Dissecting Isoform Selectivity Of PI3 Kinase Inhibitors. Uncovering Leads For Rational Drug Design.
Funder
National Health and Medical Research Council
Funding Amount
$518,989.00
Summary
The PI3 kinase enzyme controls many functions in cells and in many cases contributes to the onset and progression of diseases such as cancer, thrombosis and inflammatory diseases. Compounds that block PI3 kinase activity may be useful drugs but will need to act specifically to minimize side effects. We aim to understand the way in which inhibitors block the PI3 kinase activity with the belief that this information will allow us to make better drugs.
Multi-domain Regulation Of DNA Damage Response Kinases
Funder
National Health and Medical Research Council
Funding Amount
$313,427.00
Summary
DNA damage plays a key role in the onset of cancer and the response to cancer therapies. Mutations in the Chk2 DNA damage response kinase are associated with increased cancer risk. We will study detailed mechanisms how phosphorylation of Chk2-like kinases contributes to normal copying of our DNA every time a cell divides, and how it regulates how Chk2 is activated. The studies will improve our understanding how cancer may originate and how cancer cells respond to chemo- or radiation therapy.
Biochemical Investigation Of Ubiquitination By The Fanconi Anaemia Pathway
Funder
National Health and Medical Research Council
Funding Amount
$603,447.00
Summary
Fanconi anaemia is an inherited disorder with greatly elevated risk of leukaemia and cancers. The causal genes are ‘tumour suppressors’ that protect us from cancer by a complex function in repair of damage to our DNA. This study aims to understand how this DNA repair function protects us from cancer, and may influence some forms of new forms of cancer treatment.
Structure, Assembly, And Inhibition Of The Human Telomerase Enzyme Complex
Funder
National Health and Medical Research Council
Funding Amount
$645,359.00
Summary
In contrast to the limited growth of normal human cells, cancer cells proliferate out of control and without limit. At least 85% of all human cancers rely on the enzyme TELOMERASE to sustain their unlimited proliferation. Telomerase is absent in most normal tissues and therefore represents a potentially effective and specific target for future cancer therapy. We aim to determine the precise 3-dimensional shape of human telomerase to provide a template for rational anti-telomerase drug design.
Biochemical Analysis Of Akt 3-specific Signal Transduction
Funder
National Health and Medical Research Council
Funding Amount
$349,375.00
Summary
The Akt family of enzymes consists of 3 protein kinases (Akt 1,2 and 3) and has been shown to regulate many normal cellular processes such as cell proliferation, growth, survival and motility, as well as the growth of new blood vessels. All these processes are critical for cancers to grow. However, few studies have distinguished the roles of the individual family members. Our preliminary data revealed Akt3 is far more active than the other two forms. Furthermore, using our unique Akt3 specific a ....The Akt family of enzymes consists of 3 protein kinases (Akt 1,2 and 3) and has been shown to regulate many normal cellular processes such as cell proliferation, growth, survival and motility, as well as the growth of new blood vessels. All these processes are critical for cancers to grow. However, few studies have distinguished the roles of the individual family members. Our preliminary data revealed Akt3 is far more active than the other two forms. Furthermore, using our unique Akt3 specific antibody, we find Akt 3 protein and activity levels are high in rapidly proliferating ovarian cancer cell lines and in primary ovarian tumours. The aim of this proposal is to characterise the mode and role of signalling via Akt3, including the identification of targeted substrates and signaling pathways and the outcomes of Akt3 driven signaling on cellular properties. These studies will provide important clues to understanding how this family member functions in both health and disease. Elucidation of the basis of Akt3 dependent signalling will open the possibility for the development of drugs that interfere with Akt3 function (for example in high Akt 3 expressing tumours like those of the ovary). In the long term, extension of our profiling studies to other tumour types will give a novel insight into the extent of Akt3 de-regulation as a key mediator of cancer formation.Read moreRead less
A New Approach To Explore The Role Of Selenoproteins In Health And Disease
Funder
National Health and Medical Research Council
Funding Amount
$374,284.00
Summary
Selenoproteins play an important role in a variety of major diseases. Yet knowledge of the biology of selenium and its role in disease prevention and progression is not sufficient to recommend selenium supplementation for disease prevention or treatment. The broad aim of this research is to identify and characterise the response of selenoproteins to selenium supplementation and disease states.
