Lipid bilayers and their interactions with the antimicrobial peptide LL37: a TIR Raman study

Sammanfattning: As a direct consequence of the misuse of antibiotics since its first discovery, bacteria have developed extensive resistance mechanisms making them once again potential lethal threats. This eventuality has triggered a vast research effort from scientists worldwide to find solutions to mitigate antimicrobial resistance. One such option is the identification of new potential antimicrobial agents, like for example antimicrobial peptides (AMPs). Various methods have been applied to evaluate the properties and determine the complex mechanism of AMPs. However, the details of the mechanism remain unknown and hence the work in this project seeks to examine the suitability of using TIR Raman, a vibrational spectroscopy technique which is sufficiently surface sensitive to study the interaction of AMPs in contact with lipid bilayers, which are just a few nanometres thick. In order to evaluate the information that could be extracted from TIR Raman, measurement of solid supported lipid bilayers in the absence of peptides were first carried out. In particular, the lipid DMPC with a phase transition close to room temperature, was measured at various temperatures to determine spectral changes associated with the transition. For the peptide-membrane interactions, the AMP LL37 was put into contact with solid supported lipid bilayers modelling the cell membranes of bacteria (DOPE, DOPG) or humans (DOPC) respectively. The data clearly indicates that the membrane composition, and specifically the lipid head group charge, play an important role in the peptide-membrane interactions. In the bilayers mimicking bacteria cell membranes, the peptide either absorbed onto or inserted into the bilayer. In contrast, for the bilayer modelling a human cell membrane, no significant variations were detected, indicating no interaction with LL37. The findings presented in this work generally coincide with similar research of LL37 using other techniques. At hand of the herein presented data, TIR Raman has proven suitable and effective in detecting effects of antimicrobial peptides in contact with model lipid bilayers, and hence can be recommended for further studies.