Download or read book Targeting the Initiating Proteases of the Complement System Using Structure-based Small Molecule Drug Discovery written by Denise Lauren Rohlik and published by . This book was released on 2023 with total page 0 pages. Available in PDF, EPUB and Kindle. Book excerpt: The complement system is an essential element of host development and immune homeostasis. This immunoregulatory enzyme cascade is driven by serine protease activation and plays critical roles in the recognition of danger signals associated with pathogens and damaged or apoptotic self-molecules. Due to its potent effector functions and ability to drive overwhelming innate and adaptive immune responses against a particular target, tight regulation is vital to prevent damage to host tissues. In the event of complement dysregulation, humans are known to become susceptible to an ever-growing number of autoimmune, inflammatory, and neurodegenerative disorders. A detailed understanding of the molecular mechanisms that drive protein function, and specifically complement activation, is fundamental to the design and development of specific complement-directed therapeutics. The complement system is comprised of three distinct pathways that differ in the molecular targets that drive pathway activation. The initiating proteases of the classical and lectin pathways are set apart from other serine proteases in that they undergo autocatalytic activation in the presence of a molecular trigger without necessitating extrinsic factors for full enzymatic activation. Using structural data derived from the enzyme-product complex of self-associated lectin pathway MASP-2 proteases, we elucidate the conformational changes that occur during autoactivation in the initiating proteases of the classical and lectin pathway. Our structural model provides an empirically derived alternative mechanism for autocatalysis that has not been previously described in the complement proteases. Using structural information derived from X-ray crystallography and autocatalysis as well as known interactions between bacterial inhibitors utilized for host complement evasion, we pursued multiple avenues for rational small-molecule drug design aimed at C1r and C1s, which are initiating proteases of the classical pathway. Molecular dynamics studies and chemical modification of compounds were used to guide the optimization and development of competitive small-molecule inhibitors against the active site of C1r. Structure-activity relationship data was generated through the bioisosteric replacement of chemical moieties of another lead compound to drive noncompetitive C1r inhibition. Moreover, advancements in technology building off protein-ligand interaction fingerprints derived from known structures were utilized in collaborative machine learning and artificial intelligence methods for the rational design of novel C1s inhibitors. Additional optimization of small-molecule compounds may ultimately lead to novel therapeutic options for diseases mediated by aberrant classical pathway activation. To aid in future endeavors in small-molecule drug screening and design, we developed a novel platform and methodology for evaluating targets outside of the complement system that requires the presence of lipid bilayers for activity. Using surface plasmon resonance, we established a bilayer model to mimic biological membranes to aid in protein characterization and screen for inhibitors capable of high affinity binding to the target surface as well as those that block protein association to the membrane, thereby inhibiting protein function. As such, biofunctional assays, such as surface plasmon resonance, can serve as powerful tools for aiding structure-based drug design strategies. Together, the structural insights gleaned from the enzyme-product complex of MASP-2, as well as surface plasmon resonance binding assays, allowed us to identify three small-molecule compound hits against both C1r and C1s using different methodologies and means of inhibition, validating differing strategies of inhibitor design. The identification of these hits, in addition to the development of a novel SPR screening platform, has led to the generation of in-depth structural data and method systems to guide future continued optimization efforts that may one day lead to the design of a small-molecule therapeutic option for diseases marked by autoimmune and inflammatory pathologies.