ERC FUNDED PROJECTS

Cellular identity is defined by complex patterns of DNA and histone modifications, which partition our chromosomes and determine how cells interpret the genetic information. For cells to remember who they are, these modifications have to be tightly regulated over time and through cell division. Loss of cellular identity promotes different types of disease including neurological disorders and cancer. Histone modifications can spread along chromatin and can be transmitted through cell division, giving rise to chromatin position effects and cellular memory. However, the underlying molecular mechanisms are not understood. In particular, we do not know how the size and stability of modified domains is controlled, and we currently lack techniques to study these processes in real-time. Here, I propose to develop the single-molecule ‘chromatin curtains’ platform to directly visualize spreading and maintenance of histone methylation in a reconstituted system and to compare the resulting domains to those found on individual chromatin fibers isolated from cells. In a complementary approach, I will devise and set up a tunable synthetic circuit that installs and reinforces orthogonal epigenetic modifications in living cells to define the functional modules that are necessary and sufficient for chromatin position effects and cellular memory. My project combines molecular biophysics with synthetic biology to elucidate the fundamental principles that govern the dynamics of histone modifications to establish and preserve cellular identity. The chromatin curtains platform I will develop complements sequencing-based methods and will make it for the first time possible to directly assess the dynamics of histone modification patterns on single chromatin fibers under native conditions. I anticipate that the insights gained in my project will aid in the design of future strategies to control histone modifications in disease.

1 447 860 €

Start date: 2019-07-01, End date: 2024-06-30

Linear motifs are short sequence stretches that occur in intrinsically disordered protein regions (IDRs) lacking stable secondary and tertiary structure, and mediate vital interactions within various biological systems. An exemplary system for the presence of IDRs and a high concentration of linear motifs is the clathrin mediated endocytosis machinery of the eukaryotic cell, where a complex interaction network of IDR-rich adaptor proteins enables both protein and lipid interactions. The molecular mechanism of such interactions, especially when multiple motifs act in concert, is however only poorly understood particularly since the dynamic and flexible nature of IDRs makes them a very difficult object to study. I aim to develop an integrative approach based on single molecule fluorescence and NMR spectroscopies to characterize the molecular principles of IDRs in clathrin mediated endocytosis. A systematic analysis of IDRs with different types of motifs and various interaction partners will not only shed light on the molecular functions of linear motifs within endocytosis, but also on how multiplicities of linear motifs may work in various biological processes in general. In vitro structural studies will be connected with single molecule imaging to relate molecular conformation with function within the cell.

1 599 809 €

Start date: 2019-02-01, End date: 2024-01-31

While viral infections create an important threat for humanity, our knowledge of the viruses that infect humans is largely incomplete. So far, discovery of new viruses has been limited by the inability to propagate them in cell culture, the lack of serological cross-reactivity, or the absence of conserved genetic element to target by PCR. Thus, numerous acute and chronic diseases with unknown etiology are caused by yet unidentified viruses. Among the highest failure rates in determining the etiological cause of disease, pneumonia, encephalitis, and pericarditis are usually cited. In these cases, the search for unknown viruses is an urgent scientific task. We propose to identify new viruses, both indigenous and pathogenic, using metagenomics (shotgun Sanger sequencing and 454 pyrosequencing) of RNA and DNA from purified viral particles found in clinical samples of individuals presenting encephalitis, pneumonia, or pericarditis diseases without known etiology. Virus-centered bioinformatics methods will be developed to detect close as well as distant relatives of known viral species. Initial viral sequence similarity analysis will be followed by full viral genome reconstruction and phylogenetic analysis. The prevalence, abundance, and geographical distribution of newly identified viruses will then be determined using quantitative real-time PCR and RT-PCR on a 10-year collection of samples from extensively characterized patients.

831 902 €

Start date: 2010-02-01, End date: 2014-01-31

Individual performance of surgeon is a core element of successful surgery that can vary greatly over career for poorly understood reasons. Solutions to optimize physical and mental condition of surgeon during operation have not been thoroughly explored so far, while this may represent basic foundation for delivering high quality surgery. This surgeon-centred outcome research pursues three successive goals: 1-Identifying the key determinants related to surgeon's human factor and operating room organization influencing his/her performance in terms of patient safety and care efficiency; 2-Developing a customized coaching program for surgeons based on the human and organizational factors previously discovered, which includes a charting system for individual parameters and surgical outcomes feedback, profiling of individual surgeon, and standardized modules of improvement; 3-Implementing and measuring the impact of this program on surgical outcomes of a randomized group of surgeons against a control group of non-exposed surgeons. Inspired from previous experiences in the aeronautic and sport arena to improve pilots and athletes performance, our approach will take place in real time at the point of care in close collaboration with front-line personnel. A particular attention will be paid to quantify the influence of several factors that may affect how the surgeon operates every day (physiological stress, sleep quality, physical activities, workload, team composition and unplanned events in operating room). Generated knowledge on these factors will be exploited for identifying deficiencies that, if corrected, could improve surgeon's functional capacity. Solutions to control these factors and achieve optimal outcomes will then be experimentally tested to establish evidence-based standards of surgical practice. Those standards will be adapted to each surgeon's needs and preferences, potentially leading to a certification model for surgeons complying with excellence criteria.

1 499 818 €

Start date: 2019-02-01, End date: 2024-01-31