A Comprehensive Analysis Of Myb Target Genes Involved In Myelopoiesis And Myeloid Transformation
Funder
National Health and Medical Research Council
Funding Amount
$511,294.00
Summary
The MYB gene is essential for both normal blood cell formation and the growth of leukaemia cells. It acts by switching other genes (target genes) on and off. This project aims to advance our understanding of how MYB functions, by carrying out a comprehensive search for MYB target genes. In particular it will focus on target genes that help explain MYB's ability to control cellular growth and maturation. Some of these target genes may provide leads for future anti-cancer drug development.
Functional Analysis Of The P160 Myb-binding Protein - A Regulator Of Multiple Transcription Factors?
Funder
National Health and Medical Research Council
Funding Amount
$376,697.00
Summary
The c-myb gene is a key molecular regulator of normal blood cell production, but alterations to this gene can also lead to leukaemia. The protein (Myb) encode by the c-myb gene acts as a transcription factor, ie, it controls the activity of other genes. There is good evidence that interactions with other proteins can regulate the activity of Myb. Our laboratory has identified what we believe is one such protein - p160 - that binds to a part of Myb that reduces its activity, and thus that is like ....The c-myb gene is a key molecular regulator of normal blood cell production, but alterations to this gene can also lead to leukaemia. The protein (Myb) encode by the c-myb gene acts as a transcription factor, ie, it controls the activity of other genes. There is good evidence that interactions with other proteins can regulate the activity of Myb. Our laboratory has identified what we believe is one such protein - p160 - that binds to a part of Myb that reduces its activity, and thus that is likely to be responsible for regulating Myb. However, it has recently become apparent that p160 interacts with a number of other transcription factors in addition Myb. The primary aim of this project is to elucidate precisely how p160 interacts with Myb and what the consequences of this interaction are. A range of experimental approaches, which range from in vitro to genetic studies, will be employed to do this. We will test a specific role of p160 suggested by our preliminary studies - that of a transporter of transcription factors between the nucleus and the cytoplasm of the cell. Because of the wide range of transcription factors that p160 interacts with, its effects on the function of the cell are likely to be profound. For this same reason, it is difficult to specifically predict the possible medical-health implications of this work However, what we know to date is consistent with a role for p160 as a tumour suppressor gene. Moreover, parts of this project aim to generate genetic information and tools which will help in determining whether p160 does play such a role and generally, in identifying any other associations of p160 with particular diseases.Read moreRead less
Molecular Identification Of Causative Genetic And Epigenetic Alterations That Induce And Promote Colorectal Cancer
Funder
National Health and Medical Research Council
Funding Amount
$381,821.00
Summary
The majority of mouse models currently employed to study colorectal cancer have two failings. The first is that they tend to focus on small intestinal cancers rather than colorectal cancers. It is important to note that small intestinal cancers are in the minority of gastrointestinal cancers in humans. The second problem is that the genetic lesions introduced into mice are mostly in all cells throughout development. This is a poor representation of the random nature of genetic changes that under ....The majority of mouse models currently employed to study colorectal cancer have two failings. The first is that they tend to focus on small intestinal cancers rather than colorectal cancers. It is important to note that small intestinal cancers are in the minority of gastrointestinal cancers in humans. The second problem is that the genetic lesions introduced into mice are mostly in all cells throughout development. This is a poor representation of the random nature of genetic changes that underpin the probable cause of colon cancer. We therefore propose to genetically engineer unique mouse models that focus on colon cancer to most closely replicate the situation in human disease. These models will then be available to others and us to develop and test therapies to prevent and-or treat colorectal cancer that will ultimately be used in patients.Read moreRead less