Repair and regulation in DNA damage response

The fundamental mechanisms of DNA repair have long been separated from the following regulation of transcription factors, and it is the main goal of this project to bridge these fields in order to establish a holistic picture of how living cells deal with DNA damage. It is well known that damage of DNA, introduces a broad cascade of pathways, but why the important transcription factor p53 start to shown oscillatory concentration dynamics is still not known. The link between this fingerprint in p53 behaviour, with the sudden creation of multiple foci has not been fully investigated, and thereby this project can enhance our understanding of cellular response and why this breaks down when cells pass on damaged DNA.

I will combine the theoretical knowledge of spatiotemporal signaling and biological networks with experimental results on p53 regulation and DNA repair proteins in order to create mathematical models that can predict the relation between foci formation and p53 concentration dynamics. Through this, we can obtain a deeper understanding of the underlying mechanisms in signaling between DNA repair and regulation. I have previously worked with p53 regulation at Harvard Medical School, and with the physical principles of DNA repair at Ecole Normale Superieure. In collaboration with experimentalists at both institutions, I will examine the link between DNA repair and regulation, and with this grant, I can pursue this fundamental idea of combining these areas.