Understanding How RUVBL1 And RUVBL2 Organise Chromosomes And Their Links To Disease
Funder
National Health and Medical Research Council
Funding Amount
$605,005.00
Summary
Our proposal will provide a deep mechanistic framework to inform both clinicians in diagnosis and management of RUVBL related diseases and also therapeutically, as industry looks to use these proteins as drug targets. The great excitement of RUVBL in translation has outpaced the gathering of vital knowledge underpinning the function; knowledge this proposal will provide for the first time.
Understanding The Structure And Function Of The Chromosome Condensin Complex
Funder
National Health and Medical Research Council
Funding Amount
$620,731.00
Summary
In order to survive cells need to divide their genetic material (DNA) equally between two daughter cells. For correct cell division to occur DNA has to be correctly packaged into condensed and organised chromosomes. Improper packaging of genetic material can result in unregulated cells that may become cancerous or lead to other genetic diseases such as Down's Syndrome. Understanding the key players regulating this process is vital to allowing researchers to further work in these areas.
Investigating Deregulation Of Mitosis As A Mechanism Of Tumourigenesis In MYCN-driven Neuroblastoma
Funder
National Health and Medical Research Council
Funding Amount
$372,298.00
Summary
Neuroblastoma chemotherapy often only works temporarily because a small number of tumour cells can resist drugs and eventually regrow as a new tumour. These resistant cells resemble the very first cells that turn into a cancer cell at tumour initiation. We have used single cell technology to uncover genetic markers of tumour initiating cells. In this project we will determine how these marker genes cause tumour initiation and develop therapies that target them in drug resistant neuroblastoma.
How Replication Stress Activates The Mitotic Telomere DNA Damage Response To Kill Cancer Cells
Funder
National Health and Medical Research Council
Funding Amount
$486,467.00
Summary
We discovered a novel mechanism linking stress during DNA replication to difficulties with the cell division process, and identified how this turns on DNA damage response signals from the chromosome ends (i.e. “telomeres”). We have further identified that we can exploit this mechanism to kill cancer cells. In this project we will explore this newly discovered mechanism and identify how it can be targeted for therapeutic purposes.
The Role Of Clathrin In The Spindle Assembly Checkpoint And As An Anti-cancer Target
Funder
National Health and Medical Research Council
Funding Amount
$651,768.00
Summary
Cell division produces two daughter cells. Incorrect localisation and modification of proteins that regulate mitosis cause errors that can lead to cancer. As well as using a unique machinery mitosis uses proteins involved in non-cell cycle pathways. This project investigates the role during mitosis of one such protein: clathrin. We will identify lead clathrin inhibitory compounds, pitstops, that have potential anti-cancer properties, ultimately to be used as a chemotherapy agent.
New Insights Into Mechanisms That Coordinate Kinase Signalling And Molecular Motors In Mitosis: A Novel Role For The Protein Scaffold WD-repeat Protein 62 (WDR62).
Funder
National Health and Medical Research Council
Funding Amount
$529,122.00
Summary
Proteins perform all functions within a cell. Commonly, different proteins are assembled into large complexes to carry out processes, such as cell division, with significant implications for human health. Scaffold proteins facilitate the proper assembly of large complexes but are a poorly understood protein class. We will perform molecular analysis of a newly discovered scaffold, WDR62, to define how it drives cell division and reveal how this can be exploited to develop new anti-cancer drugs.
Ubiquitin And SUMO DNA Damage Response Signalling At Deprotected Telomeres During The Cell Cycle
Funder
National Health and Medical Research Council
Funding Amount
$302,627.00
Summary
Following genome damage cells stop the cell division process and initiate DNA repair. We discovered that at specific times during cell division his does not happen if the damage signals originate from the chromosome ends (i.e. “telomeres”). We anticipate this is necessary to prevent genomic instability in healthy cells and may be driving genomic instability in cancer cells. Experiments described here will elucidate the molecular mechanisms and biological significance of our observation.