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The need for new drugs became ever more apparent in the year 2020 when the world was faced with a viral pandemic. How drugs are discovered and their relevance to society became part of daily discussions in workplaces and homes throughout the world. Consequently, efficient strategies for preclinical drug discovery are clearly needed. 

The aim of this thesis has been to contribute to the drug discovery process by developing novel methods for fragment-based drug discovery (FBDD), a rapidly developing approach where success relies on access to sensitive and informative analytical methods as well as chemical compounds with suitable properties. This process is fundamentally dependent on the interplay between scientists and engineers across biology, chemistry and physics. 

This project is characterized by the development and implementation of novel biophysical methods over a series of studies, which are subdivided into: 1. Development of biosensor assays and approaches for challenging targets, 2. Discovery of fragments targeting dynamic proteins using biosensors, and 3. Reconstruction of ligands using fragment-based strategies.

A selection of diverse targets was used as challenging prototypes for the target agnostic methodologies described herein. The targets in focus were: acetylcholine-binding protein (AChBP), a soluble homologue of ligand gated ion channels, and two complex multi-domain epigenetic enzymes lysine specific demethylase 1 (LSD1) and SET and MYND domain-containing protein 3 (SMYD3). Expression, purification, engineering of protein variants, and biochemical characterization were required before robust screening strategies could be established.

Three types of biosensors, based on different time-resolved and very sensitive detection principles (SPR, SHG, GCI), were used to identify and characterize the kinetics of the interactions of novel fragments for the proteins. For SPR, a variety of multiplexed assays were designed for the screening of fragments against difficult targets. Notably, it led to the identification of an allosteric ligand and site in SMYD3, which was subsequently characterized kinetically and structurally using X-ray crystallography, and further evolved using computational approaches.

An innovative SHG assay for the specific detection of ligands inducing conformational changes was developed and used for fragment screening against AChBP. It revealed that fragments with a potential to serve as functional regulators of ligand gated ion channels can be identified using this technique. The combined application of the novel biophysical and computational approaches enabled the identification of useful starting points for drug discovery projects.

The work presented in this thesis describes how structural information about a protein can be acquired, and how it can be used to answer scientific questions about proteins’ function, their dynamic behaviour and their interactions with other proteins or ligands.

The catalytic function of the pyrimidine-degrading, drug metabolizing enzyme β-ureidopropionase (βUP) is dependent on the shift between oligomeric states. Substitution of amino acids H173 and H307 in the dimer-dimer interface and E207Q in the active site revealed that these are crucial for βUP activation. Inhibition studies of substrate-and product analogues allowed for a hypothesis that the ability to interact with F205 might distinguish activators from inhibitors. The first structure of the activated higher oligomer state of human βUP was determined using cryogenic electron microscopy, and confirmed that the closed entrance loop conformations and dimer-dimer interfaces are conserved between HsβUP and DmβUP. 

Interactions between the epigenetic drug target SET and MYND domain containing protein 3 (SMYD3) and possible inhibitors were investigated. A crystal structure confirmed the covalent bond of a rationally designed, targeted inhibitor to C186 in the active site of SMYD3. A new allosteric binding site was discovered using a biosensor screen with a blocked active site. Crystal structures revealed the location of the new binding site, and the binding mode of the (S)-and (R) enantiomers of the allosteric inhibitor. Lastly, a fragment based drug discovery approach was taken, co-crystallizing and soaking SMYD3 with hits from a fragment screen. This resulted in four crystal structures with weak electron density of fragments at several locations in the enzyme. 

The dynamic acetylcholine binding protein (AChBP) is a homologue of a Cys-loop type ligand gated ion channel. Hits from various biosensor screens, of which some indicated conformational changes, were co-crystallized with AChBP. Seven crystal structures of AChBP in complex with hit compounds from the biophysical screens were determined. Small conformational changes in the Cys-loop were detected in several of the crystal structures, coinciding with the results from the biosensor screens.

In these studies, we explore new strategies for the investigation of the function and regulation of proteins relevant in drug discovery and optimization.