The Role Of The MYST Family Transcriptional Co-activator, Mof, In Embryonic Development
Funder
National Health and Medical Research Council
Funding Amount
$319,446.00
Summary
A major task in biology is to understand how the human genome directs the development of a single cell to form an entire individual. Clearly, a large part of this task is to understand how the expression of genes is regulated during embryonic development. Gene expression requires co-activator complexes. Co-activator complexes typically contain proteins which regulate the structure of chromatin (a complex of DNA and histones). However, the physiological function of most co-activators is entirely ....A major task in biology is to understand how the human genome directs the development of a single cell to form an entire individual. Clearly, a large part of this task is to understand how the expression of genes is regulated during embryonic development. Gene expression requires co-activator complexes. Co-activator complexes typically contain proteins which regulate the structure of chromatin (a complex of DNA and histones). However, the physiological function of most co-activators is entirely unclear. The aim of this project is to study the function of Mof during embryonic development. Mof is a co-activator that directly regulates chromatin structure by modifying histones. Mof is a member of the MYST family of co activators, which includes Moz and Qkf. We have recently shown that Moz and Qkf are essential for the haematopoietic stem cell population and the neural stem cell population, respectively. The purpose of this project is to produce a detailed analysis of the function of Mof in vivo and determine it's importance in regulating gene expression. All biological processes relay on accurate regulation of gene transcription and all diseases, whether they involve pathogens or cell intrinsic pathological changes, such as cancer, lead to changes in gene expression. Regulation of chromatin structure has been identified as a major mechanism of transcriptional regulation in health and disease. However, our understanding of the precise molecular mechanisms regulating chromatin structure in vivo are very limited. This work will fully investigate the role of an important co-activator in vivo including a mechanistic analysis. This will increase understanding of how gene expression is regulated and, ultimately, this knowledge will find wide application in the development of new treatment paradigms.Read moreRead less
The Role Of The MYST Family Lysine Acetyltransferase, Hbo1, In Development And In The Adult
Funder
National Health and Medical Research Council
Funding Amount
$403,368.00
Summary
This project will produce a detailed analysis of the function of Hbo1, a transcription factor, and determine its importance in regulating gene expression. All biological processes rely on accurate regulation of gene transcription and all diseases lead to changes in gene expression. This work will increase understanding of how gene expression is regulated and, ultimately, this knowledge will find wide application in the development of new treatment paradigms.
Molecular Control Of Cell Proliferation In Early Mouse Development
Funder
National Health and Medical Research Council
Funding Amount
$338,009.00
Summary
Elucidation of cell cycle regulation in the proliferating pluripotent cells of the early mammalian embryo is likely to have important impact on basic scientific knowledge, and on the development of novel therapeutic strategies. Investigation of this problem, in vitro and in vivo, requires specialist skills in cell cycle analysis, and experimental manipulation of mammalian embryos and pluripotent cells. This application will seek to address these fundamental issues of early development and cell p ....Elucidation of cell cycle regulation in the proliferating pluripotent cells of the early mammalian embryo is likely to have important impact on basic scientific knowledge, and on the development of novel therapeutic strategies. Investigation of this problem, in vitro and in vivo, requires specialist skills in cell cycle analysis, and experimental manipulation of mammalian embryos and pluripotent cells. This application will seek to address these fundamental issues of early development and cell proliferation using molecular approaches. The general aims will be: 1. to obtain a detailed description of cell cycles in pluripotent and differentiating cells of the mouse embryo 2. use this information to build a molecular description of cell cycle events during early embryogenesis 3. investigate the relationship between rapid cell proliferation in the embryo and pluripotencyRead moreRead less