Periodic Reporting for period 4 - complexNMR (Structural Dynamics of Protein Complexes by Solid-State NMR)
Berichtszeitraum: 2019-11-01 bis 2020-10-31
The overarching goal of complexNMR was to develop a multidisciplinary approach involving solid and solution state NMR complemented by modelling to enable direct atomic resolution determination of the structure, dynamics and interactions of protein domains in large biomolecular complexes. Our approach paves the way towards a more holistic understanding of many processes occurring in the cell by simplifying studies of proteins, not only as isolated entities but as components of interacting complex systems.
In order to maximize applicability of our methods we aim them to be feasible with very small amounts of proteins.
During the tenure of the project we have developed a general approach for measuring structure and dynamics of moderate size proteins in large complexes. We have developed a number of solid-state NMR methods that provide access to the structure, dynamics and interactions of proteins in large complexes. We have applied this methodology in a wide range complexes, especially in the context of systems involved in biosynthesis of antibiotics. We have used the insights from the structural studies to engineer biosynthetic machinery to make new compounds.
We have applied the developed approach in the context of integrated structural biology of protein complexes. In particular, we have studied the molecular level basis for specificity and directionality of antibiotic biosynthesis and modes of action for antibiotics. For example, we have elucidated the mechanism for chain termination in biosynthesis of enacyloxin, antibiotic active against multidrug resistant WHO priority pathogen Acinetobacter baumannii), and shown the suitability of the crucial to the process interaction between intrinsically disordered Short Linear Motif and beta-hairpin docking domain for engineering and creating hybrid systems to make new compounds (Nat. Chem. 2019, 11 (10), 913.). We have developed mechanistic understanding of the interactions between epimerisation domains and condensation domains in biosynthesis of antibiotic tyrocidine and further evaluated the suitability of the involved communication domains for protein engineering. A notable example of investigation for modes of action of antibiotic is our study on interactions of antibiotic teixobactin with the building block of bacterial wall, lipid II (Chem. Sci. 2018, 9 (47), 8850.), which has revealed that a composite fibril formation is behind the incredible efficiency of the antibiotic in question.