An RNA interference based genetic screen for novel epigenetic modifiers involved in mammalian X inactivation. All the information required to form an adult human is contained in the DNA of the fertilized egg. Development is achieved by a complex orchestration of genes being switched on and off, controlled by proteins called epigenetic modifiers. Sometimes this goes awry, leading to disease. Despite their vital role, only around ten percent of the potential epigenetic modifiers have been characte ....An RNA interference based genetic screen for novel epigenetic modifiers involved in mammalian X inactivation. All the information required to form an adult human is contained in the DNA of the fertilized egg. Development is achieved by a complex orchestration of genes being switched on and off, controlled by proteins called epigenetic modifiers. Sometimes this goes awry, leading to disease. Despite their vital role, only around ten percent of the potential epigenetic modifiers have been characterized in humans, making it impossible to interpret how they work together, or when they fail. We will develop a novel screen-based technology to find hundreds more true epigenetic modifiers. This technology will aid us and other Australian scientists to understand the role of epigenetics in normal development and disease, ultimately leading to better public health.Read moreRead less
Tissue specific regulation of gene expression. Despite the polarized public debate concerning the use of stem cells for tissue regeneration, fundamental questions relating to the identity and hierarchy of these cells remain unanswered. The benefit to Australia will be scientific in terms of providing an understanding of how stem and progenitor cells integrate transcriptional control systems during differentiation and the networks that are involved. This is fundamental to the future isolation a ....Tissue specific regulation of gene expression. Despite the polarized public debate concerning the use of stem cells for tissue regeneration, fundamental questions relating to the identity and hierarchy of these cells remain unanswered. The benefit to Australia will be scientific in terms of providing an understanding of how stem and progenitor cells integrate transcriptional control systems during differentiation and the networks that are involved. This is fundamental to the future isolation and manipulation of these stem cell types to benefit the community. The work will also provide postgraduate students with training in state of the art genomic techniques and in the interface between bioinformatics and experimental science. Read moreRead less