, all-human way forward to treat people with gene therapy. One way to help us achieve our aims is to stretch out centromeres in a controlled way to make it easier to visualise their structure. Our tools will be antibodies, fluorescently-labelled proteins and high resolution microscopes. These include an electron microscope, and microscopes that can produce optical sections and in turn a 3D image. One of these is the confocal laser scanning microscope; the other involves removal of out-of-focus light from images using deconvolution software to achieve the same goal. We will detect different centromere proteins with different fluorochromes for fluorescence microscopes and different sizes of gold particles for the electron microscope. Using these microscopes we have already been able to find out where one of our neocentromeres is located within the nucleus. We have also started to look at centromeres with the electron microscope.Read moreRead less
Regulation Of The Drosophila C-Myc Homologue In Stem Cell Growth And Division.
Funder
National Health and Medical Research Council
Funding Amount
$613,397.00
Summary
The mechanisms controlling stem cell growth and division require elucidation if we are to use stem cells in regenerative medicine and find cancer treatments. Due to experimental limitations such mechanisms are largely unknown in humans. We aim to use the vinegar fly as a model system to understand the importance of microenvironment to cancer gene control in stem cells. We will identify the secreted signals, from the neighbouring cells, required to control cancer initiation in stem cells.
Cell death by a specialised process known apoptosis is a way of deleting unwanted and harmful cells from the body. As such, aberrant apoptosis is associated with a wide array of diseases including cancer. For example, abnormal levels of proteins that suppress apoptosis or enhance cell survival can result in cancer and often produce resistance to chemotherapy. To understand and treat cancers that result from aberrant apoptosis we need to know at a molecular level how apoptosis is regulated. Centr ....Cell death by a specialised process known apoptosis is a way of deleting unwanted and harmful cells from the body. As such, aberrant apoptosis is associated with a wide array of diseases including cancer. For example, abnormal levels of proteins that suppress apoptosis or enhance cell survival can result in cancer and often produce resistance to chemotherapy. To understand and treat cancers that result from aberrant apoptosis we need to know at a molecular level how apoptosis is regulated. Central to the apoptosis execution are a group of enzymes called caspases that target many cellular proteins for specific cleavage. In this proposal, we will investigate the function of one of the caspases (called caspase-2), in order to better understand its potential role in the apoptosis of cancer cells. A number of recent reports suggest that caspase-2 levels are reduced in many cancer cells. The human caspase-2 gene localizes to a chromosomal region frequently affected- deleted in leukaemia, and caspase-2 levels have been proposed to be predictors of remission and survival in patients with some types of leukaemia. We will study if loss of caspase-2 in cancer cells makes them resistant to killing by drugs and if mice lacking caspase-2 have an increased potential to develop cancer. Understanding caspase-2 function and its regulation is likely to provide new therapeutic opportunities and potential targets for cancer therapy.Read moreRead less