Vascular Smooth Muscle Cell Senescence And The Effects Of Oestrogen
Funder
National Health and Medical Research Council
Funding Amount
$191,370.00
Summary
The incidence of cardiovascular diseases is much lower in women before menopause, and this is thought to be due to a beneficial effect of oestrogen on the cardiovascular system. However the mechanisms of the hormone’s cardiovascular-protective actions are still not clear. The proposed project will determine whether oestrogen acts by slowing the natural ageing process of cells.
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.
ALT-associated PML Bodies: Keys To The Biology And Treatment Of An Important Subset Of Cancers
Funder
National Health and Medical Research Council
Funding Amount
$813,614.00
Summary
Alternative Lengthening of Telomeres (ALT) is a molecular mechanism used by ~10% of cancers to sustain their relentless growth. ALT is common in sarcomas and brain tumours which are difficult to treat. ALT cancers contain nuclear structures called ALT-associated PML nuclear bodies (APBs) which may be part of the ALT machinery. This research will investigate characteristics of APBs and how they are formed, and will use this information to identify drugs to treat ALT tumours.
Manipulating Oncogenic-signalling Pathways In The Genesis And Treatment Of Melanoma
Funder
National Health and Medical Research Council
Funding Amount
$601,484.00
Summary
Melanoma is a major Australian health problem. It is the third most common cancer in men and women and has a disproportionately heavy impact on productive years of life. The use of small molecule inhibitors is the most promising strategy for treating melanoma. In this project, we will examine the mechanisms of resistance to this class of drugs and define new drug targets by examining the molecular-circuitry is damaged in melanomas. This work will greatly accelerate the development of new therapi ....Melanoma is a major Australian health problem. It is the third most common cancer in men and women and has a disproportionately heavy impact on productive years of life. The use of small molecule inhibitors is the most promising strategy for treating melanoma. In this project, we will examine the mechanisms of resistance to this class of drugs and define new drug targets by examining the molecular-circuitry is damaged in melanomas. This work will greatly accelerate the development of new therapies.Read moreRead less
Manipulating The B-RAF/MEK Pathway In The Genesis And Treatment Of Melanoma
Funder
National Health and Medical Research Council
Funding Amount
$562,815.00
Summary
Melanoma is a major Australian health problem. It is the third most common cancer in men and women and has a disproportionately heavy impact on productive years of life. The use of small molecule inhibitors is the most promising strategy for treating melanoma. In this project, we will examine the mechanisms of resistance to this class of drugs and define new drug targets by examining the molecular-circuitry that is damaged in melanomas. This work will greatly accelerate the development of new th ....Melanoma is a major Australian health problem. It is the third most common cancer in men and women and has a disproportionately heavy impact on productive years of life. The use of small molecule inhibitors is the most promising strategy for treating melanoma. In this project, we will examine the mechanisms of resistance to this class of drugs and define new drug targets by examining the molecular-circuitry that is damaged in melanomas. This work will greatly accelerate the development of new therapies.Read moreRead less
Functions Of A Novel Conserved DNA Damage Response Protein Family In Telomere Stability
Funder
National Health and Medical Research Council
Funding Amount
$282,825.00
Summary
The free DNA ends of chromosomes, termed telomeres, generally resemble broken DNA. Because broken DNA is a major contributing factor to the onset of cancer, cells try to fix broken ends. However, in case of telomeres, such repair processes have to be prevented because otherwise different chromosomes would fuse with each other. Fused chromosomes are very fragile and cannot be evenly distributed between dividing cells, and are therefore another important trigger of cancer development. Therefore, c ....The free DNA ends of chromosomes, termed telomeres, generally resemble broken DNA. Because broken DNA is a major contributing factor to the onset of cancer, cells try to fix broken ends. However, in case of telomeres, such repair processes have to be prevented because otherwise different chromosomes would fuse with each other. Fused chromosomes are very fragile and cannot be evenly distributed between dividing cells, and are therefore another important trigger of cancer development. Therefore, chromosome ends are covered by a cap, which hides them from the DNA damage response machinery. From these considerations it is clear that there are close connections between the cellular DNA damage response and chromosome ends. Moreover, recently it has become clear that DNA damage proteins are also required to stop normal cells from growing, a process termed senescence. Senescence is a consequence of shortened chromosome ends, and does not occur in cancer cells. Altogether, it is clear that DNA breaks and senescence are two of the major questions for our understanding of cancer development. We have identified a novel conserved protein family that is involved in the response to DNA damage in yeast and humans. In addition, the yeast Mdt1 protein is a very sensitive indicator of changes in the telomere cap. Absence of proteins that organise the cap leads to the addition of several phosphate groups to the Mdt1 protein. We propose that phosphate-coupled Mdt1 prevents chromosome ends from fusion with each other, or from fusing with broken DNA ends after widespread damage. As a consequence, cells that have mild cap defects die at an >1000-fold increased rate in response to DNA damage when they also lack Mdt1. As part of this application we want to find out the precise mechanism by which Mdt1 stabilises chromosome ends, and test our hypothesis that the corresponding human protein termed ASCIZ also has similar functions in protecting chromosome ends.Read moreRead less