The Molecular Mechanism Of Sphingosine Kinase Activation
Funder
National Health and Medical Research Council
Funding Amount
$442,500.00
Summary
Many cell processes like growth, death and differentiation are controlled by hormones and other molecules that interact with receptors on the outside of the cell. When this type of molecule binds to a receptor, it often triggers the production of signaling molecules inside the cell that initiate a change in the cells behaviour. The lipid molecule, sphingosine phosphate has been identified as such a signaling molecule that appears to be involved in the regulation of a diverse array of important m ....Many cell processes like growth, death and differentiation are controlled by hormones and other molecules that interact with receptors on the outside of the cell. When this type of molecule binds to a receptor, it often triggers the production of signaling molecules inside the cell that initiate a change in the cells behaviour. The lipid molecule, sphingosine phosphate has been identified as such a signaling molecule that appears to be involved in the regulation of a diverse array of important mammalian cellular processes. Recent studies have found that sphingosine phosphate is involved in the inflammation of cells, and if its production can be blocked, inflammation is not seen. Therefore, this provides a potential target for therapeutic intervention in the inflammation process. However, the manner by which cells regulate sphingosine phosphate levels is not well known. It is known that sphingosine phosphate is produced by the enzyme sphingosine kinase, and strong evidence suggests that changes in this enzyme's activity in the cell regulate sphingosine phosphate levels. However, how the cell changes the levels of sphingosine kinase activity is completely unknown. This study will investigate this problem with the view that understanding this process will allow the development of new drugs to block increases in sphingosine kinase activity, preventing increases in sphingosine phosphate levels, and it turn, preventing cellular inflammation.Read moreRead less
Regulation Of The Tumour Suppressor PTEN By Phosphorylation And Oligomerization
Funder
National Health and Medical Research Council
Funding Amount
$241,650.00
Summary
The tumour suppressor PTEN is an enzyme involved in controlling cell growth, cell death, and cell migration. PTEN was identified as a tumour suppressor because many tumour cells were found to carry mutations in the PTEN gene that cause the loss of PTEN protein or the loss of PTEN enzyme activity. Hereditary mutations of the PTEN gene are the causes of a rare genetic disease called Cowden's disease. Cowden's disease patients are predisposed to developing skin, thyroid, and breast cancers. In labo ....The tumour suppressor PTEN is an enzyme involved in controlling cell growth, cell death, and cell migration. PTEN was identified as a tumour suppressor because many tumour cells were found to carry mutations in the PTEN gene that cause the loss of PTEN protein or the loss of PTEN enzyme activity. Hereditary mutations of the PTEN gene are the causes of a rare genetic disease called Cowden's disease. Cowden's disease patients are predisposed to developing skin, thyroid, and breast cancers. In laboratory conditions, increasing the abundance of PTEN in tumour cells such as brain and prostate tumour cells can suppress their growth, hence its role as a tumour suppressor. In addition to its role as a tumour suppressor, PTEN controls cancer cell spreading. Although much is known about the involvement of PTEN in cancer formation and the spreading of cancer cells, how PTEN suppresses tumour cell growth and spreading is not fully understood. The enzyme activity of PTEN enhances the removal of a chemical group called phosphate group from proteins and the fat-soluble compounds called phospholipids in the cell membrane. The ability of PTEN to suppress cell growth and spreading is due to its enzyme activity. However, exactly how the enzyme activity of PTEN is regulated is not well understood. In order for PTEN to efficiently enhance the removal of phosphate group from specific cellular proteins and phospholipids, PTEN needs to be located in close vicinity to these proteins and phospholipids. However, exactly how PTEN moves to the locations where these proteins and phospholipids are present remains elusive. This proposal aims at studying the regulation of PTEN enzyme activity and movement inside the cells. Results of the proposed studies will shed new light on how PTEN gene mutations contribute to cancer formation and the spreading of cancer cells and may facilitate the search for the cure of cancers.Read moreRead less
A Tumour Suppressor Pathway That Removes DNA-RNA Hybrids
Funder
National Health and Medical Research Council
Funding Amount
$935,780.00
Summary
DNA:RNA hybrids are found normally in our chromosomes. But, the regions where DNA:RNA hybrids form are linked to chromosome changes that occur during breast and blood cancer development. We have uncovered why these chromosome changes occur, and have linked it to the important function of a cancer-associated gene called FANCM. Our study is exploring this important finding that has implications for both the cause and treatment of cancer.