We will investigate how the master control gene, Kruppel-like factor 1, orchestrates production of red blood cells. We will use genetic and cell biology approaches to determine exactly how this factor interprets the genome blueprint in a cell specific manner. We will also determine how mutations in KLF1 cause human diseases such as congenital dyserythropoietic anemia and hereditary persistence of fetal haemoglobin. This has implications for reactivation of HbF in adults with sickle cell disease.
KLFs are master control genes that regulate the expression of many target genes to determine cell fate and to convert one cell fate to another. Mutations in KLFs cause human diseases. This grant will focus on the founding member of the KLF family, KLF1. We will use genomics techniques and animal models to determine how KLF1 works in normal blood cell production and in disease
The BHLH Transcription Factor LYL1 In Normal And Leukemic Hematopoiesis
Funder
National Health and Medical Research Council
Funding Amount
$520,945.00
Summary
This project aims to understand how two closely related genes, called SCL and LYL1, work together to control the production of normal red blood cells and when abnormally expressed, cause cancer of the white blood cells. We will specifcially examine how LYL1 causes a specific type of leukemia in children and determine blocking the function of LYL1 will be a useful way to kill leukemia cells.
Redefining The Pro-thrombotic Mechanism Of Von Willebrand Factor
Funder
National Health and Medical Research Council
Funding Amount
$750,005.00
Summary
Blood clotting is the underlying cause of heart attacks and strokes. The blood protein, von Willebrand factor, is a critical player in blood clotting and impairment of its function is life threatening. We have discovered that there are three forms of VWF in human blood that have different functions in blood clotting. Characterisation of these different forms will likely lead to new blood clotting diagnostics and improved therapies.
Zbtb11 is a druggable protein that is mis-expressed in blood cancers - second biggest cause of cancer death in Australia - and liver cancer, third leading cause of death from cancer worldwide. We have found that it interacts with 2 other proteins with potential roles in these diseases. Our studies examine the nature of these Zbtb11-partner interactions and their particular consequences for blood disorders. Zbtb11 contributions to disease development will be a target for novel disease therapy.
Role Of Zeb2/Sip1 In Leukaemic Stem Cell Formation And Cancer Progression
Funder
National Health and Medical Research Council
Funding Amount
$655,174.00
Summary
T-cell acute lymphoblastic leukaemia (T-ALL) results from the abnormal development of T cells that are an important cell type in the body's immune system. Although the prognosis for T-ALL has improved remarkably over the last decade, for one out of five T-ALL cases the underlying genetic defects remain unresolved and are refractory to current therapies. This project aims to use both novel mouse models and human patient cell lines to better understand this disease and discover novel targets for f ....T-cell acute lymphoblastic leukaemia (T-ALL) results from the abnormal development of T cells that are an important cell type in the body's immune system. Although the prognosis for T-ALL has improved remarkably over the last decade, for one out of five T-ALL cases the underlying genetic defects remain unresolved and are refractory to current therapies. This project aims to use both novel mouse models and human patient cell lines to better understand this disease and discover novel targets for fighting this disease.Read moreRead less