Communication skills training for oncology health care professionals working with culturally and linguistically diverse patients. The project will develop and evaluate two novel training programs designed to equip health professionals to communicate with cancer patients from different cultures. It is expected that the programs will improve trainees’ ability to communicate in a culturally sensitive way.
Cellular And Molecular Determinants Of Preleukaemic And Leukaemic Stem Cells
Funder
National Health and Medical Research Council
Funding Amount
$292,635.00
Summary
It has recently become evident that the formation, growth and relapse of many cancers is driven by a rare population of cancer stem cells (CSCs) that have the unique ability to propagate new tumours and are highly resistant to current therapies. However, which normal cells are transformed into CSCs is not known. We will take a potent cancer gene found in leukaemia, and switch it on and off in specific blood cells in mice to determine which healthy cells can be turned into leukaemic stem cells.
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.
Title: Mechanisms of telomere cap function DNA within each cell is packaged into chromosomes, the ends of which are called telomeres. The DNA in telomeres consists of 6 letters of the genetic code, TTAGGG, repeated hundreds or thousands of times. A number of proteins, including some that have not yet been identified, bind to this DNA and form a cap structure to protect the chromosome ends. Telomeres need to be able to serve a number of specialised functions, including protection against enzymes ....Title: Mechanisms of telomere cap function DNA within each cell is packaged into chromosomes, the ends of which are called telomeres. The DNA in telomeres consists of 6 letters of the genetic code, TTAGGG, repeated hundreds or thousands of times. A number of proteins, including some that have not yet been identified, bind to this DNA and form a cap structure to protect the chromosome ends. Telomeres need to be able to serve a number of specialised functions, including protection against enzymes that degrade DNA ends, and preventing chromosome ends from sticking to each other, while allowing access for DNA copying enzymes when the cell is preparing to divide into two. In some inherited conditions, the telomeres fail to perform these functions efficiently, leading to cellular dysfunction, premature ageing of cells, and ultimately disease. In some types of cells, especially cancer cells, the telomeres also permit the access of molecular machinery that lengthens the telomeres. There are at least two types of lengthening processes, one of which is a complex enzyme called telomerase, and the other an incompletely characterised process that we discovered and named Alternative Lengthening of Telomeres (ALT). In some circumstances, the telomeres of cancer cells appear to be able to discriminate between telomerase and ALT, and to allow one mechanism to operate but not the other. We will analyse how telomeres perform their capping functions, and will determine the differences between normal and cancer cells in this regard. This will lay the groundwork for efforts to develop new forms of cancer treatment that act by preventing cancer cells from lengthening their telomeres.Read moreRead less
Structural and pharmaceutical studies on a novel human protein, MIC-1. Cancer and obesity are two of the main health problems facing Australia, as reflected by the National Research Priority: Promoting and Maintaining Good Health. This project will develop new diagnostic tools for early cancer detection and prognosis using the protein, MIC-1. MIC-1 is responsible for cachexia, a wasting disorder responsible for 25% of cancer deaths, which has no effective therapy. MIC-1 and antibodies neutrali ....Structural and pharmaceutical studies on a novel human protein, MIC-1. Cancer and obesity are two of the main health problems facing Australia, as reflected by the National Research Priority: Promoting and Maintaining Good Health. This project will develop new diagnostic tools for early cancer detection and prognosis using the protein, MIC-1. MIC-1 is responsible for cachexia, a wasting disorder responsible for 25% of cancer deaths, which has no effective therapy. MIC-1 and antibodies neutralising MIC-1 may provide therapeutic agents to control cancer cachexia and severe obesity. The project will optimise these molecules for therapeutic uses. These diagnostic and therapeutic tools will form the basis of a spin-off company for commercialisation. Read moreRead less
This study will address the idea that cancer commonly involves a genetic pathway that is normally used by stem cells to proliferate in an undifferentiated state. We have evidence to indicate that this system is active in cancer cells and believe this could explain how cancer cells manage to divide rapidly in a primitive state. This project may bring a new perspective to the study of malignant transformation and has the potential to reveal multiple new targets for cancer therapy.