Periodic Reporting for period 4 - SMPFv2.0 (Next generation single molecule protein fluorescence)
Période du rapport: 2019-05-01 au 2021-04-30
Despite all progress, single molecule fluorescence science suffers from the need for site-specific labelling and the intrinsic low throughput. In this project, we aimed to improve single molecule science, by integrating chemical biology and microfluidic tools into a synergistic process on how to study disordered biological building blocks with high resolution. The tools were directly used to study a set of IDPs highly relevant to a fundamental function of the eukaryotic cell, which in turn also feedbacks on the tool development.
In the eukaryotic cell all genetic material is stored in the nucleus, which for example protects it modifications due to pathogens, like viruses. However, constant information exchange in the form of biomolecules entering and exiting the nucleus is essential for cellular function. Intrinsically disordered proteins termed nucleoporins form a permeability barrier of still elusive nature inside nuclear pore complexes spanning the nuclear envelope. While key to controlling nucleocytoplasmic transport, likely due to their disordered nature, many of those proteins can also take on vital functions in processes like gene regulation elsewhere in the cell. The fundamental principles behind such multifunctionality are largely unknown.
Genetic Code expansion (GCE), is a technology that enables to swap a normal amino acid, against a noncanonical amino acid harboring a unique functionality to which we can couple small fluorescent dyes. This way we can introduce very small stable fluorophores into proteins that we want to study. This protein engineering is done inside the cell, and this can have an impact on cellular physiology and lead to unwanted effects. In a series of publications (most prominent Nikic et al Angewandte 2016 and Reinkemeier Science 2019) we showed that we can visualize single proteins inside nuclear pore complexes labelled with single dyes in a site-specific manner. However, as powerful as GCE is, it has also many shortcomings that limit its application in cellular biology since it does also interfere with canonical function of the cell. However, we have developed a conceptually new approach how to solve this problem, which I detail in the next section.
Furthermore, and to cope with the small throughput of our fluorescent microscopy approaches, we combined our technologies also with a novel microfluidic flow platform, in which proteins pass one after the other through an observation area (JCB 2019). Doing this enabled us to identify that nucleoporins can form a simple liquid droplet like aggregate/condensate that already obeys many characteristics of functional nuclear pore complexes. Our work provided a new model platform to study the nuclear transport machinery under controlled conditions and already enabled us new insights into the key features that charaterize functional nuclear transport.
While our ERC COG grant focused on developing fluorescence labelling technologies, we also realized the potential of our ultrafast and ultra precise labelling technologies for other applications. With the idea to engineer antibodies with radionuclides, we were awarded an ERC proof of concept grant. This brought us into the field of antibody drug and radio conjugates, and ultimately lead to foundation of a company: Araxa Biosciences GmbH. Just recently the company fused with another Biotech startup to Veraxa Biosciences GmbH, and the company has now over 10 full time employees and keeps growing. Two former coworkers are now heads of R&D in this company, and seeing the company flourish on its way to find cures against cancer is a major success that we would have not been able to foresee when we started the ERC COG.