Molecular Regulation Of Replicative Lifespan; Implications In Carcinogenesis And Haematopoiesis
Funder
National Health and Medical Research Council
Funding Amount
$420,872.00
Summary
The lifespan of normal cells in the body is limited by the number of times they can replicate. In contrast, cancer cells can replicate indefinitely – they are immortal. Our proposed investigations will determine how the mechanisms that control cell lifespan become dysfunctional as normal cells evolve into cancer cells. Understanding these mechanisms will enable the development of new anti-cancer drugs that will reverse cell immortality and halt the replication of cancer cells.
Interaction Of TRF2 With DNA Repair Proteins In Alternative Lengthening Of Telomeres
Funder
National Health and Medical Research Council
Funding Amount
$297,246.00
Summary
10-15% of human cancers, including some of the most difficult-to-treat and aggressive, depend for their continuing growth on a molecular process called Alternative Lengthening of Telomeres (ALT). We have identified for the first time a protein whose normal role includes repressing ALT. We will study how this protein works, what its molecular partners are, and how these molecules interact with each other. This information is expected to lay the foundations for cancer treatments that target ALT.
Activation Of TERT Gene Expression In Breast Carcinogenesis
Funder
National Health and Medical Research Council
Funding Amount
$693,440.00
Summary
A key step in the development of most cancers is the switching on of an enzyme, telomerase, that allows cancer cells to keep growing without limit. We will study the molecular details of this step using new techniques for functional analyses of the genome in human breast cells grown in the laboratory. Blocking telomerase has great potential for cancer treatment, so analysing how this enzyme gets switched on may identify new strategies for achieving this for breast cancer - and other cancers.
Molecular Mechanisms And Control Of Alternative Lengthening Of Telomeres
Funder
National Health and Medical Research Council
Funding Amount
$453,055.00
Summary
Studies of a mechanism cancer cells use to protect the ends of their chromosomes The DNA within cell nuclei is arranged in linear packages referred to as chromosomes, capped at each end by structures called telomeres. Telomeres consist of a long stretch of a repetitive DNA sequence that does not contain any genes. Most normal cells are unable to copy the DNA at the extreme ends of their chromosomes, so every time they divide their telomeres get slightly shorter. This ultimately stops the cell fr ....Studies of a mechanism cancer cells use to protect the ends of their chromosomes The DNA within cell nuclei is arranged in linear packages referred to as chromosomes, capped at each end by structures called telomeres. Telomeres consist of a long stretch of a repetitive DNA sequence that does not contain any genes. Most normal cells are unable to copy the DNA at the extreme ends of their chromosomes, so every time they divide their telomeres get slightly shorter. This ultimately stops the cell from dividing any further, and acts as a very potent barrier to the cell becoming cancerous. Some normal cells are not subject to this inexorable telomere shortening: these are the germ cells in the testis and ovary, that are responsible for passing on genetic material to the next generation. Such cells express an enzyme, telomerase, which is able to synthesise new telomeric DNA to replace that lost during cell division. 85% of human cancers are also able to prevent shortening of their telomeres - and thus have breached the barrier that normally prevents unlimited cell proliferation - via telomerase activity. Therefore, if drugs that inhibit telomerase can be developed they may be a very useful new form of cancer treatment. We have found, however, that some cancers are able to prevent telomere shortening by a process that does not involve telomerase, and which we refer to as Alternative Lengthening of Telomeres (ALT). One practical implication of this finding for the design of new cancer treatments is that telomerase inhibitors will need to be used in combination with ALT inhibitors. In this study, we will determine A. how normal cells keep the ALT mechanism permanently shut down and B. the molecular details of the ALT mechanism itself. An understanding of these processes may ultimately contribute to the development of novel cancer treatments that disrupt the ability of cancer cells to divide an unlimited number of times.Read moreRead less