We have recently discovered that MOZ (monocytic leukaemia zinc finger gene), a gene first identified in rmutations leading to a particularly aggressive form of leukaemia, is a major regulator of senescence. In the absence of MOZ cells exit the cell cycle and become senescent, independently of DNA damage. These obsevations are very important for understanding cancer development because for cancer to grow and spread the cells must avoid senescence.
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.
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
Role Of DNA Methylation And Non-coding RNA In Human Centromere Function
Funder
National Health and Medical Research Council
Funding Amount
$499,000.00
Summary
A chromosome is a grouping of coiled strands of DNA, containing many genes. Every human cell has 23 pairs of chromosomes, which together comprise the genome. Both gain and loss of any of these chromosomes will lead to severe medical problems including birth defects and cancer development. Thus, the understanding of the mechanisms underlying the exact passage of these chromosomes from a parental cell to two new cells during cell division, and how the information is copied from from one cell gener ....A chromosome is a grouping of coiled strands of DNA, containing many genes. Every human cell has 23 pairs of chromosomes, which together comprise the genome. Both gain and loss of any of these chromosomes will lead to severe medical problems including birth defects and cancer development. Thus, the understanding of the mechanisms underlying the exact passage of these chromosomes from a parental cell to two new cells during cell division, and how the information is copied from from one cell generation to another, is an important area of research, however, much remains to be learnt about the mechanisms. Our laboratory was the first to discover a key component of the chromosome that is involved in the regulation of the cell division process, ensuring the accurate segregation of chromosomes. This structure, known as a neocentromere, is an ideal model system to study important aspects of chromosome segregation. The present project proposes to study the properties of this neocentromere in detail. The outcome will contribute to our knowledge on the processes underlying cell and chromosome division, which will ultimately have a direct impact on our understanding of the causes for some of the most common clinical conditions that affect human health.Read moreRead less
Developing Novel Molecules That Target Hormone Receptors As An Alternative Cancer Therapy
Funder
National Health and Medical Research Council
Funding Amount
$459,867.00
Summary
A promising class of cancer drugs target heat shock protein 90 (Hsp90) and prevent Hsp90 from maintaining its ~100 proteins involved in cell growth. However, all current Hsp90 chemotherapeutics non-selectively target proteins maintained by Hsp90, and induce a cell rescue mechanism involving Hsp70. We describe the development of a novel molecule that will selectively control cell growth and prevent cell rescue via a unique Hsp90 regulated mechanism.
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.
Alternative Splicing- A Regulatory Mechanism Determining Self-renewal And Pluripotency Of ES And IPS Cells
Funder
National Health and Medical Research Council
Funding Amount
$664,650.00
Summary
Stem cells hold great promise in cell replacement therapies and may provide models to study human diseases and to screen new pharmaceuticals. For successful future therapeutic applications, a deeper understanding of the molecular mechanisms governing the behavior of stem cells is crucial. In this proposal we will investigate the role of alternative splicing in the control of the fundamental properties of stem cells, and identify target RNAs and gene expression networks regulated by splicing fact ....Stem cells hold great promise in cell replacement therapies and may provide models to study human diseases and to screen new pharmaceuticals. For successful future therapeutic applications, a deeper understanding of the molecular mechanisms governing the behavior of stem cells is crucial. In this proposal we will investigate the role of alternative splicing in the control of the fundamental properties of stem cells, and identify target RNAs and gene expression networks regulated by splicing factors.Read moreRead less