Genetic networks regulating gene silencing by intronic repeat expansions . Changes in the copy number of DNA repeats are associated with phenotypic variations in several species. Expansions of DNA repeats underlie several human genetic diseases, including Friedreich’s ataxia. The molecular mechanisms that mediate these genetic abnormalities are currently unclear. This project aims to identify the novel genetic pathways and mechanisms mediating these genetic disorders. Using a plant model in an .... Genetic networks regulating gene silencing by intronic repeat expansions . Changes in the copy number of DNA repeats are associated with phenotypic variations in several species. Expansions of DNA repeats underlie several human genetic diseases, including Friedreich’s ataxia. The molecular mechanisms that mediate these genetic abnormalities are currently unclear. This project aims to identify the novel genetic pathways and mechanisms mediating these genetic disorders. Using a plant model in an innovative way this project will discover novel genes, uncover fundamental molecular mechanisms and reveal the genetic networks that govern gene silencing caused by triplet repeat expansions. This project, in addition to revealing fundamental biological mechanisms, will also have implications for human disease.
Read moreRead less
Unveiling the epigenome dynamics through the pluripotency continuum. This project aims to utilise stem cells and genomics based technologies, in combination with new computational algorithms to dissect the fundamental molecular events that drive the first steps during development. The project is expected to unveil the basic mechanisms underpinning how genes driving the developmental master plan are controlled in cells that have the capacity to give rise to the whole organism and placenta. The kn ....Unveiling the epigenome dynamics through the pluripotency continuum. This project aims to utilise stem cells and genomics based technologies, in combination with new computational algorithms to dissect the fundamental molecular events that drive the first steps during development. The project is expected to unveil the basic mechanisms underpinning how genes driving the developmental master plan are controlled in cells that have the capacity to give rise to the whole organism and placenta. The knowledge gained from this work will inform and guide future novel approaches, such as in assisted reproductive technologies or regenerative medicine.Read moreRead less