Nature is a major source of inspiration for drug design. Bacteria are developing resistance towards conventional antibiotics. Utilizing... Show moreNature is a major source of inspiration for drug design. Bacteria are developing resistance towards conventional antibiotics. Utilizing antimicrobial peptides (AMPs) – an essential component of innate immune system, as therapeutic agents, may be a viable alternative. Unfortunately, there are a number of serious hurdles on the way towards clinical application of AMPs, including their low bioavailability, costly manufacturing process and toxicity against host cells. To address this issues, current research is focused on the design of synthetic compounds mimicking natural peptides, among which oligo(Nsubstituted glycines), or peptoids, have shown great promise. Antimicrobial drug efficacy is defined by how it interacts with the membrane of invading pathogen. The physicochemical characteristics of peptoid molecule play a crucial role in these interactions, yet their detailed structure-activity relationships remain obscure. Herein, we have demonstrated that conformational flexibility, cationic charge or hydrophobicity, are critical for oligomeric peptoids to permeate bacterial cell membranes. The outer surface of membrane was modeled by Langmuir monolayers of desired lipid composition and subjected to the constant-pressure insertion assays, epifluorescence microscopy (EFM), synchrotron X-ray reflectivity (XR) and grazing incident-angle X-ray diffraction (GIXD). Our results shed light on the critical details in peptoid mode of action. We believe this will aid in the rational design and of novel anti-infective drugs. Additionally, we have applied our experimental system to model the processes occurring at the air-water interface in lungs. Alveoli are coated by a complex lipidprotein mixture referred to as pulmonary surfactant. This facilitates respiration and prevents alveolar collapse. Patients with respiratory distress receive surfactant replacement therapy that often has the serious drawbacks. X-ray scattering data shows that the structural organization of adsorbed films correlates with surfactant delivery methods onto the respiratory surface. We anticipate that our findings will contribute to the development of novel clinical approaches for treating respiratory diseases. Ph.D. in Biology, May 2017 Show less